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Revisiting the value of polysomnographic data in insomnia: more than meets the eye
Journal Pre-proof Revisiting the value of polysomnographic data in insomnia: more than meets the eye Thomas Andrillon, Geoffroy Solelhac, Paul Bouchequet, Francesco Romano, Max-Pol Le Brun, Marco Brigham, Mounir Chennaoui, Damien Léger PII:
S1389-9457(19)31644-2
DOI:
https://doi.org/10.1016/j.sleep.2019.12.002
Reference:
SLEEP 4251
To appear in:
Sleep Medicine
Received Date: 19 September 2019 Revised Date:
22 November 2019
Accepted Date: 4 December 2019
Please cite this article as: Andrillon T, Solelhac G, Bouchequet P, Romano F, Le Brun M-P, Brigham M, Chennaoui M, Léger D, Revisiting the value of polysomnographic data in insomnia: more than meets the eye, Sleep Medicine, https://doi.org/10.1016/j.sleep.2019.12.002. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Elsevier B.V. All rights reserved.
Author Contribution Statement Conceptualization: TA, GS, DL; Data curation: GS, PB, FR, DL; Formal analysis: TA, GS, PB, MPLB, MB; Funding acquisition: DL; Investigation: TA, GS, PB, M-PLB, MB, DL; Methodology: TA, GS, PB, FR, M-PLB, MB, DL; Project administration: DL; Resources: DL, MC; Software: PB, GS, M-PLB, MB; Supervision: DL; Validation: DL; Visualization: TA, GS, PB; Roles/Writing - original draft: TA, GS, DL; Writing - review & editing: TA, GS, PB, FR, M-PLB, MB, MC, DL.
Highlights: - PSG allows to significantly differentiate good sleepers from subjects with insomnia. -
EEG spectrum and sleep microstructure reveal common physiological signatures of insomnia.
-
Insomnia seems characterized by increased cortical excitability during sleep.
-
AI classifiers allow to classify good sleepers from insomnia patients.
-
AI and PSG should be used more extensively in the diagnosis of insomnia
1
Revisiting the value of polysomnographic data in insomnia: more than
2
meets the eye
3 4
Thomas Andrillon a-b, Geoffroy Solelhac a-c*, Paul Bouchequet a-c*, Francesco Romano a-c,
5
Max-Pol Le Brund, Marco Brigham d, Mounir Chennaoui a-e & Damien Léger a-c.
6
a. Université de Paris, Equipe d'accueil VIgilance FAtigue SOMmeil (VIFASOM) EA 7330,
7
Paris, France;
8
b. School of Psychological Sciences and Turner Institute for Brain and Mental Health,
9
Monash University, Melbourne, Victoria, Australia
10
c. Assistance Publique-Hôpitaux de Paris (APHP) Hôtel Dieu, Centre du Sommeil et de la
11
Vigilance, Paris, France
12
d. Ecole Polytechnique, Centre de mathématiques appliquées (CMAP), Palaiseau, France
13
e. Institut de recherche biomédicale des armées (IRBA), Brétigny-sur-Orge, France
14
*: equal contribution,
15 16
Corresponding authors: [email protected]
17 18 19 20
1
21
Abstract (max. 250)
22
BACKGROUND: Polysomnography (PSG) is not recommended as a diagnostic tool in
23
insomnia. However, this consensual approach might be tempered in the light of two ongoing
24
transformations in sleep research: big data and artificial intelligence (AI).
25 26
METHOD: We analyzed the PSG of 347 patients with chronic insomnia, including 59 with
27
Sleep State Misperception (SSM) and 288 without (INS). 89 good sleepers (GS) were used as
28
controls. PSGs were compared regarding: (1) macroscopic indexes derived from the
29
hypnogram, (2) mesoscopic indexes extracted from the electroencephalographic (EEG)
30
spectrum, (3) sleep microstructure (slow waves, spindles). We used supervised algorithms to
31
differentiate patients from GS.
32 33
RESULTS: Macroscopic features illustrate the insomnia conundrum, with SSM patients
34
displaying similar sleep metrics as GS, whereas INS patients show a deteriorated sleep.
35
However, both SSM and INS patients showed marked differences in EEG spectral
36
components (meso) compared to GS, with reduced power in the delta band and increased
37
power in the theta/alpha, sigma and beta bands. INS and SSM patients showed decreased
38
spectral slope in NREM. INS and SSM patients also differed from GS in sleep microstructure
39
with fewer and slower slow waves and more and faster sleep spindles. Importantly, SSM and
40
INS patients were almost indistinguishable at the meso and micro levels. Accordingly,
41
unsupervised classifiers can reliably categorize insomnia patients and GS (Cohen’s =0.87)
42
but fail to tease apart SSM and INS patients when restricting classifiers to micro and meso
43
features ( =0.004).
44 45
CONCLUSION: AI analyses of PSG recordings can help moving insomnia diagnosis beyond
46
subjective complaints and shed light on the physiological substrate of insomnia.
47 48
2
49 50 51
Highlights: - PSG allows to significantly differentiate good sleepers from subjects with insomnia. -
EEG spectrum and sleep microstructure reveal common physiological signatures of insomnia.
52 53
-
Insomnia seems characterized by increased cortical excitability during sleep.
54
-
AI classifiers allow to classify good sleepers from insomnia patients.
55
-
AI and PSG should be used more extensively in the diagnosis of insomnia
56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72
Keywords: Artificial intelligence-machine learning-insomnia-polysomnography-REM-NREM sleepsupervised classification Abbreviations NREM: Non-Rapid Eye Movement REM: Rapid Eye Movement PSG: Polysomnography AI: Artificial Intelligence ML: Machine Learning EEG: Electroencephalography CI: Chronic Insomnia SSM: Sleep State Misperception SOL: Sleep Onset Latency TST: Total Sleep Time: WASO: Wake After Sleep Onset
73 74 75
Acknowledgements This work was supported by the Banque Publique d’Investissement (BPI) supporting the
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MORPHEO project associating three partners: RHYTHM (Paris, France); Université Paris
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Descartes (Paris, France) and Ecole Polytechnique (Palaiseau, France). TA is supported by
78
the International Brain Research Organization (IBRO), the Human Frontiers Science Program
79
(HFSP, LT000362/2018) and the Australian National Health and Medical Research
80
(NHMRC, ECF-APP11614980).
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3
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Introduction
83
Sleep is a need, like eating or breathing [1,2]. Yet, we are not equal in the face of sleep
84
and some individuals have a hard time fulfilling this basic physiological imperative [3,4]. In
85
particular, individuals suffering from Chronic Insomnia (CI, here referred as “insomnia”) are
86
characterized by difficulties in initiating or maintaining sleep and/or a chronic sensation of
87
non-restorative sleep. The associated sleep deficit has substantial daytime consequences,
88
notably in terms of well-being, productivity and health [5]. Insomnia is the most common
89
sleep disorder and affects between 10 and 20 % of the general population of industrialized
90
countries [6,7], which makes it a major public health concern. Accordingly, insomnia has
91
been associated with a broad range of comorbidities: it has been linked to an increased risk of
92
cardiovascular diseases or diabetes [8–13], psychiatric disorders (anxiety, depression, suicide)
93
[11,14], cognitive impairments and neurodegenerative disorders [11,15,16].
94
There is a growing literature on the physiological underpinnings of insomnia (see [17–
95
19] for reviews). Yet, contrary to other sleep disorders, insomnia is almost never diagnosed or
96
assessed via objective physiological recordings. This is particularly striking when considering
97
that sleep is usually described as a phenomenon “of the brain, by the brain, for the brain”
98
[20]. The main reason advanced is that PSG recordings are costly and often fail to reveal
99
sleep anomalies despite clear subjective complaints of CI [19]. Besides, it is unclear if
100
clinicians would treat patients differently with the additional information from PSG
101
recordings. Indeed, the most consensual therapy of insomnia, the so-called cognitive
102
behavioral therapy (CBT), is based mostly on subjective assessments of sleep quality and
103
quantity by patients themselves [21]. Finally, it has been argued that a single night of PSG
104
recordings is not enough to assess insomnia. Phenomena like the “first night effect” (FNE, i.e.
105
deterioration of sleep when sleeping in a new environment, like a sleep clinic [22]) are
106
regularly observed in good sleepers but can be often reversed in individuals with insomnia
107
[23], questioning the reliability of PSG recordings as a diagnostic tool for insomnia.
108
Consequently, the 3rd edition of the International classification of sleep disorders
109
(ICSD-3) [24] recommends a diagnosis of insomnia purely based on subjective complaints. In
110
this framework, CI severity is assessed by self-report questionnaires like the Pittsburgh Sleep
111
Quality Index (PSQI) or the Insomnia Severity Index (ISI) [25,26]. PSG recordings are
112
specifically limited to rule out comorbidities commonly associated with insomnia such as
113
sleep apnea (OSA) or periodic leg movements (PLM).
4
114
The limited use of PSG recordings in the diagnosis of insomnia could stem from the
115
notoriously noisy relationship between subjective and objective estimates of sleep duration
116
and sleep quality [19], although it could be argued that these discrepancies are precisely what
117
makes PSG valuable since it provides complementary information to subjective reports. The
118
largest objective epidemiological survey on insomnia, made in 1042 inhabitants of Sao Paulo
119
Brazil, reported that only 35% of subjects with an ICSD-3 diagnosis of insomnia had a PSG
120
confirming insomnia [27]. In addition, 23% of those who declare themselves good sleepers
121
matched the PSG insomnia criteria [27]. The case of the so-called Sleep State Misperception
122
(also referred to as “paradoxical insomnia”) is particularly telling as, in such cases, there is a
123
direct contradiction between the subjective complaints of insomnia and the visual inspection
124
of PSG recordings by sleep experts [28,29]. Importantly, even if insomnia patients with SSM
125
do not show signs of a significantly degraded sleep, they still feel they have poor sleep and do
126
present the daytime consequences of insomnia, which argues in favor of retaining the
127
subjective complaints and sometimes discarding the information extracted from PSG
128
recordings.
129
Nonetheless, previous research has evidenced robust markers of insomnia within PSG
130
recordings. For example, the spectral decomposition of the EEG signal allows tracking neural
131
dynamics across vigilance states and evidenced differences between good sleepers and
132
insomnia patients [30–33]. The discovery that insomnia is associated with heightened levels
133
of high-frequency activity during sleep [30], a rhythm typically associated with wakefulness,
134
supports the “hyperarousal model” of insomnia [17], that is the notion that individuals
135
suffering from insomnia are hypersensitive to perturbations, notably during their sleep. Others
136
have found increased levels of alpha oscillations during sleep, another wakeful pattern of
137
brain activity that normally disappears during sleep [34]. Sleep also appears more fragile in
138
insomnia: with more frequent micro-arousals [35] and the preservation of neural signatures of
139
light sleep during deeper sleep stages [36]. This sleep fragility could be due to an increased
140
sensitivity to external [39–41] or internal perturbations [42], according to the hyperarousal
141
model. The fact that attentional networks seem more activated during sleep in insomnia
142
patients [37,38] could explain this increased sensitivity to external and internal perturbations.
143
PSG recordings also play a central role in the evaluation of insomnia treatments. Drug
144
agencies, like the American Food and Drug Agency (FDA) require positive evidence from
145
PSG studies to release new hypnotics [39]. The European Medicines Agency (EMA)
146
guidelines [19,40] for assessing insomnia treatments consider PSG recordings “helpful” to
5
147
diagnose insomnia and while drug efficacy is based on “clinically relevant improvement of
148
subjective parameters”, the agency recommends to support these changes with objective data.
149
In addition, PSG data is mandatory for new treatments’ proof of concept.
150
However, even if PSG data contain clinically relevant information regarding insomnia,
151
it does not necessarily imply its use is relevant in clinical settings. PSG are still a costly, time-
152
consuming medical examination, both regarding its acquisition and analysis. Yet, rapid
153
evolutions in the field of Sleep Medicine might offer ways to overcome these practical
154
limitations. First, technological improvements make it now possible to easily and
155
inexpensively record high-quality data at home, for multiple nights, with minimal impact on
156
patients’ life and sleep [41,42]. Second, recent progress in artificial intelligence and machine
157
learning have rendered the analysis of large, multi-modal datasets more efficient and
158
clinically relevant [43,44]. In sleep medicine, such techniques have already transformed the
159
evaluation of PSG recordings and the detection of specific sleep disorders [44–48]. We aim at
160
showing here how similar tools can be applied to insomnia. First, we show it is possible to
161
streamline the analysis of PSG recordings with minimal human intervention. Second, by
162
devising automated, unbiased and exhaustive analyses of physiological data, we propose a
163
reassessment of the benefits and costs of PSG recordings in the context of insomnia.
164
To revisit the value of physiological data for the diagnosis and understanding of
165
insomnia, we undertook a comprehensive analysis of a large dataset of PSG recordings,
166
acquired in a classical clinical setting. Indeed, in the past few years, our sleep clinic (Center
167
for Sleep and Vigilance of the Hôtel-Dieu Hospital in Paris) changed its clinical management
168
of insomnia patients and propose a PSG to all referred patients with a complaint of insomnia
169
lasting for at least 5 years. We present here an analysis of the comparison of these PSG
170
recordings with good sleepers, deprived of insomnia symptoms. In particular, we focused on a
171
multi-level analysis of PSG recordings. We examined classical hypnogram-based metrics of
172
sleep quality and quantity, coupled with the analysis of EEG spectral decomposition and sleep
173
microstructure (sleep spindles and slow waves). We further investigated how advanced
174
analyses of PSG recordings can help the diagnosis of insomnia in difficult cases such as
175
patients with SSM. Most importantly, we aimed at understanding how discrepancies between
176
objective and subjective assessments of sleep can be resolved through a more in-depth
177
analysis of PSG data.
178
6
179
METHODS
180
Participants
181
In this study, we analyzed PSG recordings from 347 patients suffering from insomnia. These
182
patients were selected retrospectively, following their visit to the Center for Sleep and
183
Vigilance of the Hotel-Dieu Hospital in Paris (France). All the patients included in this study
184
complained of CI for at least five years according to ICSD-3 criteria [19]. As part of their
185
clinical assessment, these patients were proposed to undergo an ambulatory or laboratory
186
PSG, whether or not comorbidities were suspected. All diagnoses were delivered by the
187
medical doctors affiliated with the Center, independently of this retrospective study.
188
Patients were diagnosed with CI according to the ICSD-3 criteria [24], i.e. whenever they
189
reported (i) difficulties initiating sleep or sleep onset latency (SOL) ≥ 30 minutes, or (ii)
190
difficulty maintaining sleep and/or early-morning awakenings (iii) at least three times a week,
191
(iv) since at least three months and (v) with consequence on daytime activities.
192
Patients were further screened for comorbidities through a visual inspection of the PSG
193
recordings and according to the guidelines of the American Academy of Sleep Medicine
194
(AASM) [45]. We excluded patients with a diagnosis of OSA (i.e. patients with a Respiratory
195
Disturbance Index (RDI) >10) or a diagnosis of PLM disorder (criterion: >10/hour).
196
We focused here on two subtypes of primary insomnia: patients with or without SSM, also
197
respectively referred as “objective” and “subjective” insomnia in the literature.
198
Insomnia without SSM:
199
The so-called “objective” nature of insomnia was confirmed by examining PSG recordings to
200
rule out a significant case of SSM, that is a discrepancy between patients’ reports of sleep
201
quantity and quality and the quantification of sleep quantity and quality via PSG. Patients
202
with at least one of the following PSG criteria were diagnosed with insomnia without SSM:
203
SOL > 30 minutes, Wake After Sleep Onset (WASO)> 30 minutes, Total Sleep Time (TST) <
204
360 minutes [19,27]. These patients are referred to as the INS group throughout (N=288
205
patients; age: 45.7 ± 0.84 (mean ± Standard-Error of the Mean or SEM); sex ratio: 0.46).
206
Insomnia with SSM:
207
Patients with SSM were diagnosed based on (i) a subjective complaint of Chronic Insomnia
208
for at least five years according to the ICSD-3 criteria and (ii) the absence of objective criteria
7
209
of insomnia in PSG recordings (SOL ≤ 30 minutes, WASO ≤ 30 minutes, and TST ≥ 360
210
minutes [22]). These patients are referred to as the SSM group throughout (N=59; age: 39.4 ±
211
1.55; sex ratio: 0.31).
212
Treatments:
213
Patients were not asked to suspend their treatment for the night of PSG. Out of 347 patients,
214
we had access to treatment information in 335 patients (12 patients with missing data). 132
215
patients were taking benzodiazepines or benzodiazepine-like drugs (40% of INS patients;
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29% of SSM patients); 73, antidepressants (INS: 19%; SSM: 29%); 35, melatonin (INS: 10%;
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SSM: 9%); 17, antihistamines (INS: 5%; SSM: 3%) and 154 had no treatment.
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Controls:
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Patients were compared to individuals who did not report any sleep disorder and who were
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considered good sleepers (GS) after reviewing their PSG recordings. These individuals were
221
originally recruited as part of research protocols conducted in the same sleep clinic. All these
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control subjects underwent one night of baseline PSG at the clinic or at home (similarly as
223
patients). This baseline night, identical for all individuals and not affected by the details of
224
each research protocol, was analyzed and compared to patients. Based on PSG recordings, we
225
further discarded individuals with OSA or PLM. 100 individuals were reviewed and 89 good
226
sleepers were retained as controls (age: 34.5 ± 1.33; sex ratio: 3.68).
227 228
PSG recordings
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PSG were performed according to the AASM guidelines [46] and included: (i) at least 3 and
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usually 6 electroencephalographic (EEG) derivations at frontal (F3/F4), central (C3/C4) and
231
occipital (O1/O2) sites and referenced to the contralateral mastoid, (ii) 2 electrooculographic
232
(EOG) derivations and, (iii) 3 electromyographic (EMG) derivations placed on the chin (N=1)
233
and legs (N=2). Respiratory parameters (respiratory flow, thoracic and abdominal bands,
234
oxygen saturation), as well as body movements (position sensor and the 2 leg EMG
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derivations placed on the left and right tibial muscles), were also systematically recorded in
236
order to exclude individuals with OSA and PLM syndromes.
237
Different recording devices were used in this study, all validated and routinely used in our
238
sleep clinic: the NOX-A1 (Nox Medical), ACTIWAVE (CamNTech LTd), MORPHEUS
8
239
(Micromed S.p.A.) and SOMNOLOGICA (Medcare). INS patients were recorded with NOX-
240
A1 (N=284) and MORPHEUS (N=4) devices. SSM patients with NOX-A1 (N=59) devices
241
and good sleepers with NOX-A1 (N=6), ACTIWAVE (N=73) and SOMNOLOGICA (N=10)
242
devices.
243
Sleep scoring and sleep markers identification
244
Immediately after the completion of the night recording, PSG data were visually examined
245
and scored according to the AASM guidelines [47] to establish individual hypnograms. We
246
also identified arousals, leg movements and respiratory events. Arousals were defined as an
247
acceleration of the EEG for epochs between 3 and 15 seconds. This visual scoring was
248
performed by a medical doctor specialized in sleep medicine. In practice, 30-s-long epochs
249
including EEG (referenced to the mastoids), EMG and EOG data were scored as wakefulness
250
(W), NREM stage 1 (N1), NREM stage 2 (N2), NREM stage 3 (N3) and REM sleep (REM).
251
In addition to this initial sleep scoring and as part of this retrospective study, all files were
252
blindly scored again by the same sleep technician (F.R.), with more than 5 years of
253
experience in sleep medicine, to ensure the homogeneity of the sleep scoring across the entire
254
dataset. From this second scoring, we extracted classical parameters from individual
255
hypnograms reflecting the macro-structure of sleep: TTS, WASO, SOL, duration of each
256
sleep stage, number and density of arousals, etc (see Table 1). Sleep cycles were also visually
257
identified based on the hypnogram. No specific detection of physiological or non-
258
physiological artefacts was performed beyond the ones relevant to establish a diagnosis.
259
Based on the hypnograms, we also computed state-transition matrices for each night (Fig. 1),
260
by looking at how sleepers transit from one sleep stage to another. To do so, we considered
261
the individual hypnograms obtained on 30-s-long epochs. For each epoch, we computed the
262
transition probability by considering the sleep stage of the following epoch. We then
263
computed the proportion (probability) of each state transition. Figure 1 shows the resulting
264
transition matrices.
265
Identification of sleep disorders
266
The same expert (F.R.) visually identified markers of sleep disturbances. Occurrences of
267
apnea (respiratory flow below 10% for more than 10 seconds) and hypopnea (>30% decrease
268
in respiratory flow associated with arousal or oxygen desaturation of more than 3% and for
269
more than 10 seconds) were marked. For each apnea and hypopnea event, thoracic and
9
270
abdominal bands were used to categorize these events as ‘central’, ‘obstructive’ or ‘mixed’.
271
Leg periodic movements were identified and marked whenever 4 leg movements were
272
observed over a period of 90s. All these markers of sleep disturbances were then quantified
273
and the diagnosis of OSA or PLS was established based on existing guidelines [24]. All
274
individuals with OSA and PLS were excluded from our analyses.
275
REM sleep and Rapid Eye-Movements.
276
The AASM guidelines do not propose a subdivision of REM sleep but previous studies
277
sometimes distinguish between phasic (REM sleep epochs with at least one Rapid-Eye
278
Movement on the EOG derivations) and tonic (REM sleep without Rapid-Eye Movement)
279
REM sleep [48,49]. Rapid Eye-Movements in REM sleep have been associated with sleep
280
depth, sensory isolation [48,50] and oneiric activity [51,52]. To examine whether insomnia
281
was associated with a change in REM physiology and its associated oculographic activity, we
282
visually identified Rapid Eye-Movements using the 2 EOG derivations. A REM was defined
283
as an initial deflection in the EOG signal of less than 0.5 seconds, with phase opposition
284
between the 2 EEG channels [51]. For each recording, we computed the total number of
285
REMs and density of REMs (number of REMs/minutes spent in REM). We also computed
286
the number and duration of individual REM epochs.
287
Automatic detection of sleep spindles, K-complexes and slow waves
288
NREM sleep stages 2 and 3 are characterized by the presence of specific patterns of brain
289
activity [53,54]. These NREM sleep hallmarks are slow waves and K-complexes (large-
290
amplitude [1-4]Hz waves occurring in isolation or train) and sleep spindles (waxing-and-
291
waving [11-16]Hz oscillations lasting for 0.5 to 2.5s). To detect slow waves, K-complexes
292
(both here referred as slow waves) and sleep spindles, and to extract relevant parameters from
293
individual events, we relied on previously published algorithms [55–58].
294
In short, the detection of slow waves was performed by first filtering the EEG mastoid-
295
reference signal between 0.2 and 3Hz (zero-phase Finite Impulse Response (FIR) filter).
296
Individual waves were identified as the interval between two descending zero-crossing. Only
297
waves with a down-state duration (negative half-wave period) between 0.25s and 1s, and a
298
peak-to-peak amplitude above 75 V were identified as slow waves. For each of these slow
299
waves, we extracted the following parameters: wave frequency (1/wave duration), peak-to-
10
300
peak amplitude and positive slope (slope from the down-state to the up-state of the slow
301
wave).
302
Sleep spindles were likewise detected by first filtering the mastoid-referenced EEG signal
303
between 11 and 16Hz (zero-phase FIR filter). From the filtered signal, we extracted the
304
Hilbert envelope, which gives an estimate of instantaneous power within the [11-16]Hz range.
305
A threshold corresponding to the median envelope voltage + two standard-deviations (median
306
+ 2 SD, computed on 30-s-long epochs) was computed and used to identify epochs of high
307
spindle power. The beginning and end of each high spindle-power epoch were further
308
determined using a more liberal threshold (median +1 SD) and these epochs were considered
309
spindle candidates. Spindle candidates within 500ms were aggregated. These candidates were
310
considered sleep spindles if: (i) their duration was comprised between 0.5 and 2.5s, (ii) they
311
were not concomitant with large increases in high-frequency power ([60-90]Hz) typically
312
associated with artifacts, (iii) they did not cross a median + 10 SD threshold (also typically
313
associated with artifacts). For each of these detected spindles, we then extracted the following
314
parameters: the maximal amplitude (of the [11-16]Hz envelope), duration and frequency. The
315
spindle frequency was estimated using a Fast-Fourier Transform (FFT) on a 1-s-long window
316
centered on the peak in spindle power (resolution: 1Hz).
317
For both the slow wave and sleep spindle detection, only events detected in NREM2 and
318
NREM3 were analyzed. We applied the detection algorithms to central and frontal derivations
319
(C3, F3 or C4, F4) independently. Slow waves and spindles detection algorithms were
320
implemented in Python and used the MNE toolbox [59,60]
321
Spectral analysis
322
The EEG signal is classically described as resulting from the superposition of neural
323
oscillations [54]. To quantify these different rhythms, we performed a spectral decomposition
324
of the EEG signal. The EEG spectrogram was obtained by applying an FFT to 30-s-long
325
epochs of mastoid-referenced EEG data using the “eegkit” package in R. We then computed
326
the relative power within the [0.5-20]Hz range by dividing the power in each frequency bin
327
with the sum of power values between 0.5 and 20Hz (step: 0.5Hz). The relative power was
328
expressed as a percentage.
329
We applied a supervised classification approach for each frequency bin (Fig. 2a) in order to
330
evidence which frequency bins can differentiate between the 3 groups of sleepers (see
331
following section for the details of the training and testing of the classifiers). This procedure 11
332
was applied to the power spectrum averaged across NREM and REM epochs separately and
333
for each individual. We computed the ROC (Receiver Operating Characteristic) curve area
334
(chance level: 0.5; perfect performance: 1) to quantify the classifiers’ performance. We
335
repeated the supervised classification 100 times to estimate the variability of the performance
336
estimate. Cluster-permutations (see below) were used to compare the distribution of the
337
classifiers’ performance (across the different frequency bins) to chance (0.5) or between
338
NREM and REM sleep.
339
To examine how the EEG power was modulated across groups and throughout the night, we
340
binned NREM and REM epochs (N=51 bins) from the beginning (0) to the end of the night
341
(100%). Bonferroni-corrected ANCOVAs and cluster permutation were used to identify the
342
time-windows and frequency bands significantly modulated across groups (Fig. 2b).
343
The EEG signal is not only composed of periodic oscillations but also contains aperiodic
344
activity constituting the background EEG activity upon which neural oscillations develop
345
[61]. Recent work has stressed the relevance of such aperiodic activity and developed means
346
to quantify the strength of the aperiodic component of the EEG spectrum [62–64]. To
347
examine whether insomnia was associated with changes in aperiodic activity, we computed
348
the slope of the spectrum’s 1/f trend, an index of aperiodic activity. The slope of the EEG
349
spectrum was computed via the FOOOF (Fitting Oscillations and One-Over-F) package for
350
Python [61]. In short, the average EEG spectrum for a given recording and sleep stage was
351
obtained by averaging the FFT power spectrum computed over all the 30-s-long epochs for
352
this sleep stage and recording. A first aperiodic fit was then computed for the average power
353
(P=f-s, where P is the power, f the frequency and s the slope, a variable parameter). This initial
354
fit was removed, evidencing deviations from the aperiodic background (i.e. peaks
355
corresponding to the different periodic oscillations). Each peak was modeled as a Gaussian.
356
The Gaussian fits were then used to remove the periodic peaks from the original spectrum and
357
a second aperiodic fit was performed to obtain an approximation of the spectrum without the
358
periodic activity (peaks). The slope of this second fit was used to estimate the slope of the
359
aperiodic spectrum.
360
Supervised classification
361
To determine whether features extracted from PSG recordings are predictive of insomnia and
362
insomnia sub-types, we tried to classify individuals in clinically-relevant diagnostic categories
12
363
using supervised classifiers. This supervised classification was performed in R using the caret
364
package (Classification And REgression Training).
