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Brain-derived neurotrophic factor in substance use disorders: A systematic review and meta-analysis
Accepted Manuscript Title: Brain-derived neurotrophic factor in substance use disorders: A systematic review and meta-analysis Authors: Felipe Ornell, Fernanda Hansen, Felipe Barreto Schuch, Fernando Pezzini Rebelatto, Ana Laura Tavares, Juliana Nichterwitz Scherer, Andrei Garziera Valerio, Flavio Pechansky, Felix Henrique Paim Kessler, Lisia von Diemen PII: DOI: Reference:
S0376-8716(18)30725-7 https://doi.org/10.1016/j.drugalcdep.2018.08.036 DAD 7161
To appear in:
Drug and Alcohol Dependence
Received date: Revised date: Accepted date:
15-6-2018 23-8-2018 29-8-2018
Please cite this article as: Ornell F, Hansen F, Schuch FB, Pezzini Rebelatto F, Tavares AL, Scherer JN, Valerio AG, Pechansky F, Paim Kessler FH, von Diemen L, Brain-derived neurotrophic factor in substance use disorders: A systematic review and meta-analysis, Drug and Alcohol Dependence (2018), https://doi.org/10.1016/j.drugalcdep.2018.08.036 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. 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.
Brain-derived neurotrophic factor in substance use disorders: A systematic review and meta-analysis*
Felipe Ornell a, b, f, Fernanda Hansen a, c, Felipe Barreto Schuch d, e, Fernando Pezzini Rebelatto a
, Ana Laura Tavares a, Juliana Nichterwitz Scherer
a, b
, Andrei Garziera Valerio a, Flavio
Pechansky a, b, Felix Henrique Paim Kessler a, b, Lisia von Diemen a, b a
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Center for Drug and Alcohol Research and Collaborating Center on Alcohol and Drugs,
Hospital de Clínicas de Porto Alegre, Federal University of Rio Grande do Sul, Rua Professor b
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Álvaro Alvim, 400, 90420-020, Porto Alegre, RS, Brazil
Postgraduate Program in Psychiatry and Behavioral Science, Federal University of Rio
Grande do Sul, Porto Alegre, RS, Brazil c
Department of Nutrition, Health Sciences Center, Federal University of Santa Catarina,
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Florianópolis, SC, Brazil
Hospital de Clínicas de Porto Alegre, Porto Alegre, RS, Brazil
e
Universidade La Salle, Porto Alegre, RS, Brazil
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d
Correspondence
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Felipe Ornell
Center for Drug and Alcohol Research and Collaborating Center on Alcohol and Drugs
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Hospital de Clínicas de Porto Alegre, Federal University of Rio Grande do Sul
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Rua Professor Álvaro Alvim, 400, 90420-020, Porto Alegre, RS, Brazil Phone: +55 51 33596488
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[email protected]; [email protected]
Highlights Patients with active drug use show lower serum brain-derived neurotropic factor (BDNF) than controls. There is no difference between BDNF levels of abstinence users and controls.
Alcohol and crack/cocaine users showed lower levels of serum BDNF than controls. Sex, age, and age of the first use influence BDNF levels in subjects with substance use disorders (SUDs).
Abstract
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Background: Brain-derived neurotrophic factor (BDNF) is associated with several neurodegenerative and psychiatric disorders. It is not clear, however, whether BDNF levels are
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modified in substance use disorders (SUDs).
Methods: We conducted a systematic search of electronic databases to identify studies comparing peripheral plasma or serum BDNF levels in adults with SUDs vs. non-user controls.
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Forty studies were included in the meta-analysis involving a total of 2238 participants with
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SUDs and 2574 controls.
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Results: After trim and fill adjustment, current drug users presented lower serum BDNF levels
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(SMD= -0.99, 95%CI -1.40 to -0.58, I2=95.9) than non-user controls. However, this difference
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disappears during withdrawal. Studies using serum or plasma BDNF samples have shown different results. Subgroup analysis revealed lower levels of serum BDNF in alcohol users
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(SMD= -0.70, 95%CI -1.15 to -0.25, I2=89.81) and crack/cocaine users (SMD= -1.78, 95%CI -2.92 to -0.65, I2=97.59) than controls. Meta-regression analysis revealed that gender, age, and
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age of first use moderate the effects of drug use in peripheral BDNF levels. Conclusions: Peripheral BDNF levels are decreased in the serum, but not the plasma, of active
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drug users. Altogether, these findings suggest that BDNF levels may be related to acute use and addiction severity and also point to BDNF’s potential utility as a biomarker in this population.
