- Email: [email protected]
Cannabidiol increases the nociceptive threshold in a preclinical model of Parkinson's disease
Journal Pre-proof Cannabidiol increases the nociceptive threshold in a preclinical model of Parkinson's disease Glauce Crivelaro do Nascimento, Daniele Pereira Ferrari, Francisco Silveira Guimaraes, Elaine Aparecida Del Bel, Mariza Bortolanza, Nilson Carlos FerreiraJunior PII:
S0028-3908(19)30370-3
DOI:
https://doi.org/10.1016/j.neuropharm.2019.107808
Reference:
NP 107808
To appear in:
Neuropharmacology
Received Date: 22 May 2019 Revised Date:
11 September 2019
Accepted Date: 2 October 2019
Please cite this article as: Crivelaro do Nascimento, G., Ferrari, D.P., Guimaraes, F.S., Del Bel, E.A., Bortolanza, M., Ferreira- Junior, N.C., Cannabidiol increases the nociceptive threshold in a preclinical model of Parkinson's disease, Neuropharmacology (2019), doi: https://doi.org/10.1016/ j.neuropharm.2019.107808. 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 Published by Elsevier Ltd.
1
Cannabidiol increases the nociceptive threshold in a preclinical model of Parkinson’s disease
*Glauce Crivelaro do Nascimento1,2; *Daniele Pereira Ferrari3; Francisco Silveira Guimaraes4; Elaine Aparecida Del Bel1,2,3; Mariza Bortolanza1a; Nilson Carlos FerreiraJunior1a
* GCN and DPF are equally responsible for this paper. 1 Department of Basic and Oral Biology, School of Dentistry of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14040-904, Brazil. 2 Department of Physiology, School of Medicine of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14049-900, Brazil. 3 Department of Neuroscience, School of Medicine of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14049-900, Brazil. 4 Department of Pharmacology, School of Medicine of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14049-900, Brazil.
a Corresponding authors: MB and NCFJ Department of Oral and Basic Biology School of Dentistry of Ribeirao Preto, University of Sao Paulo Cafe Avenue - FORP - USP – Ribeirao Preto - SP - Brazil - 14049-900 Phone.: + 55-16-33154050 E-mail address: [email protected]; [email protected].
2
1
Abstract
2
Medications that improve pain threshold can be useful in the pharmacotherapy of Parkinson’s
3
disease (PD). Pain is a prevalent PD´s non-motor symptom with a higher prevalence of
4
analgesic drugs prescription for patients. However, specific therapy for PD-related pain are
5
not available. Since the endocannabinoid system is expressed extensively in different levels of
6
pain pathway, drugs designed to target this system have promising therapeutic potential in the
7
modulation of pain. Thus, we examined the effects of the 6-hydroxydopamine- induced PD on
8
nociceptive responses of mice and the influence of cannabidiol (CBD) on 6-
9
hydroxydopamine-induced nociception. Further, we investigated the pathway involved in the
10
analgesic effect of the CBD through the co-administration with a fatty acid amide hydrolase
11
(FAAH) inhibitor, increasing the endogenous anandamide levels, and possible targets from
12
anandamide, i.e., the cannabinoid receptors subtype 1 and 2 (CB1 and CB2) and the transient
13
receptor potential vanilloid type 1 (TRPV1). We report that 6-hydroxydopamine- induced
14
parkinsonism decreases the thermal and mechanical nociceptive threshold, whereas CBD
15
(acute and chronic treatment) reduces this hyperalgesia and allodynia evoked by 6-
16
hydroxydopamine. Moreover, ineffective doses of either FAAH inhibitor or TRPV1 receptor
17
antagonist potentialized the CBD- evoked antinociception while an inverse agonist of the CB1
18
and CB2 receptor prevented the antinociceptive effect of the CBD. Altogether, these results
19
indicate that CBD can be a useful drug to prevent the parkinsonism-induced nociceptive
20
threshold reduction. They also suggest that CB1 and TRPV1 receptors are important for
21
CBD-induced analgesia and that CBD could produce these analgesic effects increasing
22
endogenous anandamide levels.
23 24 25 26 27 28
Keywords:
29
Parkinson’s disease; Pain; Transient receptor potential vanilloid type 1.
30
6-hydroxydopamine;
anandamide;
cannabidiol;
cannabinoid
receptors;
3 11. Introduction 2
Besides originally described as a motor disease, Parkinson´s disease (PD) patients
3
suffer from a variety of non-motor symptoms such as sleep disorders, olfactory dysfunctions,
4
anxiety, depression, and pain (Dauer and Przedborski, 2003; Faivre et al., 2019). All these
5
symptoms have a significant impact on their quality of life (Aarsland and Kramberger, 2015;
6
Calabresi et al., 2006; Nègre-Pagès et al., 2008), and usually appear a long time before the
7
first motor signals (Bezard and Fernagut, 2014; Blanchet and Brefel-Courbon, 2018).
8
Around 60% of PD patients are affected by pain (Barone et al., 2009; Faivre et al.,
9
2019; Politis et al., 2010), which can be directly or partly related to the disease. It can appear
10
as nociceptive, neuropathic, or miscellaneous pain (Wasner and Deuschl, 2012). Also,
11
compared to healthy controls, these patients have lower pain threshold and tolerance
12
(Blanchet and Brefel-Courbon, 2018), developing allodynia (Djaldetti et al., 2004;
13
Schestatsky et al., 2007). However, the mechanisms of PD-associated pain are not completely
14
understood, and this problem has not received much attention from preclinical researchers.
15
Decreased nociceptive threshold has been reported in rodent models of PD after 1-
16
methyl-4-phenyl-1,2,4,5-tetrahydropyridine (MPTP) or 6-hydroxydopamine (6-OHDA)-
17
induced dopaminergic degeneration (Gómez-Paz et al., 2018; Nascimento et al., 2018;
18
Zengin-Toktas et al., 2013). These findings suggest that the loss of dopamine (DA) in the
19
basal ganglia may be involved in the reduced pain threshold (Wasner and Deuschl, 2012).
20
The degeneration of the nigrostriatal pathway impairs the dopamine-mediated
21
descending pathways, resulting in hyperalgesia (Fil et al., 2013). In this way, Magnusson and
22
Fisher (2000) showed that systemic administration of DA agonists induced hypoalgesia by
23
modulating D2 receptors in the dorsolateral striatum (Magnusson and Fisher, 2000).
24
Furthermore, some studies have pointed out to an increase in the pain threshold after
25
administration of the dopaminergic medication such as levodopa (Brefel-Courbon et al., 2005;
26
Gerdelat-Mas et al., 2007). However, the absence of a total recuperation of these symptoms
27
with dopaminergic therapy suggests that non-dopaminergic mechanisms could also be
28
involved in the appearance or maintenance of pain symptoms (Brefel-Courbon et al., 2005).
29
Despite the higher prevalence of analgesic drugs prescription for PD patients (33%)
30
than for general population (20%), pain is often neglected and insufficiently treated in these
31
patients (Broetz et al., 2007; Blanchet and Brefel-Courbon, 2018). In addition, analgesic drugs
32
frequently cause side effects such as opiate-induced constipation that in turn may exacerbate
33
constipation developed by parkinsonian patients in early stages of the disease (Stocchi and
4 1
Torti, 2017). Therefore, even though the well-established correlation between pain and PD,
2
still there is no specific therapy for the Parkinson's disease-related pain, thus requiring further
3
efforts in investigating effective drugs, with fewer side effects, for pain in this
4
neurodegenerative condition (Seppi et al., 2019).
5
The endocannabinoid system could be a promising target for the treatment of PD-
6
associated pain. This system has now been recognized as presenting great therapeutic
7
potential in the modulation of pain (Guindon and Hohmann, 2009), besides having a
8
neuroprotective effect on neurodegenerative diseases (Chagas et al., 2014). Cannabidiol
9
(CBD) is the principal non-intoxicating phytocannabinoid constituent of the Cannabis sativa
10
plant (Shohami et al., 2011; Russo, 2017). CBD has low affinity for both cannabinoid subtype
11
1 (CB1) and 2 (CB2) receptors (Ligresti et al., 2016), but it can upregulate the levels of the
12
endocannabinoid anandamide (AEA) by inactivation of the Fatty Acid Amide Hydrolase
13
(FAAH) (Campos et al., 2010), the enzyme responsible for anandamide degradation.
14
Besides AEA effects in cannabinoid receptors, AEA is also an agonist of the transient
15
receptor potential vanilloid type 1 (TRPV1) (Campos et al., 2010; dos-Santos- Pereira et al.,
16
2016; Zygmunt et al., 2000). TRPV1 is a channel activated by multiple painful stimuli
17
including noxious heat, pungent chemicals (capsaicin and jellyfish venom), and protons
18
(Kaneko and Szallasi, 2014; Szallasi et al., 2007). Accumulated compelling data have
19
demonstrated the role of TRPV1 in inflammatory and neuropathic pain states (Moran and
20
Szallasi, 2018; Stocchi and Torti, 2017). For instance, TRPV1 activation in nociceptive
21
neurons triggers the release of neuropeptides and transmitters, resulting in perceived pain
22
(Jara-Oseguera et al., 2010).
23
Therefore, CBD may represent a useful pharmacological alternative in the treatment of
24
PD-related pain. Here, we tested the hypothesis that CBD has an antinociceptive effect in a
25
preclinical model of 6-OHDA-induced parkinsonism in mice via FAAH inhibition and
26
indirect activation of the CB1 receptor.
27 282. Materials and Methods
Ethical statement: Male adult C57⁄BL6 mice (FMRP-USP, Ribeirão Preto, Brazil;
29
2.1.
30
20– 25g body weight) were used in this study. All animal experimental procedures were
31
approved by the local Animal Care and Use Committee of the University of São Paulo/Brazil
32
at the Ribeirao Preto campus (Protocol number # 2017.1.369.58.4) and are in accordance with
33
the Guide for the Care and Use of Laboratory Animals of the National Council for the Control
5 1
of Animal Experimentation (CONCEA).
2
2.2.
3
groups of three animals per cage in a controlled environment under a light-dark cycle of
4
12 hours (lights on at 06:00 and off at 18:00h), in a quiet room with controlled temperature
5
(23 ºC ± 1 ºC). All animals had free access to food and water. Animal care, including the
6
manual recording of body weight, observation of food and water intake, and cage changes that
7
occurred daily during the middle of the light cycle. Mice were left undisturbed during their
8
dark cycle.
Experimental animals - Housing and husbandry: C57⁄BL6 mice were housed in
9 10
2.3.
Pharmacological treatments: The following drugs, at doses based on the literature,
11
were used: cannabidiol (CBD, 10, 30 and 100 mg/kg (McPartland et al., 2015)), morphine
12
(MOR, 10 mg/kg (Aksu et al., 2018)), celecoxib (CXB, non-steroidal anti-inflammatory, 20
13
mg/kg, (Zhao et al., 2017)), URB597 (URB, FAAH inhibitor, 0.5 mg/kg, (Campos et al.,
14
2013)), AM251 (AM, CB1 antagonist, 1 mg/kg, (Campos et al., 2013)), Capsazepine (CPZ,
15
TRPV1 antagonist, 5 mg/kg, (dos-Santos-Pereira et al., 2016)) and SCH 336 (SCH, CB2
16
inverse agonist, 2mg/kg, (Lunn et al, 2006). All drugs were administered intraperitoneally.
17 18
2.4.
Sample size: The total number of mice used in this work was 49. All mice were tested
19
in the nociception tests before and after 6-OHDA lesion for determination of hyperalgesia and
20
allodynia time-course (first experimental protocol). Then, they were randomly distributed to
21
vehicle (VEH, n=6), CXB (n=6), MOR (n=6), CBD (n=7 per each dose) groups for the
22
second experimental protocol. After a 3-day drug washout, these mice were randomly
23
redistributed to the following groups: VEH (n=9), URB (n=10), AM (n=10), CPZ (n=10) and
24
SCH (n=10) treatments. Finally, one-week drug washout was performed, and 32 mice were
25
randomly distributed to VEH (n=7), CBD (n=8), CBD+URB (n=8), CBD+AM (n=8),
26
CBD+CPZ (n=8) or CBD+SCH (n=8) groups. In all cases, the animals were re-tested in the
27
nociception tests to ensure drug washout.
28 29
2.5.
30
experimental protocols:
31 32
Drug treatment and experimental design: This work was compounded by four
(1)
First, nociceptive tests were performed before the 6-OHDA lesion (-1 day) and
after 7, 14, and 21 days of the surgery.
6
(2)
1
After 21 days of the surgery, these mice were distributed into VEH, CXB,
2
MOR and CBD10, CBD30 and CBD100 mg/kg for the second experimental protocol. This
3
protocol consisted in evaluating CBD effects on hyperalgesia (by Hot Plate and Tail Flick
4
tests) and allodynia (Acetone Drop and Von Frey tests) responses compared to effects of
5
celecoxib, morphine and saline administration in mice with established motor impairment
6
(Data not shown).
7
(3)
After 3-day of drug washout, we tested the antinociceptive effects of chronic
8
treatment of CBD. Mice received CBD (10 mg/kg) for 14 days, once a day, and then were
9
tested for nociceptive behaviors 60 minutes after the last administration. (4)
10
After 3-day of drug washout, we tested different doses of URB, AM, CPZ and
11
SCH to find ineffective doses of these drugs on hyperalgesia and allodynia responses in
12
parkinsonian mice. These ineffective doses were used in the fourth protocol. (5)
13
Finally, after one week of drug washout, we test the involvement of FAAH,
14
CB1, CB2 and TRPV1 in the antinociceptive effect of the CBD in parkinsonian mice. A pre-
15
treatment with URB, AM, CPZ or SCH was made 30 min before CBD administration (30
16
mg/kg – the least effective dose according to our results). Hyperalgesia and allodynia tests
17
were performed 30 min after CBD administration.
18
After each protocol and drug washout, animals were re-subjected to nociception tests
19
to ensure drug washout (data not shown) and afterward regrouped randomly for performing
20
the following protocol.
21 22
2.6.
Experimental Procedures: All tests were performed at the light phase, in the
23
morning period (8:00-12:00) and at the same place (in the same laboratory). The same trained
24
person performed all the nociception tests. The information about the treatments was withheld
25
from experimenters that performed the hyperalgesia and allodynia tests to reduce bias, thus
26
characterizing a blinded-experiment.
27
2.6.1.
28
on a previous study (dos-Santos-Pereira et al., 2016). 6-Hydroxydopamine (6- OHDA; 2,4,5-
29
Trihydroxyphenethylamine hydrochloride; 2.5 ug/ul diluted in saline 0.9% containing 0.02%
30
ascorbic acid) obtained from Sigma-Aldrich, USA, was used. Third-two animals were
31
anesthetized with 2,2,2- tribromoethanol (250 mg/kg i.p.) and fixed in the stereotaxic
32
apparatus for performing the surgery (David Kopf, model USA, 9:57). Stereotaxic
33
coordinates of the dorsolateral region of striatum were (in mm from Bregma): anteroposterior
6-Hydroxydopamine-lesioned mice model: The 6-OHDA-induced lesion was based
7 1
(AP) = +0.5; lateral-lateral (LL) = -2.3 and dorsoventral (DV) = −3.9 and −3.0 (Paxinos and
2
Franklin, 2001). 6-OHDA-HCl was microinjected in a total volume of 2 µl/injection (2
3
injection places; 1 µL/min). After the microinjection, the cannula was left in place for five
4
additional minutes to prevent reflux of the injected solution. At the end of the surgical
5
procedure, the animals were kept warm by a 60W light bulb until full recovery from
6
anesthesia and then led to the vivarium, where they received amoxicillin (5 mg/ml orally) for
7
three days.
8
2.6.2.
9
inches tall) for 2 min, and the number of times they touch the cylinder wall with the right, left,
10
or both forepaws following rearing was recorded (Schallert et al., 2000). The asymmetry
11
score was calculated as the sum of left (unaffected) forepaw touches + 1/2 bilateral
12
touches/total number of forepaw touches (right + left + bilateral). For the mice that use both
13
forepaws equally, the score would be 0.5. For mice with the complete asymmetry of forepaw
14
use due to severe dopamine depletion affecting the right forepaw, the asymmetry score would
15
be 1 (Data not shown).
16
2.6.3.
17
following sequence: Von Frey, Acetone Drop, Tail Flick, and Hot Plate. This sequence was
18
based on previous studies from our group (do Nascimento and Leite-Panissi, 2014;
19
Nascimento et al., 2018). Specifically, the hot plate test was designed to evaluate the
20
supraspinally-integrated responses (Caggiula et al., 1995; Rubinstein et al., 2002), and it
21
determines changes in latency as an indicator of modifications of the supraspinal pain process.
22
In turn, the tail-flick latency is mediated by a spino-bulbo-spinal circuit (Le Bars et al., 2001),
23
as well as acetone – cold test, which is compared with the tail-flick test, but it uses the paw
24
withdrawal as parameter, avoiding the use of the tail that is an important organ related to
25
thermoregulation. In addition, different effects could be found with mechanical von Frey
26
filament, an important instrument to access the mechanisms of cutaneous stimulation-induced
27
sensory input (Pitcher et al., 1999).
28
2.6.3.1. Hot Plate: Thermal hyperalgesia was assessed with the hot plate test as previously
29
described (Fujii et al., 2019). Mice were placed in a 10-cm wide glass cylinder in a hot plate
30
apparatus (Insight, Wembley, UK) at 55±0.3 °C. The end-point (latency) was characterized
31
by the removal of the paw, followed by clear paw flinching or licking movements. A cut-off
32
of 30 s was established to prevent tissue damage (Kinsey et al., 2011). The latency of the flick
Cylinder test: Animals were placed in a clear plastic cylinder (3.8 inches wide, 6
Nociceptive Behaviors: The nociceptive tests were performed according to the
8 1
response was measured in seconds, and each animal was tested three times with 60 seconds
2
between each trial. The scores were averaged over the 3 trials for the final score of each
3
animal.
4
2.6.3.2.
5
flick test as described previously (Nascimento et al., 2018). Mice were placed at the apparatus
6
where a thermal stimulus was applied to the tail. We measured the latency for tail withdrawal
7
as an indication of the pain threshold. A cutoff time of 9-s was used to prevent tissue damage.
8
The latency of flick response was measured in seconds, and each animal was tested three
9
times, with 60 seconds between each trial. These scores were averaged over the 3 trials for the
10
final animal score. To avoid novelty stress- induced analgesia, animals were acclimated to the
11
test situation two days before the experiment by restraining the mouse in the same apparatus,
12
but without the thermal stimulus.
13
2.6.3.3.
14
as described previously (Brenner et al., 2014). Mice were acclimated for 5 min on a wire
15
mesh. Then, we sprayed acetone (100 µL) onto the plantar surface of the hind paw, without
16
touching the skin. The first 10 seconds of activity were disregarded as a response to the direct
17
application of the droplet. We measured the flinches in response to skin cooling induced by
18
acetone using the following scores: 0- none; 1- rapid withdrawal or abrupt movement of the
19
paw; 2- prolonged withdrawal or repeated movements of the paw; 3- repeated movements
20
followed by licking of the paw.