365
Since our main goal was here to check whether quantitative analyses of PSG recordings could
366
help the diagnosis of insomnia, we trained and tested classifiers focusing on different
367
contrasts. The first classifier was trained to predict two categories of individuals (2-class
368
classifier): controls (good sleepers, GS) vs. patients with CI (with or without SSM:
369
SSM+INS). We then sought to determine if the classifier could also distinguish insomnia
370
subtypes by training a classifier on our three different groups (GS vs. SSM vs. INS). Finally,
371
we examined if a classifier could distinguish between patients with CI using 2-class classifiers
372
trained on SSM and INS patients.
373
In addition to the number and definition of the groups to classify, we also varied the type of
374
data provided to the classifiers. The first type of classifiers (“visual” or “V” in Fig. 6) was
375
trained on features extracted from the hypnogram and thus obtained via a visual inspection of
376
PSG recordings (TST, total bed-time, sleep efficiency, WASO, duration and proportion of
377
time spent in each stage, micro-arousals, probability transition between stages, etc.). These
378
features correspond to the macroscopic features detailed above. The second type of classifiers
379
(“computed” or “C” in Fig. 6) was trained on features computed from the EEG recordings,
380
including meso (spectral features) and microstructural (slow waves, sleep spindles) variables.
381
Finally, we also trained classifiers on all features combined (“V+C” in Fig. 6).
382
Each classifier was trained and tested in the same way. We first split PSG recordings into a
383
training set (80% of the data) and a test set (remaining 20%). As there is 1 PSG recording per
384
patient, the training and test sets were disjoint groups of patients. The classifier was trained on
385
the training set using a Random Forest approach. A 3-fold cross-validation was performed to
386
select the classifier’s hyper-parameters. This procedure was repeated 10 times, each time with
387
a new random split. The model with the best hyper-parameters was then used to train the
388
classifier on the entire training set. Once the classifier was trained, we tested it on the test set,
389
which, importantly, was not used to train the classifier. We then compared the labels
390
predicted by the classifier with the real labels (e.g. INS, SSM or GS). The same methodology
391
was used for the classification of the EEG power spectrum per frequency bin (Fig. 2a, single-
392
feature classifiers) across the INS, SSM and GS groups.
393
Since the groups to predict are not equal, we computed either ROC (Receiver Operating
394
Characteristic) curve area (chance level: 0.5) or Cohen’s κ (chance level: 0) to quantify the
13
395
classifiers’ performance. A negative or null κ means that the classifier is not performing
396
above chance. The more the κ value is close to 1, the better the classifier is able to retrieve the
397
original labels of each individual recording. In order to better estimate the variability in the
398
classifiers’ ability to predict individuals’ clinical labels, we repeated this procedure 100 times
399
for each classifier. We plot in Fig. 6 the resulting distribution of κ values (N=100) as well as
400
the average confusion matrices over these 100 iterations. Finally, for each model we retrieved
401
the Variable Importance (VI) for each feature, which describes how important the feature is
402
for the classification. These VI values are shown for the top-20 features (i.e. the ones with the
403
highest VI values) for each model in Table 2.
404
Statistics
405
All statistical analyses were performed in Matlab. We examined group-effect (modulations
406
across the INS, SSM and control groups) using an Analysis of Covariance (ANCOVA). The
407
INS, SSM and control groups were used as a categorical predictor. We also included the age
408
and gender of participants as covariates. Bonferroni correction was used to account for
409
multiple comparisons. We used unpaired t-tests for post-hoc comparisons.
410
When comparing groups across time (Fig. 2), we relied on a cluster-permutation approach
411
[65]. For each time-point, we estimated the group-effect using an ANCOVA (covariates: age
412
and gender). We then identified clusters of time-points crossing a given uncorrected statistical
413
threshold (p<0.05). For each cluster, we computed the sum of the F-values associated with the
414
group-effect, for all the samples within the cluster. A surrogate dataset was obtained by
415
repeating this procedure when permuting the group labels across subjects (1000
416
permutations). We then compared the cluster statistics (sum of F-values) of the original
417
dataset with the maximum cluster statistics of the 1000 random permutations. The position of
418
the cluster statistics within the surrogate dataset was used to estimate the significance of the
419
cluster, allowing us to compute a nonparametric Monte-Carlo p-value (pcluster) for that
420
particular cluster.
421
Ethics
422
This research was conducted according to the principles expressed in the Declaration of
423
Helsinki of 1975, revised in 2001. The retrospective analysis of PSG data of patients and
424
controls was approved by the local ethics committee (Comité de Protection des personnes
425
(CPP) Ouest IV, from Nantes, France). Patients data were anonymously analyzed according
14
426
to legal requirements (Commission Informatique et Liberté (CNIL) from the French
427
Government).
15
428
RESULTS
429
We investigated how PSG recordings differ between the three groups of sleepers: patients
430
diagnosed with insomnia but without SSM (INS group), patients with insomnia and SSM
431
(SSM group) and Good Sleepers (GS group). As previously explained in the Methods section,
432
we extracted various features from PSG recordings. First, we extracted classical summary
433
statistics derived from the hypnograms obtained after visual scoring of the PSG (which we
434
termed “macroscopic” features); then features extracted from the spectral decomposition of
435
the EEG data (“mesoscopic” features) to capture changes in sleep/wake oscillations across the
436
three groups; finally, key graphoelements characteristic of either NREM (slow waves, sleep
437
spindles) and REM (eye-movements) sleep were compared across groups (“microscopic”
438
features). The macro-, meso-, and microscopic features were then aggregated and used to
439
train a supervised ML algorithm to classify patients in the three groups.
440
Hypnogram-based macroscopic features confirm the sub-phenotyping of insomnia
441
patients with and without SSM
442
When first comparing hypnograms of sleepers using classical metrics of sleep quantity and
443
quality (Table 1), we confirmed that patients diagnosed with insomnia but without SSM spent
444
less time asleep than good sleepers (TST: 361 min ± 5.1 (mean ± SEM) vs. 406 min ± 5.4;
445
unpaired t-test: p=4.0.10-6) and had a decreased sleep efficiency (72.0% ± 0.8 vs. 79.7% ±
446
1.1; unpaired t-test: p=2.1.10-6). Even when taking into account differences in total sleep time,
447
patients from the INS group spent a larger proportion of time awake during the night (27.8%
448
± 0.8 vs. 20.3% ± 1.1; unpaired t-test: p=4.1.10-6) and less time in NREM2 (41.7% ± 0.7 vs.
449
47.1% ± 0.9; unpaired t-test: p=3.8.10-5) as well as REM sleep (12.9% ± 0.3 vs. 15.0% ± 0.5;
450
unpaired t-test: p=0.001). The reduction in NREM2 was observed throughout the night (Fig.
451
1, top; unpaired t-tests: p<0.005 for both 1st and 2nd halves of the night) whereas the
452
decrease in the proportion of REM sleep was observed only in the end of the night (p=0.003).
453
These results confirm the rather archetypal profile of the patients from the INS group.
454
However, the same features failed to evidence any sleep disturbance in the insomnia group
455
with SSM. These patients appeared to actually sleep better than controls, with increased sleep
456
efficiency (88.4% ± 0.8 vs. 79.7% ± 1.1; unpaired t-test: p=2.4.10-8), decreased proportion of
457
wakefulness during the night (11.7% ± 0.8 vs. 20.3% ± 1.1; unpaired t-test: p=2.2.10-8) and
458
increased proportion of NREM3 stage (19.5% ± 1.2 vs. 15.1% ± 0.7; unpaired t-test:
459
p=4.4.10-4). Yet, based on subjective complaints, these patients were diagnosed with
16
460
insomnia. Contrary to previous reports, both INS and SSM patients did not show a significant
461
increase in the density of arousals in REM or NREM sleep when correcting for multiple
462
comparisons (Table 1).
463
We further examined the dynamics of individual nights. Using ANCOVAs, we examined the
464
interactions between the part of the night (1st vs. 2nd half) and individuals’ group and found a
465
significant interaction only for NREM3 (Bonferroni correction, p=8.45.10-7). This interaction
466
seems driven by INS patients who show less NREM3 in the beginning of the night compared
467
to controls and SSM patients but more NREM3 in the second part of the night (Fig. 1a). There
468
was no other significant interaction in other sleep stages (after Bonferroni correction)
469
suggesting that other group-effects are stable throughout the night.
470
We also examined how sleepers dynamically transit from one sleep stage to another by
471
looking at the transition probabilities derived from each hypnogram (Fig. 1, bottom; see also
472
Methods). There was a significant difference in how sleepers transit from stage NREM2 and
473
wakefulness (ANCOVA: p<10-6). The effect on the transition from NREM2 seemed mostly
474
driven by the INS group showing an unstable NREM2 stage (less NREM2-to-NREM2
475
transitions compared to controls: unpaired t-test p=2.3.10-5). The SSM group differed from
476
both INS and control groups by the tendency of these individuals to transit more from
477
wakefulness to NREM2 (wake-to-NREM2 transition compared to controls: p=5.2.10-8). These
478
rapid and frequent transitions to deeper stages of NREM sleep illustrate well the SSM
479
paradox, whereby subjective complaints contrast with a better-than-usual transition to sleep.
480
Features derived from the EEG spectrum show common differences between INS and
481
SSM patients compared to good sleepers
482
In this first level of analysis, examining macroscopic features extracted from the hypnograms
483
show that individuals from the SSM group were much more similar to good sleepers than
484
other insomnia patients (INS group). Yet, based on subjective complaints, SSM patients were
485
diagnosed with CI. To overcome this paradox, we set out to analyze in more depth PSG
486
recordings. First, we computed and examine the spectral decomposition of the EEG signal on
487
30-s-long windows (Fig. 2). We termed the output of this spectral decomposition mesoscopic
488
features as it represents a level of analysis between hypnogram-based macroscopic features
489
(summarizing an entire night) and sleep micro-structure (spindles, slow waves; time scale of
490
~1s).
17
491
To examine whether the power in certain frequencies could distinguish across clinical groups,
492
we used a supervised classifier approach. We trained a classifier on a subset of data and on a
493
single feature (relative power for a given frequency in REM or NREM sleep) to categorize
494
patients into our three clinical groups (INS, SSM and controls; see Methods for details). We
495
then tested the trained classifier on the remaining data, not included in the training set. The
496
performance of the classifier (quantified as the ROC area, see Methods) was then used as a
497
proxy to determine to what extent a given frequency band can discriminate individuals across
498
clinical groups. Values higher than 0.5 denote above-chance performance. Importantly, this
499
approach does not rely on the a priori definition of frequency bands of interest.
500
The results indicate that in both NREM and REM sleep, individual recordings can be
501
accurately categorized in the 3 clinical groups across all frequencies (Fig. 2a; NREM and
502
REM clusters: [0.5-20]Hz, pcluster<0.001). However, the decoding accuracy was not constant
503
and certain frequency domains led to particularly high classifying accuracies (peaks in
504
classifying performance). In particular, we could identify 4 main clinically relevant frequency
505
bands: (i) delta ([1-4]Hz), (ii) theta ([5-7]Hz), (iv) sigma oscillations ([11-15]Hz) and (iii)
506
beta oscillations ([16-20]Hz). Training and testing our classifiers on NREM and REM sleep
507
separately showed that certain frequency ranges give higher classifying accuracies for a given
508
sleep state. For example, theta/alpha (alpha: [8-11]Hz) and beta oscillations led to higher
509
decoding accuracy in REM sleep than in NREM sleep (clusters: [5, 10.5]Hz and [17.5-20]Hz,
510
pcluster<0.005) whereas in NREM sleep, delta and sigma oscillations led to higher decoding
511
accuracies (clusters: [0.5, 4.5]Hz and [11.5, 14.5]Hz, pcluster<0.0001). These results are
512
concordant with the dominant rhythms in NREM (slow waves: delta, sleep spindles: sigma)
513
and REM sleep (theta and fast oscillations). It is finally worth noting the high levels of
514
accuracy obtained for both NREM and REM within the delta range (ROC area > 0.8), which
515
suggests that simple features extracted from the EEG spectrum can accurately support the
516
automated identification of insomnia.
517
Then, as detailed in the Methods, we examined how the three different groups differed in each
518
of the frequency bands of interest (delta, theta/alpha, sigma and beta) and throughout the
519
night. This analysis was motivated by the well-documented influence of both circadian and
520
homeostatic processes on sleep rhythms [66]. Besides, past research has stressed that
521
differences between good sleepers and individuals suffering from insomnia also vary during
522
the night [30]. Differences were observed in the delta ([0.5, 4]Hz), theta/alpha ([5, 11]Hz),
523
sigma ([11, 15]Hz) and beta ([16, 20]Hz) bands (Bonferroni correction for cluster Monte18
524
Carlo p-values) but were restricted to the beginning of the night (<50% total progression).
525
Good sleepers were characterized by higher levels of delta power but lower levels of
526
theta/alpha and beta oscillations. In other words, insomnia patients showed weaker sleep-
527
related oscillations and stronger wake-related oscillations during sleep than good sleepers. We
528
observed however an exception to that rule with the small, temporally restricted, modulation
529
in spindle power (cluster: [12, 16]%, pcluster<0.05, corrected), with controls showing less
530
spindle power than insomnia patients.
531
Importantly, despite drastic differences at the macroscopic level, the spectrum of the insomnia
532
subtypes (INS and SSM) significantly overlap. Only one significant post-hoc cluster emerged
533
when comparing INS and SSM, with INS patients showing an increased level of alpha/theta
534
oscillations compared to SSM (post-hoc cluster: [0, 30]%, pcluster<0.005). These results alone
535
could positively help overcome the discrepancy between objective and subjective assessments
536
of insomnia: SSM patients no longer look like good sleepers but are much more similar to
537
INS patients when examining the spectral features of the EEG signal.
538
While quite standard, these spectral analyses have several limitations. First, since they rely on
539
relative power, it is difficult to be conclusive on the exact frequencies impacted by insomnia.
540
Indeed, effects observed on a specific frequency band could actually stem from other
541
frequency domains used in the normalization. Second, while frequency bands have been often
542
linked to specific patterns of neuronal activity (e.g. sleep spindles and the sigma band), this
543
relationship can be complex. For example, an increase in sigma power does not necessarily
544
mean an increase in spindle density as sleep spindles are also defined by a duration criterion.
545
Third, there can be significant inter-individual variations in terms of the frequency of the
546
different sleep rhythms, which are not taken into account when dealing with fixed frequency
547
bands. Finally, the EEG power spectrum does not only reflect periodic brain oscillations but
548
also aperiodic activity [61,62]. Periodic oscillations typically show up as peaks in the power
549
spectrum whereas aperiodic signals can be quantified by computing the slope of the 1/f trend
550
of the EEG spectrum. This is why we also examined whether insomnia had an effect on the
551
aperiodic component of the EEG spectrum by computing the slope of the power spectrum
552
across all sleep stages and for each individual (Fig. 3, see Methods). Bonferroni-corrected
553
ANCOVAs show significant modulations of the spectrum’s slope in NREM2 and NREM3
554
(p<0.01, Bonferroni corrected). This modulation was driven by decreased slopes for patients
555
with insomnia (INS and SSM) compared to controls.
19
556
The decrease in the slope of the spectrum was even more pronounced for SSM patients in
557
NREM3, which showed slopes that were smaller than in NREM2 and equivalent to NREM1,
558
in striking contrast with both controls and INS patients. Indeed, in controls and INS patients,
559
the slope increases with sleep depth (wake
560
in the slope of the EEG spectrum for SSM patients is particularly interesting since the slope
561
of the power spectrum has been associated with the excitation/inhibition balance [62]. A
562
decrease in the slope of the spectrum during sleep could be associated with an abnormally
563
high level of excitation during NREM3 in SSM patients, in link with the hyperarousal model
564
of insomnia (see Discussion).
565
Sleep’s micro-structure evidences a decrease in slow waves and increase in sleep
566
spindles in insomnia
567
Finally, as detailed in the Methods, we focused on the micro-structure of sleep and NREM
568
sleep hallmarks such as slow waves (including K-complexes) and sleep spindles. We
569
automated the detection of slow waves and extracted slow-waves’ density (number of events
570
per minute), amplitude, frequency and slope (see Fig. 4 and Methods). We used Bonferroni-
571
corrected ANCOVAs to assess the differences across groups in NREM2 and NREM3
572
separately, as well as for central and frontal derivations separately (16 comparisons across all
573
slow waves variables). Results indicate that, in both NREM2 and NREM3, for central
574
electrodes, insomnia patients showed fewer slow waves (ANCOVAs: p<10-6; post-hoc
575
unpaired t-tests p<0.001) as well as slower and less steep slow waves (ANCOVAs: p<10-4;
576
post-hoc unpaired t-tests p<0.001). The reduction of slow waves frequency was also observed
577
in frontal electrodes in NREM2 and NREM3 (ANCOVAs: p<0.001). The amplitude of slow
578
waves was not significantly modulated across groups when correcting for multiple
579
comparisons. When comparing SSM and INS patients directly, there was no significant
580
difference between the density and properties of slow waves in NREM sleep (uncorrected
581
post-hoc unpaired t-tests: all p>0.05 except for a minor difference in slow-wave amplitude:
582
p=0.046 in NREM2) suggesting that the impairment of slow-wave generation is a common
583
feature of insomnia subtypes.
584
We then examined sleep spindles, yet again based on automated detection algorithms (see
585
Methods). Bonferroni ANCOVAs were used to assess group differences in terms of spindles
586
density, maximum amplitude, duration and frequency over central and frontal derivations and
587
in NREM2 and NREM3 separately (16 comparisons). As for slow waves, spindle density
20
588
appears modulated across groups, this time in both NREM2 and NREM3, frontal and central
589
derivations (ANCOVAs, all p<0.001, corrected threshold). However, the direction of this
590
modulation was opposite to slow waves, with INS and SSM patients showing more sleep
591
spindles than controls (post hoc t-tests: P<0.001). These spindles also tended to vary in
592
duration in NREM2 and NREM3, central and frontal electrodes (ANCOVAs, all p<0.001,
593
corrected threshold). Similarly, spindle power was reduced in insomnia patients for central
594
and frontal derivations, NREM2 and NREM3 (ANCOVAs, all p<0.001, corrected threshold).
595
Spindle frequency varied across groups in NREM2 only (ANCOVAs, all p<0.05, corrected
596
threshold) with faster spindles in INS and SSM patients.
597
Importantly, there were significant differences between insomnia subtypes in terms of spindle
598
density. SSM patients showed larger number of sleep spindles compared to INS patients, in
599
NREM2 and NREM3, for central and frontal derivations (uncorrected post-hoc unpaired t-
600
tests: p<0.005).
601
Unsupervised AI algorithms can detect and phenotype insomnia using features
602
extracted from PSG recordings
603
From the results presented above, it appears that PSG recordings contain information
604
allowing not only to distinguish insomnia patients from good sleepers but can also make
605
important distinctions within insomnia (e.g. between insomnia with and without SSM).
606
However, the previous analyses are rarely employed in clinical settings, potentially because
607
they are complex, varied and often arbitrarily focus on specific aspects of the data (e.g. power
608
spectrum or micro-structure).
609
To facilitate the translation of our approach to clinical settings, we set out to determine if
610
features extracted from PSG recordings could predict whether an individual is a good sleeper
611
or suffers from insomnia. To do so, we relied on recent developments in computer science
612
and machine learning, which have made the computation and classification of large datasets
613
seamless (see Methods). In practice, for each PSG recording and patient, we extracted the
614
different macro, meso and micro-features described above. These features were divided into
615
“visual” (typically micro) and “computed” (typically meso and macro) features, depending on
616
whether they were obtained through the visual inspection of the data (N=71 features) or
617
through automated algorithms (N=302). This separation of visual and computed features was
618
made in order to check whether an entirely automated analysis of the signal would be enough
21
619
to help the diagnosis of insomnia and whether it could even outperform a classification based
620
on features obtained from the visual inspection of the PSG recordings.
621
We first focused on whether a classifier could predict if an individual suffers from CI by
622
training a classifier on good sleepers (GS) and patients with CI (SSM + INS) (see Methods).
623
To assess the efficacy of the classifier, we computed Cohen’s κ values for 100 repetitions of
624
this classification (Fig. 6a, left). For memory, a perfect classification corresponds to κ=1
625
(irrespective of the number of predicted classes) while a random classification corresponds to
626
κ=0. We also show the Confusion Matrix which represents how the predicted labels (rows)
627
compared to the real labels (columns). A perfect classification shows up as a diagonal
628
confusion matrix (predicted labels = real labels). Our results indicate that participants’ clinical
629
assessment (GS or CI) can be recovered with moderate accuracy when using visual features
630
(κ=0.49 ± 0.01) but this accuracy is much improved when using computed features (κ=0.88 ±
631
0.01; unpaired t-test: p<10-16). In fact, κ values above 0.8 are usually considered as almost
632
perfect classification [67]. Combining visual and computed features did not significantly
633
improve the overall accuracy of the classifier (κ=0.88 ± 0.007; unpaired t-test to compare
634
visual+computed and computed classifiers: p=0.67), implying that computed features already
635
maximize the ability to predict CI from PSG recordings.
636
We then examined whether we could also retrieve insomnia subtype. To do so, we trained a
637
classifier on our three clinical groups (GS, SSM and INS, Fig. 6b). Visual features led to
638
moderate accuracy (κ=0.45 ± 0.009). As the confusion matrix shows, this moderate level of
639
performance is due to a large proportion of good sleepers (56.8%) and SSM patients (46.5%)
640
being mistakenly diagnosed as INS patients. A limited ability to classify these 3 groups is
641
expected given that SSM, INS and GS individuals sometimes overlap when considering only
642
visual (micro) features (see Fig. 1 and Table 1). However, the performance significantly
643
improved when focusing on features extracted from the EEG signal (κ=0.59 ± 0.008; unpaired
644
t-test with the visual-features classifier: p<10-16). In this case, GS were reasonably well
645
categorized (87.5% correct) but SSM patients were almost always categorized as INS patients
646
(96.1% miscategorization as INS patients). This is again not surprising when considering that
647
INS and SSM patients largely overlap when considering the computed features: meso (Fig. 2-
648
3) and micro (Fig. 4-5) features. Finally, combining both sets of features led to significantly
649
better performance (κ=0.73 ± 0.007; unpaired t-test compared to visual- or computed-features
650
classifiers: p<10-16),
22
651
Given the inability for the 3-way classifier to distinguish between INS and SSM patients, we
652
finally trained and tested classifiers when using INS and SSM these patients only. Using
653
visual features, we could classify the two subtypes of insomnia with moderate accuracy
654
(κ=0.51 ± 0.01). But, when considering features extracted from the EEG signal, the classifier
655
was at chance (κ=0.0049 ± 0.008; t-test compared to 0: p=0.51). A significantly better-than-
656
chance classification was retrieved when combining both visual and computed features
657
(κ=0.54 ± 0.02; t-test compared to 0: p<10-16), but the level of performance attained was not
658
significantly different from the visual-only classifier (unpaired t-test: p=0.07). These results
659
confirm that SSM and INS patients largely overlapped for EEG-derived features, making
660
them indistinguishable by an automated classifier.
661
Finally, supervised classifiers have the crucial advantage of providing insight on the nature of
662
group differences. Indeed, the ML algorithms used here allowed us to retrieve which features
663
contributed the most to the classification output, which can be interpreted (when the classifier
664
is performing well) as the features that best distinguish the groups of interest (see Methods).
665
By stressing which differences matter, supervised classifiers could shed light on the
666
physiological substrates and aetiology of insomnia. To illustrate this possibility, we show in
667
Table 2 the top-20 most discriminative features for the GS. vs. CI, GS vs. SSM vs. INS, and
668
SSM vs. INS classifiers. As expected from Fig. 2, spectral information in the delta band is
669
discriminating best between GS and CI patients (top-20 features were all computed from the
670
power spectrum). When classifying GS, SSM and INS patients however, the top features were
671
a combination of features extracted from the EEG power spectrum and the hypnogram. This
672
may be related to the fact that SSM and INS patients do not seem to differ in terms of power
673
spectrum but do differ in terms of hypnograms. In fact, it seems that only the combination of
674
the information coming from the micro, meso and macro levels can allow the 3-way
675
distinction of the INS, SSM and GS groups. This was illustrated by the classifier focusing on
676
the SSM and INS groups. In this case, the top-20 variables were a combination of
677
hypnogram-based features, spectral features and information about sleep micro-structure
678
(sleep spindles).
679
Impact of covariates and limitations
680
This study being a retrospective analysis, it bears several potential limiting factors associated
681
with the nature of the dataset and the individuals included in this study. Indeed, the different
682
groups are not age or gender-matched: good sleepers were on average younger and comprised
23
683
a greater proportion of males (Table 1). Age and gender impacting PSG recordings at the
684
macro, meso and micro levels [68–70], we integrated these two variables as covariates in all
685
our analyses (see Statistics section).
686
Another possible confound is the fact that patients were not instructed to interrupt their
687
treatments and, consequently, 52% of INS and 53% of SSM patients were under insomnia
688
medication during the night of PSG, which is known to affect the recordings [71]. To mitigate
689
the risk that part of our results could result from the effect of medications, we replicated all
690
our analyses by discarding patients with any record of medication. By and large, these
691
replications confirm our initial results regarding the meso and micro level of analysis. Indeed,
692
we could confirm that unmedicated insomnia patients show a reduction in slow wave density
693
(uncorrected post-hoc t-tests: p<0.01 in NREM2/3, central electrodes), frequency (p<0.01 in
694
NREM2/3, central electrodes) and slope (p<0.05 in NREM2/3, central electrodes); an
695
increase in spindle density (p<0.001 in central/frontal channels and NREM2/3), frequency
696
(p<0.01 in central channels and NREM2) and decrease in amplitude (p<0.001 in
697
central/frontal channels and NREM2/3); a decrease in delta oscillations coupled with an
698
increase in theta/alpha and beta oscillations (pcluster<0.05); a decrease in the slope of the power
699
spectrum in NREM2 and NREM3 (p<0.05). It seems thus that our results are confirmed when
700
taking into account confounding variables (age, gender and medication).
701
PSG recordings were also recorded in different locations, either at home (ambulatory
702
recordings) or at the hospital. The proportion of home recordings differed between controls
703
and patients (GS: 6.7%; INS: 71.2%; SSM: 80.2%) as most of patients were recorded at home
704
while controls consisted of volunteers to research protocols typically conducted in controlled
705
environments. The proportion of home recordings did not differ between insomnia sub-types
706
(chi-test: chi2 =2.4, p=0.12). Within the population of insomnia patients (INS + SSM), we
707
examined the impact of recordings’ location (home or hospital) on the macro, meso and micro
708
features. We observed an increase in Total Sleep Time, proportion of REM and number of
709
REM episodes for ambulatory recordings (p<0.01, Bonferroni-corrected unpaired t-tests,
710
N=273 ambulatory and 74 hospital recordings in 347 patients). This is due to the fact that
711
hospital recordings can be disrupted by hospital routine in the morning, leading to extended
712
and REM-rich home recordings. However, meso (spectral slope (Fig. 3) and overall power in
713
the delta, theta/alpha, sigma and beta bands (Fig. 2)) and micro (density and properties of
714
slow waves (Fig. 4) and sleep spindles (Fig. 5)) features were not significantly impacted by
715
the recording type within the insomnia population (unpaired t-tests, corrected threshold: 24
716
0.05). Furthermore, when comparing patients and controls, most of the effects reported
717
concern NREM sleep (Fig. 3-5) or the beginning of the night (Fig. 2) and are thus less likely
718
to be affected by an extension of sleep in ambulatory recordings.
719
Finally, PSGs were recorded using different devices. Although all these devices are routinely
720
and indiscriminately used in our Sleep Clinic for clinical assessments, different devices could
721
alter some aspects of the PSG recordings. In addition, the type of recording device differed
722
between controls (82% of ACTIWAVE devices) and insomnia patients (99% and 100% of
723
NOX-A1 devices for INS and SSM patients resp.). However, most of the differences
724
observed between patients and controls were limited to specific sleep stages (Fig. 1-5), time
725
windows (Fig. 1, 2b), scalp location (Fig. 4-5) or to specific properties of the micro-structure
726
(Fig. 4-5). It is thus unlikely that the recording device used in a given PSG would be the
727
source of the observed group differences as the type of recording device should affect a
728
specific feature of PSG recordings indiscriminately of the time, sleep stage or location of the
729
recorded data.