Keywords: Biomarker; Substance Use Disorder; Brain-Derived Neurotrophic Factor; Meta-
Analysis; Alcohol; Crack-Cocaine
1. Introduction Drug addiction is a chronic disorder characterized by a set of cognitive, behavioral, and physiological symptoms that include continued use despite negative consequences as well as
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high rates of relapse (American Psychiatric Association, 2013; Wikler, 1973). Although it has been postulated that the chronic use of psychoactive-substances (PAS) entails changes in brain
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function and structure which lead to dysfunctional neuroadaptations (whether transitory or
permanent), the period of use and quantities necessary to provoke such alterations are unknown
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(George and Koob, 2010; Seger, 2010; Volkow et al., 2011). A better understanding of these
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neuroadaptations may lead to analytical tools that characterize interindividual variability in
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drug abuse and treatment response (Büttner, 2011; Mendelson et al., 2011; Seger, 2010; Sinha,
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2011).
In recent decades, significant advances have been made in the psychobiology of
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addictive disorders, which have reinforced the idea that addiction is a chronic disease characterized by structural and functional alterations in different brain systems (George and
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Koob, 2010; George et al., 2012; Goldstein and Volkow, 2002; Koob, 1992, 2000; Koob et al., 2004; Leshner, 1997; Sinha, 2011; Volkow et al., 2010). Brain-derived neurotrophic factor
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(BDNF) has been studied as a potential biomarker in several psychiatric disorders, including substance use disorder (SUD) (Autry and Monteggia, 2012; Nagahara and Tuszynski, 2011).
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BDNF is the most abundant neurotrophin in the brain and is related to cell growth and differentiation, synaptic connectivity and neuroplasticity, modulation of neurotransmission and neuronal repair, neurogenic and neurodegenerative processes (Binder and Scharfman, 2004; Huang and Reichardt, 2001), and learning and memory (Bekinschtein et al., 2008). Pre-clinical and clinical evidence indicates that neurotrophins are involved in neuroadaptation to PAS as
well as different processes related to the mediation of behavioral effects including drug sensitization, craving, and relapse (Castrén, 2004; Grimm et al., 2003; Miguel-Hidalgo, 2009; Schmidt and Duman, 2010; Volkow et al., 2015). Since it freely crosses the blood-brain barrier, and its peripheral concentration is strongly correlated with concentrations found in the central nervous system, peripheral BDNF has been widely assessed in clinical studies (Karege et al.,
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2002; Pan et al., 1998).
Previous studies evaluating BDNF levels in individuals with SUDs have found different
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and even controversial results, which indicates that the variations could be related to drug type, usage patterns at the moment of testing, and stage of dependence (Angelucci et al., 2010a;
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Cavus et al., 2012; Corominas-Roso et al., 2015; D'Sa et al., 2011; Huang et al., 2011; Ke et
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al., 2014; Pedraz et al., 2015; Roncero et al., 2016; Sordi et al., 2014). In healthy social drinkers
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submitted to an acute stress protocol, family history of alcohol use disorder and age at first
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alcohol use were also related to a decrease in serum BDNF (Sharma et al., 2017). However, these studies have mostly involved small heterogeneous samples and
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evaluated only one type of drug, preventing comparison of BDNF levels between different substance users. To the authors’ knowledge, no systematic review has meta-analyzed the
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difference between BDNF levels in individuals with SUDs and controls. Therefore, the present study aims to: 1) compare peripheral serum and plasma levels of BDNF between individuals
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with SUDs and non-user controls, 2) determine whether this difference occurs in different drug types and subtypes, during withdrawal, and in blood fractions through subgroup analysis, and
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3) explore, using meta-regressions, potential moderating factors. 2. Methods and materials The protocol developed for this meta-analytic review followed the recommendations of the PRISMA statement (Moher et al., 2009). Each element of the search, the selection of eligible studies (FO and AGV), and data extraction (FPR and ALT) were performed by two
authors. Disagreements were resolved through consensus and the opinion of a third author (LVD). 2.1 Search strategy We conducted a systematic search of all potentially eligible references, without language restrictions, in the PubMed/MEDLINE, EMBASE and PsycINFO databases. The
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search was performed on November 21, 2017. This search strategy was augmented by manually tracking the reference list of all retrieved publications to identify additional eligible studies.