21
2.6.3.4.
22
force required to elicit a behavioral response, such as the withdrawal of a paw from the
23
applied stimulus (Chaplan et al., 1994; Nascimento et al., 2018, 2013). Employing von Frey
24
filaments (Nylon monofilaments - 0.35 mm diameter, Scientific Anglers™ Full Sinking Fly
25
Fishing Line) from 0.01 to 15.1 g, we first characterized the percent response at each stimulus
26
intensity (calibration). In the experimental day, the mice were placed individually in a cage
27
(10 X 20 X 15 cm) with a meshed metal wire floor (squares of 5 X 5 mm). Mice were
28
successively stimulated starting with the weakest to the strongest filaments (0.05 to 4 g). The
29
sequence of stimuli stopped when the animal reacted with immediate flinching or licking of
30
the hind paw. The force of the last used filament was considered the pain threshold.
31
Tail Flick: The spinally mediated thermal hyperalgesia was assessed by the tail-
Acetone Drop Test: Cold allodynia was assessed by the modified acetone drop test
Von Frey test: Mechanosensitivity can be determined as the threshold amount of
9 1
2.7.
Euthanasia and Tissue Processing: At the end of the behavioral analysis, the animals
2
were deeply anesthetized with urethane (1.5 g/kg, Sigma-Aldrich, St. Louis, MO, USA) and
3
rapidly perfused transcardially with cold 0.9% saline solution containing heparin (200 µl of
4
heparin 25,000 UI/l of solution) and sodium nitrite (1 g/l solution). Animals were then
5
immediately perfused with 4% paraformaldehyde (PFA; pH 7.4; Sigma-Aldrich, St. Louis,
6
MO, USA). Brains were immediately removed, post- fixed in 4% paraformaldehyde for 2 h,
7
and cryoprotected in 30% sucrose solution. Brains were quickly frozen in isopentane (−40 °C,
8
Sigma-Aldrich, St. Louis, MO, USA) and stored at −80 °C until histological processing.
9
Coronal sections (25 µm) were processed in a freezing microtome (Leica, model CM1850)
10
throughout the rostrocaudal extent of the striatum and substantia nigra compacta. Striatal
11
sections were obtained from rostral (Bregma: +0.86 mm), medial (Bregma +0.02 mm) and
12
caudal areas (Bregma −0.58 mm). Substantia nigra sections were obtained from rostral
13
(Bregma −2.54 mm), medial (Bregma −3.16 mm) and caudal areas (Bregma −3.80 mm).
14
2.8.
Immunohistochemistry: To verify the extension of 6-OHDA lesion, immunostaining
15
was
then
16
immunohistochemical protocols (Gomes et al., 2008) with specific tyrosine hydroxylase (TH,
17
1:2000; Pel Freez, Arkansas, USA) antibody diluted in 0.1 M phosphate-buffered saline (pH
18
7.4), containing 0.15% Triton X-100. After incubation with the primary (48 h) and secondary
19
(1.5 h) antisera, peroxidase reactions were developed with diaminobenzidine. The slices were
20
mounted on slides and coverslipped for microscope observations. Samples from each
21
experimental group were processed at the same time. Quantitative analyses were then
22
performed in striatum and substantia nigra.
carried
out
in
free-floating
sections
with
standard
avidin–
biotin
23 24
2.9.
25
was evaluated by repeated measures analysis of variance (r-ANOVA), with drug and time as
26
factors. The results are expressed as mean ± S.E.M, and post-hoc analysis was performed with
27
the help of the Bonferroni's test. For the analysis of the nociception tests and
28
immunohistochemistry, comparison between different groups was performed using two-way
29
analysis of variance (ANOVA) followed by the Tukey’s multiple comparisons test. Values are
30
presented as mean ± S.E.M. Statistical significance was set at p<0.05. All statistics in this
31
study were performed using Prism 6, version 6.0d (GraphPad Software, Inc.).
32
Statistical Analysis: The effect on the time course of 6-OHDA-induced nociception
10 1
3.
Results
2
3.1.
Time-course of 6-OHDA-induced hyperalgesia and allodynia responses
3
In the present study, we first confirmed by immunohistochemistry that 6-OHDA
4
induced PD-like lesions (Figure 1A). We used TH-immunoreactivity (TH-ir) to assess the
5
percentage of the striatal area devoid of TH-ir for all mice used in the experiments. On
6
average, 65% of the striatum was denervated. There was a lesion side effect for all striatal
7
analyzed areas (rostral: F2,42 = 3.3; p<0.05; medial: F2,38 = 12.7; p<0.05; caudal: F2,48 = 6.4;
8
p<0.05, data not shown).
9
To rule out that different lesion intensity would interfere with CBD analgesic effects,
10
the cylinder test was performed. The ratio of forelimb placement [(left- right)/(right + left +
11
both)] of the non-treated group did not differ from drug treatment group (F4,42 = 4.2; p>0.05).
12
As expected, there was no interaction “lesion side × drug treatment” (F4,48 = 13.1; p>0.05,
13
Supplementary Data).
14
We used four nociceptive behavioral tests to measure the time-course of thermal and
15
mechanical pain threshold in mice after 6-OHDA-injection. The hot plate test showed a
16
significantly decrease in thermal latency in mice at 14 and 21 days from surgery (F4,48 = 3. 1;
17
p<0.01; Figure 1C) when compared to basal measures. On the other hand, tail flick latency
18
diminished since the first analyzed period (7 – 21 days) after 6- OHDA lesion (F4,48 = 6.4;
19
p<0.05; Figure 1D). Regarding allodynia responses, there was significantly increase in
20
nociception behavior at 14 and 21 days from surgery when compared to basal measures in
21
both tests (acetone drop, F4,48 = 13.3; p<0.05; Figure E; and von Frey, F4,48 = 4.3; p<0.05;
22
Figure F).
23
These results suggest that the mice model of PD induced by unilateral lesion of the
24
striatum displays thermal and mechanical pain hypersensitivity that start at different time
25
points after the 6-OHDA lesion.
26 27
3.2.
Antinociceptive effects of acute CBD on experimental parkinsonism
28
Hyperalgesia response – Twenty-one days after 6-OHDA injection, we tested the
29
antinociceptive effects of CBD. Three different doses (10, 30, 100 mg/kg i.p.) of CBD were
30
administered 60 min previously to the nociceptive tests. CXB, MOR, and CBD (10, 30 and
31
100 mg/kg) increased hot plate response latency (p<0.05; Figure 2A) when compared to VEH
32
group. Morphine (MOR) also significantly increased this latency when compared to CXB and
33
the three doses of CBD (F3,48 = 5.31 p<0.01; Figure 2A). In addition, the highest dose of CBD
11 1
(100 mg/kg) induced antinociceptive effects in the hot plate test comparing to the other two
2
doses (F3,32 = 6.8; p<0.05; Figure 2A). The tail flick latency was measured to evaluate a
3
hyperalgesia response under spinal control. The results indicated that celecoxib (CXB),
4
morphine (MOR) and the three doses of CBD significantly reduced this thermal hyperalgesia
5
when compared to VEH group (F3,48 = 17.3; p<0.05; Figure 2B). The highest dose of CBD
6
(100 mg/kg) was the most effective in increasing tail flick latency.
7
Allodynia response – There was no change in the withdrawal latency to cold stimulus
8
in the VEH, CXB, and CBD (30 mg/kg) mice groups (p>0.05; Figure 2C). MOR and the
9
doses of 10 and 100 mg/kg of CBD significantly increased this latency (F4,48 = 26.1 p<0.01;
10
Figure 2C). CBD and MOR presented similar antinociceptive effects in this test (p>0.05;
11
Figure 2C). Antinociceptive effects in mechanical allodynia measured by Von Frey method
12
were observed after CXB, MOR and CBD (10 and 100 mg/kg) administration when compared
13
to CBD at 30 mg/kg (F3,32 = 26.2; p<0.05; Figure 2D).
14 15
3.3.
We also tested the antinociceptive effects of chronic treatment with CBD. Mice
16 17
Antinociceptive effects of chronic CBD on experimental parkinsonism
received CBD (10 mg/kg i.p.) either in one single dose or daily dose for 14 days.
18
Hyperalgesia response – Both acute and chronic CBD increased hot plate response
19
latency (p<0.01) when compared to VEH group. The chronic CBD had significantly higher
20
antinociceptive effect compared to acute dose of CBD (F 2,19 = 96.22; p<0.01; Figure 3A). In
21
tail flick, both acute and chronic CBD treatments significantly reduced this thermal
22
hyperalgesia when compared to VEH group (F
23
differences were found between acute and chronic CBD (p>0.05).
2,19
= 14.26; p<0.01; Figure 3B). No
24
Allodynia response – The withdrawal latency for cold stimulus were increased in mice
25
that receive CBD, compared to VEH group (F 2,19 = 8.881; p<0.01; Figure 3C). Similar effects
26
were found between acute and chronic treatment of CBD (p>0.05). The evaluation of
27
mechanical allodynia showed similar antinociceptive effects of both acute and chronic CBD
28
when compared to VEH (F 2,19 =14.06; p<0.05; Figure 3D).
29 30
3.4.
Antinociceptive effects of URB, AM251, Capsazepine and SCH 336 on
31
experimental parkinsonism
32
The progression in understanding the pain pathways have helped in discovering
33
several new pharmacological targets to treat pain: TRPV1 and the cannabinoid receptors
12 1
along with their endogenous agonists (endocannabinoids) are some of them.
2
Hyperalgesia response – Following three days of CBD washout, we tested the effect
3
of URB, AM251, CPZ and SCH in lesioned-mice using the hot plate and tail flick tests. The
4
drugs were administered 60 min previously to reach the plasmatic peak during the nociceptive
5
tests (Deiana et al., 2012). There were no changes in the hot plate and tail flick responses
6
latency in doses tested of VEH, URB, AM, CPZ and SCH in any of the groups (p>0.05;
7
Figure 4A-B).
8
Allodynia response – URB, AM, CPZ and SCH effects were also tested in allodynia
9
responses. There was no change in the withdrawal latency to a cold stimulus (Figure 4C) nor
10
intensity of mechanical allodynia (Figure 4D) measured by Von Frey method in doses tested
11
of VEH, URB, AM, CPZ and SCH (p>0.05).
12 13
3.5.
Involvement of CB1, CB2 FAAH, and TRPV1 in the antinociceptive effects
14
induced by CBD on experimental parkinsonism
15
To test the hypothesis that CBD could act on 6-OHDA-induced nociception via FAAH
16
inhibition, and modulation of CB1, CB2 and TRPV1 receptors, we administrated CBD
17
(30mg/kg) plus each drug related to the cited targets (URB, AM, CPZ and SCH). The
18
hyperalgesia and allodynia responses were evaluated in mice with experimental parkinsonism.
19
For this, the animals were randomly distributed into the groups after a new 3 days period of
20
drug washout. The nociception tests were repeated before the experiment to ensure drug
21
washout.
22
Hyperalgesia response – Pre-treatment with the FAAH inhibitor (URB) and TRPV1
23
antagonist (CPZ) potentiated the effect induced by CBD (interaction: F2,42= 12.6; p<0.05,
24
two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5A). On the other hand, pre-treatment
25
with the CB1 receptor antagonist AM251 blocked the effects induced by CBD on hot plate
26
response latency (interaction: F2,48= 21.5; p<0.05, two- way ANOVA; p<0.05 vs. VEH and
27
CBD). The CB2 inverse agonist SCH 336 had no influence on antinociceptive effects of CBD
28
(p>0.05; Figure 5A). A similar finding was observed for tail flick latency. Pre-treatment with
29
URB and CPZ potentiated the effect induced by CBD (interaction: F2,42= 20.6; p<0.05, two-
30
way ANOVA; p<0.05 vs. VEH and CBD; Figure 5B), while pre-treatment with AM and SCH
31
blocked the effects induced by CBD on tail flick response latency (interaction: F2,48= 21.5;
32
p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5B).
33
Allodynia response – Administration of URB or CPZ potentiated the antinociceptive
13 1
effect of CBD (30 mg/kg) on withdrawal latency to a cold stimulus (interaction: F2,50= 6.2;
2
p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5C). Distinctly, pre-treatment
3
with both AM and SCH blocked the effects induced by CBD in this test (interaction: F2,48=
4
8.7; p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5C). Ineffective doses on
5
allodynia of the URB or CPZ, when administered with an inefficacious dose of 30 mg/kg of
6
CBD, evoked a synergistic increased in the withdrawal latency to a mechanical stimulus,
7
suggesting similar mechanisms of action of the CBD, URB, and CPZ (interaction: F2,48= 18.1;
8
p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5D). On the other hand, AM
9
and SCH did not change the lack of effect of the CBD in mechanical allodynia response
10
(p>0.05; Figure 5D).
11 12
4.
Discussion
13
The present results showed that: (i) experimental parkinsonism decreases the
14
nociceptive threshold to thermal and mechanical stimulations, (ii) acute or chronic treatment
15
with CBD decreases the hyperalgesia and allodynia in this condition, (iii) the highest CBD
16
dose (100 mg/kg) induces a similar effect to morphine in parkinsonian mice, (iv) the inverse
17
agonist of the CB1 receptor prevents the antinociceptive effect of CBD while ineffective
18
doses of either a FAAH inhibitor or a TRPV1 antagonist increase the CBD antinociceptive
19
effect. Altogether, these results indicate that acute or chronic treatment with CBD can be
20
useful to reduce parkinsonism-increased nociception. They also suggest that CBD induces
21
antinociception increasing endogenous anandamide levels and acting via CB1 and TRPV1
22
receptors, but not via CB2 receptors.
23
Our data showed an antinociceptive effect of the three analyzed doses of CBD in
24
hyperalgesia responses (hot plate and tail flick tests). For allodynia responses, the lower and
25
higher doses of CBD were significantly effective, whereas an intermediate dose did not work.
26
Moreover, in three of the four performed tests (Figure 2B-D), a similar antinociceptive effect
27
between CBD (100mg/kg) and morphine (MOR) was found. CBD was also compared to
28
celecoxib (CXB), a nonsteroidal anti‐inflammatory drug, which was minimally effective
29
against both thermal and mechanical endpoints, which corroborates previous results
30
(Hosseinzadeh et al., 2017). In our animal model, the highest dose of CBD promoted a better
31
antinociceptive effect than CXB.
32
Hypernociception found in 6-OHDA lesioned animals are in line with several other
33
studies in the field (Charles et al., 2018; Gee et al., 2015; Kaszuba et al., 2017; Zengin-Toktas
34
et al., 2013). Hyperalgesia and allodynia can be mediated by central sensitization at distinct
14 1
central nervous system levels. At note, Charles and colleagues described a hyperexcitability
2
of neurons from lamina V of the spinal cord in 6-OHDA-induced parkinsonism (Charles et
3
al., 2018). The dorsal horn of the spinal cord is the first relay for nociceptive inputs from the
4
periphery. Our data evidence decrease in nociceptive threshold in the first days after the 6-
5
OHDA lesion when tail flick test was performed. Importantly, the tail flick use a noxious heat
6
stimulation of the tail that produces a spinally mediated flexion reflex (Bannon and
7
Malmberg, 2007). In contrast, in the hot-plate test, the final response involves not only spinal,
8
but also supraspinal pathways.
9
Dennis and Melzack first described an essential role for the dopamine system in
10
mediating antinociception (Dennis and Melzack, 1983). Basal ganglia, limbic areas, thalamus,
11
periaqueductal gray matter (PAG), and other brain areas modulated by the dopaminergic
12
system play a critical role in the processing of pain (Chudler and Dong, 1995; Hagelberg et
13
al., 2002). The dopaminergic circuitry could also directly influence nociceptive behavior
14
acting in the dorsal horn of spinal cord through hypothalamic A11 projections to spinal D2
15
receptors (Kim and Abdi, 2014; Taniguchi et al., 2011). Recent findings have shown a
16
dysregulation of GABAergic neurotransmission in the PAG ventrolateral (the major
17
component of the descending inhibitory pain pathway) induced by 6-OHDA nigrostriatal
18
lesions, suggesting an impairment of descending analgesic system and stimulation of the
19
descending pain facilitatory system (Domenici et al., 2019). This unbalance promotes
20
downregulation of the spinal opioidergic modulation and, consequently, leads to a nociceptive
21
sensitization. Based on these findings, we speculate that dysfunctions in limbic areas and at
22
the spinal level could be responsible for the decreased nociceptive threshold observed in the
23
6-OHDA-induced PD model in the present work.
24
In patients, decreased function of the nigrostriatal pathway is associated with pain,
25
(Hagelberg et al., 2004) while persistent and chronic pain reduces intracranial self-stimulation
26
of the medial forebrain bundle (Leitl et al., 2014; Pereira Do Carmo et al., 2009). Since these
27
pieces of evidence indicate that chronic pain leads to a significant impairment of dopamine
28
activity (Chudler and Dong, 1995; Magnusson and Fisher, 2000; Taylor et al., 2016; Wood,
29
2008), the loss of dopaminergic nigrostriatal activation after injection of 6-OHDA into the
30
striatum can directly contribute to the decreased nociceptive threshold observed in the current
31
work.
32
The involvement of the endocannabinoid system in dopamine signaling within reward
33
circuits affected by chronic pain is few explored (Mlost et al., 2019). Despite the
34
antinociceptive potential of cannabinoids (Jensen et al., 2015), CBD effect on nociception
15 1
induced by striatal lesions in mice has never been investigated. Our results show that a CB1
2
receptor antagonist blunted CBD-induced antinociception while a CB2 receptor antagonist did
3
not affect CBD response, suggesting that CB1 receptors play an important role in CBD
4
antinociception. Although CBD has a low affinity for cannabinoid receptors, CBD can act
5
directly, at micromolar concentrations, as a partial agonist of CB1 and CB2 receptors
6
(McPartland et al., 2015; Pertwee, 2008a). CB2 receptors are mainly expressed in cells of the
7
immune system (Cabral and Griffin-Thomas, 2009) and mediated many anti-inflammatory
8
properties of cannabinoids (Turcotte et al., 2016), and albeit celecoxib has produced
9
antinociception in our experimental model of PD, CB2 receptors are unlikely to mediate CBD
10
effects in our studysince the selective CB2 antagonist did not change the CBD
11
antinociception.
12
Conversely, a TRPV1 antagonist and a FAAH inhibitor increased the CBD-induced
13
analgesia, suggesting that the TRPV1 have a different role from CB1 increasing nociception
14
and that CBD actions might be depending on AEA. CBD can inhibit FAAH, increasing
15
endogenous AEA concentration (Leweke et al., 2012; McPartland et al., 2015). AEA is an
16
agonist of both CB1 and TRPV1 receptors (Di Marzo and De Petrocellis, 2012), as well as
17
can bind to CB2 receptor, but with less efficacy, behaving like a CB2 antagonist in some in
18
vitro bioassays (McPartland et al., 2015; Pertwee, 2008b). CB1 and TRPV1 have a distinct
19
mechanism of action: CB1 is a metabotropic receptor coupled to a Gi-protein while TRPV1 is
20
a channel permeable to several cations such as calcium (Di Marzo and De Petrocellis, 2012).