730
25
731
DISCUSSION
732
Towards a comprehensive exploration of the physiological substrates of insomnia
733
Our study revisits the use of PSG in the diagnosis of insomnia. Indeed, insomnia stands in
734
striking contrast with other sleep pathologies as PSG recordings are neither needed nor
735
recommended for the diagnosis of insomnia, despite the fact that PSG is widely considered as
736
the golden standard for the objective measurement of sleep [19]. This paradox has been
737
justified by the fact that PSG recordings do not bring reliable information to inform the
738
diagnosis and treatment of insomnia. PSG recordings can even, at times, directly contradict
739
what individuals report [27]. A telltale example of such discrepancies is the case of insomnia
740
with SSM, in which patients can sometimes be indistinguishable from good sleepers when
741
referring to classical summary statistics of PSG recordings (TSA, WASO, number of
742
awakenings, time spent in each sleep sub-stage) [28,29]. In this study, we set out to resolve
743
this discrepancy between objective and subjective indexes of sleep and to reconcile insomnia
744
with PSG recordings. To do so, we relied on a large dataset of PSG recordings in insomnia
745
patients (N=347), including different insomnia subtypes (N=59 with SSM, N=288 without).
746
The size of this dataset allowed us to examine PSG recordings at various scales of analyses
747
and to apply Machine Learning (ML) techniques, typically requiring large datasets.
748
Our approach was to systematically perform and aggregate the different types of analyses
749
performed in the past to investigate insomnia in PSG recordings. We divided these analyses
750
into 3 levels. First, we extracted “macroscopic” indexes of sleep quantity and quality as
751
classically reported in the literature on insomnia (TST, WASO, Sleep Efficiency, proportions
752
of Sleep Stages, etc). These metrics tend to summarize a given aspect of sleep across the
753
entire night. Second, we focused on the EEG signal on 30-s-long epochs and analyzed brain
754
rhythms through the spectral decomposition of the EEG signal (see [30–33] and [18] for a
755
review on similar approaches in insomnia). We termed this level of analysis “mesoscopic” as
756
it focuses on an intermediate time-scale (30s). Third, we performed a fine-grained analysis
757
(~1s scale) of PSG’s microstructure (slow waves and sleep spindles). Past studies have
758
investigated changes in sleep microstructure in insomnia (see [18] for a review) but these
759
results remained largely inconclusive. Although most of the analyses presented here have a
760
precedent in the literature, our study is the first to integrate all these approaches.
761
26
762
PSG as a useful tool for the diagnosis of insomnia
763
The analysis of the macro features of PSG recordings illustrate the distinctions classically
764
made between insomnia with and without SSM. Indeed, global metrics of sleep quantity and
765
quality derived from the hypnogram show two groups of insomnia patients: individuals in
766
which PSG recordings tend to confirm the subjective complaint of insomnia (CI without
767
SSM: INS group) and individuals in which PSG recordings do not support or even appear to
768
contradict the diagnosis of CI (CI with SSM: SSM group). In the latter case, patients appeared
769
to sleep as well if not better than controls (equivalent TTS; shorter SOL, WASO; better sleep
770
efficiency; see Table 1). In contrast, patients without SSM had shorter TTS, longer WASO
771
and worse sleep efficiency (Table 1). It is worth noting the rather long SOL observed in
772
controls, which could be explained by a FNE [22]. A reverse FNE could be also responsible
773
for the short SOL observed in patients with SSM [23].
774
While macro features of sleep are an easy way to rapidly assess a night, our analyses and
775
previous studies show their limitations as they fail to capture a common denominator among
776
insomnia patients. Examining further the proportion of sleep stages leads to the same
777
conclusion: patients without SSM showed a deteriorated sleep (increased proportion of wake
778
during the night, decreased proportion of NREM2 and REM; Table 1) whereas patients with
779
SSM displayed the reverse pattern (less wake, more NREM2, NREM3 and REM; Table 1).
780
Similar results were obtained when splitting the night into two parts (Fig. 1, top).
781
Interestingly, the increase in REM for SSM patients could be interpreted in the light of the
782
positive relationship between REM duration and subjective estimates of the time spent awake
783
during the night [35]. The fact that REM sleep is often associated with dreaming [72], and
784
therefore consciousness, could potentially explain the difficulty experienced by patients in
785
determining if they were awake or asleep. However, we did not replicate previous findings on
786
the increase in arousals during sleep, and REM in particular, in insomnia [35]. Nonetheless,
787
we could observe a trend in this direction and our results could be explained by the strict
788
statistical thresholds used in this study (Bonferroni correction, see Methods). Finally, the
789
analysis of state-transitions during the night (i.e. how sleepers move from one state to
790
another; Fig. 1, bottom) also describes INS patients’ sleep as unstable (more frequent
791
NREM2>Wake transitions compared to controls) and SSM patients’ sleep as more stable
792
(more frequent WAKE>NREM2 transitions compared to controls).
27
793
Overall macro features derived from the hypnogram do not seem able to solve the conundrum
794
of insomnia as they fail at unravelling a common denominator between insomnia subtypes. Of
795
course, this does not mean that PSG recordings are not informative, even at this level of
796
analysis. Rather, information extracted from PSG recordings allows the phenotyping of
797
insomnia (e.g. to determine the presence of SSM) based on a pre-existing diagnosis of
798
insomnia established on patients’ subjective complaint.
799
Nonetheless, there is more in PSG recordings than what can be derived from the hypnogram
800
and previous studies have shown how PSG recordings can be harnessed to better understand
801
the physiopathology of insomnia. In particular, the spectral decomposition of the EEG signal
802
allows identifying and quantifying the neural oscillations that are constitutive of wakefulness
803
and sleep. Accordingly, we here extracted spectral information on epochs of 30s (mesoscopic
804
features; see Methods) and examined the relative power across the entire [0.5-20]Hz range
805
(Fig. 2a) or in frequency-bands of interest (Fig. 2b). Past studies have shown that individuals
806
with insomnia present more fast oscillations that are characteristic of wakefulness during
807
sleep (alpha, beta oscillations) and less oscillations typical of sleep (delta rhythm) (see [18,30]
808
for reviews). Our results are in line with these findings (Fig. 3). However, the sigma range,
809
which is typically associated with sleep, showed a moderate up-regulation in insomnia
810
patients compared to controls. Such an increase seems driven by SSM patients, which is
811
concordant with previous findings in “subjective” insomnia [73]. This increase in sigma
812
power in CI patients speaks against a simple down-regulation of sleep rhythms and up-
813
regulation of wake activity during sleep in CI.
814
A striking aspect of the comparison between macro and meso features is that, while macro
815
features clearly distinguished between insomnia sub-types (i.e. SSM patients are closer to
816
good sleepers than INS patients according to these metrics), the meso features did not (Fig.
817
3). Both SSM and INS patients showed very similar changes in power compared to controls,
818
demonstrating that the paradox of SSM dissolves as soon as the neural activity is analyzed in
819
more detail. This is an important result in order to reassess the validity of PSG recordings in
820
insomnia as it shows that, despite inconsistencies at the level of macroscopic metrics, PSG
821
recordings can actually show robust markers of insomnia. Finally, although we observed
822
robust differences across groups in several frequency bands, the fact that we could only
823
examine the EEG spectrum in a limited number of scalp locations means that we cannot
824
conclude on the topographical aspects of these changes as previously done [34,74].
825
Furthermore, we could not explore other spectral differences such as differences in occipital 28
826
alpha or sigma [34]. The replication of our findings in high-density EEG could lead to further
827
insights about insomnia patients and good sleepers differ.
828
Examining the EEG spectrum, we also extracted information about the aperiodic component
829
of neural activity. Indeed, the EEG signal is not uniquely composed of oscillations or pseudo-
830
oscillations [54]. Rather, neural oscillations are embedded in an aperiodic background, which
831
translates into the 1/f relationship between power and frequency observed in scalp EEG [61].
832
Importantly, modulations of this aperiodic background are physiologically and cognitively
833
relevant as the parameters of this aperiodic activity can change with sleep/wake transitions
834
[64], age [75] or can be altered in disorders such as schizophrenia [76]. Here, we show that
835
the slope of the aperiodic signal is decreased in CI patients (both SSM and INS) in deep
836
NREM sleep (NREM2 and NREM3, Fig. 3). Interestingly, a reduction of the slope of the
837
EEG spectrum has been interpreted as a modification of the Excitatory/Inhibitory (E/I)
838
balance among cortical networks and an increase in cortical excitability [62]. If the latter
839
findings can be extrapolated to humans, our results would suggest that insomnia is
840
characterized by an increase in cortical excitability (see below).
841
Finally, we dove further into the details of sleep physiology and focused on sleep’s
842
microstructure (micro features). We automatically detected slow waves and sleep spindles
843
(see Methods) and extracted basic properties of individual grapholelements (frequency,
844
duration, amplitude, etc). In concordance with the spectral analyses (e.g. decrease in delta
845
power, Fig. 2), we observed a decrease in slow-wave density in both insomnia groups (Fig.
846
4). Slow waves were not only less numerous in insomnia but they also appeared slower
847
(decreased frequency) and with reduced down-to-up slopes. Previous reports indicate that
848
slow waves with reduced slopes tend to occur later during the night [55,77] and recruit
849
smaller portions of the cortex [58,77]. Less steep, slower slow waves have also been
850
interpreted as reflecting a smaller recruitment of neuronal populations due to reduced synaptic
851
strength or density [78] but changes in wake-promoting neuromodulation or inhibitory
852
neurons could also be responsible [77,78]. In addition, slow waves are usually steeper
853
following sleep deprivation [55]. Consequently, less steep slow waves in a population that
854
complaint from chronic sleep loss could be interpreted as a disruption of sleep’s homeostatic
855
regulations. Finally, the changes observed in slow waves could affect the physiological
856
functions of slow waves (e.g. synaptic homeostasis, memory consolidation [79–81]) and lead
857
to the subjective feeling of a non-recovering sleep as well as daytime cognitive impairments
858
as typically seen in insomnia. 29
859
The analysis of the microstructure also showed that, contrary to slow waves, sleep spindles
860
are increased in both insomnia groups compared to GS (Fig. 5), with a maximal increase for
861
SSM patients. This increase in spindle density is concordant with the increase in sigma power
862
observed in the EEG spectrum (Fig. 3b). Sleep spindles have also reduced amplitude, and
863
increased frequency and duration in insomnia patients (Fig. 5). This increase in spindle
864
density could seem at odds with our findings which indicate a reduction in sleep rhythms in
865
favor of wake rhythms in insomnia patients (Fig. 3). However, an increase in spindle
866
frequency has been observed under conditions of circadian misalignment [82], while the
867
administration of benzodiazepine [83] or melatonin [84] tends to decrease spindle frequency,
868
suggesting that an increase in spindle frequency is a marker of a deteriorated or lighter form
869
of NREM sleep. Compatible with this view is the negative relationship between spindle
870
frequency and slow-wave activity (a classical marker of sleep depth and quality) that has been
871
previously reported [57].
872 873
PSG recording can inform on the mechanisms underlying insomnia with or without SSM
874
Several models have tried to provide a neurophysiological understanding of insomnia with the
875
hyperarousal model of insomnia [17,85] certainly being the most influential. This model
876
posits that insomnia is rooted in neurophysiology rather than being a purely psychological
877
disorder. Although this model recognizes the role of psychological components in the onset
878
and maintenance of insomnia, it views these components as being potentiated by a
879
physiological substrate. According to this model, a higher level of somatic, cognitive and
880
cortical activity (or hyperarousal) [17,73,74] would be such substrate. Dysregulations of
881
neuroendocrine systems (such as the hypothalamic-pituitary-adrenal-axis responsible for the
882
production of cortisol) have been recently proposed as a cause of this hyperarousal [86].
883
Certain changes in sleep physiology observed in insomnia support the hyperarousal model
884
such as the increase in high-frequency rhythms observed in insomnia patients with or without
885
SSM [17]. A recent study relying on high-density EEG showed that even during deep sleep,
886
individuals with CI show an increase in the prevalence of neuronal patterns of brain activity
887
typically associated with light sleep [36], a phenomenon that could be linked to hyperarousal.
888
Markers of hyperarousal have been also investigated in wakefulness since the model views
889
hyperarousal as a trait that would impact brain functioning day and night. Accordingly, it has
890
been shown that insomnia patients react more strongly to external sensory inputs and internal
891
stimuli (i.e. heartbeat) [87–90].
30
892
Although the hyperarousal model has gathered much supporting evidence, it is unclear if a
893
day-and-night increase in cortical arousal is really at the root of insomnia. Most of the studies
894
showing increase in fast oscillations during insomnia actually evidence stage-dependent
895
effects or effects constrained in specific parts of the night (typically the beginning)
896
[17,30,69]. Perlis and colleagues proposed a reformulation of the hyperarousal model
897
whereby insomnia is characterized by a disruption of homeostatic processes that promote the
898
transition to sleep at the beginning of the night [17,91]. Our results support this view as most
899
of the spectral differences between insomnia patients and controls were observed in the first
900
half of the night.
901
However, our results also indicate that insomnia was not simply characterized by an increase
902
in wake-like rhythms during sleep and a reduction in sleep-like oscillations. Indeed, we also
903
observed an increase in the number of sleep spindles in both insomnia groups (Fig. 5). This
904
increase cannot be simply explained by an increase in the proportion of NREM2 (where sleep
905
spindles are predominant [92]). Indeed, we observed an increase in sleep spindles in both
906
NREM2 and NREM3. Besides, the density of sleep spindles increased in the INS group
907
compared to controls (post-hoc unpaired t-tests: p<0.001 for frontal and central spindles)
908
despite a reduction in the proportion of NREM2 in INS patients (Table 1). Importantly,
909
spindle density was not the only parameter affected and we also observed an increase in the
910
frequency of sleep spindles (Fig. 5). Since the frequency and density of sleep spindles have
911
been found to be negatively correlated with Slow Wave Activity [57], the increase in spindle
912
density and spindle frequency observed in insomnia patients could be a direct consequence of
913
the reduction of slow waves, or both could be mediated by the same physiological
914
mechanism. We hypothesize here that both changes in slow waves (decrease density and
915
down-to-up slope) and sleep spindles (increased density and frequency) could be explained by
916
an increase in cortical excitability during sleep. Indeed, previous work in rodents has shown
917
that a down-regulation of cortical excitability with carbamazepine leads to increased slow-
918
wave power, steeper slow waves, slower spindles and fewer fast spindles [93]. In summary,
919
the administration of carbamazepine leads to a reverse profile compared to insomnia patients,
920
potentially due to the negative impact of carbamazepine on cortical excitability. In fact, the
921
administration of carbamazepine has also been shown to improve sleep parameters in
922
epileptic patients (see [94] for a review). This hypothesis is also supported by the analyses of
923
the spectral slope (see Fig. 3 and above). Thus, it is possible that an increase in cortical
31
924
excitability could be responsible for the physiological changes observed during sleep in
925
insomnia.
926
Machine Learning techniques can facilitate the integration of PSG recordings to clinical
927
practice
928
Our results show that fine-grained levels of analyses of PSG recordings can reveal robust
929
significant differences between insomnia patients and good sleepers but also between
930
insomnia subtypes. However, conducting these analyses can be time-consuming, impeding
931
their easy translation to clinical settings. Nonetheless, this translation might be facilitated by
932
two ongoing revolutions in the field of Sleep Medicine. The first one regards data and the fact
933
PSG devices have become smaller, lighter and cheaper with years. Recently, several large
934
datasets of PSG recordings have been published [68,95,96] or are in the making (e.g. Stanford
935
Technology Analytics and Genomics in Sleep (STAGES) Program), putting sleep research in
936
the era of “big data”. Most importantly, consumers-oriented devices now exist that could
937
bring PSG to the masses [42], facilitating the acquisition of massive amounts of sleep data. It
938
has thus become not only possible but also crucial to better understand what constitutes a
939
good night's sleep.
940
The second revolution is tied to the first one and regards data analysis. Indeed, PSG
941
recordings represent very rich data and, although existing methods allow to automatically
942
analyze multiple aspects of physiological data, recent developments in Artificial Intelligence
943
make it easier to integrate disparate analytic approaches. With the increase in the amount of
944
data available but also the type of available analyses, it is important to find new ways to
945
automatize and rationalize data analyses. Unfortunately, so far, studies focusing on PSG
946
recordings are confined to specific analytic approaches. Here we sought to find a way to
947
integrate these different approaches. We automated most of the analysis pipeline and showed
948
we could rely on supervised classifiers to extract information about individuals’ diagnosis.
949
Besides, even the steps that were here performed through visual inspection of the data (sleep
950
scoring) can now be reliably automated [95].
951
Supervised algorithms were here used in two ways. First, they were used as an exploratory
952
method to identify which features can distinguish between the groups of interest. For
953
example, applying supervised classifiers to spectral features (Fig. 3) allowed us to identify the
954
frequency domains that differ the most between good sleepers and insomnia patients (delta,
955
theta/alpha, sigma and beta oscillations) without relying on a priori hypotheses. The same
32
956
approach allowed us to investigate the differences between NREM and REM sleep,
957
evidencing that some neural oscillations are more predictive of insomnia in NREM (delta,
958
sigma) or REM (theta, beta) sleep.
959
Another use of supervised algorithms is to classify data according to clinically relevant
960
groups. We show here that different sets of features extracted from PSG recordings can either
961
succeed or fail at teasing apart good sleepers from insomnia patients, or to distinguishing
962
between insomnia subtypes (Fig. 6). For example, micro and meso features support an
963
excellent classification of insomnia patients vs. controls, in line with the notion that PSG
964
recordings can be highly relevant for the diagnosis of insomnia. In fact, our findings
965
demonstrate how an automatization of PSG analyses could be implemented to help clinicians
966
diagnose patients with a high level of accuracy (Fig. 6a, sensitivity > 98%, specificity >86%).
967
Importantly, classifiers are also informative when they fail. For example, the same features
968
that can distinguish insomnia patients from good sleepers (e.g. spectral information, micro-
969
structure), can fail to distinguish SSM and INS patients, which suggests that insomnia
970
subtypes are remarkably similar in terms of spectral components or micro-structure. This was
971
not the case for features extracted from the hypnogram. Hence this approach can confirm that,
972
although CI patients with or without insomnia differ according to macroscopic metrics of
973
sleep quantity and quality, their sleep is close to identical when looking at specific
974
physiological mechanisms.
975
Finally, another advantage of classifiers is that it is possible to examine which features are the
976
most responsible for the classifiers’ accuracy, which could provide insights about the
977
physiological substrate of insomnia. For example, the classification of CI patients vs. good
978
sleepers was based mostly on spectral information in the lower frequency range (delta/theta,
979
Table 2). This means that, when not taking into account the different types of insomnia, sleep-
980
related oscillations such as delta and theta rhythms represent a common signature for the
981
insomnia disorder. However, when factoring in insomnia subtypes, other features pertaining
982
to the micro and macro-scales become discriminative. These results stress the importance and
983
relevance of PSG recordings as they allow to identify both the core common physiological
984
signatures of insomnia as well as the components that are specific to particular insomnia
985
subtypes.
986
33
987
Conclusion:
988
We claim here that, in PSG recordings, there is more than meets the eye. PSG recordings
989
seem to carry very rich and reliable information about one’s sleep, in particular in the case of
990
insomnia. In fact, the paradox of SSM (presence of subjective symptoms of insomnia without
991
objective impairments of sleep) is apparent only when focusing on superficial, large-scale
992
metrics of sleep but dissolves when examining the finer dynamics of brain activity. We thus
993
conclude that the limitations outlined in the past and leading to the exclusion of PSG
994
recordings from the diagnosis of insomnia are no longer warranted and that clinicians should
995
revisit the benefits of PSG recordings.
996
We further argue that this reassessment is timely in the light of two ongoing revolutions in the
997
field of Sleep Medicine: (1) the emergence of consumer-based PSG devices will bring PSG
998
recordings to the masses, leading to an explosion in the amount of available data, similarly as
999
what happened with actigraphy, (2) the translation of computational tools from the field of
1000
Artificial Intelligence to Sleep Medicine allows the rapid, automated and massive analysis of
1001
large datasets and simplifies the difficult task of summarizing expanding amounts of data to
1002
human decision-makers (e.g. clinicians). We show here the feasibility of embracing such
1003
changes and their ability to facilitate the clinical diagnosis and management of a common but
1004
difficult sleep disorder: insomnia. We also demonstrate how these approaches can suggest
1005
new ways of understanding why some individuals sleep well while others struggle.
1006
34
1007
References:
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[1] Luyster FS, Strollo PJ, Zee PC, Walsh JK, Boards of Directors of the American Academy of Sleep Medicine and the Sleep Research Society. Sleep: a health imperative. Sleep 2012;35:727–34. doi:10.5665/sleep.1846. [2] Cirelli C, Tononi G. Is sleep essential? PLoS Biol 2008;6:e216. doi:10.1371/journal.pbio.0060216. [3] Hirshkowitz M, Whiton K, Albert SM, Alessi C, Bruni O, DonCarlos L, et al. National Sleep Foundation’s sleep time duration recommendations: methodology and results summary. Sleep Health 2015;1:40–3. doi:10.1016/j.sleh.2014.12.010. [4] Ohayon MM. Epidemiology of insomnia: what we know and what we still need to learn. Sleep Med Rev 2002;6:97–111. [5] Léger D, Bayon V. Societal costs of insomnia. Sleep Med Rev 2010;14:379–89. doi:10.1016/j.smrv.2010.01.003. [6] Ohayon MM. Epidemiology of insomnia: what we know and what we still need to learn. Sleep Med Rev 2002;6:97–111. [7] Léger D, Morin CM, Uchiyama M, Hakimi Z, Cure S, Walsh JK. Chronic insomnia, quality-of-life, and utility scores: comparison with good sleepers in a cross-sectional international survey. Sleep Med 2012;13:43–51. doi:10.1016/j.sleep.2011.03.020. [8] Gottlieb DJ, Punjabi NM, Newman AB, Resnick HE, Redline S, Baldwin CM, et al. Association of sleep time with diabetes mellitus and impaired glucose tolerance. Arch Intern Med 2005;165:863–7. doi:10.1001/archinte.165.8.863. [9] Chao C-Y, Wu J-S, Yang Y-C, Shih C-C, Wang R-H, Lu F-H, et al. Sleep duration is a potential risk factor for newly diagnosed type 2 diabetes mellitus. Metab Clin Exp 2011;60:799–804. doi:10.1016/j.metabol.2010.07.031. [10] Laugsand LE, Vatten LJ, Platou C, Janszky I. Insomnia and the risk of acute myocardial infarction: a population study. Circulation 2011;124:2073–81. doi:10.1161/CIRCULATIONAHA.111.025858. [11] Vgontzas AN, Fernandez-Mendoza J, Liao D, Bixler EO. Insomnia with objective short sleep duration: the most biologically severe phenotype of the disorder. Sleep Med Rev 2013;17:241–54. doi:10.1016/j.smrv.2012.09.005. [12] Lin C-L, Chien W-C, Chung C-H, Wu F-L. Risk of type 2 diabetes in patients with insomnia: A population-based historical cohort study. Diabetes Metab Res Rev 2018;34. doi:10.1002/dmrr.2930. [13] Bertisch SM, Pollock BD, Mittleman MA, Buysse DJ, Bazzano LA, Gottlieb DJ, et al. Insomnia with Objective Short Sleep Duration and Risk of Incident Cardiovascular Disease and All-Cause Mortality: Sleep Heart Health Study. Sleep 2018. doi:10.1093/sleep/zsy047. [14] Baglioni C, Battagliese G, Feige B, Spiegelhalder K, Nissen C, Voderholzer U, et al. Insomnia as a predictor of depression: a meta-analytic evaluation of longitudinal epidemiological studies. J Affect Disord 2011;135:10–9. doi:10.1016/j.jad.2011.01.011. [15] Fernandez-Mendoza J, Calhoun S, Bixler EO, Pejovic S, Karataraki M, Liao D, et al. Insomnia with objective short sleep duration is associated with deficits in neuropsychological performance: a general population study. Sleep 2010;33:459–65. [16] Fortier-Brochu E, Beaulieu-Bonneau S, Ivers H, Morin CM. Insomnia and daytime cognitive performance: a meta-analysis. Sleep Med Rev 2012;16:83–94. doi:10.1016/j.smrv.2011.03.008. [17] Riemann D, Spiegelhalder K, Feige B, Voderholzer U, Berger M, Perlis M, et al. The hyperarousal model of insomnia: a review of the concept and its evidence. Sleep Med Rev 2010;14:19–31. doi:10.1016/j.smrv.2009.04.002.
35
1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105
[18] Feige B, Baglioni C, Spiegelhalder K, Hirscher V, Nissen C, Riemann D. The microstructure of sleep in primary insomnia: An overview and extension. International Journal of Psychophysiology 2013;89:171–80. doi:10.1016/j.ijpsycho.2013.04.002. [19] Riemann D, Baglioni C, Bassetti C, Bjorvatn B, Dolenc Groselj L, Ellis JG, et al. European guideline for the diagnosis and treatment of insomnia. J Sleep Res 2017;26:675–700. doi:10.1111/jsr.12594. [20] Hobson JA. Sleep is of the brain, by the brain and for the brain. Nature 2005;437:1254– 6. doi:10.1038/nature04283. [21] Morin CM, Vallières A, Guay B, Ivers H, Savard J, Mérette C, et al. Cognitive behavioral therapy, singly and combined with medication, for persistent insomnia: a randomized controlled trial. JAMA 2009;301:2005–15. doi:10.1001/jama.2009.682. [22] Newell J, Mairesse O, Verbanck P, Neu D. Is a one-night stay in the lab really enough to conclude? First-night effect and night-to-night variability in polysomnographic recordings among different clinical population samples. Psychiatry Research 2012;200:795–801. doi:10.1016/j.psychres.2012.07.045. [23] Riedel BW, Winfield CF, Lichstein KL. First night effect and reverse first night effect in older adults with primary insomnia: does anxiety play a role? Sleep Medicine 2001;2:125–33. doi:10.1016/S1389-9457(00)00054-X. [24] Sateia MJ. International Classification of Sleep Disorders-Third Edition. Chest 2014;146:1387–94. doi:10.1378/chest.14-0970. [25] Buysse DJ, Reynolds CF, Monk TH, Berman SR, Kupfer DJ. The Pittsburgh sleep quality index: A new instrument for psychiatric practice and research. Psychiatry Research 1989;28:193–213. doi:10.1016/0165-1781(89)90047-4. [26] Morin CM, Belleville G, Bélanger L, Ivers H. The Insomnia Severity Index: Psychometric Indicators to Detect Insomnia Cases and Evaluate Treatment Response. Sleep 2011;34:601–8. doi:10.1093/sleep/34.5.601. [27] Castro LS, Poyares D, Leger D, Bittencourt L, Tufik S. Objective prevalence of insomnia in the São Paulo, Brazil epidemiologic sleep study. Ann Neurol 2013;74:537– 46. doi:10.1002/ana.23945. [28] Bastien CH, Ceklic T, St-Hilaire P, Desmarais F, Pérusse AD, Lefrançois J, et al. Insomnia and sleep misperception. Pathologie Biologie 2014;62:241–51. doi:10.1016/j.patbio.2014.07.003. [29] Edinger JD, Krystal AD. Subtyping primary insomnia: is sleep state misperception a distinct clinical entity? Sleep Medicine Reviews 2003;7:203–14. doi:10.1053/smrv.2002.0253. [30] Perlis ML, Merica H, Smith MT, Giles DE. Beta EEG activity and insomnia. Sleep Medicine Reviews 2001;5:365–76. doi:10.1053/smrv.2001.0151. [31] Krystal JH, Carter CS, Geschwind D, Manji HK, March JS, Nestler EJ, et al. It is time to take a stand for medical research and against terrorism targeting medical scientists. Biol Psychiatry 2008;63:725–7. doi:10.1016/j.biopsych.2008.03.005. [32] Cervena K, Espa F, Perogamvros L, Perrig S, Merica H, Ibanez V. Spectral analysis of the sleep onset period in primary insomnia. Clinical Neurophysiology 2014;125:979–87. doi:10.1016/j.clinph.2013.10.010. [33] Freedman RR. EEG power spectra in sleep-onset insomnia. Electroencephalogr Clin Neurophysiol 1986;63:408–13. [34] Riedner BA, Goldstein MR, Plante DT, Rumble ME, Ferrarelli F, Tononi G, et al. Regional Patterns of Elevated Alpha and High-Frequency Electroencephalographic Activity during Nonrapid Eye Movement Sleep in Chronic Insomnia: A Pilot Study. Sleep 2016;39:801–12. doi:10.5665/sleep.5632. [35] Feige B, Al-Shajlawi A, Nissen C, Voderholzer U, Hornyak M, Spiegelhalder K, et al.