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The search strategy is described in the supplementary material1. 2.2 Study selection
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The included studies (1) evaluated individuals diagnosed with an SUD for alcohol or
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an illicit drug according the DSM-5 or the ICD-10 (American Psychiatric Association, 2013;
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WHO, 2013), (2) compared BDNF levels between individuals with SUDs and non-user
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controls or were clinical trials using baseline data before drug treatment, and (3) measured peripheral BDNF levels. Excluded studies (1) involved participants with clinical or
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comorbidities (e.g., depression, HIV, Parkinson's disease, alzheimer or dementia) and (2) did not present original data (e.g., letters, posters, reviews, case reports, opinion pieces, or
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commentary). Studies with prescribed drugs (e.g., benzodiazepines) were not included in the search due to the difficulty of differentiating prescribed use vs. dependence and the high
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prevalence of primary psychiatric disorders. The authors came to a consensus on the final inclusion of references.
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2.3 Data extraction Two reviewers (FPR and ALT) independently extracted data on the control and SUD
groups (sample size, mean and standard deviation) from all included articles to prevent
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Supplementary material can be found by accessing the online version of this paper at http://dx.doi.org and by entering doi:
potential errors. Data entry discrepancies were double-checked by the reviewers against the original published data, and a consensus was reached. We extracted information regarding the primary drug, psychiatric comorbidities, scales and/or questionnaires used to evaluate psychiatric symptoms or disorders, BDNF levels, biological sample used to measure peripheral BDNF levels (plasma vs. serum), and time of withdrawal when the BDNF levels were
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measured. Information about sex, mean age, age of first use, years of use, tobacco use, body mass index (BMI), and clinical diseases were also extracted. When necessary data were
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unavailable in an included study, requests were emailed to the corresponding author on two different occasions. In cases where multiple reports pertained to the same participants, we
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included only the largest data set. When the data were available only in graphs, they were
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2.4 Assessment of methodological quality
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extracted using Plot Digitizer software, version 2.6.8 (http://plotdigitizer.sourceforge.net/).
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The quality of the studies included in the systematic review was evaluated using the nine-item Newcastle-Ottawa Scale (NOS) for case-control studies (Wells et al., 2014).
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However, item three (“Equivalent non-response rate between groups”) was not used in quality assessment due to the purposes of this review. For comparability questions, age was set a priori
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as the most important matching or adjustment factor. The articles were evaluated with the Cochrane Collaboration tool, which assesses the risk of bias of randomized clinical trials in six
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domains (Cochrane Handbook) (Higgins et al., 2011). 2.5 Meta-analysis
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We conducted random effect meta-analyses due to the anticipated heterogeneity across
studies. The analyses were performed using Comprehensive Meta-Analysis software version 3. The meta-analyses were conducted in three steps. First, a comparative meta-analysis was used to investigate differences in the BDNF levels of drug users vs. non-user controls. The standardized mean deviation (SMD) and the 95% confidence intervals (CI) of the effect size of
the difference were compared separately between serum and plasma BDNF levels. Second, we calculated the differences according to 1) withdrawal time (we considered withdrawal groups to be those with a minimum of 6 days of abstinence) and 2) drug subtype (cocaine or crack/cocaine, methamphetamine, alcohol, heroin, opiates, ketamine, cannabis, amphetamine derivative (±)-3, 4 methylenedioxymethamphetamine (MDMA/escstasy)) in users vs. non-user
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controls in subgroup analyses. Third, we investigated potential moderators of BDNF levels
with meta-regression analyses. The potential moderators of interest were mean age, percentage
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of males, withdrawal length, and years of drug use. We assessed heterogeneity using the I²
statistic for each analysis. Publication bias was verified with the Begg-Mazumdar and Egger
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tests and adjusted using the Trim and Fill technique. The trim and fill method is a rank-based
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data augmentation technique that can be used to estimate the number of studies missing from
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a meta-analysis, adjust the effect removing the most extreme results on one side of the funnel
Duval and Tweedie, 2000).