21
Therefore, CBD or AEA can produce opposite effects acting on these receptors (Di Marzo
22
and De Petrocellis, 2012).
23
Although the activation of CB1 receptors exert an anti-nociceptive and TRPV1
24
activation, a pro-nociceptive effect, the anandamide (AEA) has low intrinsic efficacy at
25
TRPV1 as compared to CB1 ((Ross, 2003; Toth et al., 2009; McPartland et al., 2015), and this
26
could explain the preference of the CB1, instead TRPV1, modulation by increased levels of
27
anandamide. In addition, the efficacy of AEA on TRPV1 is influenced by many factors and
28
physiological and pathological states, including the fact that AEA action on CB1 receptors
29
can change the TRPV1-mediated AEA response. In this sense, it is possible to suggest that the
30
smaller dose of CBD increase AEA, by inhibiting the FAAH, evoking a CB1-mediated
31
response while intermediate doses of CBD increase AEA to levels sufficient to activate both
32
CB1 and TRPV1 receptors eliciting lesser CBD-mediated antinociception, thus explaining the
33
U-shaped curve for the CBD in our experimental model. Another work using the FAAH
34
inhibitor URB597 injected into the PAG also found a dual effect for AEA in nociception. A
16 1
low dose of URB597 into the ventrolateral PAG evoked a hyperalgesic effect that was
2
converted to antinociceptive when injected along with the CB1 receptor inverse agonist
3
AM251. However, a TRPV1 antagonist converted the antinociceptive effect of the high dose
4
of URB597 to a hyperalgesic effect (Maione, 2006).
5
In vivo microdialysis showed that intraplantar injection of formalin increase AEA
6
release within the PAG (Walker et al., 2002) while electrical stimulation of dorsal or lateral
7
columns of the PAG evokes CB1-mediated antinociception along with a rise in AEA levels in
8
the PAG (Martin et al., 1999). Moreover, mice lacking FAAH presents increased thermal
9
analgesia and reduced nociceptive behavior in the formalin and carrageenan models (Carey et
10
al., 2016). In the same experimental pain model, intra-spinal injection of AEA also evokes
11
analgesia while CB1 receptor blockade inhibits these AEA effects (Carey et al., 2016). In the
12
same way, the acute administration of URB597 decrease allodynia in a neuropathic pain
13
model, and the pretreatment with a CB1 antagonist blunts this effect (Kinsey et al., 2009).
14
Altogether, these results suggest that AEA has antinociceptive effects acting via CB1
15
receptors in different experimental pain models.
16
The CB1 receptor is present in several brain regions involved in pain processing such
17
as PAG, dorsal root ganglion, superficial laminae of the spinal cord, cortical areas, and
18
amygdala (Di Marzo and De Petrocellis, 2012; Starowicz and Finn, 2017). Administration of
19
WIN55,212-2, a synthetic cannabinoid agonist, into the amygdala increases tail-flick latency
20
in rats, while the pharmacological blockade of CB1 receptors within the basolateral amygdala
21
attenuates the stress-induced analgesia in the same pain mode (Connell et al., 2006). In
22
nonhuman primates, the amygdala is essential to cannabinoid-induced antinociception
23
(Manning et al., 2018), thus suggesting that amygdala may be a target for AEA-induced
24
analgesia after peripheral CBD administration.
25
Amygdala and prefrontal cortex are areas that play a major role in mood disorders
26
(Price and Drevets, 2010), and both are involved in the neurocircuitry of pain (Taylor, 2018;
27
Xiao and Zhang, 2018). Neuroimaging studies show that these areas are affected in PD
28
patients (Chagas et al., 2017; Yoshimura et al., 2005), thus contributing to the increased risk
29
of anxiety and depression in these patients. Mood disorders can promote hypersensitivity to
30
pain (Bushnell et al., 2013; Taylor, 2018), and a study showed a correlation between
31
depression and pain in PD (Rana et al., 2017). Therefore, since several works demonstrate
32
that CBD is useful to treat affective disorders such as depression (Blessing et al., 2015; Crippa
33
et al., 2018; (Campos et al., 2016), the modulation of the emotional component of pain can be
34
part of CBD evoked-antinociception in our experimental model.
17 1
5.
Conclusion
2
In summary, our results suggest that CBD decreases the enhanced nociception of
3
animals with selective loss of dopaminergic nigrostriatal pathway. URB (selective FAAH
4
inhibitor) treatment potentialized the CBD antinociception effect. On the other hand, the
5
blockage of the CB1 receptors with the selective antagonist AM251 inhibited the CBD effect
6
while TRPV1 receptor antagonism increased the antinociception effect of CBD. Altogether,
7
these results suggest that CBD decrease the nociception inhibiting FAAH and consequently
8
increasing AEA. In turns, AEA can bind to CB1 and TRPV1 receptors. These receptors have
9
opposite effects on pain modulation. Thus, AEA binds to CB1 receptors promoting analgesia
10
while decreases the nociception via TRPV1 receptors.
11 12 13 14
Acknowledgments We thank Célia Aparecida da Silva for technical assistance and Mauricio dos Santos
15
Pereira for drug offering.
16
Author contributions
17
G.C.N., D.P.F, M.B. and N.C.F.J. performed experiments. F.S.G. and E.A.D.B.
18
provided feedback on project and participated in writing the manuscript. G.C.N., D.P.F,
19
M.B. and N.C.F.J. designed study, analyzed data, interpreted results, and wrote the
20
manuscript.
21
Financial Support
22 23 24
This study was supported by grants from CNPq, CAPES, and FAPESP. Conflict interests There is no conflict of interests to declare.
25 26 27
References
28
Aarsland, D., Kramberger, M.G., 2015. Neuropsychiatric symptoms in Parkinson’s disease. J.
29
Parkinsons. Dis. https://doi.org/10.3233/JPD-150604
30
Aksu, A.G., Gunduz, O., Ulugol, A., 2018. Contribution of spinal 5-HT 5A receptors to the
31
antinociceptive effects of systemically administered cannabinoid agonist WIN 55,212-
32
2 and morphine. Can. J. Physiol. Pharmacol. https://doi.org/10.1139/cjpp- 2017-0567
33
Bannon, A.W., Malmberg, A.B., 2007. Models of Nociception: Hot-Plate, Tail-Flick, and
18 1
Formalin
Tests
in
Rodents,
in:
Current
2
https://doi.org/10.1002/0471142301.ns0809s41
Protocols
in
Neuroscience.
3
Barone, P., Antonini, A., Colosimo, C., Marconi, R., Morgante, L., Avarello, T.P., Bottacchi,
4
E., Cannas, A., Ceravolo, G., Ceravolo, R., Cicarelli, G., Gaglio, R.M., Giglia, R.M.,
5
Iemolo, F., Manfredi, M., Meco, G., Nicoletti, A., Pederzoli, M., Petrone, A., Pisani,
6
A., Pontieri, F.E., Quatrale, R., Ramat, S., Scala, R., Volpe, G., Zappulla, S.,
7
Bentivoglio, A.R., Stocchi, F., Trianni, G., Del Dotto, P., 2009. The PRIAMO study:
8
A multicenter assessment of nonmotor symptoms and their impact on quality of life in
9
Parkinson’s disease. Mov. Disord. https://doi.org/10.1002/mds.22643
10 11 12
Bezard, E., Fernagut, P.O., 2014. Premotor parkinsonism models. Park. Relat. Disord. https://doi.org/10.1016/S1353-8020(13)70007-5 Blanchet, P.J., Brefel-Courbon, C., 2018. Chronic pain and pain processing in Parkinson’s
13
disease.
14
https://doi.org/10.1016/j.pnpbp.2017.10.010
15
Prog.
Neuro-Psychopharmacology
Biol.
Psychiatry.
Blessing, E.M., Steenkamp, M.M., Manzanares, J., Marmar, C.R., 2015. Cannabidiol as a
16
Potential
Treatment
for
Anxiety
17
https://doi.org/10.1007/s13311-015-0387-1
Disorders.
Neurotherapeutics.
18
Brefel-Courbon, C., Payoux, P., Thalamas, C., Ory, F., Quelven, I., Chollet, F., Montastruc,
19
J.L., Rascol, O., 2005. Effects of levodopa on pain threshold in Parkinson’s disease: A
20
clinical
21
https://doi.org/10.1002/mds.20629
22
and
positron
emission
tomography
study.
Mov.
Disord.
Brenner, D.S., Vogt, S.K., Gereau IV, R.W., 2014. A technique to measure cold adaptation in
23
freely
behaving
mice.
24
https://doi.org/10.1016/j.jneumeth.2014.08.009
J.
Neurosci.
Methods.
25
Broetz, D., Eichner, M., Gasser, T., Weller, M., Steinbach, J.P., 2007. Radicular and
26
nonradicular back pain in Parkinson’s disease: A controlled study. Mov. Disord.
27
https://doi.org/10.1002/mds.21439
28
Bushnell, M.C., Ceko, M., Low, L.A., 2013. Cognitive and emotional control of pain and its
29
disruption in chronic pain. Nat. Rev. Neurosci. https://doi.org/10.1038/nrn3516
30
Cabral, G.A., Griffin-Thomas, L., 2009. Emerging role of the cannabinoid receptor CB2 in
31
immune regulation: therapeutic prospects for neuroinflammation. Expert. Rev. Mol.
19 1 2
Med. https://doi.org/10.1017/S1462399409000957. Caggiula, A.R., Perkins, K.A., Saylor, S., Epstein, L.H., 1995. Different methods of assessing
3
nicotine-induced
antinociception
may
engage
different
neural
4
Psychopharmacology (Berl). https://doi.org/10.1007/BF02246552
mechanisms.
5
Calabresi, P., Picconi, B., Parnetti, L., Di Filippo, M., 2006. A convergent model for
6
cognitive dysfunctions in Parkinson’s disease: the critical dopamine-acetylcholine
7
synaptic balance. Lancet Neurol. https://doi.org/10.1016/S1474-4422(06)70600-7
8
Campos, A.C., Ferreira, F.R., Guimarães, F.S., Lemos, J.I., 2010. Facilitation of
9
endocannabinoid effects in the ventral hippocampus modulates anxiety-like behaviors
10
depending
on
previous
stress
11
https://doi.org/10.1016/j.neuroscience.2010.01.062
experience.
Neuroscience.
12
Campos, A.C., Ortega, Z., Palazuelos, J., Fogaça, M. V., Aguiar, D.C., Díaz-Alonso, J.,
13
Ortega-Gutiérrez, S., Vázquez-Villa, H., Moreira, F.A., Guzmán, M., Galve- Roperh,
14
I., Guimarães, F.S., 2013. The anxiolytic effect of cannabidiol on chronically stressed
15
mice depends on hippocampal neurogenesis: Involvement of the endocannabinoid
16
system. Int. J. Neuropsychopharmacol. https://doi.org/10.1017/S1461145712001502
17
Campos, A.C., Fogaca, M.V., Sonego, A.B., Guimaraes, F.S., 2016. Cannabidiol,
18
neuroprotection
and
neuropsychiatric
19
https://doi.org/10.1016/j.phrs.2016.01.033
disorders.
Pharmacol.
Res.
20
Carey, L.M., Slivicki, R.A., Leishman, E., Cornett, B., Mackie, K., Bradshaw, H., Hohmann,
21
A.G., 2016. A pro-nociceptive phenotype unmasked in mice lacking fatty-acid amide
22
hydrolase. Mol. Pain. https://doi.org/10.1177/1744806916649192
23
Chagas, M.H.N., Zuardi, A.W., Tumas, V., Pena-Pereira, M.A., Sobreira, E.T., Bergamaschi,
24
M.M., Dos Santos, A.C., Teixeira, A.L., Hallak, J.E.C., Crippa, J.A.S., 2014. Effects
25
of cannabidiol in the treatment of patients with Parkinson’s disease: An exploratory
26
double-blind trial. J. Psychopharmacol. https://doi.org/10.1177/0269881114550355
27
Chagas, M.H.N., Tumas, V., Pena-Pereira, M.A., Machado-de-Sousa, J.P., Carlos Dos Santos,
28
A., Sanches, R.F., Hallak, J.E.C., Crippa, J.A.S., 2017. Neuroimaging of major
29
depression in Parkinson's disease: Cortical thickness, cortical and subcortical volume,
30
and
31
https://doi.org/10.1016/j.jpsychires.2017.02.010
spectroscopy
findings.
J.
Psychiatr.
Res.
20 1
Chaplan, S.R., Bach, F.W., Pogrel, J.W., Chung, J.M., Yaksh, T.L., 1994. Quantitative
2
assessment
of
tactile
allodynia
in
the
3
https://doi.org/10.1016/0165-0270(94)90144-9
rat
paw.
J.
Neurosci.
Methods.
4
Charles, K.A., Naudet, F., Bouali-Benazzouz, R., Landry, M., De Deurwaerdère, P., Fossat,
5
P., Benazzouz, A., 2018. Alteration of nociceptive integration in the spinal cord of a
6
rat model of Parkinson’s disease. Mov. Disord. https://doi.org/10.1002/mds.27377
7 8
Chudler, E.H., Dong, W.K., 1995. The role of the basal ganglia in nociception and pain. Pain. https://doi.org/10.1016/0304-3959(94)00172-B
9
Connell, K., Bolton, N., Olsen, D., Piomelli, D., Hohmann, A.G., 2006. Role of the
10
basolateral nucleus of the amygdala in endocannabinoid-mediated stress-induced
11
analgesia. Neurosci. Lett. https://doi.org/10.1016/j.neulet.2005.12.008
12
Crippa, J.A., Guimarães, F.S., Campos, A.C., Zuardi, A.W., 2018. Translational Investigation
13
of the Therapeutic Potential of Cannabidiol (CBD): Toward a New Age. Front.
14
Immunol. https://doi.org/10.3389/fimmu.2018.02009
15
Dauer, W., Przedborski, S., 2003. Parkinson’s disease: mechanisms and models. Neuron.
16
Deiana, S., Watanabe, A., Yamasaki, Y., Amada, N., Arthur, M., Fleming, S., Woodcock, H.,
17
Dorward, P., Pigliacampo, B., Close, S., Platt, B., Riedel, G., 2012. Plasma and brain
18
pharmacokinetic profile of cannabidiol (CBD), cannabidivarine (CBDV), ∆ 9-
19
tetrahydrocannabivarin (THCV) and cannabigerol (CBG) in rats and mice following
20
oral and intraperitoneal administration and CBD action on obsessive-compulsive
21
behav. Psychopharmacology (Berl). https://doi.org/10.1007/s00213-011-2415-0
22
Dennis, S.G., Melzack, R., 1983. Effects of cholinergic and dopaminergic agents on pain and
23
morphine
24
https://doi.org/10.1016/0014-4886(83)90166-8
25
analgesia
measured
by
three
pain
tests.
Exp.
Neurol.
Di Marzo, V., De Petrocellis, L., 2012. Why do cannabinoid receptors have more than one
26
endogenous
ligand?
Philos.
27
https://doi.org/10.1098/rstb.2011.0382
Trans.
R.
Soc.
B
Biol.
Sci.
28
Djaldetti, R., Shifrin, A., Rogowski, Z., Sprecher, E., Melamed, E., Yarnitsky, D., 2004.
29
Quantitative measurement of pain sensation in patients with Parkinson disease.
30
Neurology. https://doi.org/10.1212/01.WNL.0000130455.38550.9D
21 1
do Nascimento, G.C., Leite-Panissi, C.R.A., 2014. Time-dependent analysis of nociception
2
and anxiety-like behavior in rats submitted to persistent inflammation of the
3
temporomandibular joint. Physiol.
4
https://doi.org/10.1016/j.physbeh.2013.11.009
Behav.
5
Domenici, R.A., Campos, A.C.P., Maciel, S.T., Berzuino, M.B., Hernandes, M.S., Fonoff,
6
E.T., Pagano, R.L., 2019. Parkinson’s disease and pain: Modulation of nociceptive
7
circuitry
8
https://doi.org/10.1016/j.expneurol.2019.02.007
in
a
rat
model
of
nigrostriatal
lesion.
Exp.
Neurol.
9
dos-Santos-Pereira, M., da-Silva, C.A., Guimarães, F.S., Del-Bel, E., 2016. Co-
10
administration of cannabidiol and capsazepine reduces L-DOPA-induced dyskinesia in
11
mice:
12
https://doi.org/10.1016/j.nbd.2016.06.013
Possible
mechanism
of
action.
Neurobiol.
Dis.
13
Faivre, F., Joshi, A., Bezard, E., Barrot, M., 2019. The hidden side of Parkinson’s disease:
14
Studying pain, anxiety and depression in animal models. Neurosci. Biobehav. Rev.
15
https://doi.org/10.1016/j.neubiorev.2018.10.004
16
Fil, A., Cano-de-la-Cuerda, R., Muñoz-Hellín, E., Vela, L., Ramiro-González, M., Fernández-
17
de-las-Peñas, C., 2013. Pain in Parkinson disease: A review of the literature. Park.
18
Relat. Disord. https://doi.org/10.1016/j.parkreldis.2012.11.009
19
Fujii, K., Koshidaka, Y., Adachi, M., Takao, K., 2019. Effects of chronic fentanyl
20
administration on behavioral characteristics of mice. Neuropsychopharmacol. Reports.
21
https://doi.org/10.1002/npr2.12040
22
Gee, L.E., Chen, N., Ramirez-Zamora, A., Shin, D.S., Pilitsis, J.G., 2015. The effects of
23
subthalamic deep brain stimulation on mechanical and thermal thresholds in 6OHDA-
24
lesioned rats. Eur. J. Neurosci. https://doi.org/10.1111/ejn.12992
25
Gerdelat-Mas, A., Simonetta-Moreau, M., Thalamas, C., Ory-Magne, F., Slaoui, T., Rascol,
26
O., Brefel-Courbon, C., 2007. Levodopa raises objective pain threshold in Parkinson’s
27
disease:
28
https://doi.org/10.1136/jnnp.2007.120212
A
RIII
reflex
study.
J.
Neurol.
Neurosurg.
Psychiatry.
29
Gomes, M.Z., Raisman-Vozari, R., Del Bel, E.A., 2008. A nitric oxide synthase inhibitor
30
decreases 6-hydroxydopamine effects on tyrosine hydroxylase and neuronal nitric
31
oxide
synthase
in
the
rat
nigrostriatal
pathway.
Brain
Res.
22 1
https://doi.org/10.1016/j.brainres.2008.01.088
2
Gómez-Paz, A., Drucker-Colín, R., Milán-Aldaco, D., Palomero-Rivero, M., Ambriz- Tututi,
3
M., 2018. Intrastriatal Chromospheres’ Transplant Reduces Nociception in
4
Hemiparkinsonian Rats.
5
https://doi.org/10.1016/j.neuroscience.2017.08.052
6 7
Neuroscience.