36
1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155
[36]
[37]
[38]
[39] [40] [41]
[42]
[43] [44]
[45]
[46] [47]
[48]
[49]
[50]
[51]
Does REM sleep contribute to subjective wake time in primary insomnia? A comparison of polysomnographic and subjective sleep in 100 patients. Journal of Sleep Research 2008;17:180–90. doi:10.1111/j.1365-2869.2008.00651.x. Christensen JAE, Wassing R, Wei Y, Ramautar JR, Lakbila-Kamal O, Jennum PJ, et al. Data-Driven Analysis of EEG Reveals Concomitant Superficial Sleep During Deep Sleep in Insomnia Disorder. Frontiers in Neuroscience 2019;13. doi:10.3389/fnins.2019.00598. Khazaie H, Veronese M, Noori K, Emamian F, Zarei M, Ashkan K, et al. Functional reorganization in obstructive sleep apnoea and insomnia: A systematic review of the resting-state fMRI. Neuroscience & Biobehavioral Reviews 2017;77:219–31. doi:10.1016/j.neubiorev.2017.03.013. Kay DB, Karim HT, Soehner AM, Hasler BP, James JA, Germain A, et al. Subjective– Objective Sleep Discrepancy Is Associated With Alterations in Regional Glucose Metabolism in Patients With Insomnia and Good Sleeper Controls. Sleep 2017;40. doi:10.1093/sleep/zsx155. Center for Drug Evaluation and Research. Guidance for Industry: Guidelines for the clinical evaluation of Hypnotic Drugs 1997. Guideline on medicinal products for the treatment of insomnia 2011. Arnal PJ, Thorey V, Ballard ME, Hernandez AB, Guillot A, Jourde H, et al. The Dreem Headband as an Alternative to Polysomnography for EEG Signal Acquisition and Sleep Staging. BioRxiv 2019. doi:10.1101/662734. Debellemaniere E, Chambon S, Pinaud C, Thorey V, Dehaene D, Léger D, et al. Performance of an Ambulatory Dry-EEG Device for Auditory Closed-Loop Stimulation of Sleep Slow Oscillations in the Home Environment. Frontiers in Human Neuroscience 2018;12. doi:10.3389/fnhum.2018.00088. LeCun Y, Bengio Y, Hinton G. Deep learning. Nature 2015;521:436–44. doi:10.1038/nature14539. Obermeyer Z, Emanuel EJ. Predicting the Future — Big Data, Machine Learning, and Clinical Medicine. New England Journal of Medicine 2016;375:1216–9. doi:10.1056/NEJMp1606181. Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, et al. Rules for Scoring Respiratory Events in Sleep: Update of the 2007 AASM Manual for the Scoring of Sleep and Associated Events. JCSM 2012;08:597–619. doi:10.5664/jcsm.2172. Iber C, Ancoli-Israel S, Chesson A, Quan S. The AASM Manual for the Scoring of Sleep and Associated Events: Rules, Terminology and Technical Specifications 2007. Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, et al. Rules for Scoring Respiratory Events in Sleep: Update of the 2007 AASM Manual for the Scoring of Sleep and Associated Events. JCSM 2012;08:597–619. doi:10.5664/jcsm.2172. Ermis U, Krakow K, Voss U. Arousal thresholds during human tonic and phasic REM sleep: Arousal threshold in tonic and phasic REM. Journal of Sleep Research 2010;19:400–6. doi:10.1111/j.1365-2869.2010.00831.x. Rechtschaffen A, Kales AA. A Manual of Standardized Terminology, Techniques, and Scoring System for Sleep Stages of Human Subjects (Bethesda, MD: US Department of Health, Education and Welfare). 1968. Sallinen M, Kaartinen J, Lyytinen H. Processing of auditory stimuli during tonic and phasic periods of REM sleep as revealed by event-related brain potentials. Journal of Sleep Research 1996;5:220–8. doi:10.1111/j.1365-2869.1996.00220.x. Andrillon T, Nir Y, Cirelli C, Tononi G, Fried I. Single-neuron activity and eye movements during human REM sleep and awake vision. Nature Communications 2015;6:7884. doi:10.1038/ncomms8884.
37
1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182 1183 1184 1185 1186 1187 1188 1189 1190 1191 1192 1193 1194 1195 1196 1197 1198 1199 1200 1201 1202 1203 1204 1205
[52] Arnulf I. The “scanning hypothesis” of rapid eye movements during REM sleep: a review of the evidence. Arch Ital Biol 2011;149:367–82. [53] Steriade M. Sleep, epilepsy and thalamic reticular inhibitory neurons. Trends Neurosci 2005;28:317–24. doi:10.1016/j.tins.2005.03.007. [54] Buzsáki G. Rhythms of the brain. Oxford ; New York: Oxford University Press; 2006. [55] Riedner BA, Vyazovskiy VV, Huber R, Massimini M, Esser S, Murphy M, et al. Sleep homeostasis and cortical synchronization: III. A high-density EEG study of sleep slow waves in humans. Sleep 2007;30:1643–57. [56] Nir Y, Staba R, Andrillon T, Vyazovskiy VV, Cirelli C, Fried I, et al. Regional slow waves and spindles in human sleep. Neuron 2011;70:153–69. doi:10.1016/j.neuron.2011.02.043. [57] Andrillon T, Nir Y, Staba RJ, Ferrarelli F, Cirelli C, Tononi G, et al. Sleep Spindles in Humans: Insights from Intracranial EEG and Unit Recordings. J Neurosci 2011;31:17821–34. doi:10.1523/Jneurosci.2604-11.2011. [58] Siclari F, Bernardi G, Riedner BA, LaRocque JJ, Benca RM, Tononi G. Two Distinct Synchronization Processes in the Transition to Sleep: A High-Density Electroencephalographic Study. SLEEP 2014. doi:10.5665/sleep.4070. [59] Gramfort A. MEG and EEG data analysis with MNE-Python. Frontiers in Neuroscience 2013;7. doi:10.3389/fnins.2013.00267. [60] Gramfort A, Luessi M, Larson E, Engemann DA, Strohmeier D, Brodbeck C, et al. MNE software for processing MEG and EEG data. NeuroImage 2014;86:446–60. doi:10.1016/j.neuroimage.2013.10.027. [61] Haller M, Donoghue T, Peterson E, Varma P, Sebastian P, Gao R, et al. Parameterizing neural power spectra. BioRxiv 2018. doi:10.1101/299859. [62] Gao R, Peterson EJ, Voytek B. Inferring synaptic excitation/inhibition balance from field potentials. NeuroImage 2017;158:70–8. doi:10.1016/j.neuroimage.2017.06.078. [63] Colombo MA, Napolitani M, Boly M, Gosseries O, Casarotto S, Rosanova M, et al. The spectral exponent of the resting EEG indexes the presence of consciousness during unresponsiveness induced by propofol, xenon, and ketamine. NeuroImage 2019;189:631–44. doi:10.1016/j.neuroimage.2019.01.024. [64] Lendner JD, Helfrich RF, Mander BA, Romundstad L, Lin JJ, Walker MP, et al. An Electrophysiological Marker of Arousal Level in Humans. BioRxiv 2019. doi:10.1101/625210. [65] Maris E, Oostenveld R. Nonparametric statistical testing of EEG- and MEG-data. J Neurosci Methods 2007;164:177–90. doi:10.1016/j.jneumeth.2007.03.024. [66] Borbély AA. A two process model of sleep regulation. Hum Neurobiol 1982;1:195–204. [67] Landis JR, Koch GG. The Measurement of Observer Agreement for Categorical Data. Biometrics 1977;33:159. doi:10.2307/2529310. [68] Purcell SM, Manoach DS, Demanuele C, Cade BE, Mariani S, Cox R, et al. Characterizing sleep spindles in 11,630 individuals from the National Sleep Research Resource. Nature Communications 2017;8. doi:10.1038/ncomms15930. [69] Svetnik V, Snyder ES, Ma J, Tao P, Lines C, Herring WJ. EEG spectral analysis of NREM sleep in a large sample of patients with insomnia and good sleepers: effects of age, sex and part of the night. Journal of Sleep Research 2017;26:92–104. doi:10.1111/jsr.12448. [70] Silva A, Andersen ML, De Mello MT, Bittencourt LRA, Peruzzo D, Tufik S. Gender and age differences in polysomnography findings and sleep complaints of patients referred to a sleep laboratory. Brazilian Journal of Medical and Biological Research 2008;41:1067–75. doi:10.1590/S0100-879X2008001200005. [71] Bastien CH, LeBlanc M, Carrier J, Morin CM. Sleep EEG Power Spectra, Insomnia, and
38
1206 1207 1208 1209 1210 1211 1212 1213 1214 1215 1216 1217 1218 1219 1220 1221 1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255
Chronic Use of Benzodiazepines. Sleep 2003;26:313–7. doi:10.1093/sleep/26.3.313. [72] Siclari F, Larocque JJ, Postle BR, Tononi G. Assessing sleep consciousness within subjects using a serial awakening paradigm. Front Psychol 2013;4:542. doi:10.3389/fpsyg.2013.00542. [73] Krystal AD, Edinger JD, Wohlgemuth WK, Marsh GR. NREM sleep EEG frequency spectral correlates of sleep complaints in primary insomnia subtypes. Sleep 2002;25:630–40. [74] St-Jean G, Turcotte I, Bastien CH. Cerebral asymmetry in insomnia sufferers. Front Neurol 2012;3:47. doi:10.3389/fneur.2012.00047. [75] Voytek B, Kramer MA, Case J, Lepage KQ, Tempesta ZR, Knight RT, et al. AgeRelated Changes in 1/f Neural Electrophysiological Noise. Journal of Neuroscience 2015;35:13257–65. doi:10.1523/JNEUROSCI.2332-14.2015. [76] Peterson EJ, Rosen BQ, Campbell AM, Belger A, Voytek B. 1/ neural noise is a better predictor of schizophrenia than neural oscillations. BioRxiv 2018. doi:10.1101/113449. [77] Bernardi G, Siclari F, Handjaras G, Riedner BA, Tononi G. Local and Widespread Slow Waves in Stable NREM Sleep: Evidence for Distinct Regulation Mechanisms. Frontiers in Human Neuroscience 2018;12. doi:10.3389/fnhum.2018.00248. [78] Esser SK, Hill SL, Tononi G. Sleep homeostasis and cortical synchronization: I. Modeling the effects of synaptic strength on sleep slow waves. Sleep 2007;30:1617–30. doi:10.1093/sleep/30.12.1617. [79] Tononi G, Cirelli C. Sleep and the Price of Plasticity: From Synaptic and Cellular Homeostasis to Memory Consolidation and Integration. Neuron 2014;81:12–34. doi:10.1016/j.neuron.2013.12.025. [80] Diekelmann S, Born J. The memory function of sleep. Nat Rev Neurosci 2010;11:114– 26. [81] Léger D, Debellemaniere E, Rabat A, Bayon V, Benchenane K, Chennaoui M. SlowWave Sleep: From the Cell to the Clinic. Sleep Medicine Reviews 2018. doi:10.1016/j.smrv.2018.01.008. [82] Aeschbach D, Dijk DJ, Borbély AA. Dynamics of EEG spindle frequency activity during extended sleep in humans: relationship to slow-wave activity and time of day. Brain Res 1997;748:131–6. doi:10.1016/s0006-8993(96)01275-9. [83] Plante DT, Goldstein MR, Cook JD, Smith R, Riedner BA, Rumble ME, et al. Effects of oral temazepam on sleep spindles during non-rapid eye movement sleep: A high-density EEG investigation. European Neuropsychopharmacology 2015;25:1600–10. doi:10.1016/j.euroneuro.2015.06.005. [84] Dijk DJ, Roth C, Landolt HP, Werth E, Aeppli M, Achermann P, et al. Melatonin effect on daytime sleep in men: suppression of EEG low frequency activity and enhancement of spindle frequency activity. Neurosci Lett 1995;201:13–6. doi:10.1016/03043940(95)12118-n. [85] Bonnet MH, Arand DL. Hyperarousal and insomnia: State of the science. Sleep Medicine Reviews 2010;14:9–15. doi:10.1016/j.smrv.2009.05.002. [86] Vargas I, Vgontzas AN, Abelson JL, Faghih RT, Morales KH, Perlis ML. Altered ultradian cortisol rhythmicity as a potential neurobiologic substrate for chronic insomnia. Sleep Med Rev 2018;41:234–43. doi:10.1016/j.smrv.2018.03.003. [87] Bastien CH, St-Jean G, Morin CM, Turcotte I, Carrier J. Chronic Psychophysiological Insomnia: Hyperarousal and/or Inhibition Deficits? An ERPs Investigation. Sleep 2008;31:887–98. doi:10.1093/sleep/31.6.887. [88] Turcotte I, St-Jean G, Bastien CH. Are individuals with paradoxical insomnia more hyperaroused than individuals with psychophysiological insomnia? Event-related
39
1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282
[89]
[90]
[91] [92] [93]
[94]
[95]
[96]
potentials measures at the peri-onset of sleep. International Journal of Psychophysiology 2011;81:177–90. doi:10.1016/j.ijpsycho.2011.06.008. Yang C-M, Lo H-S. ERP Evidence of Enhanced Excitatory and Reduced Inhibitory Processes of Auditory Stimuli During Sleep in Patients With Primary Insomnia. Sleep 2007;30:585–92. doi:10.1093/sleep/30.5.585. Wei Y, Ramautar JR, Colombo MA, Stoffers D, Gómez-Herrero G, van der Meijden WP, et al. I Keep a Close Watch on This Heart of Mine: Increased Interoception in Insomnia. SLEEP 2016;39:2113–24. doi:10.5665/sleep.6308. Pigeon WR, Perlis ML. Sleep homeostasis in primary insomnia. Sleep Med Rev 2006;10:247–54. doi:10.1016/j.smrv.2005.09.002. De Gennaro L, Ferrara M. Sleep spindles: an overview. Sleep Med Rev 2003;7:423–40. Ayoub A, Aumann D, Hörschelmann A, Kouchekmanesch A, Paul P, Born J, et al. Differential Effects on Fast and Slow Spindle Activity, and the Sleep Slow Oscillation in Humans with Carbamazepine and Flunarizine to Antagonize Voltage-Dependent Na+ and Ca2+ Channel Activity. Sleep 2013;36:905–11. doi:10.5665/sleep.2722. Jain SV, Glauser TA. Effects of epilepsy treatments on sleep architecture and daytime sleepiness: An evidence-based review of objective sleep metrics. Epilepsia 2014;55:26– 37. doi:10.1111/epi.12478. Stephansen JB, Olesen AN, Olsen M, Ambati A, Leary EB, Moore HE, et al. Neural network analysis of sleep stages enables efficient diagnosis of narcolepsy. Nature Communications 2018;9. doi:10.1038/s41467-018-07229-3. Bertisch SM, Pollock BD, Mittleman MA, Buysse DJ, Bazzano LA, Gottlieb DJ, et al. Insomnia with objective short sleep duration and risk of incident cardiovascular disease and all-cause mortality: Sleep Heart Health Study. Sleep 2018;41. doi:10.1093/sleep/zsy047.
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Figures and Tables: Table 1:
Age (years) Gender (% Females)
Controls (N=89)
SSM (N=59)
Insomnia (N=288)
Group Effect
34.5 ± 1.3
39.4 ± 1.5 (*) 76.2 (***) 399 ± 7.6 (ns) 20.5 ± 2.9 (***) 34.0 ± 3.6 (***) 88.3 ± 0.8 (***) 11.7 ± 0.8 (***) 1.7 ± 0.1
45.7 ± 0.8 (***) 68.6 (***) 361 ± 5.1 (***) 49.4 ± 3.1 (ns) 94.9 ± 4.2 (***) 72.0 ± 0.8 (***) 27.8 ± 0.8 (***) 2.0 ± 0.1
50.0 ± 1.1 (*) 19.5 ± 1.2 (***) 17.1 ± 0.7 (*) 4.1 ± 0.2
41.7 ± 0.7 (***) 15.3 ± 0.5 (ns) 12.9 ± 0.3 (**) 3.6 ± 0.1 3.1 ± 0.2 (***) 0.23 ± 0.01
1.5.10-10 (***) 1.5.10-22 (***) 3.2.10-5 (***) 5.2.10-6 (***) 1.5.10-10 (***) 9.5.10-16 (***) 2.8.10-15 (***) 0.73 (ns) 1.6.10-8 (***) 0.002 (ns) 2.8.10-6 (***) 0.03 (ns) 3.4.10-4 (**) 0.009 (ns) 0.006 (ns) 3.3.10-11 (***) 1.6.10-7 (***) 0.02 (ns)
21.3
TST (minutes)
406 ± 5.4
SOL (minutes)
50.3 ± 6.0
WASO (minutes)
57.1 ± 4.2
Sleep Efficiency (%)
79.7 ± 1.1
% Wake
20.3 ± 1.1
% N1
2.4 ± 0.2
% N2
47.1 ± 0.9
% N3
15.1 ± 0.7
% REM
15.0 ± 0.5
# Cycles
3.9 ± 0.1
# REM episodes
4.3 ± 0.3
Arousals NREM (/min)
0.20 ± 0.01
3.6 ± 0.2 (ns) 0.18 ± 0.01
Arousals REM (/min)
0.20 ± 0.01
0.24 ± 0.02
0.22 ± 0.01
Spindles (/min)
1.6 ± 0.1
Slow Waves (/min)
6.9 ± 0.4
REMS (/min)
6.4 ± 0.3
3.6 ± 0.3 (***) 4.6 ± 0.4 (***) 4.7 ± 0.3
2.7 ± 0.1 (***) 4.0 ± 0.2 (***) 5.1 ± 0.2
p-value, (corrected threshold)
1287
41
1288 1289 1290 1291 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329 1330 1331 1332
Table 1: Demographics and sleep differences across controls (GS), SSM and INS patients. Numbers show the average and standard-error-of-the-mean (mean ± SEM) across individuals. The Group Effect column shows the p-values for an ANCOVA on groups with age and gender as covariates. In case of a significant group effect (Bonferroni correction for N=18 comparisons), the stars denote the corrected significance levels of post-hoc two-sided unpaired t-tests (GS vs. SSM and GS vs. INS resp.). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
42
1333 1334
Table 2: Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
GS. vs. CI (VI) Power - [0-0.5] Hz - Wake (200) Power - [0.5-1] Hz - N2 (68.9) Power - [0.5-1] Hz - NREM (56.5) Power - ∂ - N2 (40.1) Power - ∂ - NREM (39.6) Power - [1.5-2] Hz - Wake (39.6) Power - [0-0.5] Hz - N2 (33.7) Power - [0-0.5] Hz - NREM (32.5) Power - [0.5-1] Hz - Wake (30.2) Power - [0-1.5] Hz – REM (29.1) Power - [1.5-2] Hz - N2 (27.4) Power - ∂ - Wake (27.3) Power - [1-1.5] Hz - NREM (26.2) Power - [1.5-2] Hz - NREM (25.6) Power - [0.5-1] Hz - REM (24.5) Power - [5.5-6] Hz - REM (24.1) Power - [1-1.5] Hz - N3 (23.8) Power - [6-6.5] Hz - REM (23.8) Power - [2-2.5] Hz - Wake (23.7) Power - [3.5-4] Hz - Wake (23.0)
GS. vs. SSM vs. INS (VI) Power - [0-0.5] Hz - Wake (99.5) Hypno - duration - Wake (46.2) Power - [0.5-1] Hz - N2 (42.4) Hypno - sleep efficiency (38.6) Hypno - % Wake (31.7) Power - [0.5-1] Hz - NREM (28.4)
SSM vs. INS (VI) Hypno - duration - Wake (196.8) Hypno - sleep efficiency (145.7) Hypno - % Wake (103.8) Hypno - transition - W>W (80.8) Hypno - WASO (69.7) Hypno - transition - W>N2 (63.8) Spindle – density C3/4 - N3 (47.0) Hypno - transition - N2>W (43.4) Spindle - duration C3/4 - N2 (42.1) Power - [10-10.5] Hz - N1 (40.9) Hypno - duration - REM (39.5)
Power - ∂ - N2 (26.3) Hypno - transition - W>W (25.9) Power - [1.5-2] Hz - Wake (23.6) Power - [0-0.5] Hz - N2 (21.1) Power - [0-0.5] Hz - NREM (20.8) Power - ∂ - NREM Hypno - sleep latency (38.2) (20.6) Hypno - WASO Hypno - duration - bed-time (20.6) (36.9) Power - [0.5-1] Hz - Wake Hypno - duration - sleep time (20.5) (36.0) Hypno - transition - W>N2 Hypno - transition - N3>N2 (20.3) (34.8) Power - [3.5-4] Hz - Wake Hypno - duration - cycle (19.7) (34.6) Power - [0.5-1] Hz - REM Hypno - arousals - N3 (18.9) (33.2) Power - ∂ - Wake Spindle - freq. F3/4 – N3 (18.6) (32.9) Power - [2-2.5] Hz - Wake Spindle - duration F3/4 – N3 (18.4) (32.0) Power - ß - Wake Power - [4 -4.5] Hz - REM (18.1) (31.4)
1335 1336
43
1337 1338 1339 1340 1341 1342 1343 1344
Table 2: Classifiers’ top-features. For each feature used by a classifier, a Variable Importance (VI) index can be calculated, which expresses the weight of this particular feature in the classification. We selected the top20 features for each classifier (1st column: 2-class GS vs. CI; 2nd column: 3-class GS vs. SSM vs. INS; 3rd column: 2-class SSM vs. INS) and show the name of these features sorted in descending order of VI value. For each feature, the VI value is also displayed (parentheses).
44
1345 1346
1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 1358 1359 1360 1361 1362 1363 1364 1365 1366
Figure 1:
Figure 1: Sleep stages and stages-transitions across controls, SSM and insomnia patients. Top: Proportion of time spent in all sleep stages (wakefulness, NREM1, NREM2, NREM3 and REM sleep) across the three different groups (GS (controls), INS (insomnia) and SSM patients) for the first half (left) and the second half (right) of the night. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. ANCOVAs were used to assess group-differences for each stage and time period. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/10). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5. The horizontal line between the left and right part of the graph denotes the only significant interaction between groups and night-segment. Bottom: Matrices of state-transition probabilities for the three groups (GS, SSM and INS). Each cell shows the probability to transition from a state at time t to another state at time t+1. Probabilities were extracted from the individual hypnograms (30s time-windows). Red-squares show the cells showing a significant modulation across groups according to ANCOVAs. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/25).
45
1367 1368
Figure 2:
1369 1370 1371
46
1372 1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383 1384 1385 1386 1387 1388 1389 1390 1391 1392
Figure 2: Spectral features can distinguish good sleepers from insomnia patients with or without SSM. (a) Supervised classifiers were trained on relative power from 0 to 20Hz (step: 0.5Hz) to classify PSG recordings into 3 clinical groups (GS, INS and SSM). The graph shows the classifiers’ performance (ROC curve area), quantifying the discriminability of the different groups at each frequency bin (chance-level: 0.5; see Methods). The procedure was applied for NREM (blue) and REM (green) epochs separately. Colored horizontal bars showed significant clusters when comparing the ROC areas between NREM and REM epochs (cluster permutation; blue: NREM>REM; green: REM>NREM, pcluster<0.001). (b) Relative power spectra for the delta ([0.5-4]Hz), theta/alpha ([5-11]Hz), sigma ([11-15]Hz) and beta ([1620]Hz) bands across the entire night. Power was normalized across the entire [0-20]Hz spectrum and expressed in percentage (see Methods). Each night recording being of a different length, their duration was also normalized and is expressed in percentage. Only epochs in NREM1, NREM2, NREM3 and REM sleep were here considered. Time 0 corresponds to sleep onset (defined as either the first two consecutive epochs of NREM1 or first epoch of NREM2, NREM3 and REM sleep). Black horizontal lines show significance statistical differences across groups as assessed by ANCOVAs at the sample level and corrected for multiple comparisons with a cluster permutation approach (see Methods). Clusters p-values were also corrected for multiple comparisons with Bonferroni (threshold: 0.05/4).
47
1393 1394
1395 1396 1397 1398 1399 1400 1401 1402 1403 1404 1405 1406
Figure 3:
Figure 3: CI patients have reduced spectral slopes in NREM sleep (a) Distribution of the slope of the 1/f background of the EEG spectrum (see Methods for details), computed on the power spectrum averaged by sleep stage (Wake, NREM1, NREM2, NREM3 and REM) and across individuals for each group. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. (b) Same data but ordered by ascending slope values in the GS group. ANCOVAs were used to assess group-differences for each sleep-stage. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/5). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
48
1407 1408
Figure 4:
1409 1410
49
1411 1412 1413 1414 1415 1416 1417 1418 1419 1420 1421
Figure 4: Properties of sleep slow waves across GS individuals, SSM and INS patients. Panels show the differences across groups for several parameters of sleep slow waves (from top to bottom: density of detected slow waves (waves/minute), peak-to-peak amplitude ( V), slow-wave frequency (Hz) and slope ( V/s); see Methods for details). These properties are shown for slow waves detected in NREM2 (left) and NREM3 (right) for central and frontal electrodes. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. ANCOVAs were used to assess group-differences for each sleep-stage and electrode locations. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/16). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
50
1422 1423
Figure 5:
1424 1425
51
1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436
Figure 5: Properties of sleep spindles GS individuals, SSM and INS patients. Panels show the differences across groups for several parameters of sleep spindles (from top to bottom: density of detected spindles (spindles/minutes), maximum amplitude of the spindles ( V), duration (s) and frequency (Hz); see Methods for details). These properties are shown for spindles detected in NREM2 (left) and NREM3 (right) for central and frontal electrodes. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. ANCOVAs were used to assess group-difference for each sleep-stage and electrode locations. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/16). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
52
1437 1438
Figure 6:
1439 1440
53
1441 1442 1443 1444 1445 1446 1447 1448 1449 1450 1451 1452 1453 1454
Figure 6: Supervised classifiers can automatically diagnose insomnia and insomnia subtypes. A series of classifiers were trained on features obtained from the visual inspection of the PSG recordings (visual, V) or computed from the EEG signal (computed, C) or both (V+C). Different classifications were tested (top: good sleepers (GS) vs. insomnia patients (CI: SSM+INS); middle: GS vs. SSM vs. INS (3 classes); bottom: INS vs. SSM). For each classifier type, 100 iterations of the classification were performed. Violin plots (left) show the distribution of the Cohen’s κ values (classifiers’ accuracy) across iterations. Confusion matrices (left) show the average performance of the visual and computed classifiers (horizontal lines show predicted labels, vertical lines real labels). Number in each cell represents the % of individuals within a particular group (e.g. CI) for which a specific prediction has been made (columns add up to 100%).