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3. Results
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plot, and augment the observed data until the funnel plot is more symmetric (Duval et al., 2000;
A total of 4175 studies were identified as potentially relevant, of which 91 were selected
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for review. After reading these papers in full and checking their reference lists for further relevant publications, a total of 50 articles were considered to meet the eligibility criteria and
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were included in this systematic review, of which 40 were included in the meta-analysis. Three papers were identified in hand-searches and were added to the analysis (Figure 1).
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3.1 Study and participants’ characteristics Forty unique studies with 58 arms were included (44 serum samples and 14 plasma
samples), totaling 2575 participants with SUDs and 2425 controls. The sample size of drug users ranged from 9 to 378. Thirteen studies evaluated BDNF levels in alcohol users (n=672), nine in crack/cocaine users (n=515), nine in opiate users (n=685), two in cannabis users (n=35),
five in methamphetamine users (n=3535), two in ketamine users (n=110), and one in MDMA/ecstasy users (n=23). Fourteen arms used data from plasma samples to measure BDNF levels (n=994, 399 in active use and 595 in withdrawal), while 44 used serum samples (n=2171, 1255 in active use and 559 in withdrawal). Out of the 40 studies included in the meta-analysis, 20 excluded subjects with psychiatric comorbidities, 13 reported the existence of
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comorbidities, and 7 did not present this information. Of the 40 studies that integrated this meta-analysis, 11 included only men, 27 included men and women, and 2 studies evaluated
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only women. The time of consumption among the users was: Alcohol = 15.32 (7.22), Heroin = 11.28 (7.60), Crack / cocaine = 7.76 (8.55), Methamphetamine = 9 (7.62), and MDMA =
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3.08. Further details of the included studies are summarized in Table 1.
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3.2 Study quality
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3.2.1 Quality assessment with the NOS. Two authors (FH and AS) conducted the quality
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assessment of the studies using The Newcastle-Ottawa Scale (NOS). This instrument is broadly used to assess the quality of non-randomized studies in meta-analyses (Wells et al., 2000,
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2011). The scores range from 0 to 9, with lower scores indicating lower study quality. In our paper, we classified the studies included from 0 to 8 stars because we believed the question
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regarding "non-response rate" did not apply to any of the studies, since there was no comparison between groups in this matter. Studies with quality scores lower than 3 were
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considered of low quality (Wu et al., 2015). According to NOS, the studies included presented a good quality evaluation (mean = 6.45, SD = 1.01). The quality assessment details can be
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found in the supplementary materials 2. 3.2.2 Quality assessment with the Cochrane Collaboration’s Risk of Bias Tool. Although none of the eligible studies presented a high risk of bias, one had an uncertain
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Supplementary material can be found by accessing the online version of this paper at http://dx.doi.org and by entering doi:
risk of bias for allocation concealment and selective reporting (D'Souza et al., 2009), while another had an uncertain risk of bias for random sequence generation (Geisel et al., 2016). The quality assessment details can be found in the supplementary materials 3. 3.3 Meta-analyses We investigated BDNF levels in plasma or serum separately as different subgroups
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(Table 2 and Table 3). For each matrix, we investigated the specific role of current substance
use status (current use/withdrawal) and the drug subtype: alcohol, heroin, crack/cocaine,
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cannabis, ketamine, MDMA/ecstasy, or Methamphetamine. Powder cocaine and crack cocaine originate from the same active principle. Although the route of administration (inhaled and
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smoked) changes the pharmacokinetics of the drug in the body, the pharmacodynamics are very
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similar (Cone, 1995). Thus, we chose to analyze these substances together according to the
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class of substance independent of the route of administration. We also investigated the role of
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drug action and drug subtype for current users and those in withdrawal separately and did the same for both serum and plasma BDNF levels. The subgroup analyses are detailed below
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(Table 2 and Table 3). 3.4 Serum BDNF levels
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The 45 subgroups included a pooled total of 2171 blood samples from participants with SUDs and 2484 from controls, and significant differences in BDNF levels were found between
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them (SMD=-0.30, 95%CI -0.62 to 0.02, p=0.02, I2=95.9). No significant publication bias was identified in the Begg-Mazumdar (tau=-0.13, p=0.20) or Egger tests (intercept=-5.10, p=0.01).