Guindon, J., Hohmann, A., 2009. The Endocannabinoid System and Pain. CNS Neurol. Disord. - Drug Targets. https://doi.org/10.2174/187152709789824660
8
Hagelberg, N., Jääskeläinen, S.K., Martikainen, I.K., Mansikka, H., Forssell, H., Scheinin, H.,
9
Hietala, J., Pertovaara, A., 2004. Striatal dopamine D2 receptors in modulation of pain
10
in humans: A review. Eur. J. Pharmacol. https://doi.org/10.1016/j.ejphar.2004.07.024
11
Hagelberg, N., Martikainen, I.K., Mansikka, H., Hinkka, S., Någren, K., Hietala, J., Scheinin,
12
H., Pertovaara, A., 2002. Dopamine D2 receptor binding in the human brain is
13
associated with the response to painful stimulation and pain modulatory capacity.
14
Pain. https://doi.org/10.1016/S0304-3959(02)00121-5
15
Hosseinzadeh, H., Mazaheri, F., Ghodsi, R., 2017. Pharmacological effects of a synthetic
16
quinoline, a hybrid of tomoxiprole and naproxen, against acute pain and inflammation
17
in
18
https://doi.org/10.22038/ijbms.2017.8588
19 20
mice:
a
behavioral
and
docking
study.
Iran.
J.
Basic
Med.
Sci.
Jara-Oseguera, A., Simon, S., Rosenbaum, T., 2010. TRPV1: On the Road to Pain Relief. Curr. Mol. Pharmacol. https://doi.org/10.2174/1874467210801030255
21
Jensen, B., Chen, J., Furnish, T., Wallace, M., 2015. Medical Marijuana and Chronic Pain: a
22
Review of Basic Science and Clinical Evidence. Curr. Pain Headache Rep.
23
https://doi.org/10.1007/s11916-015-0524-x
24 25 26
Kaneko, Y., Szallasi, A., 2014. Transient receptor potential (TRP) channels: A clinical perspective. Br. J. Pharmacol. https://doi.org/10.1111/bph.12414 Kaszuba, B.C., Walling, I., Gee, L.E., Shin, D.S., Pilitsis, J.G., 2017. Effects of subthalamic
27
deep brain stimulation with duloxetine on mechanical and thermal thresholds
28
6OHDA
29
https://doi.org/10.1016/j.brainres.2016.10.025
30
lesioned
rats.
in
Brain Res.
Kim, K.H., Abdi, S., 2014. Rediscovery of nefopam for the treatment of neuropathic pain.
23 1
Korean J. Pain. https://doi.org/10.3344/kjp.2014.27.2.103
2
Kinsey, S.G., Long, J.Z., O’Neal, S.T., Abdullah, R.A., Poklis, J.L., Boger, D.L., Cravatt,
3
B.F., Lichtman, A.H., 2009. Blockade of Endocannabinoid-Degrading Enzymes
4
Attenuates
5
https://doi.org/10.1124/jpet.109.155465
Neuropathic
Pain.
J.
Pharmacol.
Exp.
Ther.
6
Kinsey, S.G., Naidu, P.S., Cravatt, B.F., Dudley, D.T., Lichtman, A.H., 2011. Fatty acid
7
amide hydrolase blockade attenuates the development of collagen-induced arthritis
8
and
9
https://doi.org/10.1016/j.pbb.2011.06.022
10 11
related
thermal
hyperalgesia
in
mice.
Pharmacol.
Biochem.
Behav.
Le Bars, D., Gozariu, M., Cadden, S.W., 2001. Animal models of nociception. Pharmacol. Rev.
12
Leitl, M.D., Potter, D.N., Cheng, K., Rice, K.C., Carlezon, W.A., Negus, S.S., 2014.
13
Sustained pain-related depression of behavior: Effects of intraplantar formalin and
14
complete freund’s adjuvant on intracranial self-stimulation (ICSS) and endogenous
15
kappa opioid biomarkers in rats. Mol. Pain. https://doi.org/10.1186/1744-8069-10- 62
16
Leweke, F.M., Piomelli, D., Pahlisch, F., Muhl, D., Gerth, C.W., Hoyer, C., Klosterkötter, J.,
17
Hellmich, M., Koethe, D., 2012. Cannabidiol enhances anandamide signaling and
18
alleviates
19
https://doi.org/10.1038/tp.2012.15
psychotic
symptoms
of
schizophrenia.
Transl.
Psychiatry.
20
Ligresti, A., De Petrocellis, L., Di Marzo, V., 2016. From Phytocannabinoids to Cannabinoid
21
Receptors and Endocannabinoids: Pleiotropic Physiological and Pathological Roles
22
Through
23
https://doi.org/10.1152/physrev.00002.2016
Complex
Pharmacology.
Physiol.
Rev.
24
Lunn, C. A., Fine, J. S., Rojas-Triana, A., Jackson, J. V., Fan, X., Kung, T. T., ... & Narula, S.
25
K., 2006. A novel cannabinoid peripheral cannabinoid receptor-selective inverse
26
agonist blocks leukocyte recruitment in vivo. Journal of Pharmacology and
27
Experimental Therapeutics. https://doi:10.1124/jpet.105.093500.
28
Magnusson, J.E., Fisher, K., 2000. The involvement of dopamine in nociception: The role of
29
D1
30
https://doi.org/10.1016/S0006-8993(99)02396-3
31
and
D2
receptors
in
the
dorsolateral
striatum.
Brain
Res.
Maione, S., 2006. Elevation of Endocannabinoid Levels in the Ventrolateral Periaqueductal
24 1
Grey through Inhibition of Fatty Acid Amide Hydrolase Affects Descending
2
Nociceptive Pathways via Both Cannabinoid Receptor Type 1 and Transient Receptor
3
Potential
4
https://doi.org/10.1124/jpet.105.093286
Vanilloid
Type-1
Re.
J.
Pharmacol.
Exp.
Ther.
5
Manning, B.H., Merin, N.M., Meng, I.D., Amaral, D.G., 2018. Reduction in Opioid- and
6
Cannabinoid-Induced Antinociception in Rhesus Monkeys after Bilateral Lesions of
7
the Amygdaloid Complex. J. Neurosci. https://doi.org/10.1523/jneurosci.21-20-
8
08238.2001
9
Martin, W.J., Coffin, P.O., Attias, E., Balinsky, M., Tsou, K., Michael Walker, J., 1999.
10
Anatomical basis for cannabinoid-induced antinociception as revealed by intracerebral
11
microinjections. Brain Res. https://doi.org/10.1016/S0006- 8993(98)01368-7
12
McPartland, J.M., Duncan, M., Di Marzo, V., Pertwee, R.G., 2015. Are cannabidiol and ∆9-
13
tetrahydrocannabivarin negative modulators of the endocannabinoid system? A
14
systematic review. Br. J. Pharmacol. https://doi.org/10.1111/bph.12944
15
Mlost, J., Wąsik, A., Starowicz, K., 2019. Role of endocannabinoid system in dopamine
16
signalling within the reward circuits affected by chronic pain. Pharmacol. Res.
17
https://doi.org/10.1016/j.phrs.2019.02.029
18
Moran, M.M., Szallasi, A., 2018. Targeting nociceptive transient receptor potential channels
19
to
treat
chronic
pain:
current
20
https://doi.org/10.1111/bph.14044
state
of
the
field.
Br.
J.
Pharmacol.
21
Nascimento, G.C., Bariotto-dos-Santos, K., Leite-Panissi, C.R.A., Del-Bel, E.A., Bortolanza,
22
M., 2018. Nociceptive Response to l-DOPA-Induced Dyskinesia in Hemiparkinsonian
23
Rats. Neurotox. Res. https://doi.org/10.1007/s12640-018-9896- 0
24
Nascimento, G.C., Rizzi, E., Gerlach, R.F., Leite-Panissi, C.R.A., 2013. Expression of MMP-
25
2 and MMP-9 in the rat trigeminal ganglion during the development of
26
temporomandibular
27
https://doi.org/10.1590/1414-431X20133138
joint
inflammation.
Brazilian
J.
Med.
Biol.
Res.
28
Nègre-Pagès, L., Regragui, W., Bouhassira, D., Grandjean, H., Rascol, O., 2008. Chronic pain
29
in Parkinson’s disease: The cross-sectional French DoPaMiP survey. Mov. Disord.
30
https://doi.org/10.1002/mds.22142
31
Paxinos, G., Franklin, K.B.J., 2001. Mouse brain in stereotaxic coordinates, Academic Press.
25
https://doi.org/10.1016/S0306-4530(03)00088-X
1 2
Pereira Do Carmo, G., Stevenson, G.W., Carlezon, W.A., Negus, S.S., 2009. Effects of pain-
3
and analgesia-related manipulations on intracranial self-stimulation in rats: Further
4
studies on
5
https://doi.org/10.1016/j.pain.2009.04.010
6
pain-depressed
behavior.
Pain.
Pertwee, R.G., 2008a. The diverse CB1 and CB2 receptor pharmacology of three plant
7
cannabinoids:
8
tetrahydrocannabivarin. Br. J. Pharmacol. https://doi.org/10.1038/sj.bjp.0707442.
9
delta9-tetrahydrocannabinol,
anandamide
11
1600.2008.00108.x
and
neuropathic,
14
3959(99)00085-8
beyond.
Addict.
surgical
and
central
disease
17
https://doi.org/10.1002/mds.23135
19 20
Biol.
https://doi.org/10.1111/j.1369-
pain.
Pain.
https://doi.org/10.1016/S0304-
Politis, M., Wu, K., Molloy, S., Bain, P.G., Chaudhuri, K.R., Piccini, P., 2010. Parkinson’s
16
18
delta9-
Pitcher, G.M., Ritchie, J., Henry, J.L., 1999. Nerve constriction in the rat: Model of
13
15
and
Pertwee, R.G., 2008b. Ligands that target cannabinoid receptors in the brain: from THC to
10
12
cannabidiol
Price,
J.L.,
symptoms:
Drevets,
The
W.C.,
patient’s
2010.
perspective.
Neurocircuitry
of
Mov.
mood
Disord.
disorders.
Neuropsychopharmacology. https://doi.org/10.1038/npp.2009.104 Rácz, I., Nent, E., Erxlebe, E., Zimmer, A., 2015. CB1 receptors modulate affective behaviour
21
induced
by
neuropathic
pain.
22
https://doi.org/10.1016/j.brainresbull.2015.03.005
Brain
Res.
Bull.
23
Rana, A.Q., Qureshi, A.R.M., Rehman, N., Mohammed, A., Sarfraz, Z., Rana, R., 2017.
24
Disability from pain directly correlated with depression in Parkinson’s disease. Clin.
25
Neurol. Neurosurg. https://doi.org/10.1016/j.clineuro.2017.05.022
26 27
Ross, R.A., 2003. Anandamide and vanilloid TRPV1 receptors. British journal of pharmacology. https://doi.org/10.1038/sj.bjp.0705467
28
Rubinstein, M., Mogil, J.S., Japon, M., Chan, E.C., Allen, R.G., Low, M.J., 2002. Absence of
29
opioid stress-induced analgesia in mice lacking beta-endorphin by site- directed
30
mutagenesis. Proc. Natl. Acad. Sci. https://doi.org/10.1073/pnas.93.9.3995
26 1
Russo, E.B., 2017. Cannabidiol Claims and Misconceptions: (Trends in Pharmacological
2
Sciences
38,
198-201;
2017).
3
https://doi.org/10.1016/j.tips.2016.12.004
Trends
Pharmacol.
Sci.
4
Schestatsky, P., Kumru, H., Valls-Solé, J., Valldeoriola, F., Marti, M.J., Tolosa, E., Chaves,
5
M.L., 2007. Neurophysiologic study of central pain in patients with Parkinson disease.
6
Neurology.https://doi.org/10.1212/01.wnl.0000295669.12443.d3
7
Seppi, K., Ray Chaudhuri, K., Coelho, M., Fox, S.H., Katzenschlager, R., Perez Lloret, S.,
8
Weintraub, D., Sampaio, C., Chahine, L., Hametner, E.M., Heim, B., Lim, S.Y.,
9
Poewe, W., Djamshidian-Tehrani, A., 2019. Update on treatments for nonmotor
10
symptoms of Parkinson’s disease—an evidence-based medicine review. Mov. Disord.
11
https://doi.org/10.1002/mds.27602
12
Shohami, E., Cohen-Yeshurun, A., Magid, L., Algali, M., Mechoulam, R., 2011.
13
Endocannabinoids
14
https://doi.org/10.1111/j.1476-5381.2011.01343.x
15
18 19
traumatic
brain
injury.
Br.
J.
Pharmacol.
Starowicz, K., Finn, D.P., 2017. Cannabinoids and Pain: Sites and Mechanisms of Action, in:
16 17
and
Advances
in
Pharmacology.
https://doi.org/10.1016/bs.apha.2017.05.003 Stocchi, F., Torti, M., 2017. Constipation in Parkinson’s Disease. Int. Rev. Neurobiol. https://doi.org/10.1016/bs.irn.2017.06.003
20
Szallasi, A., Cortright, D.N., Blum, C.A., Eid, S.R., 2007. The vanilloid receptor TRPV1: 10
21
years from channel cloning to antagonist proof-of-concept. Nat. Rev. Drug Discov.
22
https://doi.org/10.1038/nrd2280
23
Taniguchi, W., Nakatsuka, T., Miyazaki, N., Yamada, H., Takeda, D., Fujita, T., Kumamoto,
24
E., Yoshida, M., 2011. In vivo patch-clamp analysis of dopaminergic antinociceptive
25
actions
26
https://doi.org/10.1016/j.pain.2010.09.034
on
substantia
gelatinosa
neurons
in
the
spinal
cord.
Pain.
27
Taylor, A.M.W., Becker, S., Schweinhardt, P., Cahill, C., 2016. Mesolimbic dopamine
28
signaling in acute and chronic pain: Implications for motivation, analgesia, and
29
addiction. Pain. https://doi.org/10.1097/j.pain.0000000000000494
30 31
Taylor, A.M.W., 2018. Corticolimbic circuitry in the modulation of chronic pain and substance
abuse.
Prog
Neuropsychopharmacol
Biol.
Psychiatry.
27 1 2
https://doi.org/10.1016/j.pnpbp.2017.05.009 Turcotte, C., Blanchet, M.R., Laviolette, M., Flamand, N., 2016. The CB2 receptor and its
3
role
4
https://doi.org/10.1007/s00018-016-2300-4.
5 6
as
a
regulator
of
inflammation.
Cell
Mol.
Life
Sci.
Toth, A., Blumberg, P.M., Boczan, J., 2009. Anandamide and the vanilloid receptor (TRPV1). Vitam Horm https://doi.org/10.1016/S0083-6729(09)81015-7
7
Walker, J.M., Huang, S.M., Strangman, N.M., Tsou, K., Sanudo-Pena, M.C., 2002. Pain
8
modulation by release of the endogenous cannabinoid anandamide. Proc. Natl. Acad.
9
Sci. https://doi.org/10.1073/pnas.96.21.12198
10 11 12 13
Wasner, G., Deuschl, G., 2012. Pains in Parkinson disease-many syndromes under one umbrella. Nat. Rev. Neurol. https://doi.org/10.1038/nrneurol.2012.54 Wood, P.B., 2008. Role of central dopamine in pain and analgesia. Expert Rev.Neurother. https://doi.org/10.1586/14737175.8.5.781
14
Xiao, X., Zhang, Y.Q., 2018. A new perspective on the anterior cingulate cortex and affective
15
pain. Neurosci Biobehav Rev. https://doi.org/10.1016/j.neubiorev.2018.03.022
16
Yoshimura, N., Kawamura, M., Masaoka, Y., Homma, I., 2005. The amygdala of patients
17
with Parkinson's disease is silent in response to fearful facial expressions.
18
Neuroscience. https://doi.org/10.1016/j.neuroscience.2004.09.054
19
Zengin-Toktas, Y., Ferrier, J., Durif, F., Llorca, P.M., Authier, N., 2013. Bilateral lesions of
20
the
nigrostriatal
pathways
are
associated
21
hypersensitivity
22
https://doi.org/10.1016/j.neures.2013.05.003
in rats. Neurosci.
with
chronic
mechanical
pain
Res.
23
Zhao, Y.-Q., Wang, H.-Y., Yin, J.-B., Sun, Y., Wang, Y., Liang, J.-C., Guo, X.-J.,Tang, K.,
24
Wang, Y.-T., 2017. The Analgesic Effects of Celecoxib on the Formalin- induced
25
Short- and Long-term Inflammatory Pain. Pain Physician.
26 27
Zygmunt, P.M., Julius, D., Di Marzo, V., Högestätt, E.D., 2000. Anandamide - The other side of the coin. Trends Pharmacol. Sci. https://doi.org/10.1016/S0165- 6147(99)01430-3
28 29 30 31
Figure legends Figure 1. Time-course of 6-OHDA-induced hyperalgesia and allodynia responses. (A)
28 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
Photomicrographs of coronal sections from brains at different positions relative to Bregma illustrating the loss of TH + fibers in the rostral (A’), medial (A’’) and caudal (A’’’) striatum. 10x, Bar=50um. (B-D) Two-way analysis of variance (repeated measure) with Bonferroni’s post-hoc test for Basal measures (1 day before surgery: -1) and for 6-OHDA-treated rats 1, 7, 14 and 21 days after surgery. Decrease in thermal (Hot Plate - B, Tail Flick - C, Acetoneinduced cold stimulus - D) and mechanical (Von Frey - E) withdrawal thresholds in 6-OHDAtreated rats have distinct temporal profiles. Data represent the mean ± SEM. *p < 0.05 from Basal (-1) measure, n = 8/test. Figure 2. Antinociceptive effects of CBD on experimental parkinsonism. Antinociceptive effects induced by CBD (10, 30, and 100 mg/kg), in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C), and Von Frey tests (D). Data represent the mean ± SEM. *p < 0.05 from VEH group, #p < 0.05 from CBD100 group; +p < 0.05 from MOR groups n = 8/group. Figure 3. Antinociceptive effects of chronic therapy with CBD on experimental parkinsonism. Antinociceptive effects induced by chronic injection of CBD (10 mg/kg), in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C), and Von Frey tests (D). Data represent the mean ± SEM. *p < 0.05 from VEH group, #p < 0.05 from CBD100 group; +p < 0.05 from MOR groups n = 8/group. Figure 4. Antinociceptive effects of URB597 (URB), AM251 (AM), capsazepine (CPZ) and SCH336 (SCH) on experimental parkinsonism. Antinociceptive effects induced by URB (0.5 mg/kg), AM251 (1 mg/kg), CPZ (5 mg/kg) and SCH (2 mg/kg), in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C), and Von Frey tests (D). Data represent the mean ± SEM. n = 8/group. Figure 5. Involvement of CB1, CB2, FAAH and TRPV1 in the antinociceptive effects induced by CBD on experimental parkinsonism: proposal mechanisms. Effects of the pretreatment with FAAH inhibitor URB (0.5 mg/kg); CB1 receptor antagonist AM251 (1 mg/kg) and TRPV1 antagonist CPZ (5 mg/kg) followed by CBD (10 mg/kg) in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C) and Von Frey tests (D). Data represent the mean ± SEM. *p < 0.05 from VEH group, #p < 0.05 from CBD10 group n = 5-7/group.