54
S1389-9457(19)31644-2
DOI:
https://doi.org/10.1016/j.sleep.2019.12.002
Reference:
SLEEP 4251
To appear in:
Sleep Medicine
Received Date: 19 September 2019 Revised Date:
22 November 2019
Accepted Date: 4 December 2019
Please cite this article as: Andrillon T, Solelhac G, Bouchequet P, Romano F, Le Brun M-P, Brigham M, Chennaoui M, Léger D, Revisiting the value of polysomnographic data in insomnia: more than meets the eye, Sleep Medicine, https://doi.org/10.1016/j.sleep.2019.12.002. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Elsevier B.V. All rights reserved.
Author Contribution Statement Conceptualization: TA, GS, DL; Data curation: GS, PB, FR, DL; Formal analysis: TA, GS, PB, MPLB, MB; Funding acquisition: DL; Investigation: TA, GS, PB, M-PLB, MB, DL; Methodology: TA, GS, PB, FR, M-PLB, MB, DL; Project administration: DL; Resources: DL, MC; Software: PB, GS, M-PLB, MB; Supervision: DL; Validation: DL; Visualization: TA, GS, PB; Roles/Writing - original draft: TA, GS, DL; Writing - review & editing: TA, GS, PB, FR, M-PLB, MB, MC, DL.
Highlights: - PSG allows to significantly differentiate good sleepers from subjects with insomnia. -
EEG spectrum and sleep microstructure reveal common physiological signatures of insomnia.
-
Insomnia seems characterized by increased cortical excitability during sleep.
-
AI classifiers allow to classify good sleepers from insomnia patients.
-
AI and PSG should be used more extensively in the diagnosis of insomnia
1
Revisiting the value of polysomnographic data in insomnia: more than
2
meets the eye
3 4
Thomas Andrillon a-b, Geoffroy Solelhac a-c*, Paul Bouchequet a-c*, Francesco Romano a-c,
5
Max-Pol Le Brund, Marco Brigham d, Mounir Chennaoui a-e & Damien Léger a-c.
6
a. Université de Paris, Equipe d'accueil VIgilance FAtigue SOMmeil (VIFASOM) EA 7330,
7
Paris, France;
8
b. School of Psychological Sciences and Turner Institute for Brain and Mental Health,
9
Monash University, Melbourne, Victoria, Australia
10
c. Assistance Publique-Hôpitaux de Paris (APHP) Hôtel Dieu, Centre du Sommeil et de la
11
Vigilance, Paris, France
12
d. Ecole Polytechnique, Centre de mathématiques appliquées (CMAP), Palaiseau, France
13
e. Institut de recherche biomédicale des armées (IRBA), Brétigny-sur-Orge, France
14
*: equal contribution,
15 16
Corresponding authors: [email protected]
17 18 19 20
1
21
Abstract (max. 250)
22
BACKGROUND: Polysomnography (PSG) is not recommended as a diagnostic tool in
23
insomnia. However, this consensual approach might be tempered in the light of two ongoing
24
transformations in sleep research: big data and artificial intelligence (AI).
25 26
METHOD: We analyzed the PSG of 347 patients with chronic insomnia, including 59 with
27
Sleep State Misperception (SSM) and 288 without (INS). 89 good sleepers (GS) were used as
28
controls. PSGs were compared regarding: (1) macroscopic indexes derived from the
29
hypnogram, (2) mesoscopic indexes extracted from the electroencephalographic (EEG)
30
spectrum, (3) sleep microstructure (slow waves, spindles). We used supervised algorithms to
31
differentiate patients from GS.
32 33
RESULTS: Macroscopic features illustrate the insomnia conundrum, with SSM patients
34
displaying similar sleep metrics as GS, whereas INS patients show a deteriorated sleep.
35
However, both SSM and INS patients showed marked differences in EEG spectral
36
components (meso) compared to GS, with reduced power in the delta band and increased
37
power in the theta/alpha, sigma and beta bands. INS and SSM patients showed decreased
38
spectral slope in NREM. INS and SSM patients also differed from GS in sleep microstructure
39
with fewer and slower slow waves and more and faster sleep spindles. Importantly, SSM and
40
INS patients were almost indistinguishable at the meso and micro levels. Accordingly,
41
unsupervised classifiers can reliably categorize insomnia patients and GS (Cohen’s =0.87)
42
but fail to tease apart SSM and INS patients when restricting classifiers to micro and meso
43
features ( =0.004).
44 45
CONCLUSION: AI analyses of PSG recordings can help moving insomnia diagnosis beyond
46
subjective complaints and shed light on the physiological substrate of insomnia.
47 48
2
49 50 51
Highlights: - PSG allows to significantly differentiate good sleepers from subjects with insomnia. -
EEG spectrum and sleep microstructure reveal common physiological signatures of insomnia.
52 53
-
Insomnia seems characterized by increased cortical excitability during sleep.
54
-
AI classifiers allow to classify good sleepers from insomnia patients.
55
-
AI and PSG should be used more extensively in the diagnosis of insomnia
56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72
Keywords: Artificial intelligence-machine learning-insomnia-polysomnography-REM-NREM sleepsupervised classification Abbreviations NREM: Non-Rapid Eye Movement REM: Rapid Eye Movement PSG: Polysomnography AI: Artificial Intelligence ML: Machine Learning EEG: Electroencephalography CI: Chronic Insomnia SSM: Sleep State Misperception SOL: Sleep Onset Latency TST: Total Sleep Time: WASO: Wake After Sleep Onset
73 74 75
Acknowledgements This work was supported by the Banque Publique d’Investissement (BPI) supporting the
76
MORPHEO project associating three partners: RHYTHM (Paris, France); Université Paris
77
Descartes (Paris, France) and Ecole Polytechnique (Palaiseau, France). TA is supported by
78
the International Brain Research Organization (IBRO), the Human Frontiers Science Program
79
(HFSP, LT000362/2018) and the Australian National Health and Medical Research
80
(NHMRC, ECF-APP11614980).
81
3
82
Introduction
83
Sleep is a need, like eating or breathing [1,2]. Yet, we are not equal in the face of sleep
84
and some individuals have a hard time fulfilling this basic physiological imperative [3,4]. In
85
particular, individuals suffering from Chronic Insomnia (CI, here referred as “insomnia”) are
86
characterized by difficulties in initiating or maintaining sleep and/or a chronic sensation of
87
non-restorative sleep. The associated sleep deficit has substantial daytime consequences,
88
notably in terms of well-being, productivity and health [5]. Insomnia is the most common
89
sleep disorder and affects between 10 and 20 % of the general population of industrialized
90
countries [6,7], which makes it a major public health concern. Accordingly, insomnia has
91
been associated with a broad range of comorbidities: it has been linked to an increased risk of
92
cardiovascular diseases or diabetes [8–13], psychiatric disorders (anxiety, depression, suicide)
93
[11,14], cognitive impairments and neurodegenerative disorders [11,15,16].
94
There is a growing literature on the physiological underpinnings of insomnia (see [17–
95
19] for reviews). Yet, contrary to other sleep disorders, insomnia is almost never diagnosed or
96
assessed via objective physiological recordings. This is particularly striking when considering
97
that sleep is usually described as a phenomenon “of the brain, by the brain, for the brain”
98
[20]. The main reason advanced is that PSG recordings are costly and often fail to reveal
99
sleep anomalies despite clear subjective complaints of CI [19]. Besides, it is unclear if
100
clinicians would treat patients differently with the additional information from PSG
101
recordings. Indeed, the most consensual therapy of insomnia, the so-called cognitive
102
behavioral therapy (CBT), is based mostly on subjective assessments of sleep quality and
103
quantity by patients themselves [21]. Finally, it has been argued that a single night of PSG
104
recordings is not enough to assess insomnia. Phenomena like the “first night effect” (FNE, i.e.
105
deterioration of sleep when sleeping in a new environment, like a sleep clinic [22]) are
106
regularly observed in good sleepers but can be often reversed in individuals with insomnia
107
[23], questioning the reliability of PSG recordings as a diagnostic tool for insomnia.
108
Consequently, the 3rd edition of the International classification of sleep disorders
109
(ICSD-3) [24] recommends a diagnosis of insomnia purely based on subjective complaints. In
110
this framework, CI severity is assessed by self-report questionnaires like the Pittsburgh Sleep
111
Quality Index (PSQI) or the Insomnia Severity Index (ISI) [25,26]. PSG recordings are
112
specifically limited to rule out comorbidities commonly associated with insomnia such as
113
sleep apnea (OSA) or periodic leg movements (PLM).
4
114
The limited use of PSG recordings in the diagnosis of insomnia could stem from the
115
notoriously noisy relationship between subjective and objective estimates of sleep duration
116
and sleep quality [19], although it could be argued that these discrepancies are precisely what
117
makes PSG valuable since it provides complementary information to subjective reports. The
118
largest objective epidemiological survey on insomnia, made in 1042 inhabitants of Sao Paulo
119
Brazil, reported that only 35% of subjects with an ICSD-3 diagnosis of insomnia had a PSG
120
confirming insomnia [27]. In addition, 23% of those who declare themselves good sleepers
121
matched the PSG insomnia criteria [27]. The case of the so-called Sleep State Misperception
122
(also referred to as “paradoxical insomnia”) is particularly telling as, in such cases, there is a
123
direct contradiction between the subjective complaints of insomnia and the visual inspection
124
of PSG recordings by sleep experts [28,29]. Importantly, even if insomnia patients with SSM
125
do not show signs of a significantly degraded sleep, they still feel they have poor sleep and do
126
present the daytime consequences of insomnia, which argues in favor of retaining the
127
subjective complaints and sometimes discarding the information extracted from PSG
128
recordings.
129
Nonetheless, previous research has evidenced robust markers of insomnia within PSG
130
recordings. For example, the spectral decomposition of the EEG signal allows tracking neural
131
dynamics across vigilance states and evidenced differences between good sleepers and
132
insomnia patients [30–33]. The discovery that insomnia is associated with heightened levels
133
of high-frequency activity during sleep [30], a rhythm typically associated with wakefulness,
134
supports the “hyperarousal model” of insomnia [17], that is the notion that individuals
135
suffering from insomnia are hypersensitive to perturbations, notably during their sleep. Others
136
have found increased levels of alpha oscillations during sleep, another wakeful pattern of
137
brain activity that normally disappears during sleep [34]. Sleep also appears more fragile in
138
insomnia: with more frequent micro-arousals [35] and the preservation of neural signatures of
139
light sleep during deeper sleep stages [36]. This sleep fragility could be due to an increased
140
sensitivity to external [39–41] or internal perturbations [42], according to the hyperarousal
141
model. The fact that attentional networks seem more activated during sleep in insomnia
142
patients [37,38] could explain this increased sensitivity to external and internal perturbations.
143
PSG recordings also play a central role in the evaluation of insomnia treatments. Drug
144
agencies, like the American Food and Drug Agency (FDA) require positive evidence from
145
PSG studies to release new hypnotics [39]. The European Medicines Agency (EMA)
146
guidelines [19,40] for assessing insomnia treatments consider PSG recordings “helpful” to
5
147
diagnose insomnia and while drug efficacy is based on “clinically relevant improvement of
148
subjective parameters”, the agency recommends to support these changes with objective data.
149
In addition, PSG data is mandatory for new treatments’ proof of concept.
150
However, even if PSG data contain clinically relevant information regarding insomnia,
151
it does not necessarily imply its use is relevant in clinical settings. PSG are still a costly, time-
152
consuming medical examination, both regarding its acquisition and analysis. Yet, rapid
153
evolutions in the field of Sleep Medicine might offer ways to overcome these practical
154
limitations. First, technological improvements make it now possible to easily and
155
inexpensively record high-quality data at home, for multiple nights, with minimal impact on
156
patients’ life and sleep [41,42]. Second, recent progress in artificial intelligence and machine
157
learning have rendered the analysis of large, multi-modal datasets more efficient and
158
clinically relevant [43,44]. In sleep medicine, such techniques have already transformed the
159
evaluation of PSG recordings and the detection of specific sleep disorders [44–48]. We aim at
160
showing here how similar tools can be applied to insomnia. First, we show it is possible to
161
streamline the analysis of PSG recordings with minimal human intervention. Second, by
162
devising automated, unbiased and exhaustive analyses of physiological data, we propose a
163
reassessment of the benefits and costs of PSG recordings in the context of insomnia.
164
To revisit the value of physiological data for the diagnosis and understanding of
165
insomnia, we undertook a comprehensive analysis of a large dataset of PSG recordings,
166
acquired in a classical clinical setting. Indeed, in the past few years, our sleep clinic (Center
167
for Sleep and Vigilance of the Hôtel-Dieu Hospital in Paris) changed its clinical management
168
of insomnia patients and propose a PSG to all referred patients with a complaint of insomnia
169
lasting for at least 5 years. We present here an analysis of the comparison of these PSG
170
recordings with good sleepers, deprived of insomnia symptoms. In particular, we focused on a
171
multi-level analysis of PSG recordings. We examined classical hypnogram-based metrics of
172
sleep quality and quantity, coupled with the analysis of EEG spectral decomposition and sleep
173
microstructure (sleep spindles and slow waves). We further investigated how advanced
174
analyses of PSG recordings can help the diagnosis of insomnia in difficult cases such as
175
patients with SSM. Most importantly, we aimed at understanding how discrepancies between
176
objective and subjective assessments of sleep can be resolved through a more in-depth
177
analysis of PSG data.
178
6
179
METHODS
180
Participants
181
In this study, we analyzed PSG recordings from 347 patients suffering from insomnia. These
182
patients were selected retrospectively, following their visit to the Center for Sleep and
183
Vigilance of the Hotel-Dieu Hospital in Paris (France). All the patients included in this study
184
complained of CI for at least five years according to ICSD-3 criteria [19]. As part of their
185
clinical assessment, these patients were proposed to undergo an ambulatory or laboratory
186
PSG, whether or not comorbidities were suspected. All diagnoses were delivered by the
187
medical doctors affiliated with the Center, independently of this retrospective study.
188
Patients were diagnosed with CI according to the ICSD-3 criteria [24], i.e. whenever they
189
reported (i) difficulties initiating sleep or sleep onset latency (SOL) ≥ 30 minutes, or (ii)
190
difficulty maintaining sleep and/or early-morning awakenings (iii) at least three times a week,
191
(iv) since at least three months and (v) with consequence on daytime activities.
192
Patients were further screened for comorbidities through a visual inspection of the PSG
193
recordings and according to the guidelines of the American Academy of Sleep Medicine
194
(AASM) [45]. We excluded patients with a diagnosis of OSA (i.e. patients with a Respiratory
195
Disturbance Index (RDI) >10) or a diagnosis of PLM disorder (criterion: >10/hour).
196
We focused here on two subtypes of primary insomnia: patients with or without SSM, also
197
respectively referred as “objective” and “subjective” insomnia in the literature.
198
Insomnia without SSM:
199
The so-called “objective” nature of insomnia was confirmed by examining PSG recordings to
200
rule out a significant case of SSM, that is a discrepancy between patients’ reports of sleep
201
quantity and quality and the quantification of sleep quantity and quality via PSG. Patients
202
with at least one of the following PSG criteria were diagnosed with insomnia without SSM:
203
SOL > 30 minutes, Wake After Sleep Onset (WASO)> 30 minutes, Total Sleep Time (TST) <
204
360 minutes [19,27]. These patients are referred to as the INS group throughout (N=288
205
patients; age: 45.7 ± 0.84 (mean ± Standard-Error of the Mean or SEM); sex ratio: 0.46).
206
Insomnia with SSM:
207
Patients with SSM were diagnosed based on (i) a subjective complaint of Chronic Insomnia
208
for at least five years according to the ICSD-3 criteria and (ii) the absence of objective criteria
7
209
of insomnia in PSG recordings (SOL ≤ 30 minutes, WASO ≤ 30 minutes, and TST ≥ 360
210
minutes [22]). These patients are referred to as the SSM group throughout (N=59; age: 39.4 ±
211
1.55; sex ratio: 0.31).
212
Treatments:
213
Patients were not asked to suspend their treatment for the night of PSG. Out of 347 patients,
214
we had access to treatment information in 335 patients (12 patients with missing data). 132
215
patients were taking benzodiazepines or benzodiazepine-like drugs (40% of INS patients;
216
29% of SSM patients); 73, antidepressants (INS: 19%; SSM: 29%); 35, melatonin (INS: 10%;
217
SSM: 9%); 17, antihistamines (INS: 5%; SSM: 3%) and 154 had no treatment.
218
Controls:
219
Patients were compared to individuals who did not report any sleep disorder and who were
220
considered good sleepers (GS) after reviewing their PSG recordings. These individuals were
221
originally recruited as part of research protocols conducted in the same sleep clinic. All these
222
control subjects underwent one night of baseline PSG at the clinic or at home (similarly as
223
patients). This baseline night, identical for all individuals and not affected by the details of
224
each research protocol, was analyzed and compared to patients. Based on PSG recordings, we
225
further discarded individuals with OSA or PLM. 100 individuals were reviewed and 89 good
226
sleepers were retained as controls (age: 34.5 ± 1.33; sex ratio: 3.68).
227 228
PSG recordings
229
PSG were performed according to the AASM guidelines [46] and included: (i) at least 3 and
230
usually 6 electroencephalographic (EEG) derivations at frontal (F3/F4), central (C3/C4) and
231
occipital (O1/O2) sites and referenced to the contralateral mastoid, (ii) 2 electrooculographic
232
(EOG) derivations and, (iii) 3 electromyographic (EMG) derivations placed on the chin (N=1)
233
and legs (N=2). Respiratory parameters (respiratory flow, thoracic and abdominal bands,
234
oxygen saturation), as well as body movements (position sensor and the 2 leg EMG
235
derivations placed on the left and right tibial muscles), were also systematically recorded in
236
order to exclude individuals with OSA and PLM syndromes.
237
Different recording devices were used in this study, all validated and routinely used in our
238
sleep clinic: the NOX-A1 (Nox Medical), ACTIWAVE (CamNTech LTd), MORPHEUS
8
239
(Micromed S.p.A.) and SOMNOLOGICA (Medcare). INS patients were recorded with NOX-
240
A1 (N=284) and MORPHEUS (N=4) devices. SSM patients with NOX-A1 (N=59) devices
241
and good sleepers with NOX-A1 (N=6), ACTIWAVE (N=73) and SOMNOLOGICA (N=10)
242
devices.
243
Sleep scoring and sleep markers identification
244
Immediately after the completion of the night recording, PSG data were visually examined
245
and scored according to the AASM guidelines [47] to establish individual hypnograms. We
246
also identified arousals, leg movements and respiratory events. Arousals were defined as an
247
acceleration of the EEG for epochs between 3 and 15 seconds. This visual scoring was
248
performed by a medical doctor specialized in sleep medicine. In practice, 30-s-long epochs
249
including EEG (referenced to the mastoids), EMG and EOG data were scored as wakefulness
250
(W), NREM stage 1 (N1), NREM stage 2 (N2), NREM stage 3 (N3) and REM sleep (REM).
251
In addition to this initial sleep scoring and as part of this retrospective study, all files were
252
blindly scored again by the same sleep technician (F.R.), with more than 5 years of
253
experience in sleep medicine, to ensure the homogeneity of the sleep scoring across the entire
254
dataset. From this second scoring, we extracted classical parameters from individual
255
hypnograms reflecting the macro-structure of sleep: TTS, WASO, SOL, duration of each
256
sleep stage, number and density of arousals, etc (see Table 1). Sleep cycles were also visually
257
identified based on the hypnogram. No specific detection of physiological or non-
258
physiological artefacts was performed beyond the ones relevant to establish a diagnosis.
259
Based on the hypnograms, we also computed state-transition matrices for each night (Fig. 1),
260
by looking at how sleepers transit from one sleep stage to another. To do so, we considered
261
the individual hypnograms obtained on 30-s-long epochs. For each epoch, we computed the
262
transition probability by considering the sleep stage of the following epoch. We then
263
computed the proportion (probability) of each state transition. Figure 1 shows the resulting
264
transition matrices.
265
Identification of sleep disorders
266
The same expert (F.R.) visually identified markers of sleep disturbances. Occurrences of
267
apnea (respiratory flow below 10% for more than 10 seconds) and hypopnea (>30% decrease
268
in respiratory flow associated with arousal or oxygen desaturation of more than 3% and for
269
more than 10 seconds) were marked. For each apnea and hypopnea event, thoracic and
9
270
abdominal bands were used to categorize these events as ‘central’, ‘obstructive’ or ‘mixed’.
271
Leg periodic movements were identified and marked whenever 4 leg movements were
272
observed over a period of 90s. All these markers of sleep disturbances were then quantified
273
and the diagnosis of OSA or PLS was established based on existing guidelines [24]. All
274
individuals with OSA and PLS were excluded from our analyses.
275
REM sleep and Rapid Eye-Movements.
276
The AASM guidelines do not propose a subdivision of REM sleep but previous studies
277
sometimes distinguish between phasic (REM sleep epochs with at least one Rapid-Eye
278
Movement on the EOG derivations) and tonic (REM sleep without Rapid-Eye Movement)
279
REM sleep [48,49]. Rapid Eye-Movements in REM sleep have been associated with sleep
280
depth, sensory isolation [48,50] and oneiric activity [51,52]. To examine whether insomnia
281
was associated with a change in REM physiology and its associated oculographic activity, we
282
visually identified Rapid Eye-Movements using the 2 EOG derivations. A REM was defined
283
as an initial deflection in the EOG signal of less than 0.5 seconds, with phase opposition
284
between the 2 EEG channels [51]. For each recording, we computed the total number of
285
REMs and density of REMs (number of REMs/minutes spent in REM). We also computed
286
the number and duration of individual REM epochs.
287
Automatic detection of sleep spindles, K-complexes and slow waves
288
NREM sleep stages 2 and 3 are characterized by the presence of specific patterns of brain
289
activity [53,54]. These NREM sleep hallmarks are slow waves and K-complexes (large-
290
amplitude [1-4]Hz waves occurring in isolation or train) and sleep spindles (waxing-and-
291
waving [11-16]Hz oscillations lasting for 0.5 to 2.5s). To detect slow waves, K-complexes
292
(both here referred as slow waves) and sleep spindles, and to extract relevant parameters from
293
individual events, we relied on previously published algorithms [55–58].
294
In short, the detection of slow waves was performed by first filtering the EEG mastoid-
295
reference signal between 0.2 and 3Hz (zero-phase Finite Impulse Response (FIR) filter).
296
Individual waves were identified as the interval between two descending zero-crossing. Only
297
waves with a down-state duration (negative half-wave period) between 0.25s and 1s, and a
298
peak-to-peak amplitude above 75 V were identified as slow waves. For each of these slow
299
waves, we extracted the following parameters: wave frequency (1/wave duration), peak-to-
10
300
peak amplitude and positive slope (slope from the down-state to the up-state of the slow
301
wave).
302
Sleep spindles were likewise detected by first filtering the mastoid-referenced EEG signal
303
between 11 and 16Hz (zero-phase FIR filter). From the filtered signal, we extracted the
304
Hilbert envelope, which gives an estimate of instantaneous power within the [11-16]Hz range.
305
A threshold corresponding to the median envelope voltage + two standard-deviations (median
306
+ 2 SD, computed on 30-s-long epochs) was computed and used to identify epochs of high
307
spindle power. The beginning and end of each high spindle-power epoch were further
308
determined using a more liberal threshold (median +1 SD) and these epochs were considered
309
spindle candidates. Spindle candidates within 500ms were aggregated. These candidates were
310
considered sleep spindles if: (i) their duration was comprised between 0.5 and 2.5s, (ii) they
311
were not concomitant with large increases in high-frequency power ([60-90]Hz) typically
312
associated with artifacts, (iii) they did not cross a median + 10 SD threshold (also typically
313
associated with artifacts). For each of these detected spindles, we then extracted the following
314
parameters: the maximal amplitude (of the [11-16]Hz envelope), duration and frequency. The
315
spindle frequency was estimated using a Fast-Fourier Transform (FFT) on a 1-s-long window
316
centered on the peak in spindle power (resolution: 1Hz).
317
For both the slow wave and sleep spindle detection, only events detected in NREM2 and
318
NREM3 were analyzed. We applied the detection algorithms to central and frontal derivations
319
(C3, F3 or C4, F4) independently. Slow waves and spindles detection algorithms were
320
implemented in Python and used the MNE toolbox [59,60]
321
Spectral analysis
322
The EEG signal is classically described as resulting from the superposition of neural
323
oscillations [54]. To quantify these different rhythms, we performed a spectral decomposition
324
of the EEG signal. The EEG spectrogram was obtained by applying an FFT to 30-s-long
325
epochs of mastoid-referenced EEG data using the “eegkit” package in R. We then computed
326
the relative power within the [0.5-20]Hz range by dividing the power in each frequency bin
327
with the sum of power values between 0.5 and 20Hz (step: 0.5Hz). The relative power was
328
expressed as a percentage.
329
We applied a supervised classification approach for each frequency bin (Fig. 2a) in order to
330
evidence which frequency bins can differentiate between the 3 groups of sleepers (see
331
following section for the details of the training and testing of the classifiers). This procedure 11
332
was applied to the power spectrum averaged across NREM and REM epochs separately and
333
for each individual. We computed the ROC (Receiver Operating Characteristic) curve area
334
(chance level: 0.5; perfect performance: 1) to quantify the classifiers’ performance. We
335
repeated the supervised classification 100 times to estimate the variability of the performance
336
estimate. Cluster-permutations (see below) were used to compare the distribution of the
337
classifiers’ performance (across the different frequency bins) to chance (0.5) or between
338
NREM and REM sleep.
339
To examine how the EEG power was modulated across groups and throughout the night, we
340
binned NREM and REM epochs (N=51 bins) from the beginning (0) to the end of the night
341
(100%). Bonferroni-corrected ANCOVAs and cluster permutation were used to identify the
342
time-windows and frequency bands significantly modulated across groups (Fig. 2b).
343
The EEG signal is not only composed of periodic oscillations but also contains aperiodic
344
activity constituting the background EEG activity upon which neural oscillations develop
345
[61]. Recent work has stressed the relevance of such aperiodic activity and developed means
346
to quantify the strength of the aperiodic component of the EEG spectrum [62–64]. To
347
examine whether insomnia was associated with changes in aperiodic activity, we computed
348
the slope of the spectrum’s 1/f trend, an index of aperiodic activity. The slope of the EEG
349
spectrum was computed via the FOOOF (Fitting Oscillations and One-Over-F) package for
350
Python [61]. In short, the average EEG spectrum for a given recording and sleep stage was
351
obtained by averaging the FFT power spectrum computed over all the 30-s-long epochs for
352
this sleep stage and recording. A first aperiodic fit was then computed for the average power
353
(P=f-s, where P is the power, f the frequency and s the slope, a variable parameter). This initial
354
fit was removed, evidencing deviations from the aperiodic background (i.e. peaks
355
corresponding to the different periodic oscillations). Each peak was modeled as a Gaussian.
356
The Gaussian fits were then used to remove the periodic peaks from the original spectrum and
357
a second aperiodic fit was performed to obtain an approximation of the spectrum without the
358
periodic activity (peaks). The slope of this second fit was used to estimate the slope of the
359
aperiodic spectrum.
360
Supervised classification
361
To determine whether features extracted from PSG recordings are predictive of insomnia and
362
insomnia sub-types, we tried to classify individuals in clinically-relevant diagnostic categories
12
363
using supervised classifiers. This supervised classification was performed in R using the caret
364
package (Classification And REgression Training).
365
Since our main goal was here to check whether quantitative analyses of PSG recordings could
366
help the diagnosis of insomnia, we trained and tested classifiers focusing on different
367
contrasts. The first classifier was trained to predict two categories of individuals (2-class
368
classifier): controls (good sleepers, GS) vs. patients with CI (with or without SSM:
369
SSM+INS). We then sought to determine if the classifier could also distinguish insomnia
370
subtypes by training a classifier on our three different groups (GS vs. SSM vs. INS). Finally,
371
we examined if a classifier could distinguish between patients with CI using 2-class classifiers
372
trained on SSM and INS patients.