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However, the Duval and Tweedie trim and fill method was used to adjust the effect size to 0.99 (95%CI -1.40 to -0.58) by trimming eight studies. Detailed analysis of BDNF levels can be seen in Table 2; they will be briefly summarized below. 3.4.1 Subgroup analysis considering drug use status. Active users generally presented higher BDNF levels than controls (SMD= -0.62 95CI -1.18 to -0.06, p=0.02). After adjusting
for publication bias, decreased levels were found for serum BDNF levels in current users (SMD=-1.54, 95%CI -2.20 to -0.73) with eight studies trimmed. There were no differences in BDNF between drug users in withdrawal and controls (Table 2). 3.4.2 Subgroup analysis according to drug subtype. Compared to controls, lower BDNF levels were found in alcohol (SMD=-0.44, 95%CI -0.84 to -0.03, p=0.03, I2=89.81) and
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crack/cocaine users (SMD= -1.03, 95%CI -2.00 to -0.06 p=0.03, I2=97.59), although higher
levels were found in MDMA/Ecstasy users (SMD=5.72, 95%CI 4.35 to 7.09, p<0.001, I2=0).
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The adjusted differences between alcohol users and controls and between crack/cocaine users and controls were reduced to -0.70 (95%CI -1.15 to -0.25) and -1.78 (95%CI -2.92 to -0.65),
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respectively, after trimming 3 studies (Table 2).
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3.4.3 Subgroup analysis according to drug subtype among users in withdrawal. No
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significant differences were found among the BDNF serum levels of users in withdrawal, even
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when analyzed according to drug subtype (Table 2).
3.4.4 Subgroup analysis according to drug subtype among active users. Lower BDNF
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levels were found in alcohol (SMD=-0.59, 95%CI -1.03to -0.16, p=0.007, I2=84.38) and crack/cocaine users (SMD=-3,10, 95%CI -6.25 to 003, p=0.05, I2=99.01), while higher BDNF
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levels were found in ketamine users (SMD=1.13, 95%CI 0.53 to 2.22, p=0.001, I2=0). For active alcohol users, the effect size, adjusted for publication bias, was -0.83 (95%CI -1.31 to -
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0.35) after trimming two studies (Table 2). 3.5 Plasma BDNF levels
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Fourteen arms, including 994 blood samples from drug users and 679 from controls,
were compared; no significant differences were found between them (SMD=0.12, 95%CI -0.33 to 0.59, p=0.59, I2=94.49). Significant publication bias was identified in the Begg-Mazumdar (tau=0.38, p=0.04) and Egger tests (intercept=7.38, p=0.01). However, adjustments with the Duval and Tweedie trim and fill method were not made. A detailed analysis of plasma BDNF
levels can be seen in Table 3, and they are briefly summarized below. 3.5.1 Subgroup analysis according to drug use status. No significant differences were found in BDNF plasma level between active users and controls or between users in withdrawal and controls (Table 3). 3.5.2 Subgroup analysis according to drug subtype. Methamphetamine users had
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higher BDNF levels than controls (SMD=0.59, 95%CI 0.25 to 0.92, p=0.002, I2=0), and
crack/cocaine users also tended to have higher BDNF levels than controls (SMD=0.58, CI -
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0.06 to 1.23, p=0.07, l2=85.83), while heroin users had lower BDNF levels than controls (SMD= -0.86, 95%CI -1.14 to -0.58, p<0.001, I2=61.44) (Table 3).
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3.5.3 Subgroup analysis according to drug subtype among users in withdrawal. Lower
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BDNF levels were found among alcohol users (SMD=-0.87, 95%CI -1.29 to -0.44, p=0.001 l2=58.24), while higher BDNF levels were found among methamphetamine users (SMD=0.59,
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95%CI 0.25 to 0.92, p=0.001, I2=0). No analysis of this subgroup was adjusted for publication bias (Table 3).