1
Highlights •
The CBD treatment decreases hyperalgesia and allodynia in experimental parkinsonism;
•
The inverse agonist of the CB1 receptor prevents the antinociceptive effect of CBD;
•
FAAH inhibitor or TRPV1 antagonist potentiates the CBD antinociceptive effect
S0028-3908(19)30370-3
DOI:
https://doi.org/10.1016/j.neuropharm.2019.107808
Reference:
NP 107808
To appear in:
Neuropharmacology
Received Date: 22 May 2019 Revised Date:
11 September 2019
Accepted Date: 2 October 2019
Please cite this article as: Crivelaro do Nascimento, G., Ferrari, D.P., Guimaraes, F.S., Del Bel, E.A., Bortolanza, M., Ferreira- Junior, N.C., Cannabidiol increases the nociceptive threshold in a preclinical model of Parkinson's disease, Neuropharmacology (2019), doi: https://doi.org/10.1016/ j.neuropharm.2019.107808. 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 Published by Elsevier Ltd.
1
Cannabidiol increases the nociceptive threshold in a preclinical model of Parkinson’s disease
*Glauce Crivelaro do Nascimento1,2; *Daniele Pereira Ferrari3; Francisco Silveira Guimaraes4; Elaine Aparecida Del Bel1,2,3; Mariza Bortolanza1a; Nilson Carlos FerreiraJunior1a
* GCN and DPF are equally responsible for this paper. 1 Department of Basic and Oral Biology, School of Dentistry of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14040-904, Brazil. 2 Department of Physiology, School of Medicine of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14049-900, Brazil. 3 Department of Neuroscience, School of Medicine of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14049-900, Brazil. 4 Department of Pharmacology, School of Medicine of Ribeirao Preto, University of Sao Paulo, Ribeirao Preto, SP, 14049-900, Brazil.
a Corresponding authors: MB and NCFJ Department of Oral and Basic Biology School of Dentistry of Ribeirao Preto, University of Sao Paulo Cafe Avenue - FORP - USP – Ribeirao Preto - SP - Brazil - 14049-900 Phone.: + 55-16-33154050 E-mail address: [email protected]; [email protected].
2
1
Abstract
2
Medications that improve pain threshold can be useful in the pharmacotherapy of Parkinson’s
3
disease (PD). Pain is a prevalent PD´s non-motor symptom with a higher prevalence of
4
analgesic drugs prescription for patients. However, specific therapy for PD-related pain are
5
not available. Since the endocannabinoid system is expressed extensively in different levels of
6
pain pathway, drugs designed to target this system have promising therapeutic potential in the
7
modulation of pain. Thus, we examined the effects of the 6-hydroxydopamine- induced PD on
8
nociceptive responses of mice and the influence of cannabidiol (CBD) on 6-
9
hydroxydopamine-induced nociception. Further, we investigated the pathway involved in the
10
analgesic effect of the CBD through the co-administration with a fatty acid amide hydrolase
11
(FAAH) inhibitor, increasing the endogenous anandamide levels, and possible targets from
12
anandamide, i.e., the cannabinoid receptors subtype 1 and 2 (CB1 and CB2) and the transient
13
receptor potential vanilloid type 1 (TRPV1). We report that 6-hydroxydopamine- induced
14
parkinsonism decreases the thermal and mechanical nociceptive threshold, whereas CBD
15
(acute and chronic treatment) reduces this hyperalgesia and allodynia evoked by 6-
16
hydroxydopamine. Moreover, ineffective doses of either FAAH inhibitor or TRPV1 receptor
17
antagonist potentialized the CBD- evoked antinociception while an inverse agonist of the CB1
18
and CB2 receptor prevented the antinociceptive effect of the CBD. Altogether, these results
19
indicate that CBD can be a useful drug to prevent the parkinsonism-induced nociceptive
20
threshold reduction. They also suggest that CB1 and TRPV1 receptors are important for
21
CBD-induced analgesia and that CBD could produce these analgesic effects increasing
22
endogenous anandamide levels.
23 24 25 26 27 28
Keywords:
29
Parkinson’s disease; Pain; Transient receptor potential vanilloid type 1.
30
6-hydroxydopamine;
anandamide;
cannabidiol;
cannabinoid
receptors;
3 11. Introduction 2
Besides originally described as a motor disease, Parkinson´s disease (PD) patients
3
suffer from a variety of non-motor symptoms such as sleep disorders, olfactory dysfunctions,
4
anxiety, depression, and pain (Dauer and Przedborski, 2003; Faivre et al., 2019). All these
5
symptoms have a significant impact on their quality of life (Aarsland and Kramberger, 2015;
6
Calabresi et al., 2006; Nègre-Pagès et al., 2008), and usually appear a long time before the
7
first motor signals (Bezard and Fernagut, 2014; Blanchet and Brefel-Courbon, 2018).
8
Around 60% of PD patients are affected by pain (Barone et al., 2009; Faivre et al.,
9
2019; Politis et al., 2010), which can be directly or partly related to the disease. It can appear
10
as nociceptive, neuropathic, or miscellaneous pain (Wasner and Deuschl, 2012). Also,
11
compared to healthy controls, these patients have lower pain threshold and tolerance
12
(Blanchet and Brefel-Courbon, 2018), developing allodynia (Djaldetti et al., 2004;
13
Schestatsky et al., 2007). However, the mechanisms of PD-associated pain are not completely
14
understood, and this problem has not received much attention from preclinical researchers.
15
Decreased nociceptive threshold has been reported in rodent models of PD after 1-
16
methyl-4-phenyl-1,2,4,5-tetrahydropyridine (MPTP) or 6-hydroxydopamine (6-OHDA)-
17
induced dopaminergic degeneration (Gómez-Paz et al., 2018; Nascimento et al., 2018;
18
Zengin-Toktas et al., 2013). These findings suggest that the loss of dopamine (DA) in the
19
basal ganglia may be involved in the reduced pain threshold (Wasner and Deuschl, 2012).
20
The degeneration of the nigrostriatal pathway impairs the dopamine-mediated
21
descending pathways, resulting in hyperalgesia (Fil et al., 2013). In this way, Magnusson and
22
Fisher (2000) showed that systemic administration of DA agonists induced hypoalgesia by
23
modulating D2 receptors in the dorsolateral striatum (Magnusson and Fisher, 2000).
24
Furthermore, some studies have pointed out to an increase in the pain threshold after
25
administration of the dopaminergic medication such as levodopa (Brefel-Courbon et al., 2005;
26
Gerdelat-Mas et al., 2007). However, the absence of a total recuperation of these symptoms
27
with dopaminergic therapy suggests that non-dopaminergic mechanisms could also be
28
involved in the appearance or maintenance of pain symptoms (Brefel-Courbon et al., 2005).
29
Despite the higher prevalence of analgesic drugs prescription for PD patients (33%)
30
than for general population (20%), pain is often neglected and insufficiently treated in these
31
patients (Broetz et al., 2007; Blanchet and Brefel-Courbon, 2018). In addition, analgesic drugs
32
frequently cause side effects such as opiate-induced constipation that in turn may exacerbate
33
constipation developed by parkinsonian patients in early stages of the disease (Stocchi and
4 1
Torti, 2017). Therefore, even though the well-established correlation between pain and PD,
2
still there is no specific therapy for the Parkinson's disease-related pain, thus requiring further
3
efforts in investigating effective drugs, with fewer side effects, for pain in this
4
neurodegenerative condition (Seppi et al., 2019).
5
The endocannabinoid system could be a promising target for the treatment of PD-
6
associated pain. This system has now been recognized as presenting great therapeutic
7
potential in the modulation of pain (Guindon and Hohmann, 2009), besides having a
8
neuroprotective effect on neurodegenerative diseases (Chagas et al., 2014). Cannabidiol
9
(CBD) is the principal non-intoxicating phytocannabinoid constituent of the Cannabis sativa
10
plant (Shohami et al., 2011; Russo, 2017). CBD has low affinity for both cannabinoid subtype
11
1 (CB1) and 2 (CB2) receptors (Ligresti et al., 2016), but it can upregulate the levels of the
12
endocannabinoid anandamide (AEA) by inactivation of the Fatty Acid Amide Hydrolase
13
(FAAH) (Campos et al., 2010), the enzyme responsible for anandamide degradation.
14
Besides AEA effects in cannabinoid receptors, AEA is also an agonist of the transient
15
receptor potential vanilloid type 1 (TRPV1) (Campos et al., 2010; dos-Santos- Pereira et al.,
16
2016; Zygmunt et al., 2000). TRPV1 is a channel activated by multiple painful stimuli
17
including noxious heat, pungent chemicals (capsaicin and jellyfish venom), and protons
18
(Kaneko and Szallasi, 2014; Szallasi et al., 2007). Accumulated compelling data have
19
demonstrated the role of TRPV1 in inflammatory and neuropathic pain states (Moran and
20
Szallasi, 2018; Stocchi and Torti, 2017). For instance, TRPV1 activation in nociceptive
21
neurons triggers the release of neuropeptides and transmitters, resulting in perceived pain
22
(Jara-Oseguera et al., 2010).
23
Therefore, CBD may represent a useful pharmacological alternative in the treatment of
24
PD-related pain. Here, we tested the hypothesis that CBD has an antinociceptive effect in a
25
preclinical model of 6-OHDA-induced parkinsonism in mice via FAAH inhibition and
26
indirect activation of the CB1 receptor.
27 282. Materials and Methods
Ethical statement: Male adult C57⁄BL6 mice (FMRP-USP, Ribeirão Preto, Brazil;
29
2.1.
30
20– 25g body weight) were used in this study. All animal experimental procedures were
31
approved by the local Animal Care and Use Committee of the University of São Paulo/Brazil
32
at the Ribeirao Preto campus (Protocol number # 2017.1.369.58.4) and are in accordance with
33
the Guide for the Care and Use of Laboratory Animals of the National Council for the Control
5 1
of Animal Experimentation (CONCEA).
2
2.2.
3
groups of three animals per cage in a controlled environment under a light-dark cycle of
4
12 hours (lights on at 06:00 and off at 18:00h), in a quiet room with controlled temperature
5
(23 ºC ± 1 ºC). All animals had free access to food and water. Animal care, including the
6
manual recording of body weight, observation of food and water intake, and cage changes that
7
occurred daily during the middle of the light cycle. Mice were left undisturbed during their
8
dark cycle.
Experimental animals - Housing and husbandry: C57⁄BL6 mice were housed in
9 10
2.3.
Pharmacological treatments: The following drugs, at doses based on the literature,
11
were used: cannabidiol (CBD, 10, 30 and 100 mg/kg (McPartland et al., 2015)), morphine
12
(MOR, 10 mg/kg (Aksu et al., 2018)), celecoxib (CXB, non-steroidal anti-inflammatory, 20
13
mg/kg, (Zhao et al., 2017)), URB597 (URB, FAAH inhibitor, 0.5 mg/kg, (Campos et al.,
14
2013)), AM251 (AM, CB1 antagonist, 1 mg/kg, (Campos et al., 2013)), Capsazepine (CPZ,
15
TRPV1 antagonist, 5 mg/kg, (dos-Santos-Pereira et al., 2016)) and SCH 336 (SCH, CB2
16
inverse agonist, 2mg/kg, (Lunn et al, 2006). All drugs were administered intraperitoneally.
17 18
2.4.
Sample size: The total number of mice used in this work was 49. All mice were tested
19
in the nociception tests before and after 6-OHDA lesion for determination of hyperalgesia and
20
allodynia time-course (first experimental protocol). Then, they were randomly distributed to
21
vehicle (VEH, n=6), CXB (n=6), MOR (n=6), CBD (n=7 per each dose) groups for the
22
second experimental protocol. After a 3-day drug washout, these mice were randomly
23
redistributed to the following groups: VEH (n=9), URB (n=10), AM (n=10), CPZ (n=10) and
24
SCH (n=10) treatments. Finally, one-week drug washout was performed, and 32 mice were
25
randomly distributed to VEH (n=7), CBD (n=8), CBD+URB (n=8), CBD+AM (n=8),
26
CBD+CPZ (n=8) or CBD+SCH (n=8) groups. In all cases, the animals were re-tested in the
27
nociception tests to ensure drug washout.
28 29
2.5.
30
experimental protocols:
31 32
Drug treatment and experimental design: This work was compounded by four
(1)
First, nociceptive tests were performed before the 6-OHDA lesion (-1 day) and
after 7, 14, and 21 days of the surgery.
6
(2)
1
After 21 days of the surgery, these mice were distributed into VEH, CXB,
2
MOR and CBD10, CBD30 and CBD100 mg/kg for the second experimental protocol. This
3
protocol consisted in evaluating CBD effects on hyperalgesia (by Hot Plate and Tail Flick
4
tests) and allodynia (Acetone Drop and Von Frey tests) responses compared to effects of
5
celecoxib, morphine and saline administration in mice with established motor impairment
6
(Data not shown).
7
(3)
After 3-day of drug washout, we tested the antinociceptive effects of chronic
8
treatment of CBD. Mice received CBD (10 mg/kg) for 14 days, once a day, and then were
9
tested for nociceptive behaviors 60 minutes after the last administration. (4)
10
After 3-day of drug washout, we tested different doses of URB, AM, CPZ and
11
SCH to find ineffective doses of these drugs on hyperalgesia and allodynia responses in
12
parkinsonian mice. These ineffective doses were used in the fourth protocol. (5)
13
Finally, after one week of drug washout, we test the involvement of FAAH,
14
CB1, CB2 and TRPV1 in the antinociceptive effect of the CBD in parkinsonian mice. A pre-
15
treatment with URB, AM, CPZ or SCH was made 30 min before CBD administration (30
16
mg/kg – the least effective dose according to our results). Hyperalgesia and allodynia tests
17
were performed 30 min after CBD administration.
18
After each protocol and drug washout, animals were re-subjected to nociception tests
19
to ensure drug washout (data not shown) and afterward regrouped randomly for performing
20
the following protocol.
21 22
2.6.
Experimental Procedures: All tests were performed at the light phase, in the
23
morning period (8:00-12:00) and at the same place (in the same laboratory). The same trained
24
person performed all the nociception tests. The information about the treatments was withheld
25
from experimenters that performed the hyperalgesia and allodynia tests to reduce bias, thus
26
characterizing a blinded-experiment.
27
2.6.1.
28
on a previous study (dos-Santos-Pereira et al., 2016). 6-Hydroxydopamine (6- OHDA; 2,4,5-
29
Trihydroxyphenethylamine hydrochloride; 2.5 ug/ul diluted in saline 0.9% containing 0.02%
30
ascorbic acid) obtained from Sigma-Aldrich, USA, was used. Third-two animals were
31
anesthetized with 2,2,2- tribromoethanol (250 mg/kg i.p.) and fixed in the stereotaxic
32
apparatus for performing the surgery (David Kopf, model USA, 9:57). Stereotaxic
33
coordinates of the dorsolateral region of striatum were (in mm from Bregma): anteroposterior
6-Hydroxydopamine-lesioned mice model: The 6-OHDA-induced lesion was based
7 1
(AP) = +0.5; lateral-lateral (LL) = -2.3 and dorsoventral (DV) = −3.9 and −3.0 (Paxinos and
2
Franklin, 2001). 6-OHDA-HCl was microinjected in a total volume of 2 µl/injection (2
3
injection places; 1 µL/min). After the microinjection, the cannula was left in place for five
4
additional minutes to prevent reflux of the injected solution. At the end of the surgical
5
procedure, the animals were kept warm by a 60W light bulb until full recovery from
6
anesthesia and then led to the vivarium, where they received amoxicillin (5 mg/ml orally) for
7
three days.
8
2.6.2.
9
inches tall) for 2 min, and the number of times they touch the cylinder wall with the right, left,
10
or both forepaws following rearing was recorded (Schallert et al., 2000). The asymmetry
11
score was calculated as the sum of left (unaffected) forepaw touches + 1/2 bilateral
12
touches/total number of forepaw touches (right + left + bilateral). For the mice that use both
13
forepaws equally, the score would be 0.5. For mice with the complete asymmetry of forepaw
14
use due to severe dopamine depletion affecting the right forepaw, the asymmetry score would
15
be 1 (Data not shown).
16
2.6.3.
17
following sequence: Von Frey, Acetone Drop, Tail Flick, and Hot Plate. This sequence was
18
based on previous studies from our group (do Nascimento and Leite-Panissi, 2014;
19
Nascimento et al., 2018). Specifically, the hot plate test was designed to evaluate the
20
supraspinally-integrated responses (Caggiula et al., 1995; Rubinstein et al., 2002), and it
21
determines changes in latency as an indicator of modifications of the supraspinal pain process.
22
In turn, the tail-flick latency is mediated by a spino-bulbo-spinal circuit (Le Bars et al., 2001),
23
as well as acetone – cold test, which is compared with the tail-flick test, but it uses the paw
24
withdrawal as parameter, avoiding the use of the tail that is an important organ related to
25
thermoregulation. In addition, different effects could be found with mechanical von Frey
26
filament, an important instrument to access the mechanisms of cutaneous stimulation-induced
27
sensory input (Pitcher et al., 1999).
28
2.6.3.1. Hot Plate: Thermal hyperalgesia was assessed with the hot plate test as previously
29
described (Fujii et al., 2019). Mice were placed in a 10-cm wide glass cylinder in a hot plate
30
apparatus (Insight, Wembley, UK) at 55±0.3 °C. The end-point (latency) was characterized
31
by the removal of the paw, followed by clear paw flinching or licking movements. A cut-off
32
of 30 s was established to prevent tissue damage (Kinsey et al., 2011). The latency of the flick
Cylinder test: Animals were placed in a clear plastic cylinder (3.8 inches wide, 6
Nociceptive Behaviors: The nociceptive tests were performed according to the
8 1
response was measured in seconds, and each animal was tested three times with 60 seconds
2
between each trial. The scores were averaged over the 3 trials for the final score of each
3
animal.
4
2.6.3.2.
5
flick test as described previously (Nascimento et al., 2018). Mice were placed at the apparatus
6
where a thermal stimulus was applied to the tail. We measured the latency for tail withdrawal
7
as an indication of the pain threshold. A cutoff time of 9-s was used to prevent tissue damage.
8
The latency of flick response was measured in seconds, and each animal was tested three
9
times, with 60 seconds between each trial. These scores were averaged over the 3 trials for the
10
final animal score. To avoid novelty stress- induced analgesia, animals were acclimated to the
11
test situation two days before the experiment by restraining the mouse in the same apparatus,
12
but without the thermal stimulus.
13
2.6.3.3.
14
as described previously (Brenner et al., 2014). Mice were acclimated for 5 min on a wire
15
mesh. Then, we sprayed acetone (100 µL) onto the plantar surface of the hind paw, without
16
touching the skin. The first 10 seconds of activity were disregarded as a response to the direct
17
application of the droplet. We measured the flinches in response to skin cooling induced by
18
acetone using the following scores: 0- none; 1- rapid withdrawal or abrupt movement of the
19
paw; 2- prolonged withdrawal or repeated movements of the paw; 3- repeated movements
20
followed by licking of the paw.
21
2.6.3.4.