373
In addition to the number and definition of the groups to classify, we also varied the type of
374
data provided to the classifiers. The first type of classifiers (“visual” or “V” in Fig. 6) was
375
trained on features extracted from the hypnogram and thus obtained via a visual inspection of
376
PSG recordings (TST, total bed-time, sleep efficiency, WASO, duration and proportion of
377
time spent in each stage, micro-arousals, probability transition between stages, etc.). These
378
features correspond to the macroscopic features detailed above. The second type of classifiers
379
(“computed” or “C” in Fig. 6) was trained on features computed from the EEG recordings,
380
including meso (spectral features) and microstructural (slow waves, sleep spindles) variables.
381
Finally, we also trained classifiers on all features combined (“V+C” in Fig. 6).
382
Each classifier was trained and tested in the same way. We first split PSG recordings into a
383
training set (80% of the data) and a test set (remaining 20%). As there is 1 PSG recording per
384
patient, the training and test sets were disjoint groups of patients. The classifier was trained on
385
the training set using a Random Forest approach. A 3-fold cross-validation was performed to
386
select the classifier’s hyper-parameters. This procedure was repeated 10 times, each time with
387
a new random split. The model with the best hyper-parameters was then used to train the
388
classifier on the entire training set. Once the classifier was trained, we tested it on the test set,
389
which, importantly, was not used to train the classifier. We then compared the labels
390
predicted by the classifier with the real labels (e.g. INS, SSM or GS). The same methodology
391
was used for the classification of the EEG power spectrum per frequency bin (Fig. 2a, single-
392
feature classifiers) across the INS, SSM and GS groups.
393
Since the groups to predict are not equal, we computed either ROC (Receiver Operating
394
Characteristic) curve area (chance level: 0.5) or Cohen’s κ (chance level: 0) to quantify the
13
395
classifiers’ performance. A negative or null κ means that the classifier is not performing
396
above chance. The more the κ value is close to 1, the better the classifier is able to retrieve the
397
original labels of each individual recording. In order to better estimate the variability in the
398
classifiers’ ability to predict individuals’ clinical labels, we repeated this procedure 100 times
399
for each classifier. We plot in Fig. 6 the resulting distribution of κ values (N=100) as well as
400
the average confusion matrices over these 100 iterations. Finally, for each model we retrieved
401
the Variable Importance (VI) for each feature, which describes how important the feature is
402
for the classification. These VI values are shown for the top-20 features (i.e. the ones with the
403
highest VI values) for each model in Table 2.
404
Statistics
405
All statistical analyses were performed in Matlab. We examined group-effect (modulations
406
across the INS, SSM and control groups) using an Analysis of Covariance (ANCOVA). The
407
INS, SSM and control groups were used as a categorical predictor. We also included the age
408
and gender of participants as covariates. Bonferroni correction was used to account for
409
multiple comparisons. We used unpaired t-tests for post-hoc comparisons.
410
When comparing groups across time (Fig. 2), we relied on a cluster-permutation approach
411
[65]. For each time-point, we estimated the group-effect using an ANCOVA (covariates: age
412
and gender). We then identified clusters of time-points crossing a given uncorrected statistical
413
threshold (p<0.05). For each cluster, we computed the sum of the F-values associated with the
414
group-effect, for all the samples within the cluster. A surrogate dataset was obtained by
415
repeating this procedure when permuting the group labels across subjects (1000
416
permutations). We then compared the cluster statistics (sum of F-values) of the original
417
dataset with the maximum cluster statistics of the 1000 random permutations. The position of
418
the cluster statistics within the surrogate dataset was used to estimate the significance of the
419
cluster, allowing us to compute a nonparametric Monte-Carlo p-value (pcluster) for that
420
particular cluster.
421
Ethics
422
This research was conducted according to the principles expressed in the Declaration of
423
Helsinki of 1975, revised in 2001. The retrospective analysis of PSG data of patients and
424
controls was approved by the local ethics committee (Comité de Protection des personnes
425
(CPP) Ouest IV, from Nantes, France). Patients data were anonymously analyzed according
14
426
to legal requirements (Commission Informatique et Liberté (CNIL) from the French
427
Government).
15
428
RESULTS
429
We investigated how PSG recordings differ between the three groups of sleepers: patients
430
diagnosed with insomnia but without SSM (INS group), patients with insomnia and SSM
431
(SSM group) and Good Sleepers (GS group). As previously explained in the Methods section,
432
we extracted various features from PSG recordings. First, we extracted classical summary
433
statistics derived from the hypnograms obtained after visual scoring of the PSG (which we
434
termed “macroscopic” features); then features extracted from the spectral decomposition of
435
the EEG data (“mesoscopic” features) to capture changes in sleep/wake oscillations across the
436
three groups; finally, key graphoelements characteristic of either NREM (slow waves, sleep
437
spindles) and REM (eye-movements) sleep were compared across groups (“microscopic”
438
features). The macro-, meso-, and microscopic features were then aggregated and used to
439
train a supervised ML algorithm to classify patients in the three groups.
440
Hypnogram-based macroscopic features confirm the sub-phenotyping of insomnia
441
patients with and without SSM
442
When first comparing hypnograms of sleepers using classical metrics of sleep quantity and
443
quality (Table 1), we confirmed that patients diagnosed with insomnia but without SSM spent
444
less time asleep than good sleepers (TST: 361 min ± 5.1 (mean ± SEM) vs. 406 min ± 5.4;
445
unpaired t-test: p=4.0.10-6) and had a decreased sleep efficiency (72.0% ± 0.8 vs. 79.7% ±
446
1.1; unpaired t-test: p=2.1.10-6). Even when taking into account differences in total sleep time,
447
patients from the INS group spent a larger proportion of time awake during the night (27.8%
448
± 0.8 vs. 20.3% ± 1.1; unpaired t-test: p=4.1.10-6) and less time in NREM2 (41.7% ± 0.7 vs.
449
47.1% ± 0.9; unpaired t-test: p=3.8.10-5) as well as REM sleep (12.9% ± 0.3 vs. 15.0% ± 0.5;
450
unpaired t-test: p=0.001). The reduction in NREM2 was observed throughout the night (Fig.
451
1, top; unpaired t-tests: p<0.005 for both 1st and 2nd halves of the night) whereas the
452
decrease in the proportion of REM sleep was observed only in the end of the night (p=0.003).
453
These results confirm the rather archetypal profile of the patients from the INS group.
454
However, the same features failed to evidence any sleep disturbance in the insomnia group
455
with SSM. These patients appeared to actually sleep better than controls, with increased sleep
456
efficiency (88.4% ± 0.8 vs. 79.7% ± 1.1; unpaired t-test: p=2.4.10-8), decreased proportion of
457
wakefulness during the night (11.7% ± 0.8 vs. 20.3% ± 1.1; unpaired t-test: p=2.2.10-8) and
458
increased proportion of NREM3 stage (19.5% ± 1.2 vs. 15.1% ± 0.7; unpaired t-test:
459
p=4.4.10-4). Yet, based on subjective complaints, these patients were diagnosed with
16
460
insomnia. Contrary to previous reports, both INS and SSM patients did not show a significant
461
increase in the density of arousals in REM or NREM sleep when correcting for multiple
462
comparisons (Table 1).
463
We further examined the dynamics of individual nights. Using ANCOVAs, we examined the
464
interactions between the part of the night (1st vs. 2nd half) and individuals’ group and found a
465
significant interaction only for NREM3 (Bonferroni correction, p=8.45.10-7). This interaction
466
seems driven by INS patients who show less NREM3 in the beginning of the night compared
467
to controls and SSM patients but more NREM3 in the second part of the night (Fig. 1a). There
468
was no other significant interaction in other sleep stages (after Bonferroni correction)
469
suggesting that other group-effects are stable throughout the night.
470
We also examined how sleepers dynamically transit from one sleep stage to another by
471
looking at the transition probabilities derived from each hypnogram (Fig. 1, bottom; see also
472
Methods). There was a significant difference in how sleepers transit from stage NREM2 and
473
wakefulness (ANCOVA: p<10-6). The effect on the transition from NREM2 seemed mostly
474
driven by the INS group showing an unstable NREM2 stage (less NREM2-to-NREM2
475
transitions compared to controls: unpaired t-test p=2.3.10-5). The SSM group differed from
476
both INS and control groups by the tendency of these individuals to transit more from
477
wakefulness to NREM2 (wake-to-NREM2 transition compared to controls: p=5.2.10-8). These
478
rapid and frequent transitions to deeper stages of NREM sleep illustrate well the SSM
479
paradox, whereby subjective complaints contrast with a better-than-usual transition to sleep.
480
Features derived from the EEG spectrum show common differences between INS and
481
SSM patients compared to good sleepers
482
In this first level of analysis, examining macroscopic features extracted from the hypnograms
483
show that individuals from the SSM group were much more similar to good sleepers than
484
other insomnia patients (INS group). Yet, based on subjective complaints, SSM patients were
485
diagnosed with CI. To overcome this paradox, we set out to analyze in more depth PSG
486
recordings. First, we computed and examine the spectral decomposition of the EEG signal on
487
30-s-long windows (Fig. 2). We termed the output of this spectral decomposition mesoscopic
488
features as it represents a level of analysis between hypnogram-based macroscopic features
489
(summarizing an entire night) and sleep micro-structure (spindles, slow waves; time scale of
490
~1s).
17
491
To examine whether the power in certain frequencies could distinguish across clinical groups,
492
we used a supervised classifier approach. We trained a classifier on a subset of data and on a
493
single feature (relative power for a given frequency in REM or NREM sleep) to categorize
494
patients into our three clinical groups (INS, SSM and controls; see Methods for details). We
495
then tested the trained classifier on the remaining data, not included in the training set. The
496
performance of the classifier (quantified as the ROC area, see Methods) was then used as a
497
proxy to determine to what extent a given frequency band can discriminate individuals across
498
clinical groups. Values higher than 0.5 denote above-chance performance. Importantly, this
499
approach does not rely on the a priori definition of frequency bands of interest.
500
The results indicate that in both NREM and REM sleep, individual recordings can be
501
accurately categorized in the 3 clinical groups across all frequencies (Fig. 2a; NREM and
502
REM clusters: [0.5-20]Hz, pcluster<0.001). However, the decoding accuracy was not constant
503
and certain frequency domains led to particularly high classifying accuracies (peaks in
504
classifying performance). In particular, we could identify 4 main clinically relevant frequency
505
bands: (i) delta ([1-4]Hz), (ii) theta ([5-7]Hz), (iv) sigma oscillations ([11-15]Hz) and (iii)
506
beta oscillations ([16-20]Hz). Training and testing our classifiers on NREM and REM sleep
507
separately showed that certain frequency ranges give higher classifying accuracies for a given
508
sleep state. For example, theta/alpha (alpha: [8-11]Hz) and beta oscillations led to higher
509
decoding accuracy in REM sleep than in NREM sleep (clusters: [5, 10.5]Hz and [17.5-20]Hz,
510
pcluster<0.005) whereas in NREM sleep, delta and sigma oscillations led to higher decoding
511
accuracies (clusters: [0.5, 4.5]Hz and [11.5, 14.5]Hz, pcluster<0.0001). These results are
512
concordant with the dominant rhythms in NREM (slow waves: delta, sleep spindles: sigma)
513
and REM sleep (theta and fast oscillations). It is finally worth noting the high levels of
514
accuracy obtained for both NREM and REM within the delta range (ROC area > 0.8), which
515
suggests that simple features extracted from the EEG spectrum can accurately support the
516
automated identification of insomnia.
517
Then, as detailed in the Methods, we examined how the three different groups differed in each
518
of the frequency bands of interest (delta, theta/alpha, sigma and beta) and throughout the
519
night. This analysis was motivated by the well-documented influence of both circadian and
520
homeostatic processes on sleep rhythms [66]. Besides, past research has stressed that
521
differences between good sleepers and individuals suffering from insomnia also vary during
522
the night [30]. Differences were observed in the delta ([0.5, 4]Hz), theta/alpha ([5, 11]Hz),
523
sigma ([11, 15]Hz) and beta ([16, 20]Hz) bands (Bonferroni correction for cluster Monte18
524
Carlo p-values) but were restricted to the beginning of the night (<50% total progression).
525
Good sleepers were characterized by higher levels of delta power but lower levels of
526
theta/alpha and beta oscillations. In other words, insomnia patients showed weaker sleep-
527
related oscillations and stronger wake-related oscillations during sleep than good sleepers. We
528
observed however an exception to that rule with the small, temporally restricted, modulation
529
in spindle power (cluster: [12, 16]%, pcluster<0.05, corrected), with controls showing less
530
spindle power than insomnia patients.
531
Importantly, despite drastic differences at the macroscopic level, the spectrum of the insomnia
532
subtypes (INS and SSM) significantly overlap. Only one significant post-hoc cluster emerged
533
when comparing INS and SSM, with INS patients showing an increased level of alpha/theta
534
oscillations compared to SSM (post-hoc cluster: [0, 30]%, pcluster<0.005). These results alone
535
could positively help overcome the discrepancy between objective and subjective assessments
536
of insomnia: SSM patients no longer look like good sleepers but are much more similar to
537
INS patients when examining the spectral features of the EEG signal.
538
While quite standard, these spectral analyses have several limitations. First, since they rely on
539
relative power, it is difficult to be conclusive on the exact frequencies impacted by insomnia.
540
Indeed, effects observed on a specific frequency band could actually stem from other
541
frequency domains used in the normalization. Second, while frequency bands have been often
542
linked to specific patterns of neuronal activity (e.g. sleep spindles and the sigma band), this
543
relationship can be complex. For example, an increase in sigma power does not necessarily
544
mean an increase in spindle density as sleep spindles are also defined by a duration criterion.
545
Third, there can be significant inter-individual variations in terms of the frequency of the
546
different sleep rhythms, which are not taken into account when dealing with fixed frequency
547
bands. Finally, the EEG power spectrum does not only reflect periodic brain oscillations but
548
also aperiodic activity [61,62]. Periodic oscillations typically show up as peaks in the power
549
spectrum whereas aperiodic signals can be quantified by computing the slope of the 1/f trend
550
of the EEG spectrum. This is why we also examined whether insomnia had an effect on the
551
aperiodic component of the EEG spectrum by computing the slope of the power spectrum
552
across all sleep stages and for each individual (Fig. 3, see Methods). Bonferroni-corrected
553
ANCOVAs show significant modulations of the spectrum’s slope in NREM2 and NREM3
554
(p<0.01, Bonferroni corrected). This modulation was driven by decreased slopes for patients
555
with insomnia (INS and SSM) compared to controls.
19
556
The decrease in the slope of the spectrum was even more pronounced for SSM patients in
557
NREM3, which showed slopes that were smaller than in NREM2 and equivalent to NREM1,
558
in striking contrast with both controls and INS patients. Indeed, in controls and INS patients,
559
the slope increases with sleep depth (wake
560
in the slope of the EEG spectrum for SSM patients is particularly interesting since the slope
561
of the power spectrum has been associated with the excitation/inhibition balance [62]. A
562
decrease in the slope of the spectrum during sleep could be associated with an abnormally
563
high level of excitation during NREM3 in SSM patients, in link with the hyperarousal model
564
of insomnia (see Discussion).
565
Sleep’s micro-structure evidences a decrease in slow waves and increase in sleep
566
spindles in insomnia
567
Finally, as detailed in the Methods, we focused on the micro-structure of sleep and NREM
568
sleep hallmarks such as slow waves (including K-complexes) and sleep spindles. We
569
automated the detection of slow waves and extracted slow-waves’ density (number of events
570
per minute), amplitude, frequency and slope (see Fig. 4 and Methods). We used Bonferroni-
571
corrected ANCOVAs to assess the differences across groups in NREM2 and NREM3
572
separately, as well as for central and frontal derivations separately (16 comparisons across all
573
slow waves variables). Results indicate that, in both NREM2 and NREM3, for central
574
electrodes, insomnia patients showed fewer slow waves (ANCOVAs: p<10-6; post-hoc
575
unpaired t-tests p<0.001) as well as slower and less steep slow waves (ANCOVAs: p<10-4;
576
post-hoc unpaired t-tests p<0.001). The reduction of slow waves frequency was also observed
577
in frontal electrodes in NREM2 and NREM3 (ANCOVAs: p<0.001). The amplitude of slow
578
waves was not significantly modulated across groups when correcting for multiple
579
comparisons. When comparing SSM and INS patients directly, there was no significant
580
difference between the density and properties of slow waves in NREM sleep (uncorrected
581
post-hoc unpaired t-tests: all p>0.05 except for a minor difference in slow-wave amplitude:
582
p=0.046 in NREM2) suggesting that the impairment of slow-wave generation is a common
583
feature of insomnia subtypes.
584
We then examined sleep spindles, yet again based on automated detection algorithms (see
585
Methods). Bonferroni ANCOVAs were used to assess group differences in terms of spindles
586
density, maximum amplitude, duration and frequency over central and frontal derivations and
587
in NREM2 and NREM3 separately (16 comparisons). As for slow waves, spindle density
20
588
appears modulated across groups, this time in both NREM2 and NREM3, frontal and central
589
derivations (ANCOVAs, all p<0.001, corrected threshold). However, the direction of this
590
modulation was opposite to slow waves, with INS and SSM patients showing more sleep
591
spindles than controls (post hoc t-tests: P<0.001). These spindles also tended to vary in
592
duration in NREM2 and NREM3, central and frontal electrodes (ANCOVAs, all p<0.001,
593
corrected threshold). Similarly, spindle power was reduced in insomnia patients for central
594
and frontal derivations, NREM2 and NREM3 (ANCOVAs, all p<0.001, corrected threshold).
595
Spindle frequency varied across groups in NREM2 only (ANCOVAs, all p<0.05, corrected
596
threshold) with faster spindles in INS and SSM patients.
597
Importantly, there were significant differences between insomnia subtypes in terms of spindle
598
density. SSM patients showed larger number of sleep spindles compared to INS patients, in
599
NREM2 and NREM3, for central and frontal derivations (uncorrected post-hoc unpaired t-
600
tests: p<0.005).
601
Unsupervised AI algorithms can detect and phenotype insomnia using features
602
extracted from PSG recordings
603
From the results presented above, it appears that PSG recordings contain information
604
allowing not only to distinguish insomnia patients from good sleepers but can also make
605
important distinctions within insomnia (e.g. between insomnia with and without SSM).
606
However, the previous analyses are rarely employed in clinical settings, potentially because
607
they are complex, varied and often arbitrarily focus on specific aspects of the data (e.g. power
608
spectrum or micro-structure).
609
To facilitate the translation of our approach to clinical settings, we set out to determine if
610
features extracted from PSG recordings could predict whether an individual is a good sleeper
611
or suffers from insomnia. To do so, we relied on recent developments in computer science
612
and machine learning, which have made the computation and classification of large datasets
613
seamless (see Methods). In practice, for each PSG recording and patient, we extracted the
614
different macro, meso and micro-features described above. These features were divided into
615
“visual” (typically micro) and “computed” (typically meso and macro) features, depending on
616
whether they were obtained through the visual inspection of the data (N=71 features) or
617
through automated algorithms (N=302). This separation of visual and computed features was
618
made in order to check whether an entirely automated analysis of the signal would be enough
21
619
to help the diagnosis of insomnia and whether it could even outperform a classification based
620
on features obtained from the visual inspection of the PSG recordings.
621
We first focused on whether a classifier could predict if an individual suffers from CI by
622
training a classifier on good sleepers (GS) and patients with CI (SSM + INS) (see Methods).
623
To assess the efficacy of the classifier, we computed Cohen’s κ values for 100 repetitions of
624
this classification (Fig. 6a, left). For memory, a perfect classification corresponds to κ=1
625
(irrespective of the number of predicted classes) while a random classification corresponds to
626
κ=0. We also show the Confusion Matrix which represents how the predicted labels (rows)
627
compared to the real labels (columns). A perfect classification shows up as a diagonal
628
confusion matrix (predicted labels = real labels). Our results indicate that participants’ clinical
629
assessment (GS or CI) can be recovered with moderate accuracy when using visual features
630
(κ=0.49 ± 0.01) but this accuracy is much improved when using computed features (κ=0.88 ±
631
0.01; unpaired t-test: p<10-16). In fact, κ values above 0.8 are usually considered as almost
632
perfect classification [67]. Combining visual and computed features did not significantly
633
improve the overall accuracy of the classifier (κ=0.88 ± 0.007; unpaired t-test to compare
634
visual+computed and computed classifiers: p=0.67), implying that computed features already
635
maximize the ability to predict CI from PSG recordings.
636
We then examined whether we could also retrieve insomnia subtype. To do so, we trained a
637
classifier on our three clinical groups (GS, SSM and INS, Fig. 6b). Visual features led to
638
moderate accuracy (κ=0.45 ± 0.009). As the confusion matrix shows, this moderate level of
639
performance is due to a large proportion of good sleepers (56.8%) and SSM patients (46.5%)
640
being mistakenly diagnosed as INS patients. A limited ability to classify these 3 groups is
641
expected given that SSM, INS and GS individuals sometimes overlap when considering only
642
visual (micro) features (see Fig. 1 and Table 1). However, the performance significantly
643
improved when focusing on features extracted from the EEG signal (κ=0.59 ± 0.008; unpaired
644
t-test with the visual-features classifier: p<10-16). In this case, GS were reasonably well
645
categorized (87.5% correct) but SSM patients were almost always categorized as INS patients
646
(96.1% miscategorization as INS patients). This is again not surprising when considering that
647
INS and SSM patients largely overlap when considering the computed features: meso (Fig. 2-
648
3) and micro (Fig. 4-5) features. Finally, combining both sets of features led to significantly
649
better performance (κ=0.73 ± 0.007; unpaired t-test compared to visual- or computed-features
650
classifiers: p<10-16),
22
651
Given the inability for the 3-way classifier to distinguish between INS and SSM patients, we
652
finally trained and tested classifiers when using INS and SSM these patients only. Using
653
visual features, we could classify the two subtypes of insomnia with moderate accuracy
654
(κ=0.51 ± 0.01). But, when considering features extracted from the EEG signal, the classifier
655
was at chance (κ=0.0049 ± 0.008; t-test compared to 0: p=0.51). A significantly better-than-
656
chance classification was retrieved when combining both visual and computed features
657
(κ=0.54 ± 0.02; t-test compared to 0: p<10-16), but the level of performance attained was not
658
significantly different from the visual-only classifier (unpaired t-test: p=0.07). These results
659
confirm that SSM and INS patients largely overlapped for EEG-derived features, making
660
them indistinguishable by an automated classifier.
661
Finally, supervised classifiers have the crucial advantage of providing insight on the nature of
662
group differences. Indeed, the ML algorithms used here allowed us to retrieve which features
663
contributed the most to the classification output, which can be interpreted (when the classifier
664
is performing well) as the features that best distinguish the groups of interest (see Methods).
665
By stressing which differences matter, supervised classifiers could shed light on the
666
physiological substrates and aetiology of insomnia. To illustrate this possibility, we show in
667
Table 2 the top-20 most discriminative features for the GS. vs. CI, GS vs. SSM vs. INS, and
668
SSM vs. INS classifiers. As expected from Fig. 2, spectral information in the delta band is
669
discriminating best between GS and CI patients (top-20 features were all computed from the
670
power spectrum). When classifying GS, SSM and INS patients however, the top features were
671
a combination of features extracted from the EEG power spectrum and the hypnogram. This
672
may be related to the fact that SSM and INS patients do not seem to differ in terms of power
673
spectrum but do differ in terms of hypnograms. In fact, it seems that only the combination of
674
the information coming from the micro, meso and macro levels can allow the 3-way
675
distinction of the INS, SSM and GS groups. This was illustrated by the classifier focusing on
676
the SSM and INS groups. In this case, the top-20 variables were a combination of
677
hypnogram-based features, spectral features and information about sleep micro-structure
678
(sleep spindles).
679
Impact of covariates and limitations
680
This study being a retrospective analysis, it bears several potential limiting factors associated
681
with the nature of the dataset and the individuals included in this study. Indeed, the different
682
groups are not age or gender-matched: good sleepers were on average younger and comprised
23
683
a greater proportion of males (Table 1). Age and gender impacting PSG recordings at the
684
macro, meso and micro levels [68–70], we integrated these two variables as covariates in all
685
our analyses (see Statistics section).
686
Another possible confound is the fact that patients were not instructed to interrupt their
687
treatments and, consequently, 52% of INS and 53% of SSM patients were under insomnia
688
medication during the night of PSG, which is known to affect the recordings [71]. To mitigate
689
the risk that part of our results could result from the effect of medications, we replicated all
690
our analyses by discarding patients with any record of medication. By and large, these
691
replications confirm our initial results regarding the meso and micro level of analysis. Indeed,
692
we could confirm that unmedicated insomnia patients show a reduction in slow wave density
693
(uncorrected post-hoc t-tests: p<0.01 in NREM2/3, central electrodes), frequency (p<0.01 in
694
NREM2/3, central electrodes) and slope (p<0.05 in NREM2/3, central electrodes); an
695
increase in spindle density (p<0.001 in central/frontal channels and NREM2/3), frequency
696
(p<0.01 in central channels and NREM2) and decrease in amplitude (p<0.001 in
697
central/frontal channels and NREM2/3); a decrease in delta oscillations coupled with an
698
increase in theta/alpha and beta oscillations (pcluster<0.05); a decrease in the slope of the power
699
spectrum in NREM2 and NREM3 (p<0.05). It seems thus that our results are confirmed when
700
taking into account confounding variables (age, gender and medication).
701
PSG recordings were also recorded in different locations, either at home (ambulatory
702
recordings) or at the hospital. The proportion of home recordings differed between controls
703
and patients (GS: 6.7%; INS: 71.2%; SSM: 80.2%) as most of patients were recorded at home
704
while controls consisted of volunteers to research protocols typically conducted in controlled
705
environments. The proportion of home recordings did not differ between insomnia sub-types
706
(chi-test: chi2 =2.4, p=0.12). Within the population of insomnia patients (INS + SSM), we
707
examined the impact of recordings’ location (home or hospital) on the macro, meso and micro
708
features. We observed an increase in Total Sleep Time, proportion of REM and number of
709
REM episodes for ambulatory recordings (p<0.01, Bonferroni-corrected unpaired t-tests,
710
N=273 ambulatory and 74 hospital recordings in 347 patients). This is due to the fact that
711
hospital recordings can be disrupted by hospital routine in the morning, leading to extended
712
and REM-rich home recordings. However, meso (spectral slope (Fig. 3) and overall power in
713
the delta, theta/alpha, sigma and beta bands (Fig. 2)) and micro (density and properties of
714
slow waves (Fig. 4) and sleep spindles (Fig. 5)) features were not significantly impacted by
715
the recording type within the insomnia population (unpaired t-tests, corrected threshold: 24
716
0.05). Furthermore, when comparing patients and controls, most of the effects reported
717
concern NREM sleep (Fig. 3-5) or the beginning of the night (Fig. 2) and are thus less likely
718
to be affected by an extension of sleep in ambulatory recordings.
719
Finally, PSGs were recorded using different devices. Although all these devices are routinely
720
and indiscriminately used in our Sleep Clinic for clinical assessments, different devices could
721
alter some aspects of the PSG recordings. In addition, the type of recording device differed
722
between controls (82% of ACTIWAVE devices) and insomnia patients (99% and 100% of
723
NOX-A1 devices for INS and SSM patients resp.). However, most of the differences
724
observed between patients and controls were limited to specific sleep stages (Fig. 1-5), time
725
windows (Fig. 1, 2b), scalp location (Fig. 4-5) or to specific properties of the micro-structure
726
(Fig. 4-5). It is thus unlikely that the recording device used in a given PSG would be the
727
source of the observed group differences as the type of recording device should affect a
728
specific feature of PSG recordings indiscriminately of the time, sleep stage or location of the
729
recorded data.