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3.5.4 Subgroup analysis according to drug subtype among active users. In the crack/cocaine group, plasma BDNF was higher than controls (SMD=0.97, 95%CI, 0.48 to 1.47,
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p<0.001, I2=0), while in the heroin group it was lower (SMD=-1.01, 95%CI, -1.27 to -0.75
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p<0.001, I2=0); however, only one study was involved in the heroin analysis (Table 3). 3.6 Meta-regressions of potential moderators Among active users, sex (k=26, β=-0.009, 95%CI -0.01 to -0.00, p<0.001, R2=0.35),
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age (k=26, β=0.06 95%CI 0.00 to -0.12, p=0.02, R2=0.05) and age of the first use (k=10, β=0.49, 95%CI 0.20 to 0.79, p<0.001, R2=0.004) moderated the difference in BDNF levels between drug users and healthy controls. For users in withdrawal, the percent of males (k=23, β=-0.013, 95%CI -0.02 to -0.79, p=0.03, R2=0.08) was the only moderating variable for differences in BDNF levels among drug users and controls. The full details of the tested models
can be found in Table 4. 4. Discussion To the best of our knowledge, this is the first meta-analysis to compare peripheral BDNF levels in individuals with SUDs and non-user controls, and its main finding was that BDNF levels were lower in individuals with SUDs. Subanalysis showed that this reduction was
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related to active drug use, to alcohol and crack/cocaine use, and to serum samples (regardless
of drug type and active use or withdrawal). Age of first drug use, years of use, and male gender
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were found to be moderators in meta-regression analysis, supporting the hypothesis that BDNF levels are modified in individuals with SUDs.
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These results corroborate prior evidence that BDNF is a reliable biomarker for other
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psychiatric and neurodegenerative disorders (Angelucci et al., 2010b; Ciammola et al., 2007;
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Connor et al., 1997; Fernandes et al., 2014; Fernandes et al., 2011; Fernandes et al., 2015a;
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Fernandes et al., 2015b; Kishi et al., 2017; Krabbe et al., 2007; Lee et al., 2009; Munkholm et al., 2016; Murer et al., 2001; Polyakova et al., 2015; Qin et al., 2017; Salas-Magaña et al.,
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2017; Ventriglia et al., 2013; Yasutake et al., 2006; Zuccato and Cattaneo, 2009). For example, in bipolar disorder, depressive disorder, suicide, and schizophrenia, lower BDNF levels were
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observed in symptomatic phases than in euthymic subjects and healthy controls (Fernandes et al., 2014; Fernandes et al., 2011; Fernandes et al., 2015a; Fernandes et al., 2015b; Kishi et al.,
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2017; Munkholm et al., 2016; Polyakova et al., 2015; Salas-Magaña et al., 2017). The lack of significant difference in BDNF levels between cases in withdrawal and controls also agrees
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with previous evidence from other psychiatric disorders, where BDNF increased in asymptomatic periods to levels similar to those of controls (Fernandes et al., 2015a; Polyakova et al., 2015). Benzodiazepine-dependent patients with major depression diagnoses also showed similar BDNF levels compared to controls after completion of benzodiazepine withdrawal (Heberlein et al., 2010). However, in this same study, the BDNF levels of the patients were
increased in relation to the controls at baseline, diverging from our findings. This may be due to treatment with antidepressants, which may increase levels of BDNF (Shimizu et al., 2003). Nevertheless, while acute administration of benzodiazepine-like drugs generates a significant reduction in expression and level of BDNF in the hippocampus, repeated administration failed to influence BDNF expression in this brain area involved in drug-related plasticity (Licata et
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al., 2013).
The apparent contradiction in peripheral BDNF levels (plasma vs. serum) could be
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explained by different analytical mechanisms (Fernandes et al., 2015a; Fernandes et al., 2015b;
Fujimura et al., 2002) and phases of the disease, e.g., chronic exposure and withdrawal (Barker
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et al., 2015). These results were more consistent in crack/cocaine and alcohol users. In
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ketamine and MDMA/ecstasy users, the observed differences are not generalizable, since the
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analysis only included one study. These findings agree with previous pre-clinical and clinical
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studies (Barker et al., 2015). Studies with voluntary administration protocols have found that acute use of alcohol and cocaine transiently increases brain BDNF levels, although prolonged
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and excessive use lead to a robust reduction in BDNF expression. Nevertheless, after discontinuing use, animal studies indicate that BDNF levels return to baseline (Geoffroy and
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Noble, 2017; Graham et al., 2007; Li and Wolf, 2015; Logrip et al., 2015). Corroborating the hypothesis of transient drug-induced changes in BDNF, a study with rats submitted to a
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protocol of acute benzodiazepine administration verified that BDNF returned to near baseline levels after 40 hours (Huopaniemi et al., 2004). Pre-clinical and clinical studies suggest that
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BDNF could vary in different stages of drug use (e.g. acute, chronic, recovery) and could be associated with cumulative neurological damage (Gama et al., 2013; Grande et al., 2012; Kapczinski et al., 2014; Kapczinski et al., 2008). We also verified that peripheral BDNF levels varied according to the drug used, possibly due to factors such as the substance’s mechanism of action, the pattern and duration
of drug use, the user’s clinical and psychiatric comorbidities, and polysubstance use. In crack/cocaine users, for example, polysubstance use is very common: 77% and 85% report alcohol and tobacco consumption, respectively, in the last year (Bastos and Bertoni, 2014). Hilburn et al. found differences in serum BDNF levels among alcohol, cocaine, and methamphetamine users in relation to craving and duration of withdrawal (Hilburn et al., 2011).