22
force required to elicit a behavioral response, such as the withdrawal of a paw from the
23
applied stimulus (Chaplan et al., 1994; Nascimento et al., 2018, 2013). Employing von Frey
24
filaments (Nylon monofilaments - 0.35 mm diameter, Scientific Anglers™ Full Sinking Fly
25
Fishing Line) from 0.01 to 15.1 g, we first characterized the percent response at each stimulus
26
intensity (calibration). In the experimental day, the mice were placed individually in a cage
27
(10 X 20 X 15 cm) with a meshed metal wire floor (squares of 5 X 5 mm). Mice were
28
successively stimulated starting with the weakest to the strongest filaments (0.05 to 4 g). The
29
sequence of stimuli stopped when the animal reacted with immediate flinching or licking of
30
the hind paw. The force of the last used filament was considered the pain threshold.
31
Tail Flick: The spinally mediated thermal hyperalgesia was assessed by the tail-
Acetone Drop Test: Cold allodynia was assessed by the modified acetone drop test
Von Frey test: Mechanosensitivity can be determined as the threshold amount of
9 1
2.7.
Euthanasia and Tissue Processing: At the end of the behavioral analysis, the animals
2
were deeply anesthetized with urethane (1.5 g/kg, Sigma-Aldrich, St. Louis, MO, USA) and
3
rapidly perfused transcardially with cold 0.9% saline solution containing heparin (200 µl of
4
heparin 25,000 UI/l of solution) and sodium nitrite (1 g/l solution). Animals were then
5
immediately perfused with 4% paraformaldehyde (PFA; pH 7.4; Sigma-Aldrich, St. Louis,
6
MO, USA). Brains were immediately removed, post- fixed in 4% paraformaldehyde for 2 h,
7
and cryoprotected in 30% sucrose solution. Brains were quickly frozen in isopentane (−40 °C,
8
Sigma-Aldrich, St. Louis, MO, USA) and stored at −80 °C until histological processing.
9
Coronal sections (25 µm) were processed in a freezing microtome (Leica, model CM1850)
10
throughout the rostrocaudal extent of the striatum and substantia nigra compacta. Striatal
11
sections were obtained from rostral (Bregma: +0.86 mm), medial (Bregma +0.02 mm) and
12
caudal areas (Bregma −0.58 mm). Substantia nigra sections were obtained from rostral
13
(Bregma −2.54 mm), medial (Bregma −3.16 mm) and caudal areas (Bregma −3.80 mm).
14
2.8.
Immunohistochemistry: To verify the extension of 6-OHDA lesion, immunostaining
15
was
then
16
immunohistochemical protocols (Gomes et al., 2008) with specific tyrosine hydroxylase (TH,
17
1:2000; Pel Freez, Arkansas, USA) antibody diluted in 0.1 M phosphate-buffered saline (pH
18
7.4), containing 0.15% Triton X-100. After incubation with the primary (48 h) and secondary
19
(1.5 h) antisera, peroxidase reactions were developed with diaminobenzidine. The slices were
20
mounted on slides and coverslipped for microscope observations. Samples from each
21
experimental group were processed at the same time. Quantitative analyses were then
22
performed in striatum and substantia nigra.
carried
out
in
free-floating
sections
with
standard
avidin–
biotin
23 24
2.9.
25
was evaluated by repeated measures analysis of variance (r-ANOVA), with drug and time as
26
factors. The results are expressed as mean ± S.E.M, and post-hoc analysis was performed with
27
the help of the Bonferroni's test. For the analysis of the nociception tests and
28
immunohistochemistry, comparison between different groups was performed using two-way
29
analysis of variance (ANOVA) followed by the Tukey’s multiple comparisons test. Values are
30
presented as mean ± S.E.M. Statistical significance was set at p<0.05. All statistics in this
31
study were performed using Prism 6, version 6.0d (GraphPad Software, Inc.).
32
Statistical Analysis: The effect on the time course of 6-OHDA-induced nociception
10 1
3.
Results
2
3.1.
Time-course of 6-OHDA-induced hyperalgesia and allodynia responses
3
In the present study, we first confirmed by immunohistochemistry that 6-OHDA
4
induced PD-like lesions (Figure 1A). We used TH-immunoreactivity (TH-ir) to assess the
5
percentage of the striatal area devoid of TH-ir for all mice used in the experiments. On
6
average, 65% of the striatum was denervated. There was a lesion side effect for all striatal
7
analyzed areas (rostral: F2,42 = 3.3; p<0.05; medial: F2,38 = 12.7; p<0.05; caudal: F2,48 = 6.4;
8
p<0.05, data not shown).
9
To rule out that different lesion intensity would interfere with CBD analgesic effects,
10
the cylinder test was performed. The ratio of forelimb placement [(left- right)/(right + left +
11
both)] of the non-treated group did not differ from drug treatment group (F4,42 = 4.2; p>0.05).
12
As expected, there was no interaction “lesion side × drug treatment” (F4,48 = 13.1; p>0.05,
13
Supplementary Data).
14
We used four nociceptive behavioral tests to measure the time-course of thermal and
15
mechanical pain threshold in mice after 6-OHDA-injection. The hot plate test showed a
16
significantly decrease in thermal latency in mice at 14 and 21 days from surgery (F4,48 = 3. 1;
17
p<0.01; Figure 1C) when compared to basal measures. On the other hand, tail flick latency
18
diminished since the first analyzed period (7 – 21 days) after 6- OHDA lesion (F4,48 = 6.4;
19
p<0.05; Figure 1D). Regarding allodynia responses, there was significantly increase in
20
nociception behavior at 14 and 21 days from surgery when compared to basal measures in
21
both tests (acetone drop, F4,48 = 13.3; p<0.05; Figure E; and von Frey, F4,48 = 4.3; p<0.05;
22
Figure F).
23
These results suggest that the mice model of PD induced by unilateral lesion of the
24
striatum displays thermal and mechanical pain hypersensitivity that start at different time
25
points after the 6-OHDA lesion.
26 27
3.2.
Antinociceptive effects of acute CBD on experimental parkinsonism
28
Hyperalgesia response – Twenty-one days after 6-OHDA injection, we tested the
29
antinociceptive effects of CBD. Three different doses (10, 30, 100 mg/kg i.p.) of CBD were
30
administered 60 min previously to the nociceptive tests. CXB, MOR, and CBD (10, 30 and
31
100 mg/kg) increased hot plate response latency (p<0.05; Figure 2A) when compared to VEH
32
group. Morphine (MOR) also significantly increased this latency when compared to CXB and
33
the three doses of CBD (F3,48 = 5.31 p<0.01; Figure 2A). In addition, the highest dose of CBD
11 1
(100 mg/kg) induced antinociceptive effects in the hot plate test comparing to the other two
2
doses (F3,32 = 6.8; p<0.05; Figure 2A). The tail flick latency was measured to evaluate a
3
hyperalgesia response under spinal control. The results indicated that celecoxib (CXB),
4
morphine (MOR) and the three doses of CBD significantly reduced this thermal hyperalgesia
5
when compared to VEH group (F3,48 = 17.3; p<0.05; Figure 2B). The highest dose of CBD
6
(100 mg/kg) was the most effective in increasing tail flick latency.
7
Allodynia response – There was no change in the withdrawal latency to cold stimulus
8
in the VEH, CXB, and CBD (30 mg/kg) mice groups (p>0.05; Figure 2C). MOR and the
9
doses of 10 and 100 mg/kg of CBD significantly increased this latency (F4,48 = 26.1 p<0.01;
10
Figure 2C). CBD and MOR presented similar antinociceptive effects in this test (p>0.05;
11
Figure 2C). Antinociceptive effects in mechanical allodynia measured by Von Frey method
12
were observed after CXB, MOR and CBD (10 and 100 mg/kg) administration when compared
13
to CBD at 30 mg/kg (F3,32 = 26.2; p<0.05; Figure 2D).
14 15
3.3.
We also tested the antinociceptive effects of chronic treatment with CBD. Mice
16 17
Antinociceptive effects of chronic CBD on experimental parkinsonism
received CBD (10 mg/kg i.p.) either in one single dose or daily dose for 14 days.
18
Hyperalgesia response – Both acute and chronic CBD increased hot plate response
19
latency (p<0.01) when compared to VEH group. The chronic CBD had significantly higher
20
antinociceptive effect compared to acute dose of CBD (F 2,19 = 96.22; p<0.01; Figure 3A). In
21
tail flick, both acute and chronic CBD treatments significantly reduced this thermal
22
hyperalgesia when compared to VEH group (F
23
differences were found between acute and chronic CBD (p>0.05).
2,19
= 14.26; p<0.01; Figure 3B). No
24
Allodynia response – The withdrawal latency for cold stimulus were increased in mice
25
that receive CBD, compared to VEH group (F 2,19 = 8.881; p<0.01; Figure 3C). Similar effects
26
were found between acute and chronic treatment of CBD (p>0.05). The evaluation of
27
mechanical allodynia showed similar antinociceptive effects of both acute and chronic CBD
28
when compared to VEH (F 2,19 =14.06; p<0.05; Figure 3D).
29 30
3.4.
Antinociceptive effects of URB, AM251, Capsazepine and SCH 336 on
31
experimental parkinsonism
32
The progression in understanding the pain pathways have helped in discovering
33
several new pharmacological targets to treat pain: TRPV1 and the cannabinoid receptors
12 1
along with their endogenous agonists (endocannabinoids) are some of them.
2
Hyperalgesia response – Following three days of CBD washout, we tested the effect
3
of URB, AM251, CPZ and SCH in lesioned-mice using the hot plate and tail flick tests. The
4
drugs were administered 60 min previously to reach the plasmatic peak during the nociceptive
5
tests (Deiana et al., 2012). There were no changes in the hot plate and tail flick responses
6
latency in doses tested of VEH, URB, AM, CPZ and SCH in any of the groups (p>0.05;
7
Figure 4A-B).
8
Allodynia response – URB, AM, CPZ and SCH effects were also tested in allodynia
9
responses. There was no change in the withdrawal latency to a cold stimulus (Figure 4C) nor
10
intensity of mechanical allodynia (Figure 4D) measured by Von Frey method in doses tested
11
of VEH, URB, AM, CPZ and SCH (p>0.05).
12 13
3.5.
Involvement of CB1, CB2 FAAH, and TRPV1 in the antinociceptive effects
14
induced by CBD on experimental parkinsonism
15
To test the hypothesis that CBD could act on 6-OHDA-induced nociception via FAAH
16
inhibition, and modulation of CB1, CB2 and TRPV1 receptors, we administrated CBD
17
(30mg/kg) plus each drug related to the cited targets (URB, AM, CPZ and SCH). The
18
hyperalgesia and allodynia responses were evaluated in mice with experimental parkinsonism.
19
For this, the animals were randomly distributed into the groups after a new 3 days period of
20
drug washout. The nociception tests were repeated before the experiment to ensure drug
21
washout.
22
Hyperalgesia response – Pre-treatment with the FAAH inhibitor (URB) and TRPV1
23
antagonist (CPZ) potentiated the effect induced by CBD (interaction: F2,42= 12.6; p<0.05,
24
two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5A). On the other hand, pre-treatment
25
with the CB1 receptor antagonist AM251 blocked the effects induced by CBD on hot plate
26
response latency (interaction: F2,48= 21.5; p<0.05, two- way ANOVA; p<0.05 vs. VEH and
27
CBD). The CB2 inverse agonist SCH 336 had no influence on antinociceptive effects of CBD
28
(p>0.05; Figure 5A). A similar finding was observed for tail flick latency. Pre-treatment with
29
URB and CPZ potentiated the effect induced by CBD (interaction: F2,42= 20.6; p<0.05, two-
30
way ANOVA; p<0.05 vs. VEH and CBD; Figure 5B), while pre-treatment with AM and SCH
31
blocked the effects induced by CBD on tail flick response latency (interaction: F2,48= 21.5;
32
p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5B).
33
Allodynia response – Administration of URB or CPZ potentiated the antinociceptive
13 1
effect of CBD (30 mg/kg) on withdrawal latency to a cold stimulus (interaction: F2,50= 6.2;
2
p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5C). Distinctly, pre-treatment
3
with both AM and SCH blocked the effects induced by CBD in this test (interaction: F2,48=
4
8.7; p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5C). Ineffective doses on
5
allodynia of the URB or CPZ, when administered with an inefficacious dose of 30 mg/kg of
6
CBD, evoked a synergistic increased in the withdrawal latency to a mechanical stimulus,
7
suggesting similar mechanisms of action of the CBD, URB, and CPZ (interaction: F2,48= 18.1;
8
p<0.05, two-way ANOVA; p<0.05 vs. VEH and CBD; Figure 5D). On the other hand, AM
9
and SCH did not change the lack of effect of the CBD in mechanical allodynia response
10
(p>0.05; Figure 5D).
11 12
4.
Discussion
13
The present results showed that: (i) experimental parkinsonism decreases the
14
nociceptive threshold to thermal and mechanical stimulations, (ii) acute or chronic treatment
15
with CBD decreases the hyperalgesia and allodynia in this condition, (iii) the highest CBD
16
dose (100 mg/kg) induces a similar effect to morphine in parkinsonian mice, (iv) the inverse
17
agonist of the CB1 receptor prevents the antinociceptive effect of CBD while ineffective
18
doses of either a FAAH inhibitor or a TRPV1 antagonist increase the CBD antinociceptive
19
effect. Altogether, these results indicate that acute or chronic treatment with CBD can be
20
useful to reduce parkinsonism-increased nociception. They also suggest that CBD induces
21
antinociception increasing endogenous anandamide levels and acting via CB1 and TRPV1
22
receptors, but not via CB2 receptors.
23
Our data showed an antinociceptive effect of the three analyzed doses of CBD in
24
hyperalgesia responses (hot plate and tail flick tests). For allodynia responses, the lower and
25
higher doses of CBD were significantly effective, whereas an intermediate dose did not work.
26
Moreover, in three of the four performed tests (Figure 2B-D), a similar antinociceptive effect
27
between CBD (100mg/kg) and morphine (MOR) was found. CBD was also compared to
28
celecoxib (CXB), a nonsteroidal anti‐inflammatory drug, which was minimally effective
29
against both thermal and mechanical endpoints, which corroborates previous results
30
(Hosseinzadeh et al., 2017). In our animal model, the highest dose of CBD promoted a better
31
antinociceptive effect than CXB.
32
Hypernociception found in 6-OHDA lesioned animals are in line with several other
33
studies in the field (Charles et al., 2018; Gee et al., 2015; Kaszuba et al., 2017; Zengin-Toktas
34
et al., 2013). Hyperalgesia and allodynia can be mediated by central sensitization at distinct
14 1
central nervous system levels. At note, Charles and colleagues described a hyperexcitability
2
of neurons from lamina V of the spinal cord in 6-OHDA-induced parkinsonism (Charles et
3
al., 2018). The dorsal horn of the spinal cord is the first relay for nociceptive inputs from the
4
periphery. Our data evidence decrease in nociceptive threshold in the first days after the 6-
5
OHDA lesion when tail flick test was performed. Importantly, the tail flick use a noxious heat
6
stimulation of the tail that produces a spinally mediated flexion reflex (Bannon and
7
Malmberg, 2007). In contrast, in the hot-plate test, the final response involves not only spinal,
8
but also supraspinal pathways.
9
Dennis and Melzack first described an essential role for the dopamine system in
10
mediating antinociception (Dennis and Melzack, 1983). Basal ganglia, limbic areas, thalamus,
11
periaqueductal gray matter (PAG), and other brain areas modulated by the dopaminergic
12
system play a critical role in the processing of pain (Chudler and Dong, 1995; Hagelberg et
13
al., 2002). The dopaminergic circuitry could also directly influence nociceptive behavior
14
acting in the dorsal horn of spinal cord through hypothalamic A11 projections to spinal D2
15
receptors (Kim and Abdi, 2014; Taniguchi et al., 2011). Recent findings have shown a
16
dysregulation of GABAergic neurotransmission in the PAG ventrolateral (the major
17
component of the descending inhibitory pain pathway) induced by 6-OHDA nigrostriatal
18
lesions, suggesting an impairment of descending analgesic system and stimulation of the
19
descending pain facilitatory system (Domenici et al., 2019). This unbalance promotes
20
downregulation of the spinal opioidergic modulation and, consequently, leads to a nociceptive
21
sensitization. Based on these findings, we speculate that dysfunctions in limbic areas and at
22
the spinal level could be responsible for the decreased nociceptive threshold observed in the
23
6-OHDA-induced PD model in the present work.
24
In patients, decreased function of the nigrostriatal pathway is associated with pain,
25
(Hagelberg et al., 2004) while persistent and chronic pain reduces intracranial self-stimulation
26
of the medial forebrain bundle (Leitl et al., 2014; Pereira Do Carmo et al., 2009). Since these
27
pieces of evidence indicate that chronic pain leads to a significant impairment of dopamine
28
activity (Chudler and Dong, 1995; Magnusson and Fisher, 2000; Taylor et al., 2016; Wood,
29
2008), the loss of dopaminergic nigrostriatal activation after injection of 6-OHDA into the
30
striatum can directly contribute to the decreased nociceptive threshold observed in the current
31
work.
32
The involvement of the endocannabinoid system in dopamine signaling within reward
33
circuits affected by chronic pain is few explored (Mlost et al., 2019). Despite the
34
antinociceptive potential of cannabinoids (Jensen et al., 2015), CBD effect on nociception
15 1
induced by striatal lesions in mice has never been investigated. Our results show that a CB1
2
receptor antagonist blunted CBD-induced antinociception while a CB2 receptor antagonist did
3
not affect CBD response, suggesting that CB1 receptors play an important role in CBD
4
antinociception. Although CBD has a low affinity for cannabinoid receptors, CBD can act
5
directly, at micromolar concentrations, as a partial agonist of CB1 and CB2 receptors
6
(McPartland et al., 2015; Pertwee, 2008a). CB2 receptors are mainly expressed in cells of the
7
immune system (Cabral and Griffin-Thomas, 2009) and mediated many anti-inflammatory
8
properties of cannabinoids (Turcotte et al., 2016), and albeit celecoxib has produced
9
antinociception in our experimental model of PD, CB2 receptors are unlikely to mediate CBD
10
effects in our studysince the selective CB2 antagonist did not change the CBD
11
antinociception.
12
Conversely, a TRPV1 antagonist and a FAAH inhibitor increased the CBD-induced
13
analgesia, suggesting that the TRPV1 have a different role from CB1 increasing nociception
14
and that CBD actions might be depending on AEA. CBD can inhibit FAAH, increasing
15
endogenous AEA concentration (Leweke et al., 2012; McPartland et al., 2015). AEA is an
16
agonist of both CB1 and TRPV1 receptors (Di Marzo and De Petrocellis, 2012), as well as
17
can bind to CB2 receptor, but with less efficacy, behaving like a CB2 antagonist in some in
18
vitro bioassays (McPartland et al., 2015; Pertwee, 2008b). CB1 and TRPV1 have a distinct
19
mechanism of action: CB1 is a metabotropic receptor coupled to a Gi-protein while TRPV1 is
20
a channel permeable to several cations such as calcium (Di Marzo and De Petrocellis, 2012).
21
Therefore, CBD or AEA can produce opposite effects acting on these receptors (Di Marzo
22
and De Petrocellis, 2012).