730
25
731
DISCUSSION
732
Towards a comprehensive exploration of the physiological substrates of insomnia
733
Our study revisits the use of PSG in the diagnosis of insomnia. Indeed, insomnia stands in
734
striking contrast with other sleep pathologies as PSG recordings are neither needed nor
735
recommended for the diagnosis of insomnia, despite the fact that PSG is widely considered as
736
the golden standard for the objective measurement of sleep [19]. This paradox has been
737
justified by the fact that PSG recordings do not bring reliable information to inform the
738
diagnosis and treatment of insomnia. PSG recordings can even, at times, directly contradict
739
what individuals report [27]. A telltale example of such discrepancies is the case of insomnia
740
with SSM, in which patients can sometimes be indistinguishable from good sleepers when
741
referring to classical summary statistics of PSG recordings (TSA, WASO, number of
742
awakenings, time spent in each sleep sub-stage) [28,29]. In this study, we set out to resolve
743
this discrepancy between objective and subjective indexes of sleep and to reconcile insomnia
744
with PSG recordings. To do so, we relied on a large dataset of PSG recordings in insomnia
745
patients (N=347), including different insomnia subtypes (N=59 with SSM, N=288 without).
746
The size of this dataset allowed us to examine PSG recordings at various scales of analyses
747
and to apply Machine Learning (ML) techniques, typically requiring large datasets.
748
Our approach was to systematically perform and aggregate the different types of analyses
749
performed in the past to investigate insomnia in PSG recordings. We divided these analyses
750
into 3 levels. First, we extracted “macroscopic” indexes of sleep quantity and quality as
751
classically reported in the literature on insomnia (TST, WASO, Sleep Efficiency, proportions
752
of Sleep Stages, etc). These metrics tend to summarize a given aspect of sleep across the
753
entire night. Second, we focused on the EEG signal on 30-s-long epochs and analyzed brain
754
rhythms through the spectral decomposition of the EEG signal (see [30–33] and [18] for a
755
review on similar approaches in insomnia). We termed this level of analysis “mesoscopic” as
756
it focuses on an intermediate time-scale (30s). Third, we performed a fine-grained analysis
757
(~1s scale) of PSG’s microstructure (slow waves and sleep spindles). Past studies have
758
investigated changes in sleep microstructure in insomnia (see [18] for a review) but these
759
results remained largely inconclusive. Although most of the analyses presented here have a
760
precedent in the literature, our study is the first to integrate all these approaches.
761
26
762
PSG as a useful tool for the diagnosis of insomnia
763
The analysis of the macro features of PSG recordings illustrate the distinctions classically
764
made between insomnia with and without SSM. Indeed, global metrics of sleep quantity and
765
quality derived from the hypnogram show two groups of insomnia patients: individuals in
766
which PSG recordings tend to confirm the subjective complaint of insomnia (CI without
767
SSM: INS group) and individuals in which PSG recordings do not support or even appear to
768
contradict the diagnosis of CI (CI with SSM: SSM group). In the latter case, patients appeared
769
to sleep as well if not better than controls (equivalent TTS; shorter SOL, WASO; better sleep
770
efficiency; see Table 1). In contrast, patients without SSM had shorter TTS, longer WASO
771
and worse sleep efficiency (Table 1). It is worth noting the rather long SOL observed in
772
controls, which could be explained by a FNE [22]. A reverse FNE could be also responsible
773
for the short SOL observed in patients with SSM [23].
774
While macro features of sleep are an easy way to rapidly assess a night, our analyses and
775
previous studies show their limitations as they fail to capture a common denominator among
776
insomnia patients. Examining further the proportion of sleep stages leads to the same
777
conclusion: patients without SSM showed a deteriorated sleep (increased proportion of wake
778
during the night, decreased proportion of NREM2 and REM; Table 1) whereas patients with
779
SSM displayed the reverse pattern (less wake, more NREM2, NREM3 and REM; Table 1).
780
Similar results were obtained when splitting the night into two parts (Fig. 1, top).
781
Interestingly, the increase in REM for SSM patients could be interpreted in the light of the
782
positive relationship between REM duration and subjective estimates of the time spent awake
783
during the night [35]. The fact that REM sleep is often associated with dreaming [72], and
784
therefore consciousness, could potentially explain the difficulty experienced by patients in
785
determining if they were awake or asleep. However, we did not replicate previous findings on
786
the increase in arousals during sleep, and REM in particular, in insomnia [35]. Nonetheless,
787
we could observe a trend in this direction and our results could be explained by the strict
788
statistical thresholds used in this study (Bonferroni correction, see Methods). Finally, the
789
analysis of state-transitions during the night (i.e. how sleepers move from one state to
790
another; Fig. 1, bottom) also describes INS patients’ sleep as unstable (more frequent
791
NREM2>Wake transitions compared to controls) and SSM patients’ sleep as more stable
792
(more frequent WAKE>NREM2 transitions compared to controls).
27
793
Overall macro features derived from the hypnogram do not seem able to solve the conundrum
794
of insomnia as they fail at unravelling a common denominator between insomnia subtypes. Of
795
course, this does not mean that PSG recordings are not informative, even at this level of
796
analysis. Rather, information extracted from PSG recordings allows the phenotyping of
797
insomnia (e.g. to determine the presence of SSM) based on a pre-existing diagnosis of
798
insomnia established on patients’ subjective complaint.
799
Nonetheless, there is more in PSG recordings than what can be derived from the hypnogram
800
and previous studies have shown how PSG recordings can be harnessed to better understand
801
the physiopathology of insomnia. In particular, the spectral decomposition of the EEG signal
802
allows identifying and quantifying the neural oscillations that are constitutive of wakefulness
803
and sleep. Accordingly, we here extracted spectral information on epochs of 30s (mesoscopic
804
features; see Methods) and examined the relative power across the entire [0.5-20]Hz range
805
(Fig. 2a) or in frequency-bands of interest (Fig. 2b). Past studies have shown that individuals
806
with insomnia present more fast oscillations that are characteristic of wakefulness during
807
sleep (alpha, beta oscillations) and less oscillations typical of sleep (delta rhythm) (see [18,30]
808
for reviews). Our results are in line with these findings (Fig. 3). However, the sigma range,
809
which is typically associated with sleep, showed a moderate up-regulation in insomnia
810
patients compared to controls. Such an increase seems driven by SSM patients, which is
811
concordant with previous findings in “subjective” insomnia [73]. This increase in sigma
812
power in CI patients speaks against a simple down-regulation of sleep rhythms and up-
813
regulation of wake activity during sleep in CI.
814
A striking aspect of the comparison between macro and meso features is that, while macro
815
features clearly distinguished between insomnia sub-types (i.e. SSM patients are closer to
816
good sleepers than INS patients according to these metrics), the meso features did not (Fig.
817
3). Both SSM and INS patients showed very similar changes in power compared to controls,
818
demonstrating that the paradox of SSM dissolves as soon as the neural activity is analyzed in
819
more detail. This is an important result in order to reassess the validity of PSG recordings in
820
insomnia as it shows that, despite inconsistencies at the level of macroscopic metrics, PSG
821
recordings can actually show robust markers of insomnia. Finally, although we observed
822
robust differences across groups in several frequency bands, the fact that we could only
823
examine the EEG spectrum in a limited number of scalp locations means that we cannot
824
conclude on the topographical aspects of these changes as previously done [34,74].
825
Furthermore, we could not explore other spectral differences such as differences in occipital 28
826
alpha or sigma [34]. The replication of our findings in high-density EEG could lead to further
827
insights about insomnia patients and good sleepers differ.
828
Examining the EEG spectrum, we also extracted information about the aperiodic component
829
of neural activity. Indeed, the EEG signal is not uniquely composed of oscillations or pseudo-
830
oscillations [54]. Rather, neural oscillations are embedded in an aperiodic background, which
831
translates into the 1/f relationship between power and frequency observed in scalp EEG [61].
832
Importantly, modulations of this aperiodic background are physiologically and cognitively
833
relevant as the parameters of this aperiodic activity can change with sleep/wake transitions
834
[64], age [75] or can be altered in disorders such as schizophrenia [76]. Here, we show that
835
the slope of the aperiodic signal is decreased in CI patients (both SSM and INS) in deep
836
NREM sleep (NREM2 and NREM3, Fig. 3). Interestingly, a reduction of the slope of the
837
EEG spectrum has been interpreted as a modification of the Excitatory/Inhibitory (E/I)
838
balance among cortical networks and an increase in cortical excitability [62]. If the latter
839
findings can be extrapolated to humans, our results would suggest that insomnia is
840
characterized by an increase in cortical excitability (see below).
841
Finally, we dove further into the details of sleep physiology and focused on sleep’s
842
microstructure (micro features). We automatically detected slow waves and sleep spindles
843
(see Methods) and extracted basic properties of individual grapholelements (frequency,
844
duration, amplitude, etc). In concordance with the spectral analyses (e.g. decrease in delta
845
power, Fig. 2), we observed a decrease in slow-wave density in both insomnia groups (Fig.
846
4). Slow waves were not only less numerous in insomnia but they also appeared slower
847
(decreased frequency) and with reduced down-to-up slopes. Previous reports indicate that
848
slow waves with reduced slopes tend to occur later during the night [55,77] and recruit
849
smaller portions of the cortex [58,77]. Less steep, slower slow waves have also been
850
interpreted as reflecting a smaller recruitment of neuronal populations due to reduced synaptic
851
strength or density [78] but changes in wake-promoting neuromodulation or inhibitory
852
neurons could also be responsible [77,78]. In addition, slow waves are usually steeper
853
following sleep deprivation [55]. Consequently, less steep slow waves in a population that
854
complaint from chronic sleep loss could be interpreted as a disruption of sleep’s homeostatic
855
regulations. Finally, the changes observed in slow waves could affect the physiological
856
functions of slow waves (e.g. synaptic homeostasis, memory consolidation [79–81]) and lead
857
to the subjective feeling of a non-recovering sleep as well as daytime cognitive impairments
858
as typically seen in insomnia. 29
859
The analysis of the microstructure also showed that, contrary to slow waves, sleep spindles
860
are increased in both insomnia groups compared to GS (Fig. 5), with a maximal increase for
861
SSM patients. This increase in spindle density is concordant with the increase in sigma power
862
observed in the EEG spectrum (Fig. 3b). Sleep spindles have also reduced amplitude, and
863
increased frequency and duration in insomnia patients (Fig. 5). This increase in spindle
864
density could seem at odds with our findings which indicate a reduction in sleep rhythms in
865
favor of wake rhythms in insomnia patients (Fig. 3). However, an increase in spindle
866
frequency has been observed under conditions of circadian misalignment [82], while the
867
administration of benzodiazepine [83] or melatonin [84] tends to decrease spindle frequency,
868
suggesting that an increase in spindle frequency is a marker of a deteriorated or lighter form
869
of NREM sleep. Compatible with this view is the negative relationship between spindle
870
frequency and slow-wave activity (a classical marker of sleep depth and quality) that has been
871
previously reported [57].
872 873
PSG recording can inform on the mechanisms underlying insomnia with or without SSM
874
Several models have tried to provide a neurophysiological understanding of insomnia with the
875
hyperarousal model of insomnia [17,85] certainly being the most influential. This model
876
posits that insomnia is rooted in neurophysiology rather than being a purely psychological
877
disorder. Although this model recognizes the role of psychological components in the onset
878
and maintenance of insomnia, it views these components as being potentiated by a
879
physiological substrate. According to this model, a higher level of somatic, cognitive and
880
cortical activity (or hyperarousal) [17,73,74] would be such substrate. Dysregulations of
881
neuroendocrine systems (such as the hypothalamic-pituitary-adrenal-axis responsible for the
882
production of cortisol) have been recently proposed as a cause of this hyperarousal [86].
883
Certain changes in sleep physiology observed in insomnia support the hyperarousal model
884
such as the increase in high-frequency rhythms observed in insomnia patients with or without
885
SSM [17]. A recent study relying on high-density EEG showed that even during deep sleep,
886
individuals with CI show an increase in the prevalence of neuronal patterns of brain activity
887
typically associated with light sleep [36], a phenomenon that could be linked to hyperarousal.
888
Markers of hyperarousal have been also investigated in wakefulness since the model views
889
hyperarousal as a trait that would impact brain functioning day and night. Accordingly, it has
890
been shown that insomnia patients react more strongly to external sensory inputs and internal
891
stimuli (i.e. heartbeat) [87–90].
30
892
Although the hyperarousal model has gathered much supporting evidence, it is unclear if a
893
day-and-night increase in cortical arousal is really at the root of insomnia. Most of the studies
894
showing increase in fast oscillations during insomnia actually evidence stage-dependent
895
effects or effects constrained in specific parts of the night (typically the beginning)
896
[17,30,69]. Perlis and colleagues proposed a reformulation of the hyperarousal model
897
whereby insomnia is characterized by a disruption of homeostatic processes that promote the
898
transition to sleep at the beginning of the night [17,91]. Our results support this view as most
899
of the spectral differences between insomnia patients and controls were observed in the first
900
half of the night.
901
However, our results also indicate that insomnia was not simply characterized by an increase
902
in wake-like rhythms during sleep and a reduction in sleep-like oscillations. Indeed, we also
903
observed an increase in the number of sleep spindles in both insomnia groups (Fig. 5). This
904
increase cannot be simply explained by an increase in the proportion of NREM2 (where sleep
905
spindles are predominant [92]). Indeed, we observed an increase in sleep spindles in both
906
NREM2 and NREM3. Besides, the density of sleep spindles increased in the INS group
907
compared to controls (post-hoc unpaired t-tests: p<0.001 for frontal and central spindles)
908
despite a reduction in the proportion of NREM2 in INS patients (Table 1). Importantly,
909
spindle density was not the only parameter affected and we also observed an increase in the
910
frequency of sleep spindles (Fig. 5). Since the frequency and density of sleep spindles have
911
been found to be negatively correlated with Slow Wave Activity [57], the increase in spindle
912
density and spindle frequency observed in insomnia patients could be a direct consequence of
913
the reduction of slow waves, or both could be mediated by the same physiological
914
mechanism. We hypothesize here that both changes in slow waves (decrease density and
915
down-to-up slope) and sleep spindles (increased density and frequency) could be explained by
916
an increase in cortical excitability during sleep. Indeed, previous work in rodents has shown
917
that a down-regulation of cortical excitability with carbamazepine leads to increased slow-
918
wave power, steeper slow waves, slower spindles and fewer fast spindles [93]. In summary,
919
the administration of carbamazepine leads to a reverse profile compared to insomnia patients,
920
potentially due to the negative impact of carbamazepine on cortical excitability. In fact, the
921
administration of carbamazepine has also been shown to improve sleep parameters in
922
epileptic patients (see [94] for a review). This hypothesis is also supported by the analyses of
923
the spectral slope (see Fig. 3 and above). Thus, it is possible that an increase in cortical
31
924
excitability could be responsible for the physiological changes observed during sleep in
925
insomnia.
926
Machine Learning techniques can facilitate the integration of PSG recordings to clinical
927
practice
928
Our results show that fine-grained levels of analyses of PSG recordings can reveal robust
929
significant differences between insomnia patients and good sleepers but also between
930
insomnia subtypes. However, conducting these analyses can be time-consuming, impeding
931
their easy translation to clinical settings. Nonetheless, this translation might be facilitated by
932
two ongoing revolutions in the field of Sleep Medicine. The first one regards data and the fact
933
PSG devices have become smaller, lighter and cheaper with years. Recently, several large
934
datasets of PSG recordings have been published [68,95,96] or are in the making (e.g. Stanford
935
Technology Analytics and Genomics in Sleep (STAGES) Program), putting sleep research in
936
the era of “big data”. Most importantly, consumers-oriented devices now exist that could
937
bring PSG to the masses [42], facilitating the acquisition of massive amounts of sleep data. It
938
has thus become not only possible but also crucial to better understand what constitutes a
939
good night's sleep.
940
The second revolution is tied to the first one and regards data analysis. Indeed, PSG
941
recordings represent very rich data and, although existing methods allow to automatically
942
analyze multiple aspects of physiological data, recent developments in Artificial Intelligence
943
make it easier to integrate disparate analytic approaches. With the increase in the amount of
944
data available but also the type of available analyses, it is important to find new ways to
945
automatize and rationalize data analyses. Unfortunately, so far, studies focusing on PSG
946
recordings are confined to specific analytic approaches. Here we sought to find a way to
947
integrate these different approaches. We automated most of the analysis pipeline and showed
948
we could rely on supervised classifiers to extract information about individuals’ diagnosis.
949
Besides, even the steps that were here performed through visual inspection of the data (sleep
950
scoring) can now be reliably automated [95].
951
Supervised algorithms were here used in two ways. First, they were used as an exploratory
952
method to identify which features can distinguish between the groups of interest. For
953
example, applying supervised classifiers to spectral features (Fig. 3) allowed us to identify the
954
frequency domains that differ the most between good sleepers and insomnia patients (delta,
955
theta/alpha, sigma and beta oscillations) without relying on a priori hypotheses. The same
32
956
approach allowed us to investigate the differences between NREM and REM sleep,
957
evidencing that some neural oscillations are more predictive of insomnia in NREM (delta,
958
sigma) or REM (theta, beta) sleep.
959
Another use of supervised algorithms is to classify data according to clinically relevant
960
groups. We show here that different sets of features extracted from PSG recordings can either
961
succeed or fail at teasing apart good sleepers from insomnia patients, or to distinguishing
962
between insomnia subtypes (Fig. 6). For example, micro and meso features support an
963
excellent classification of insomnia patients vs. controls, in line with the notion that PSG
964
recordings can be highly relevant for the diagnosis of insomnia. In fact, our findings
965
demonstrate how an automatization of PSG analyses could be implemented to help clinicians
966
diagnose patients with a high level of accuracy (Fig. 6a, sensitivity > 98%, specificity >86%).
967
Importantly, classifiers are also informative when they fail. For example, the same features
968
that can distinguish insomnia patients from good sleepers (e.g. spectral information, micro-
969
structure), can fail to distinguish SSM and INS patients, which suggests that insomnia
970
subtypes are remarkably similar in terms of spectral components or micro-structure. This was
971
not the case for features extracted from the hypnogram. Hence this approach can confirm that,
972
although CI patients with or without insomnia differ according to macroscopic metrics of
973
sleep quantity and quality, their sleep is close to identical when looking at specific
974
physiological mechanisms.
975
Finally, another advantage of classifiers is that it is possible to examine which features are the
976
most responsible for the classifiers’ accuracy, which could provide insights about the
977
physiological substrate of insomnia. For example, the classification of CI patients vs. good
978
sleepers was based mostly on spectral information in the lower frequency range (delta/theta,
979
Table 2). This means that, when not taking into account the different types of insomnia, sleep-
980
related oscillations such as delta and theta rhythms represent a common signature for the
981
insomnia disorder. However, when factoring in insomnia subtypes, other features pertaining
982
to the micro and macro-scales become discriminative. These results stress the importance and
983
relevance of PSG recordings as they allow to identify both the core common physiological
984
signatures of insomnia as well as the components that are specific to particular insomnia
985
subtypes.
986
33
987
Conclusion:
988
We claim here that, in PSG recordings, there is more than meets the eye. PSG recordings
989
seem to carry very rich and reliable information about one’s sleep, in particular in the case of
990
insomnia. In fact, the paradox of SSM (presence of subjective symptoms of insomnia without
991
objective impairments of sleep) is apparent only when focusing on superficial, large-scale
992
metrics of sleep but dissolves when examining the finer dynamics of brain activity. We thus
993
conclude that the limitations outlined in the past and leading to the exclusion of PSG
994
recordings from the diagnosis of insomnia are no longer warranted and that clinicians should
995
revisit the benefits of PSG recordings.
996
We further argue that this reassessment is timely in the light of two ongoing revolutions in the
997
field of Sleep Medicine: (1) the emergence of consumer-based PSG devices will bring PSG
998
recordings to the masses, leading to an explosion in the amount of available data, similarly as
999
what happened with actigraphy, (2) the translation of computational tools from the field of
1000
Artificial Intelligence to Sleep Medicine allows the rapid, automated and massive analysis of
1001
large datasets and simplifies the difficult task of summarizing expanding amounts of data to
1002
human decision-makers (e.g. clinicians). We show here the feasibility of embracing such
1003
changes and their ability to facilitate the clinical diagnosis and management of a common but
1004
difficult sleep disorder: insomnia. We also demonstrate how these approaches can suggest
1005
new ways of understanding why some individuals sleep well while others struggle.
1006
34
1007
References:
1008 1009 1010 1011 1012 1013 1014 1015 1016 1017 1018 1019 1020 1021 1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055
[1] Luyster FS, Strollo PJ, Zee PC, Walsh JK, Boards of Directors of the American Academy of Sleep Medicine and the Sleep Research Society. Sleep: a health imperative. Sleep 2012;35:727–34. doi:10.5665/sleep.1846. [2] Cirelli C, Tononi G. Is sleep essential? PLoS Biol 2008;6:e216. doi:10.1371/journal.pbio.0060216. [3] Hirshkowitz M, Whiton K, Albert SM, Alessi C, Bruni O, DonCarlos L, et al. National Sleep Foundation’s sleep time duration recommendations: methodology and results summary. Sleep Health 2015;1:40–3. doi:10.1016/j.sleh.2014.12.010. [4] Ohayon MM. Epidemiology of insomnia: what we know and what we still need to learn. Sleep Med Rev 2002;6:97–111. [5] Léger D, Bayon V. Societal costs of insomnia. Sleep Med Rev 2010;14:379–89. doi:10.1016/j.smrv.2010.01.003. [6] Ohayon MM. Epidemiology of insomnia: what we know and what we still need to learn. Sleep Med Rev 2002;6:97–111. [7] Léger D, Morin CM, Uchiyama M, Hakimi Z, Cure S, Walsh JK. Chronic insomnia, quality-of-life, and utility scores: comparison with good sleepers in a cross-sectional international survey. Sleep Med 2012;13:43–51. doi:10.1016/j.sleep.2011.03.020. [8] Gottlieb DJ, Punjabi NM, Newman AB, Resnick HE, Redline S, Baldwin CM, et al. Association of sleep time with diabetes mellitus and impaired glucose tolerance. Arch Intern Med 2005;165:863–7. doi:10.1001/archinte.165.8.863. [9] Chao C-Y, Wu J-S, Yang Y-C, Shih C-C, Wang R-H, Lu F-H, et al. Sleep duration is a potential risk factor for newly diagnosed type 2 diabetes mellitus. Metab Clin Exp 2011;60:799–804. doi:10.1016/j.metabol.2010.07.031. [10] Laugsand LE, Vatten LJ, Platou C, Janszky I. Insomnia and the risk of acute myocardial infarction: a population study. Circulation 2011;124:2073–81. doi:10.1161/CIRCULATIONAHA.111.025858. [11] Vgontzas AN, Fernandez-Mendoza J, Liao D, Bixler EO. Insomnia with objective short sleep duration: the most biologically severe phenotype of the disorder. Sleep Med Rev 2013;17:241–54. doi:10.1016/j.smrv.2012.09.005. [12] Lin C-L, Chien W-C, Chung C-H, Wu F-L. Risk of type 2 diabetes in patients with insomnia: A population-based historical cohort study. Diabetes Metab Res Rev 2018;34. doi:10.1002/dmrr.2930. [13] Bertisch SM, Pollock BD, Mittleman MA, Buysse DJ, Bazzano LA, Gottlieb DJ, et al. Insomnia with Objective Short Sleep Duration and Risk of Incident Cardiovascular Disease and All-Cause Mortality: Sleep Heart Health Study. Sleep 2018. doi:10.1093/sleep/zsy047. [14] Baglioni C, Battagliese G, Feige B, Spiegelhalder K, Nissen C, Voderholzer U, et al. Insomnia as a predictor of depression: a meta-analytic evaluation of longitudinal epidemiological studies. J Affect Disord 2011;135:10–9. doi:10.1016/j.jad.2011.01.011. [15] Fernandez-Mendoza J, Calhoun S, Bixler EO, Pejovic S, Karataraki M, Liao D, et al. Insomnia with objective short sleep duration is associated with deficits in neuropsychological performance: a general population study. Sleep 2010;33:459–65. [16] Fortier-Brochu E, Beaulieu-Bonneau S, Ivers H, Morin CM. Insomnia and daytime cognitive performance: a meta-analysis. Sleep Med Rev 2012;16:83–94. doi:10.1016/j.smrv.2011.03.008. [17] Riemann D, Spiegelhalder K, Feige B, Voderholzer U, Berger M, Perlis M, et al. The hyperarousal model of insomnia: a review of the concept and its evidence. Sleep Med Rev 2010;14:19–31. doi:10.1016/j.smrv.2009.04.002.
35
1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105
[18] Feige B, Baglioni C, Spiegelhalder K, Hirscher V, Nissen C, Riemann D. The microstructure of sleep in primary insomnia: An overview and extension. International Journal of Psychophysiology 2013;89:171–80. doi:10.1016/j.ijpsycho.2013.04.002. [19] Riemann D, Baglioni C, Bassetti C, Bjorvatn B, Dolenc Groselj L, Ellis JG, et al. European guideline for the diagnosis and treatment of insomnia. J Sleep Res 2017;26:675–700. doi:10.1111/jsr.12594. [20] Hobson JA. Sleep is of the brain, by the brain and for the brain. Nature 2005;437:1254– 6. doi:10.1038/nature04283. [21] Morin CM, Vallières A, Guay B, Ivers H, Savard J, Mérette C, et al. Cognitive behavioral therapy, singly and combined with medication, for persistent insomnia: a randomized controlled trial. JAMA 2009;301:2005–15. doi:10.1001/jama.2009.682. [22] Newell J, Mairesse O, Verbanck P, Neu D. Is a one-night stay in the lab really enough to conclude? First-night effect and night-to-night variability in polysomnographic recordings among different clinical population samples. Psychiatry Research 2012;200:795–801. doi:10.1016/j.psychres.2012.07.045. [23] Riedel BW, Winfield CF, Lichstein KL. First night effect and reverse first night effect in older adults with primary insomnia: does anxiety play a role? Sleep Medicine 2001;2:125–33. doi:10.1016/S1389-9457(00)00054-X. [24] Sateia MJ. International Classification of Sleep Disorders-Third Edition. Chest 2014;146:1387–94. doi:10.1378/chest.14-0970. [25] Buysse DJ, Reynolds CF, Monk TH, Berman SR, Kupfer DJ. The Pittsburgh sleep quality index: A new instrument for psychiatric practice and research. Psychiatry Research 1989;28:193–213. doi:10.1016/0165-1781(89)90047-4. [26] Morin CM, Belleville G, Bélanger L, Ivers H. The Insomnia Severity Index: Psychometric Indicators to Detect Insomnia Cases and Evaluate Treatment Response. Sleep 2011;34:601–8. doi:10.1093/sleep/34.5.601. [27] Castro LS, Poyares D, Leger D, Bittencourt L, Tufik S. Objective prevalence of insomnia in the São Paulo, Brazil epidemiologic sleep study. Ann Neurol 2013;74:537– 46. doi:10.1002/ana.23945. [28] Bastien CH, Ceklic T, St-Hilaire P, Desmarais F, Pérusse AD, Lefrançois J, et al. Insomnia and sleep misperception. Pathologie Biologie 2014;62:241–51. doi:10.1016/j.patbio.2014.07.003. [29] Edinger JD, Krystal AD. Subtyping primary insomnia: is sleep state misperception a distinct clinical entity? Sleep Medicine Reviews 2003;7:203–14. doi:10.1053/smrv.2002.0253. [30] Perlis ML, Merica H, Smith MT, Giles DE. Beta EEG activity and insomnia. Sleep Medicine Reviews 2001;5:365–76. doi:10.1053/smrv.2001.0151. [31] Krystal JH, Carter CS, Geschwind D, Manji HK, March JS, Nestler EJ, et al. It is time to take a stand for medical research and against terrorism targeting medical scientists. Biol Psychiatry 2008;63:725–7. doi:10.1016/j.biopsych.2008.03.005. [32] Cervena K, Espa F, Perogamvros L, Perrig S, Merica H, Ibanez V. Spectral analysis of the sleep onset period in primary insomnia. Clinical Neurophysiology 2014;125:979–87. doi:10.1016/j.clinph.2013.10.010. [33] Freedman RR. EEG power spectra in sleep-onset insomnia. Electroencephalogr Clin Neurophysiol 1986;63:408–13. [34] Riedner BA, Goldstein MR, Plante DT, Rumble ME, Ferrarelli F, Tononi G, et al. Regional Patterns of Elevated Alpha and High-Frequency Electroencephalographic Activity during Nonrapid Eye Movement Sleep in Chronic Insomnia: A Pilot Study. Sleep 2016;39:801–12. doi:10.5665/sleep.5632. [35] Feige B, Al-Shajlawi A, Nissen C, Voderholzer U, Hornyak M, Spiegelhalder K, et al.