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In young ecstasy users, who had fewer years of use and less frequent use, BDNF was higher at
baseline, which could indicate that they were in the initial phase of the disease (Zhang et al.,
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2014). Another study involving controlled administration of THC found higher serum BDNF in healthy controls than in subjects who had previously used cannabis (D'Souza et al., 2009),
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which indicates that recreational and chronic drug use have different effects on BDNF levels.
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Our meta-regressions showed that serum BDNF levels are moderated by sex, years of
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use, and age of first use, which corroborates previous findings that age and sex affect stored
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and circulating levels of BDNF in peripheral blood (Lommatzsch et al., 2005b). In psychiatric disorders, such as bipolar disorder and schizophrenia, meta-analyses have already shown that
Fernandes et al., 2015b).
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age and disease duration are associated with lower BDNF levels (Fernandes et al., 2011;
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It has been demonstrated that homeostatic functioning is disturbed during the course of mental disorders, and the central nervous system reorganizes itself. Although in the short term
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such reorganization can indicate a functional response mechanism, in the long term it can cause dysfunctional and pathological alterations (allostatic load), resulting in inappropriate response
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(Kapczinski et al., 2008; McEwen, 1998a, 1998b, 2000, 2002, 2003; McEwen and Wingfield, 2003). Moreover, in advanced stages, inappropriate responses can persist even during remission (Berk et al., 2011). In SUDs, the chronic use of PAS generates repeated overactivation of the dopaminergic pathway, leading to neuroadaptive mechanisms that may cause dysregulation in the brain reward system and in BDNF regulation.
The impact of age and sex in our results is in line with previous investigations of stored and circulating BDNF levels in peripheral blood (Lommatzsch et al., 2005b). Elderly women, for example, seem to have higher BDNF levels than men (Bus et al., 2011), which may result from sex-related hormonal differences. Estrogen, for instance, interferes in BDNF expression and causes variations in the menstrual cycle (Erickson et al., 2010; Lewis, 2006; Lommatzsch
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et al., 2005b). It is noteworthy that the only study with an all-female sample found higher
BDNF levels in crack/cocaine users during early withdrawal than in controls, and more than
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half of the women had some additional psychiatric comorbidity (Viola et al., 2014).
According to previous studies, the severity of drug dependence can also affect BDNF
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levels (Costa et al., 2011; D'Sa et al., 2011; Huang et al., 2011; Sordi et al., 2014). Even among
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individuals using the same substance, there are differences in BDNF levels according to the
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severity of drug use and prognosis (Corominas-Roso et al., 2015; Corominas-Roso et al., 2013;
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D'Sa et al., 2011; Scherer et al., 2015). In alcohol users, for example, significantly lower BDNF levels were found in individuals with delirium tremens than users without this condition and
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controls, and these levels persisted even after detoxification (Huang et al., 2011). In another study that followed patients for 180 days after detoxification, the serum BDNF levels of
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patients who maintained abstinence were higher than both baseline values and patients who relapsed during this period (Costa et al., 2011). Similarly, Scherer et al. found an association
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between higher BDNF levels and better clinical outcomes in crack users during detoxification (2015). Thus, during treatment, BDNF levels approaching those of controls may be associated
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with better clinical outcomes (Duman and Monteggia, 2006; Zuccato and Cattaneo, 2009). Moreover, studies with other psychiatric populations have also reported similar results: in bipolar patients, for example, different serum BDNF levels in the early and late stages have been reported. Our results also revealed differences in peripheral BDNF levels between serum and
plasma. Only two of the forty studies included in this investigation evaluated serum and plasma samples simultaneously, and they found intra-individual and intra-group variations (D'Sa et al., 2012; Zanardini et al., 2011). This difference has also been demonstrated in studies with other psychiatric disorders (Bocchio-Chiavetto et al., 2010; Piccinni et al., 2008; Polyakova et al., 2015; Salas-Magaña et al., 2017). A previous meta-analysis of subjects with major depression
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found lower serum BDNF levels and no significant differences in plasma levels, indicating that
the BDNF levels in these biological samples are not correlated (Bocchio-Chiavetto et al.,
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2010). Several hypotheses could help clarify this discrepancy in peripheral BDNF level
between biological samples. First, the origin of BDNF in the blood is not completely known.