23
Although the activation of CB1 receptors exert an anti-nociceptive and TRPV1
24
activation, a pro-nociceptive effect, the anandamide (AEA) has low intrinsic efficacy at
25
TRPV1 as compared to CB1 ((Ross, 2003; Toth et al., 2009; McPartland et al., 2015), and this
26
could explain the preference of the CB1, instead TRPV1, modulation by increased levels of
27
anandamide. In addition, the efficacy of AEA on TRPV1 is influenced by many factors and
28
physiological and pathological states, including the fact that AEA action on CB1 receptors
29
can change the TRPV1-mediated AEA response. In this sense, it is possible to suggest that the
30
smaller dose of CBD increase AEA, by inhibiting the FAAH, evoking a CB1-mediated
31
response while intermediate doses of CBD increase AEA to levels sufficient to activate both
32
CB1 and TRPV1 receptors eliciting lesser CBD-mediated antinociception, thus explaining the
33
U-shaped curve for the CBD in our experimental model. Another work using the FAAH
34
inhibitor URB597 injected into the PAG also found a dual effect for AEA in nociception. A
16 1
low dose of URB597 into the ventrolateral PAG evoked a hyperalgesic effect that was
2
converted to antinociceptive when injected along with the CB1 receptor inverse agonist
3
AM251. However, a TRPV1 antagonist converted the antinociceptive effect of the high dose
4
of URB597 to a hyperalgesic effect (Maione, 2006).
5
In vivo microdialysis showed that intraplantar injection of formalin increase AEA
6
release within the PAG (Walker et al., 2002) while electrical stimulation of dorsal or lateral
7
columns of the PAG evokes CB1-mediated antinociception along with a rise in AEA levels in
8
the PAG (Martin et al., 1999). Moreover, mice lacking FAAH presents increased thermal
9
analgesia and reduced nociceptive behavior in the formalin and carrageenan models (Carey et
10
al., 2016). In the same experimental pain model, intra-spinal injection of AEA also evokes
11
analgesia while CB1 receptor blockade inhibits these AEA effects (Carey et al., 2016). In the
12
same way, the acute administration of URB597 decrease allodynia in a neuropathic pain
13
model, and the pretreatment with a CB1 antagonist blunts this effect (Kinsey et al., 2009).
14
Altogether, these results suggest that AEA has antinociceptive effects acting via CB1
15
receptors in different experimental pain models.
16
The CB1 receptor is present in several brain regions involved in pain processing such
17
as PAG, dorsal root ganglion, superficial laminae of the spinal cord, cortical areas, and
18
amygdala (Di Marzo and De Petrocellis, 2012; Starowicz and Finn, 2017). Administration of
19
WIN55,212-2, a synthetic cannabinoid agonist, into the amygdala increases tail-flick latency
20
in rats, while the pharmacological blockade of CB1 receptors within the basolateral amygdala
21
attenuates the stress-induced analgesia in the same pain mode (Connell et al., 2006). In
22
nonhuman primates, the amygdala is essential to cannabinoid-induced antinociception
23
(Manning et al., 2018), thus suggesting that amygdala may be a target for AEA-induced
24
analgesia after peripheral CBD administration.
25
Amygdala and prefrontal cortex are areas that play a major role in mood disorders
26
(Price and Drevets, 2010), and both are involved in the neurocircuitry of pain (Taylor, 2018;
27
Xiao and Zhang, 2018). Neuroimaging studies show that these areas are affected in PD
28
patients (Chagas et al., 2017; Yoshimura et al., 2005), thus contributing to the increased risk
29
of anxiety and depression in these patients. Mood disorders can promote hypersensitivity to
30
pain (Bushnell et al., 2013; Taylor, 2018), and a study showed a correlation between
31
depression and pain in PD (Rana et al., 2017). Therefore, since several works demonstrate
32
that CBD is useful to treat affective disorders such as depression (Blessing et al., 2015; Crippa
33
et al., 2018; (Campos et al., 2016), the modulation of the emotional component of pain can be
34
part of CBD evoked-antinociception in our experimental model.
17 1
5.
Conclusion
2
In summary, our results suggest that CBD decreases the enhanced nociception of
3
animals with selective loss of dopaminergic nigrostriatal pathway. URB (selective FAAH
4
inhibitor) treatment potentialized the CBD antinociception effect. On the other hand, the
5
blockage of the CB1 receptors with the selective antagonist AM251 inhibited the CBD effect
6
while TRPV1 receptor antagonism increased the antinociception effect of CBD. Altogether,
7
these results suggest that CBD decrease the nociception inhibiting FAAH and consequently
8
increasing AEA. In turns, AEA can bind to CB1 and TRPV1 receptors. These receptors have
9
opposite effects on pain modulation. Thus, AEA binds to CB1 receptors promoting analgesia
10
while decreases the nociception via TRPV1 receptors.
11 12 13 14
Acknowledgments We thank Célia Aparecida da Silva for technical assistance and Mauricio dos Santos
15
Pereira for drug offering.
16
Author contributions
17
G.C.N., D.P.F, M.B. and N.C.F.J. performed experiments. F.S.G. and E.A.D.B.
18
provided feedback on project and participated in writing the manuscript. G.C.N., D.P.F,
19
M.B. and N.C.F.J. designed study, analyzed data, interpreted results, and wrote the
20
manuscript.
21
Financial Support
22 23 24
This study was supported by grants from CNPq, CAPES, and FAPESP. Conflict interests There is no conflict of interests to declare.
25 26 27
References
28
Aarsland, D., Kramberger, M.G., 2015. Neuropsychiatric symptoms in Parkinson’s disease. J.
29
Parkinsons. Dis. https://doi.org/10.3233/JPD-150604
30
Aksu, A.G., Gunduz, O., Ulugol, A., 2018. Contribution of spinal 5-HT 5A receptors to the
31
antinociceptive effects of systemically administered cannabinoid agonist WIN 55,212-
32
2 and morphine. Can. J. Physiol. Pharmacol. https://doi.org/10.1139/cjpp- 2017-0567
33
Bannon, A.W., Malmberg, A.B., 2007. Models of Nociception: Hot-Plate, Tail-Flick, and
18 1
Formalin
Tests
in
Rodents,
in:
Current
2
https://doi.org/10.1002/0471142301.ns0809s41
Protocols
in
Neuroscience.
3
Barone, P., Antonini, A., Colosimo, C., Marconi, R., Morgante, L., Avarello, T.P., Bottacchi,
4
E., Cannas, A., Ceravolo, G., Ceravolo, R., Cicarelli, G., Gaglio, R.M., Giglia, R.M.,
5
Iemolo, F., Manfredi, M., Meco, G., Nicoletti, A., Pederzoli, M., Petrone, A., Pisani,
6
A., Pontieri, F.E., Quatrale, R., Ramat, S., Scala, R., Volpe, G., Zappulla, S.,
7
Bentivoglio, A.R., Stocchi, F., Trianni, G., Del Dotto, P., 2009. The PRIAMO study:
8
A multicenter assessment of nonmotor symptoms and their impact on quality of life in
9
Parkinson’s disease. Mov. Disord. https://doi.org/10.1002/mds.22643
10 11 12
Bezard, E., Fernagut, P.O., 2014. Premotor parkinsonism models. Park. Relat. Disord. https://doi.org/10.1016/S1353-8020(13)70007-5 Blanchet, P.J., Brefel-Courbon, C., 2018. Chronic pain and pain processing in Parkinson’s
13
disease.
14
https://doi.org/10.1016/j.pnpbp.2017.10.010
15
Prog.
Neuro-Psychopharmacology
Biol.
Psychiatry.
Blessing, E.M., Steenkamp, M.M., Manzanares, J., Marmar, C.R., 2015. Cannabidiol as a
16
Potential
Treatment
for
Anxiety
17
https://doi.org/10.1007/s13311-015-0387-1
Disorders.
Neurotherapeutics.
18
Brefel-Courbon, C., Payoux, P., Thalamas, C., Ory, F., Quelven, I., Chollet, F., Montastruc,
19
J.L., Rascol, O., 2005. Effects of levodopa on pain threshold in Parkinson’s disease: A
20
clinical
21
https://doi.org/10.1002/mds.20629
22
and
positron
emission
tomography
study.
Mov.
Disord.
Brenner, D.S., Vogt, S.K., Gereau IV, R.W., 2014. A technique to measure cold adaptation in
23
freely
behaving
mice.
24
https://doi.org/10.1016/j.jneumeth.2014.08.009
J.
Neurosci.
Methods.
25
Broetz, D., Eichner, M., Gasser, T., Weller, M., Steinbach, J.P., 2007. Radicular and
26
nonradicular back pain in Parkinson’s disease: A controlled study. Mov. Disord.
27
https://doi.org/10.1002/mds.21439
28
Bushnell, M.C., Ceko, M., Low, L.A., 2013. Cognitive and emotional control of pain and its
29
disruption in chronic pain. Nat. Rev. Neurosci. https://doi.org/10.1038/nrn3516
30
Cabral, G.A., Griffin-Thomas, L., 2009. Emerging role of the cannabinoid receptor CB2 in
31
immune regulation: therapeutic prospects for neuroinflammation. Expert. Rev. Mol.
19 1 2
Med. https://doi.org/10.1017/S1462399409000957. Caggiula, A.R., Perkins, K.A., Saylor, S., Epstein, L.H., 1995. Different methods of assessing
3
nicotine-induced
antinociception
may
engage
different
neural
4
Psychopharmacology (Berl). https://doi.org/10.1007/BF02246552
mechanisms.
5
Calabresi, P., Picconi, B., Parnetti, L., Di Filippo, M., 2006. A convergent model for
6
cognitive dysfunctions in Parkinson’s disease: the critical dopamine-acetylcholine
7
synaptic balance. Lancet Neurol. https://doi.org/10.1016/S1474-4422(06)70600-7
8
Campos, A.C., Ferreira, F.R., Guimarães, F.S., Lemos, J.I., 2010. Facilitation of
9
endocannabinoid effects in the ventral hippocampus modulates anxiety-like behaviors
10
depending
on
previous
stress
11
https://doi.org/10.1016/j.neuroscience.2010.01.062
experience.
Neuroscience.
12
Campos, A.C., Ortega, Z., Palazuelos, J., Fogaça, M. V., Aguiar, D.C., Díaz-Alonso, J.,
13
Ortega-Gutiérrez, S., Vázquez-Villa, H., Moreira, F.A., Guzmán, M., Galve- Roperh,
14
I., Guimarães, F.S., 2013. The anxiolytic effect of cannabidiol on chronically stressed
15
mice depends on hippocampal neurogenesis: Involvement of the endocannabinoid
16
system. Int. J. Neuropsychopharmacol. https://doi.org/10.1017/S1461145712001502
17
Campos, A.C., Fogaca, M.V., Sonego, A.B., Guimaraes, F.S., 2016. Cannabidiol,
18
neuroprotection
and
neuropsychiatric
19
https://doi.org/10.1016/j.phrs.2016.01.033
disorders.
Pharmacol.
Res.
20
Carey, L.M., Slivicki, R.A., Leishman, E., Cornett, B., Mackie, K., Bradshaw, H., Hohmann,
21
A.G., 2016. A pro-nociceptive phenotype unmasked in mice lacking fatty-acid amide
22
hydrolase. Mol. Pain. https://doi.org/10.1177/1744806916649192
23
Chagas, M.H.N., Zuardi, A.W., Tumas, V., Pena-Pereira, M.A., Sobreira, E.T., Bergamaschi,
24
M.M., Dos Santos, A.C., Teixeira, A.L., Hallak, J.E.C., Crippa, J.A.S., 2014. Effects
25
of cannabidiol in the treatment of patients with Parkinson’s disease: An exploratory
26
double-blind trial. J. Psychopharmacol. https://doi.org/10.1177/0269881114550355
27
Chagas, M.H.N., Tumas, V., Pena-Pereira, M.A., Machado-de-Sousa, J.P., Carlos Dos Santos,
28
A., Sanches, R.F., Hallak, J.E.C., Crippa, J.A.S., 2017. Neuroimaging of major
29
depression in Parkinson's disease: Cortical thickness, cortical and subcortical volume,
30
and
31
https://doi.org/10.1016/j.jpsychires.2017.02.010
spectroscopy
findings.
J.
Psychiatr.
Res.
20 1
Chaplan, S.R., Bach, F.W., Pogrel, J.W., Chung, J.M., Yaksh, T.L., 1994. Quantitative
2
assessment
of
tactile
allodynia
in
the
3
https://doi.org/10.1016/0165-0270(94)90144-9
rat
paw.
J.
Neurosci.
Methods.
4
Charles, K.A., Naudet, F., Bouali-Benazzouz, R., Landry, M., De Deurwaerdère, P., Fossat,
5
P., Benazzouz, A., 2018. Alteration of nociceptive integration in the spinal cord of a
6
rat model of Parkinson’s disease. Mov. Disord. https://doi.org/10.1002/mds.27377
7 8
Chudler, E.H., Dong, W.K., 1995. The role of the basal ganglia in nociception and pain. Pain. https://doi.org/10.1016/0304-3959(94)00172-B
9
Connell, K., Bolton, N., Olsen, D., Piomelli, D., Hohmann, A.G., 2006. Role of the
10
basolateral nucleus of the amygdala in endocannabinoid-mediated stress-induced
11
analgesia. Neurosci. Lett. https://doi.org/10.1016/j.neulet.2005.12.008
12
Crippa, J.A., Guimarães, F.S., Campos, A.C., Zuardi, A.W., 2018. Translational Investigation
13
of the Therapeutic Potential of Cannabidiol (CBD): Toward a New Age. Front.
14
Immunol. https://doi.org/10.3389/fimmu.2018.02009
15
Dauer, W., Przedborski, S., 2003. Parkinson’s disease: mechanisms and models. Neuron.
16
Deiana, S., Watanabe, A., Yamasaki, Y., Amada, N., Arthur, M., Fleming, S., Woodcock, H.,
17
Dorward, P., Pigliacampo, B., Close, S., Platt, B., Riedel, G., 2012. Plasma and brain
18
pharmacokinetic profile of cannabidiol (CBD), cannabidivarine (CBDV), ∆ 9-
19
tetrahydrocannabivarin (THCV) and cannabigerol (CBG) in rats and mice following
20
oral and intraperitoneal administration and CBD action on obsessive-compulsive
21
behav. Psychopharmacology (Berl). https://doi.org/10.1007/s00213-011-2415-0
22
Dennis, S.G., Melzack, R., 1983. Effects of cholinergic and dopaminergic agents on pain and
23
morphine
24
https://doi.org/10.1016/0014-4886(83)90166-8
25
analgesia
measured
by
three
pain
tests.
Exp.
Neurol.
Di Marzo, V., De Petrocellis, L., 2012. Why do cannabinoid receptors have more than one
26
endogenous
ligand?
Philos.
27
https://doi.org/10.1098/rstb.2011.0382
Trans.
R.
Soc.
B
Biol.
Sci.
28
Djaldetti, R., Shifrin, A., Rogowski, Z., Sprecher, E., Melamed, E., Yarnitsky, D., 2004.
29
Quantitative measurement of pain sensation in patients with Parkinson disease.
30
Neurology. https://doi.org/10.1212/01.WNL.0000130455.38550.9D
21 1
do Nascimento, G.C., Leite-Panissi, C.R.A., 2014. Time-dependent analysis of nociception
2
and anxiety-like behavior in rats submitted to persistent inflammation of the
3
temporomandibular joint. Physiol.
4
https://doi.org/10.1016/j.physbeh.2013.11.009
Behav.
5
Domenici, R.A., Campos, A.C.P., Maciel, S.T., Berzuino, M.B., Hernandes, M.S., Fonoff,
6
E.T., Pagano, R.L., 2019. Parkinson’s disease and pain: Modulation of nociceptive
7
circuitry
8
https://doi.org/10.1016/j.expneurol.2019.02.007
in
a
rat
model
of
nigrostriatal
lesion.
Exp.
Neurol.
9
dos-Santos-Pereira, M., da-Silva, C.A., Guimarães, F.S., Del-Bel, E., 2016. Co-
10
administration of cannabidiol and capsazepine reduces L-DOPA-induced dyskinesia in
11
mice:
12
https://doi.org/10.1016/j.nbd.2016.06.013
Possible
mechanism
of
action.
Neurobiol.
Dis.
13
Faivre, F., Joshi, A., Bezard, E., Barrot, M., 2019. The hidden side of Parkinson’s disease:
14
Studying pain, anxiety and depression in animal models. Neurosci. Biobehav. Rev.
15
https://doi.org/10.1016/j.neubiorev.2018.10.004
16
Fil, A., Cano-de-la-Cuerda, R., Muñoz-Hellín, E., Vela, L., Ramiro-González, M., Fernández-
17
de-las-Peñas, C., 2013. Pain in Parkinson disease: A review of the literature. Park.
18
Relat. Disord. https://doi.org/10.1016/j.parkreldis.2012.11.009
19
Fujii, K., Koshidaka, Y., Adachi, M., Takao, K., 2019. Effects of chronic fentanyl
20
administration on behavioral characteristics of mice. Neuropsychopharmacol. Reports.
21
https://doi.org/10.1002/npr2.12040
22
Gee, L.E., Chen, N., Ramirez-Zamora, A., Shin, D.S., Pilitsis, J.G., 2015. The effects of
23
subthalamic deep brain stimulation on mechanical and thermal thresholds in 6OHDA-
24
lesioned rats. Eur. J. Neurosci. https://doi.org/10.1111/ejn.12992
25
Gerdelat-Mas, A., Simonetta-Moreau, M., Thalamas, C., Ory-Magne, F., Slaoui, T., Rascol,
26
O., Brefel-Courbon, C., 2007. Levodopa raises objective pain threshold in Parkinson’s
27
disease:
28
https://doi.org/10.1136/jnnp.2007.120212
A
RIII
reflex
study.
J.
Neurol.
Neurosurg.
Psychiatry.
29
Gomes, M.Z., Raisman-Vozari, R., Del Bel, E.A., 2008. A nitric oxide synthase inhibitor
30
decreases 6-hydroxydopamine effects on tyrosine hydroxylase and neuronal nitric
31
oxide
synthase
in
the
rat
nigrostriatal
pathway.
Brain
Res.
22 1
https://doi.org/10.1016/j.brainres.2008.01.088
2
Gómez-Paz, A., Drucker-Colín, R., Milán-Aldaco, D., Palomero-Rivero, M., Ambriz- Tututi,
3
M., 2018. Intrastriatal Chromospheres’ Transplant Reduces Nociception in
4
Hemiparkinsonian Rats.
5
https://doi.org/10.1016/j.neuroscience.2017.08.052
6 7
Neuroscience.
Guindon, J., Hohmann, A., 2009. The Endocannabinoid System and Pain. CNS Neurol. Disord. - Drug Targets. https://doi.org/10.2174/187152709789824660
8
Hagelberg, N., Jääskeläinen, S.K., Martikainen, I.K., Mansikka, H., Forssell, H., Scheinin, H.,
9
Hietala, J., Pertovaara, A., 2004. Striatal dopamine D2 receptors in modulation of pain
10
in humans: A review. Eur. J. Pharmacol. https://doi.org/10.1016/j.ejphar.2004.07.024
11
Hagelberg, N., Martikainen, I.K., Mansikka, H., Hinkka, S., Någren, K., Hietala, J., Scheinin,
12
H., Pertovaara, A., 2002. Dopamine D2 receptor binding in the human brain is
13
associated with the response to painful stimulation and pain modulatory capacity.