36
1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155
[36]
[37]
[38]
[39] [40] [41]
[42]
[43] [44]
[45]
[46] [47]
[48]
[49]
[50]
[51]
Does REM sleep contribute to subjective wake time in primary insomnia? A comparison of polysomnographic and subjective sleep in 100 patients. Journal of Sleep Research 2008;17:180–90. doi:10.1111/j.1365-2869.2008.00651.x. Christensen JAE, Wassing R, Wei Y, Ramautar JR, Lakbila-Kamal O, Jennum PJ, et al. Data-Driven Analysis of EEG Reveals Concomitant Superficial Sleep During Deep Sleep in Insomnia Disorder. Frontiers in Neuroscience 2019;13. doi:10.3389/fnins.2019.00598. Khazaie H, Veronese M, Noori K, Emamian F, Zarei M, Ashkan K, et al. Functional reorganization in obstructive sleep apnoea and insomnia: A systematic review of the resting-state fMRI. Neuroscience & Biobehavioral Reviews 2017;77:219–31. doi:10.1016/j.neubiorev.2017.03.013. Kay DB, Karim HT, Soehner AM, Hasler BP, James JA, Germain A, et al. Subjective– Objective Sleep Discrepancy Is Associated With Alterations in Regional Glucose Metabolism in Patients With Insomnia and Good Sleeper Controls. Sleep 2017;40. doi:10.1093/sleep/zsx155. Center for Drug Evaluation and Research. Guidance for Industry: Guidelines for the clinical evaluation of Hypnotic Drugs 1997. Guideline on medicinal products for the treatment of insomnia 2011. Arnal PJ, Thorey V, Ballard ME, Hernandez AB, Guillot A, Jourde H, et al. The Dreem Headband as an Alternative to Polysomnography for EEG Signal Acquisition and Sleep Staging. BioRxiv 2019. doi:10.1101/662734. Debellemaniere E, Chambon S, Pinaud C, Thorey V, Dehaene D, Léger D, et al. Performance of an Ambulatory Dry-EEG Device for Auditory Closed-Loop Stimulation of Sleep Slow Oscillations in the Home Environment. Frontiers in Human Neuroscience 2018;12. doi:10.3389/fnhum.2018.00088. LeCun Y, Bengio Y, Hinton G. Deep learning. Nature 2015;521:436–44. doi:10.1038/nature14539. Obermeyer Z, Emanuel EJ. Predicting the Future — Big Data, Machine Learning, and Clinical Medicine. New England Journal of Medicine 2016;375:1216–9. doi:10.1056/NEJMp1606181. Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, et al. Rules for Scoring Respiratory Events in Sleep: Update of the 2007 AASM Manual for the Scoring of Sleep and Associated Events. JCSM 2012;08:597–619. doi:10.5664/jcsm.2172. Iber C, Ancoli-Israel S, Chesson A, Quan S. The AASM Manual for the Scoring of Sleep and Associated Events: Rules, Terminology and Technical Specifications 2007. Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, et al. Rules for Scoring Respiratory Events in Sleep: Update of the 2007 AASM Manual for the Scoring of Sleep and Associated Events. JCSM 2012;08:597–619. doi:10.5664/jcsm.2172. Ermis U, Krakow K, Voss U. Arousal thresholds during human tonic and phasic REM sleep: Arousal threshold in tonic and phasic REM. Journal of Sleep Research 2010;19:400–6. doi:10.1111/j.1365-2869.2010.00831.x. Rechtschaffen A, Kales AA. A Manual of Standardized Terminology, Techniques, and Scoring System for Sleep Stages of Human Subjects (Bethesda, MD: US Department of Health, Education and Welfare). 1968. Sallinen M, Kaartinen J, Lyytinen H. Processing of auditory stimuli during tonic and phasic periods of REM sleep as revealed by event-related brain potentials. Journal of Sleep Research 1996;5:220–8. doi:10.1111/j.1365-2869.1996.00220.x. Andrillon T, Nir Y, Cirelli C, Tononi G, Fried I. Single-neuron activity and eye movements during human REM sleep and awake vision. Nature Communications 2015;6:7884. doi:10.1038/ncomms8884.
37
1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182 1183 1184 1185 1186 1187 1188 1189 1190 1191 1192 1193 1194 1195 1196 1197 1198 1199 1200 1201 1202 1203 1204 1205
[52] Arnulf I. The “scanning hypothesis” of rapid eye movements during REM sleep: a review of the evidence. Arch Ital Biol 2011;149:367–82. [53] Steriade M. Sleep, epilepsy and thalamic reticular inhibitory neurons. Trends Neurosci 2005;28:317–24. doi:10.1016/j.tins.2005.03.007. [54] Buzsáki G. Rhythms of the brain. Oxford ; New York: Oxford University Press; 2006. [55] Riedner BA, Vyazovskiy VV, Huber R, Massimini M, Esser S, Murphy M, et al. Sleep homeostasis and cortical synchronization: III. A high-density EEG study of sleep slow waves in humans. Sleep 2007;30:1643–57. [56] Nir Y, Staba R, Andrillon T, Vyazovskiy VV, Cirelli C, Fried I, et al. Regional slow waves and spindles in human sleep. Neuron 2011;70:153–69. doi:10.1016/j.neuron.2011.02.043. [57] Andrillon T, Nir Y, Staba RJ, Ferrarelli F, Cirelli C, Tononi G, et al. Sleep Spindles in Humans: Insights from Intracranial EEG and Unit Recordings. J Neurosci 2011;31:17821–34. doi:10.1523/Jneurosci.2604-11.2011. [58] Siclari F, Bernardi G, Riedner BA, LaRocque JJ, Benca RM, Tononi G. Two Distinct Synchronization Processes in the Transition to Sleep: A High-Density Electroencephalographic Study. SLEEP 2014. doi:10.5665/sleep.4070. [59] Gramfort A. MEG and EEG data analysis with MNE-Python. Frontiers in Neuroscience 2013;7. doi:10.3389/fnins.2013.00267. [60] Gramfort A, Luessi M, Larson E, Engemann DA, Strohmeier D, Brodbeck C, et al. MNE software for processing MEG and EEG data. NeuroImage 2014;86:446–60. doi:10.1016/j.neuroimage.2013.10.027. [61] Haller M, Donoghue T, Peterson E, Varma P, Sebastian P, Gao R, et al. Parameterizing neural power spectra. BioRxiv 2018. doi:10.1101/299859. [62] Gao R, Peterson EJ, Voytek B. Inferring synaptic excitation/inhibition balance from field potentials. NeuroImage 2017;158:70–8. doi:10.1016/j.neuroimage.2017.06.078. [63] Colombo MA, Napolitani M, Boly M, Gosseries O, Casarotto S, Rosanova M, et al. The spectral exponent of the resting EEG indexes the presence of consciousness during unresponsiveness induced by propofol, xenon, and ketamine. NeuroImage 2019;189:631–44. doi:10.1016/j.neuroimage.2019.01.024. [64] Lendner JD, Helfrich RF, Mander BA, Romundstad L, Lin JJ, Walker MP, et al. An Electrophysiological Marker of Arousal Level in Humans. BioRxiv 2019. doi:10.1101/625210. [65] Maris E, Oostenveld R. Nonparametric statistical testing of EEG- and MEG-data. J Neurosci Methods 2007;164:177–90. doi:10.1016/j.jneumeth.2007.03.024. [66] Borbély AA. A two process model of sleep regulation. Hum Neurobiol 1982;1:195–204. [67] Landis JR, Koch GG. The Measurement of Observer Agreement for Categorical Data. Biometrics 1977;33:159. doi:10.2307/2529310. [68] Purcell SM, Manoach DS, Demanuele C, Cade BE, Mariani S, Cox R, et al. Characterizing sleep spindles in 11,630 individuals from the National Sleep Research Resource. Nature Communications 2017;8. doi:10.1038/ncomms15930. [69] Svetnik V, Snyder ES, Ma J, Tao P, Lines C, Herring WJ. EEG spectral analysis of NREM sleep in a large sample of patients with insomnia and good sleepers: effects of age, sex and part of the night. Journal of Sleep Research 2017;26:92–104. doi:10.1111/jsr.12448. [70] Silva A, Andersen ML, De Mello MT, Bittencourt LRA, Peruzzo D, Tufik S. Gender and age differences in polysomnography findings and sleep complaints of patients referred to a sleep laboratory. Brazilian Journal of Medical and Biological Research 2008;41:1067–75. doi:10.1590/S0100-879X2008001200005. [71] Bastien CH, LeBlanc M, Carrier J, Morin CM. Sleep EEG Power Spectra, Insomnia, and
38
1206 1207 1208 1209 1210 1211 1212 1213 1214 1215 1216 1217 1218 1219 1220 1221 1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255
Chronic Use of Benzodiazepines. Sleep 2003;26:313–7. doi:10.1093/sleep/26.3.313. [72] Siclari F, Larocque JJ, Postle BR, Tononi G. Assessing sleep consciousness within subjects using a serial awakening paradigm. Front Psychol 2013;4:542. doi:10.3389/fpsyg.2013.00542. [73] Krystal AD, Edinger JD, Wohlgemuth WK, Marsh GR. NREM sleep EEG frequency spectral correlates of sleep complaints in primary insomnia subtypes. Sleep 2002;25:630–40. [74] St-Jean G, Turcotte I, Bastien CH. Cerebral asymmetry in insomnia sufferers. Front Neurol 2012;3:47. doi:10.3389/fneur.2012.00047. [75] Voytek B, Kramer MA, Case J, Lepage KQ, Tempesta ZR, Knight RT, et al. AgeRelated Changes in 1/f Neural Electrophysiological Noise. Journal of Neuroscience 2015;35:13257–65. doi:10.1523/JNEUROSCI.2332-14.2015. [76] Peterson EJ, Rosen BQ, Campbell AM, Belger A, Voytek B. 1/ neural noise is a better predictor of schizophrenia than neural oscillations. BioRxiv 2018. doi:10.1101/113449. [77] Bernardi G, Siclari F, Handjaras G, Riedner BA, Tononi G. Local and Widespread Slow Waves in Stable NREM Sleep: Evidence for Distinct Regulation Mechanisms. Frontiers in Human Neuroscience 2018;12. doi:10.3389/fnhum.2018.00248. [78] Esser SK, Hill SL, Tononi G. Sleep homeostasis and cortical synchronization: I. Modeling the effects of synaptic strength on sleep slow waves. Sleep 2007;30:1617–30. doi:10.1093/sleep/30.12.1617. [79] Tononi G, Cirelli C. Sleep and the Price of Plasticity: From Synaptic and Cellular Homeostasis to Memory Consolidation and Integration. Neuron 2014;81:12–34. doi:10.1016/j.neuron.2013.12.025. [80] Diekelmann S, Born J. The memory function of sleep. Nat Rev Neurosci 2010;11:114– 26. [81] Léger D, Debellemaniere E, Rabat A, Bayon V, Benchenane K, Chennaoui M. SlowWave Sleep: From the Cell to the Clinic. Sleep Medicine Reviews 2018. doi:10.1016/j.smrv.2018.01.008. [82] Aeschbach D, Dijk DJ, Borbély AA. Dynamics of EEG spindle frequency activity during extended sleep in humans: relationship to slow-wave activity and time of day. Brain Res 1997;748:131–6. doi:10.1016/s0006-8993(96)01275-9. [83] Plante DT, Goldstein MR, Cook JD, Smith R, Riedner BA, Rumble ME, et al. Effects of oral temazepam on sleep spindles during non-rapid eye movement sleep: A high-density EEG investigation. European Neuropsychopharmacology 2015;25:1600–10. doi:10.1016/j.euroneuro.2015.06.005. [84] Dijk DJ, Roth C, Landolt HP, Werth E, Aeppli M, Achermann P, et al. Melatonin effect on daytime sleep in men: suppression of EEG low frequency activity and enhancement of spindle frequency activity. Neurosci Lett 1995;201:13–6. doi:10.1016/03043940(95)12118-n. [85] Bonnet MH, Arand DL. Hyperarousal and insomnia: State of the science. Sleep Medicine Reviews 2010;14:9–15. doi:10.1016/j.smrv.2009.05.002. [86] Vargas I, Vgontzas AN, Abelson JL, Faghih RT, Morales KH, Perlis ML. Altered ultradian cortisol rhythmicity as a potential neurobiologic substrate for chronic insomnia. Sleep Med Rev 2018;41:234–43. doi:10.1016/j.smrv.2018.03.003. [87] Bastien CH, St-Jean G, Morin CM, Turcotte I, Carrier J. Chronic Psychophysiological Insomnia: Hyperarousal and/or Inhibition Deficits? An ERPs Investigation. Sleep 2008;31:887–98. doi:10.1093/sleep/31.6.887. [88] Turcotte I, St-Jean G, Bastien CH. Are individuals with paradoxical insomnia more hyperaroused than individuals with psychophysiological insomnia? Event-related
39
1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282
[89]
[90]
[91] [92] [93]
[94]
[95]
[96]
potentials measures at the peri-onset of sleep. International Journal of Psychophysiology 2011;81:177–90. doi:10.1016/j.ijpsycho.2011.06.008. Yang C-M, Lo H-S. ERP Evidence of Enhanced Excitatory and Reduced Inhibitory Processes of Auditory Stimuli During Sleep in Patients With Primary Insomnia. Sleep 2007;30:585–92. doi:10.1093/sleep/30.5.585. Wei Y, Ramautar JR, Colombo MA, Stoffers D, Gómez-Herrero G, van der Meijden WP, et al. I Keep a Close Watch on This Heart of Mine: Increased Interoception in Insomnia. SLEEP 2016;39:2113–24. doi:10.5665/sleep.6308. Pigeon WR, Perlis ML. Sleep homeostasis in primary insomnia. Sleep Med Rev 2006;10:247–54. doi:10.1016/j.smrv.2005.09.002. De Gennaro L, Ferrara M. Sleep spindles: an overview. Sleep Med Rev 2003;7:423–40. Ayoub A, Aumann D, Hörschelmann A, Kouchekmanesch A, Paul P, Born J, et al. Differential Effects on Fast and Slow Spindle Activity, and the Sleep Slow Oscillation in Humans with Carbamazepine and Flunarizine to Antagonize Voltage-Dependent Na+ and Ca2+ Channel Activity. Sleep 2013;36:905–11. doi:10.5665/sleep.2722. Jain SV, Glauser TA. Effects of epilepsy treatments on sleep architecture and daytime sleepiness: An evidence-based review of objective sleep metrics. Epilepsia 2014;55:26– 37. doi:10.1111/epi.12478. Stephansen JB, Olesen AN, Olsen M, Ambati A, Leary EB, Moore HE, et al. Neural network analysis of sleep stages enables efficient diagnosis of narcolepsy. Nature Communications 2018;9. doi:10.1038/s41467-018-07229-3. Bertisch SM, Pollock BD, Mittleman MA, Buysse DJ, Bazzano LA, Gottlieb DJ, et al. Insomnia with objective short sleep duration and risk of incident cardiovascular disease and all-cause mortality: Sleep Heart Health Study. Sleep 2018;41. doi:10.1093/sleep/zsy047.
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Figures and Tables: Table 1:
Age (years) Gender (% Females)
Controls (N=89)
SSM (N=59)
Insomnia (N=288)
Group Effect
34.5 ± 1.3
39.4 ± 1.5 (*) 76.2 (***) 399 ± 7.6 (ns) 20.5 ± 2.9 (***) 34.0 ± 3.6 (***) 88.3 ± 0.8 (***) 11.7 ± 0.8 (***) 1.7 ± 0.1
45.7 ± 0.8 (***) 68.6 (***) 361 ± 5.1 (***) 49.4 ± 3.1 (ns) 94.9 ± 4.2 (***) 72.0 ± 0.8 (***) 27.8 ± 0.8 (***) 2.0 ± 0.1
50.0 ± 1.1 (*) 19.5 ± 1.2 (***) 17.1 ± 0.7 (*) 4.1 ± 0.2
41.7 ± 0.7 (***) 15.3 ± 0.5 (ns) 12.9 ± 0.3 (**) 3.6 ± 0.1 3.1 ± 0.2 (***) 0.23 ± 0.01
1.5.10-10 (***) 1.5.10-22 (***) 3.2.10-5 (***) 5.2.10-6 (***) 1.5.10-10 (***) 9.5.10-16 (***) 2.8.10-15 (***) 0.73 (ns) 1.6.10-8 (***) 0.002 (ns) 2.8.10-6 (***) 0.03 (ns) 3.4.10-4 (**) 0.009 (ns) 0.006 (ns) 3.3.10-11 (***) 1.6.10-7 (***) 0.02 (ns)
21.3
TST (minutes)
406 ± 5.4
SOL (minutes)
50.3 ± 6.0
WASO (minutes)
57.1 ± 4.2
Sleep Efficiency (%)
79.7 ± 1.1
% Wake
20.3 ± 1.1
% N1
2.4 ± 0.2
% N2
47.1 ± 0.9
% N3
15.1 ± 0.7
% REM
15.0 ± 0.5
# Cycles
3.9 ± 0.1
# REM episodes
4.3 ± 0.3
Arousals NREM (/min)
0.20 ± 0.01
3.6 ± 0.2 (ns) 0.18 ± 0.01
Arousals REM (/min)
0.20 ± 0.01
0.24 ± 0.02
0.22 ± 0.01
Spindles (/min)
1.6 ± 0.1
Slow Waves (/min)
6.9 ± 0.4
REMS (/min)
6.4 ± 0.3
3.6 ± 0.3 (***) 4.6 ± 0.4 (***) 4.7 ± 0.3
2.7 ± 0.1 (***) 4.0 ± 0.2 (***) 5.1 ± 0.2
p-value, (corrected threshold)
1287
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1288 1289 1290 1291 1292 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329 1330 1331 1332
Table 1: Demographics and sleep differences across controls (GS), SSM and INS patients. Numbers show the average and standard-error-of-the-mean (mean ± SEM) across individuals. The Group Effect column shows the p-values for an ANCOVA on groups with age and gender as covariates. In case of a significant group effect (Bonferroni correction for N=18 comparisons), the stars denote the corrected significance levels of post-hoc two-sided unpaired t-tests (GS vs. SSM and GS vs. INS resp.). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
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1333 1334
Table 2: Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
GS. vs. CI (VI) Power - [0-0.5] Hz - Wake (200) Power - [0.5-1] Hz - N2 (68.9) Power - [0.5-1] Hz - NREM (56.5) Power - ∂ - N2 (40.1) Power - ∂ - NREM (39.6) Power - [1.5-2] Hz - Wake (39.6) Power - [0-0.5] Hz - N2 (33.7) Power - [0-0.5] Hz - NREM (32.5) Power - [0.5-1] Hz - Wake (30.2) Power - [0-1.5] Hz – REM (29.1) Power - [1.5-2] Hz - N2 (27.4) Power - ∂ - Wake (27.3) Power - [1-1.5] Hz - NREM (26.2) Power - [1.5-2] Hz - NREM (25.6) Power - [0.5-1] Hz - REM (24.5) Power - [5.5-6] Hz - REM (24.1) Power - [1-1.5] Hz - N3 (23.8) Power - [6-6.5] Hz - REM (23.8) Power - [2-2.5] Hz - Wake (23.7) Power - [3.5-4] Hz - Wake (23.0)
GS. vs. SSM vs. INS (VI) Power - [0-0.5] Hz - Wake (99.5) Hypno - duration - Wake (46.2) Power - [0.5-1] Hz - N2 (42.4) Hypno - sleep efficiency (38.6) Hypno - % Wake (31.7) Power - [0.5-1] Hz - NREM (28.4)
SSM vs. INS (VI) Hypno - duration - Wake (196.8) Hypno - sleep efficiency (145.7) Hypno - % Wake (103.8) Hypno - transition - W>W (80.8) Hypno - WASO (69.7) Hypno - transition - W>N2 (63.8) Spindle – density C3/4 - N3 (47.0) Hypno - transition - N2>W (43.4) Spindle - duration C3/4 - N2 (42.1) Power - [10-10.5] Hz - N1 (40.9) Hypno - duration - REM (39.5)
Power - ∂ - N2 (26.3) Hypno - transition - W>W (25.9) Power - [1.5-2] Hz - Wake (23.6) Power - [0-0.5] Hz - N2 (21.1) Power - [0-0.5] Hz - NREM (20.8) Power - ∂ - NREM Hypno - sleep latency (38.2) (20.6) Hypno - WASO Hypno - duration - bed-time (20.6) (36.9) Power - [0.5-1] Hz - Wake Hypno - duration - sleep time (20.5) (36.0) Hypno - transition - W>N2 Hypno - transition - N3>N2 (20.3) (34.8) Power - [3.5-4] Hz - Wake Hypno - duration - cycle (19.7) (34.6) Power - [0.5-1] Hz - REM Hypno - arousals - N3 (18.9) (33.2) Power - ∂ - Wake Spindle - freq. F3/4 – N3 (18.6) (32.9) Power - [2-2.5] Hz - Wake Spindle - duration F3/4 – N3 (18.4) (32.0) Power - ß - Wake Power - [4 -4.5] Hz - REM (18.1) (31.4)
1335 1336
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1337 1338 1339 1340 1341 1342 1343 1344
Table 2: Classifiers’ top-features. For each feature used by a classifier, a Variable Importance (VI) index can be calculated, which expresses the weight of this particular feature in the classification. We selected the top20 features for each classifier (1st column: 2-class GS vs. CI; 2nd column: 3-class GS vs. SSM vs. INS; 3rd column: 2-class SSM vs. INS) and show the name of these features sorted in descending order of VI value. For each feature, the VI value is also displayed (parentheses).
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1345 1346
1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 1358 1359 1360 1361 1362 1363 1364 1365 1366
Figure 1:
Figure 1: Sleep stages and stages-transitions across controls, SSM and insomnia patients. Top: Proportion of time spent in all sleep stages (wakefulness, NREM1, NREM2, NREM3 and REM sleep) across the three different groups (GS (controls), INS (insomnia) and SSM patients) for the first half (left) and the second half (right) of the night. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. ANCOVAs were used to assess group-differences for each stage and time period. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/10). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5. The horizontal line between the left and right part of the graph denotes the only significant interaction between groups and night-segment. Bottom: Matrices of state-transition probabilities for the three groups (GS, SSM and INS). Each cell shows the probability to transition from a state at time t to another state at time t+1. Probabilities were extracted from the individual hypnograms (30s time-windows). Red-squares show the cells showing a significant modulation across groups according to ANCOVAs. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/25).
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1367 1368
Figure 2:
1369 1370 1371
46
1372 1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383 1384 1385 1386 1387 1388 1389 1390 1391 1392
Figure 2: Spectral features can distinguish good sleepers from insomnia patients with or without SSM. (a) Supervised classifiers were trained on relative power from 0 to 20Hz (step: 0.5Hz) to classify PSG recordings into 3 clinical groups (GS, INS and SSM). The graph shows the classifiers’ performance (ROC curve area), quantifying the discriminability of the different groups at each frequency bin (chance-level: 0.5; see Methods). The procedure was applied for NREM (blue) and REM (green) epochs separately. Colored horizontal bars showed significant clusters when comparing the ROC areas between NREM and REM epochs (cluster permutation; blue: NREM>REM; green: REM>NREM, pcluster<0.001). (b) Relative power spectra for the delta ([0.5-4]Hz), theta/alpha ([5-11]Hz), sigma ([11-15]Hz) and beta ([1620]Hz) bands across the entire night. Power was normalized across the entire [0-20]Hz spectrum and expressed in percentage (see Methods). Each night recording being of a different length, their duration was also normalized and is expressed in percentage. Only epochs in NREM1, NREM2, NREM3 and REM sleep were here considered. Time 0 corresponds to sleep onset (defined as either the first two consecutive epochs of NREM1 or first epoch of NREM2, NREM3 and REM sleep). Black horizontal lines show significance statistical differences across groups as assessed by ANCOVAs at the sample level and corrected for multiple comparisons with a cluster permutation approach (see Methods). Clusters p-values were also corrected for multiple comparisons with Bonferroni (threshold: 0.05/4).
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1393 1394
1395 1396 1397 1398 1399 1400 1401 1402 1403 1404 1405 1406
Figure 3:
Figure 3: CI patients have reduced spectral slopes in NREM sleep (a) Distribution of the slope of the 1/f background of the EEG spectrum (see Methods for details), computed on the power spectrum averaged by sleep stage (Wake, NREM1, NREM2, NREM3 and REM) and across individuals for each group. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. (b) Same data but ordered by ascending slope values in the GS group. ANCOVAs were used to assess group-differences for each sleep-stage. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/5). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
48
1407 1408
Figure 4:
1409 1410
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1411 1412 1413 1414 1415 1416 1417 1418 1419 1420 1421
Figure 4: Properties of sleep slow waves across GS individuals, SSM and INS patients. Panels show the differences across groups for several parameters of sleep slow waves (from top to bottom: density of detected slow waves (waves/minute), peak-to-peak amplitude ( V), slow-wave frequency (Hz) and slope ( V/s); see Methods for details). These properties are shown for slow waves detected in NREM2 (left) and NREM3 (right) for central and frontal electrodes. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. ANCOVAs were used to assess group-differences for each sleep-stage and electrode locations. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/16). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
50
1422 1423
Figure 5:
1424 1425
51
1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436
Figure 5: Properties of sleep spindles GS individuals, SSM and INS patients. Panels show the differences across groups for several parameters of sleep spindles (from top to bottom: density of detected spindles (spindles/minutes), maximum amplitude of the spindles ( V), duration (s) and frequency (Hz); see Methods for details). These properties are shown for spindles detected in NREM2 (left) and NREM3 (right) for central and frontal electrodes. Violin plots show individual averages (colored circles) as well as the group median (white circles) and standard deviations (grey bars) across individuals. ANCOVAs were used to assess group-difference for each sleep-stage and electrode locations. A Bonferroni correction was applied to correct for multiple comparisons (threshold= 0.05/16). ***: p<0.001; **: p<0.01; *:p<0.05; ns: p>0.5.
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1437 1438
Figure 6:
1439 1440
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1441 1442 1443 1444 1445 1446 1447 1448 1449 1450 1451 1452 1453 1454
Figure 6: Supervised classifiers can automatically diagnose insomnia and insomnia subtypes. A series of classifiers were trained on features obtained from the visual inspection of the PSG recordings (visual, V) or computed from the EEG signal (computed, C) or both (V+C). Different classifications were tested (top: good sleepers (GS) vs. insomnia patients (CI: SSM+INS); middle: GS vs. SSM vs. INS (3 classes); bottom: INS vs. SSM). For each classifier type, 100 iterations of the classification were performed. Violin plots (left) show the distribution of the Cohen’s κ values (classifiers’ accuracy) across iterations. Confusion matrices (left) show the average performance of the visual and computed classifiers (horizontal lines show predicted labels, vertical lines real labels). Number in each cell represents the % of individuals within a particular group (e.g. CI) for which a specific prediction has been made (columns add up to 100%).
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