14
Pain. https://doi.org/10.1016/S0304-3959(02)00121-5
15
Hosseinzadeh, H., Mazaheri, F., Ghodsi, R., 2017. Pharmacological effects of a synthetic
16
quinoline, a hybrid of tomoxiprole and naproxen, against acute pain and inflammation
17
in
18
https://doi.org/10.22038/ijbms.2017.8588
19 20
mice:
a
behavioral
and
docking
study.
Iran.
J.
Basic
Med.
Sci.
Jara-Oseguera, A., Simon, S., Rosenbaum, T., 2010. TRPV1: On the Road to Pain Relief. Curr. Mol. Pharmacol. https://doi.org/10.2174/1874467210801030255
21
Jensen, B., Chen, J., Furnish, T., Wallace, M., 2015. Medical Marijuana and Chronic Pain: a
22
Review of Basic Science and Clinical Evidence. Curr. Pain Headache Rep.
23
https://doi.org/10.1007/s11916-015-0524-x
24 25 26
Kaneko, Y., Szallasi, A., 2014. Transient receptor potential (TRP) channels: A clinical perspective. Br. J. Pharmacol. https://doi.org/10.1111/bph.12414 Kaszuba, B.C., Walling, I., Gee, L.E., Shin, D.S., Pilitsis, J.G., 2017. Effects of subthalamic
27
deep brain stimulation with duloxetine on mechanical and thermal thresholds
28
6OHDA
29
https://doi.org/10.1016/j.brainres.2016.10.025
30
lesioned
rats.
in
Brain Res.
Kim, K.H., Abdi, S., 2014. Rediscovery of nefopam for the treatment of neuropathic pain.
23 1
Korean J. Pain. https://doi.org/10.3344/kjp.2014.27.2.103
2
Kinsey, S.G., Long, J.Z., O’Neal, S.T., Abdullah, R.A., Poklis, J.L., Boger, D.L., Cravatt,
3
B.F., Lichtman, A.H., 2009. Blockade of Endocannabinoid-Degrading Enzymes
4
Attenuates
5
https://doi.org/10.1124/jpet.109.155465
Neuropathic
Pain.
J.
Pharmacol.
Exp.
Ther.
6
Kinsey, S.G., Naidu, P.S., Cravatt, B.F., Dudley, D.T., Lichtman, A.H., 2011. Fatty acid
7
amide hydrolase blockade attenuates the development of collagen-induced arthritis
8
and
9
https://doi.org/10.1016/j.pbb.2011.06.022
10 11
related
thermal
hyperalgesia
in
mice.
Pharmacol.
Biochem.
Behav.
Le Bars, D., Gozariu, M., Cadden, S.W., 2001. Animal models of nociception. Pharmacol. Rev.
12
Leitl, M.D., Potter, D.N., Cheng, K., Rice, K.C., Carlezon, W.A., Negus, S.S., 2014.
13
Sustained pain-related depression of behavior: Effects of intraplantar formalin and
14
complete freund’s adjuvant on intracranial self-stimulation (ICSS) and endogenous
15
kappa opioid biomarkers in rats. Mol. Pain. https://doi.org/10.1186/1744-8069-10- 62
16
Leweke, F.M., Piomelli, D., Pahlisch, F., Muhl, D., Gerth, C.W., Hoyer, C., Klosterkötter, J.,
17
Hellmich, M., Koethe, D., 2012. Cannabidiol enhances anandamide signaling and
18
alleviates
19
https://doi.org/10.1038/tp.2012.15
psychotic
symptoms
of
schizophrenia.
Transl.
Psychiatry.
20
Ligresti, A., De Petrocellis, L., Di Marzo, V., 2016. From Phytocannabinoids to Cannabinoid
21
Receptors and Endocannabinoids: Pleiotropic Physiological and Pathological Roles
22
Through
23
https://doi.org/10.1152/physrev.00002.2016
Complex
Pharmacology.
Physiol.
Rev.
24
Lunn, C. A., Fine, J. S., Rojas-Triana, A., Jackson, J. V., Fan, X., Kung, T. T., ... & Narula, S.
25
K., 2006. A novel cannabinoid peripheral cannabinoid receptor-selective inverse
26
agonist blocks leukocyte recruitment in vivo. Journal of Pharmacology and
27
Experimental Therapeutics. https://doi:10.1124/jpet.105.093500.
28
Magnusson, J.E., Fisher, K., 2000. The involvement of dopamine in nociception: The role of
29
D1
30
https://doi.org/10.1016/S0006-8993(99)02396-3
31
and
D2
receptors
in
the
dorsolateral
striatum.
Brain
Res.
Maione, S., 2006. Elevation of Endocannabinoid Levels in the Ventrolateral Periaqueductal
24 1
Grey through Inhibition of Fatty Acid Amide Hydrolase Affects Descending
2
Nociceptive Pathways via Both Cannabinoid Receptor Type 1 and Transient Receptor
3
Potential
4
https://doi.org/10.1124/jpet.105.093286
Vanilloid
Type-1
Re.
J.
Pharmacol.
Exp.
Ther.
5
Manning, B.H., Merin, N.M., Meng, I.D., Amaral, D.G., 2018. Reduction in Opioid- and
6
Cannabinoid-Induced Antinociception in Rhesus Monkeys after Bilateral Lesions of
7
the Amygdaloid Complex. J. Neurosci. https://doi.org/10.1523/jneurosci.21-20-
8
08238.2001
9
Martin, W.J., Coffin, P.O., Attias, E., Balinsky, M., Tsou, K., Michael Walker, J., 1999.
10
Anatomical basis for cannabinoid-induced antinociception as revealed by intracerebral
11
microinjections. Brain Res. https://doi.org/10.1016/S0006- 8993(98)01368-7
12
McPartland, J.M., Duncan, M., Di Marzo, V., Pertwee, R.G., 2015. Are cannabidiol and ∆9-
13
tetrahydrocannabivarin negative modulators of the endocannabinoid system? A
14
systematic review. Br. J. Pharmacol. https://doi.org/10.1111/bph.12944
15
Mlost, J., Wąsik, A., Starowicz, K., 2019. Role of endocannabinoid system in dopamine
16
signalling within the reward circuits affected by chronic pain. Pharmacol. Res.
17
https://doi.org/10.1016/j.phrs.2019.02.029
18
Moran, M.M., Szallasi, A., 2018. Targeting nociceptive transient receptor potential channels
19
to
treat
chronic
pain:
current
20
https://doi.org/10.1111/bph.14044
state
of
the
field.
Br.
J.
Pharmacol.
21
Nascimento, G.C., Bariotto-dos-Santos, K., Leite-Panissi, C.R.A., Del-Bel, E.A., Bortolanza,
22
M., 2018. Nociceptive Response to l-DOPA-Induced Dyskinesia in Hemiparkinsonian
23
Rats. Neurotox. Res. https://doi.org/10.1007/s12640-018-9896- 0
24
Nascimento, G.C., Rizzi, E., Gerlach, R.F., Leite-Panissi, C.R.A., 2013. Expression of MMP-
25
2 and MMP-9 in the rat trigeminal ganglion during the development of
26
temporomandibular
27
https://doi.org/10.1590/1414-431X20133138
joint
inflammation.
Brazilian
J.
Med.
Biol.
Res.
28
Nègre-Pagès, L., Regragui, W., Bouhassira, D., Grandjean, H., Rascol, O., 2008. Chronic pain
29
in Parkinson’s disease: The cross-sectional French DoPaMiP survey. Mov. Disord.
30
https://doi.org/10.1002/mds.22142
31
Paxinos, G., Franklin, K.B.J., 2001. Mouse brain in stereotaxic coordinates, Academic Press.
25
https://doi.org/10.1016/S0306-4530(03)00088-X
1 2
Pereira Do Carmo, G., Stevenson, G.W., Carlezon, W.A., Negus, S.S., 2009. Effects of pain-
3
and analgesia-related manipulations on intracranial self-stimulation in rats: Further
4
studies on
5
https://doi.org/10.1016/j.pain.2009.04.010
6
pain-depressed
behavior.
Pain.
Pertwee, R.G., 2008a. The diverse CB1 and CB2 receptor pharmacology of three plant
7
cannabinoids:
8
tetrahydrocannabivarin. Br. J. Pharmacol. https://doi.org/10.1038/sj.bjp.0707442.
9
delta9-tetrahydrocannabinol,
anandamide
11
1600.2008.00108.x
and
neuropathic,
14
3959(99)00085-8
beyond.
Addict.
surgical
and
central
disease
17
https://doi.org/10.1002/mds.23135
19 20
Biol.
https://doi.org/10.1111/j.1369-
pain.
Pain.
https://doi.org/10.1016/S0304-
Politis, M., Wu, K., Molloy, S., Bain, P.G., Chaudhuri, K.R., Piccini, P., 2010. Parkinson’s
16
18
delta9-
Pitcher, G.M., Ritchie, J., Henry, J.L., 1999. Nerve constriction in the rat: Model of
13
15
and
Pertwee, R.G., 2008b. Ligands that target cannabinoid receptors in the brain: from THC to
10
12
cannabidiol
Price,
J.L.,
symptoms:
Drevets,
The
W.C.,
patient’s
2010.
perspective.
Neurocircuitry
of
Mov.
mood
Disord.
disorders.
Neuropsychopharmacology. https://doi.org/10.1038/npp.2009.104 Rácz, I., Nent, E., Erxlebe, E., Zimmer, A., 2015. CB1 receptors modulate affective behaviour
21
induced
by
neuropathic
pain.
22
https://doi.org/10.1016/j.brainresbull.2015.03.005
Brain
Res.
Bull.
23
Rana, A.Q., Qureshi, A.R.M., Rehman, N., Mohammed, A., Sarfraz, Z., Rana, R., 2017.
24
Disability from pain directly correlated with depression in Parkinson’s disease. Clin.
25
Neurol. Neurosurg. https://doi.org/10.1016/j.clineuro.2017.05.022
26 27
Ross, R.A., 2003. Anandamide and vanilloid TRPV1 receptors. British journal of pharmacology. https://doi.org/10.1038/sj.bjp.0705467
28
Rubinstein, M., Mogil, J.S., Japon, M., Chan, E.C., Allen, R.G., Low, M.J., 2002. Absence of
29
opioid stress-induced analgesia in mice lacking beta-endorphin by site- directed
30
mutagenesis. Proc. Natl. Acad. Sci. https://doi.org/10.1073/pnas.93.9.3995
26 1
Russo, E.B., 2017. Cannabidiol Claims and Misconceptions: (Trends in Pharmacological
2
Sciences
38,
198-201;
2017).
3
https://doi.org/10.1016/j.tips.2016.12.004
Trends
Pharmacol.
Sci.
4
Schestatsky, P., Kumru, H., Valls-Solé, J., Valldeoriola, F., Marti, M.J., Tolosa, E., Chaves,
5
M.L., 2007. Neurophysiologic study of central pain in patients with Parkinson disease.
6
Neurology.https://doi.org/10.1212/01.wnl.0000295669.12443.d3
7
Seppi, K., Ray Chaudhuri, K., Coelho, M., Fox, S.H., Katzenschlager, R., Perez Lloret, S.,
8
Weintraub, D., Sampaio, C., Chahine, L., Hametner, E.M., Heim, B., Lim, S.Y.,
9
Poewe, W., Djamshidian-Tehrani, A., 2019. Update on treatments for nonmotor
10
symptoms of Parkinson’s disease—an evidence-based medicine review. Mov. Disord.
11
https://doi.org/10.1002/mds.27602
12
Shohami, E., Cohen-Yeshurun, A., Magid, L., Algali, M., Mechoulam, R., 2011.
13
Endocannabinoids
14
https://doi.org/10.1111/j.1476-5381.2011.01343.x
15
18 19
traumatic
brain
injury.
Br.
J.
Pharmacol.
Starowicz, K., Finn, D.P., 2017. Cannabinoids and Pain: Sites and Mechanisms of Action, in:
16 17
and
Advances
in
Pharmacology.
https://doi.org/10.1016/bs.apha.2017.05.003 Stocchi, F., Torti, M., 2017. Constipation in Parkinson’s Disease. Int. Rev. Neurobiol. https://doi.org/10.1016/bs.irn.2017.06.003
20
Szallasi, A., Cortright, D.N., Blum, C.A., Eid, S.R., 2007. The vanilloid receptor TRPV1: 10
21
years from channel cloning to antagonist proof-of-concept. Nat. Rev. Drug Discov.
22
https://doi.org/10.1038/nrd2280
23
Taniguchi, W., Nakatsuka, T., Miyazaki, N., Yamada, H., Takeda, D., Fujita, T., Kumamoto,
24
E., Yoshida, M., 2011. In vivo patch-clamp analysis of dopaminergic antinociceptive
25
actions
26
https://doi.org/10.1016/j.pain.2010.09.034
on
substantia
gelatinosa
neurons
in
the
spinal
cord.
Pain.
27
Taylor, A.M.W., Becker, S., Schweinhardt, P., Cahill, C., 2016. Mesolimbic dopamine
28
signaling in acute and chronic pain: Implications for motivation, analgesia, and
29
addiction. Pain. https://doi.org/10.1097/j.pain.0000000000000494
30 31
Taylor, A.M.W., 2018. Corticolimbic circuitry in the modulation of chronic pain and substance
abuse.
Prog
Neuropsychopharmacol
Biol.
Psychiatry.
27 1 2
https://doi.org/10.1016/j.pnpbp.2017.05.009 Turcotte, C., Blanchet, M.R., Laviolette, M., Flamand, N., 2016. The CB2 receptor and its
3
role
4
https://doi.org/10.1007/s00018-016-2300-4.
5 6
as
a
regulator
of
inflammation.
Cell
Mol.
Life
Sci.
Toth, A., Blumberg, P.M., Boczan, J., 2009. Anandamide and the vanilloid receptor (TRPV1). Vitam Horm https://doi.org/10.1016/S0083-6729(09)81015-7
7
Walker, J.M., Huang, S.M., Strangman, N.M., Tsou, K., Sanudo-Pena, M.C., 2002. Pain
8
modulation by release of the endogenous cannabinoid anandamide. Proc. Natl. Acad.
9
Sci. https://doi.org/10.1073/pnas.96.21.12198
10 11 12 13
Wasner, G., Deuschl, G., 2012. Pains in Parkinson disease-many syndromes under one umbrella. Nat. Rev. Neurol. https://doi.org/10.1038/nrneurol.2012.54 Wood, P.B., 2008. Role of central dopamine in pain and analgesia. Expert Rev.Neurother. https://doi.org/10.1586/14737175.8.5.781
14
Xiao, X., Zhang, Y.Q., 2018. A new perspective on the anterior cingulate cortex and affective
15
pain. Neurosci Biobehav Rev. https://doi.org/10.1016/j.neubiorev.2018.03.022
16
Yoshimura, N., Kawamura, M., Masaoka, Y., Homma, I., 2005. The amygdala of patients
17
with Parkinson's disease is silent in response to fearful facial expressions.
18
Neuroscience. https://doi.org/10.1016/j.neuroscience.2004.09.054
19
Zengin-Toktas, Y., Ferrier, J., Durif, F., Llorca, P.M., Authier, N., 2013. Bilateral lesions of
20
the
nigrostriatal
pathways
are
associated
21
hypersensitivity
22
https://doi.org/10.1016/j.neures.2013.05.003
in rats. Neurosci.
with
chronic
mechanical
pain
Res.
23
Zhao, Y.-Q., Wang, H.-Y., Yin, J.-B., Sun, Y., Wang, Y., Liang, J.-C., Guo, X.-J.,Tang, K.,
24
Wang, Y.-T., 2017. The Analgesic Effects of Celecoxib on the Formalin- induced
25
Short- and Long-term Inflammatory Pain. Pain Physician.
26 27
Zygmunt, P.M., Julius, D., Di Marzo, V., Högestätt, E.D., 2000. Anandamide - The other side of the coin. Trends Pharmacol. Sci. https://doi.org/10.1016/S0165- 6147(99)01430-3
28 29 30 31
Figure legends Figure 1. Time-course of 6-OHDA-induced hyperalgesia and allodynia responses. (A)
28 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36
Photomicrographs of coronal sections from brains at different positions relative to Bregma illustrating the loss of TH + fibers in the rostral (A’), medial (A’’) and caudal (A’’’) striatum. 10x, Bar=50um. (B-D) Two-way analysis of variance (repeated measure) with Bonferroni’s post-hoc test for Basal measures (1 day before surgery: -1) and for 6-OHDA-treated rats 1, 7, 14 and 21 days after surgery. Decrease in thermal (Hot Plate - B, Tail Flick - C, Acetoneinduced cold stimulus - D) and mechanical (Von Frey - E) withdrawal thresholds in 6-OHDAtreated rats have distinct temporal profiles. Data represent the mean ± SEM. *p < 0.05 from Basal (-1) measure, n = 8/test. Figure 2. Antinociceptive effects of CBD on experimental parkinsonism. Antinociceptive effects induced by CBD (10, 30, and 100 mg/kg), in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C), and Von Frey tests (D). Data represent the mean ± SEM. *p < 0.05 from VEH group, #p < 0.05 from CBD100 group; +p < 0.05 from MOR groups n = 8/group. Figure 3. Antinociceptive effects of chronic therapy with CBD on experimental parkinsonism. Antinociceptive effects induced by chronic injection of CBD (10 mg/kg), in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C), and Von Frey tests (D). Data represent the mean ± SEM. *p < 0.05 from VEH group, #p < 0.05 from CBD100 group; +p < 0.05 from MOR groups n = 8/group. Figure 4. Antinociceptive effects of URB597 (URB), AM251 (AM), capsazepine (CPZ) and SCH336 (SCH) on experimental parkinsonism. Antinociceptive effects induced by URB (0.5 mg/kg), AM251 (1 mg/kg), CPZ (5 mg/kg) and SCH (2 mg/kg), in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C), and Von Frey tests (D). Data represent the mean ± SEM. n = 8/group. Figure 5. Involvement of CB1, CB2, FAAH and TRPV1 in the antinociceptive effects induced by CBD on experimental parkinsonism: proposal mechanisms. Effects of the pretreatment with FAAH inhibitor URB (0.5 mg/kg); CB1 receptor antagonist AM251 (1 mg/kg) and TRPV1 antagonist CPZ (5 mg/kg) followed by CBD (10 mg/kg) in the Hot Plate (A), Tail Flick (B), acetone-induced cold stimulus (C) and Von Frey tests (D). Data represent the mean ± SEM. *p < 0.05 from VEH group, #p < 0.05 from CBD10 group n = 5-7/group.
1
Highlights •
The CBD treatment decreases hyperalgesia and allodynia in experimental parkinsonism;
•
The inverse agonist of the CB1 receptor prevents the antinociceptive effect of CBD;
•
FAAH inhibitor or TRPV1 antagonist potentiates the CBD antinociceptive effect