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Although the brain is believed to be the main source of circulating peripheral BDNF, it is also
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produced in other regions (Azoulay et al., 2005; Donovan et al., 1995; Kerschensteiner et al.,
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1999; Nakahashi et al., 2000; Rasmussen et al., 2009; Sohrabji and Lewis, 2006; Yamamoto
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and Gurney, 1990). While plasma BDNF derives mainly from lymphocytes, endothelial cells, monocytes, and non-neural peripheral cells, including vascular smooth muscle cells (Donovan
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et al., 1995; Nakahashi et al., 2000), serum BDNF is probably related to the total amount of BDNF stored and released by platelets during the blood clotting process (Fujimura et al., 2002;
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Lommatzsch et al., 2005a), which generates a serum BDNF concentration up to 50 times higher than that in plasma (Fujimura et al., 2002; Lommatzsch et al., 2005a). Furthermore, while
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plasma BDNF has a half-life of less than an hour, platelets circulate for up to 11 days (Kishino et al., 2001; Poduslo and Curran, 1996). Considering that platelets contain the majority of the
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circulating BDNF in the blood, some investigations point out that serum levels seem to better reflect the amount of BDNF in whole blood and are thus a more reliable marker (Fujimura et al., 2002; Lommatzsch et al., 2005a; Serra-Millàs, 2016; Trajkovska et al., 2007). BDNF measurement is subject to variability in both plasma and serum due to biological, methodological, and analytical factors. The methodology used for collection and storage may
affect the stability of the sample (Bocchio-Chiavetto et al., 2010; Bus et al., 2011; Trajkovska et al., 2007; Zuccato et al., 2011). In plasma, the time between sample collection and processing, centrifugation conditions (Fujimura et al., 2002; Zuccato et al., 2011), and choice of anticoagulant can also interfere with the results. While ethylenediaminetetraacetic acid could increase BDNF detection due to platelet release (Lommatzsch et al., 2005a; Lommatzsch and
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Virchow, 2006), the use of heparin could result in up to a 60% decrease in plasma detection
(Begliuomini et al., 2007). Thus, plasma is considered to represent short-term BDNF content,
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while serum represents long-term BDNF content (Polyakova et al., 2015).
It should be pointed out that we found important limitations in the studies included in
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this review. Tobacco, for example, which is associated with increased peripheral BDNF, was
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not controlled in 39% of the studies (Hashimoto et al., 2006; Jamal et al., 2015). Moreover,
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several studies showed no information about the possible confounding effects of psychiatric
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comorbidities. Many studies did not exclude or did not report the existence of psychiatric comorbidities.
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The high prevalence of comorbid psychiatric disorders among subjects with SUDs is well-described in previous studies (Alcorn et al., 2013; Compton et al., 2005; Falck et al., 2004;
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Kessler et al., 1994; Narvaez et al., 2014; Pavarin, 2006; Sartor et al., 2014; Toftdahl et al., 2015). Thus, the exclusion of psychiatric comorbidities would not represent a real sample.
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Moreover, we excluded studies whose samples were based on other psychiatric disorders as main diagnosis; however, we did not exclude studies in which comorbidities were secondary
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or stabilized at the time of evaluation. It is emphasized that a minimum period of abstinence is necessary for an accurate diagnosis and to differentiate effects resulting from drug use. Studies with methamphetamine-dependent patients and depression symptoms showed significantly lower BDNF levels compared to those with no depression symptoms (Ren et al., 2017), and depressive patients with or without alcohol dependence have significantly lower
serum BDNF levels than healthy subjects. Nonetheless, no significant difference was found in the
serum
BDNF
levels
of
depressive
patients
comparing
subjects
with
and
without alcohol dependence (Umene-Nakano et al., 2009). In studies of our group, we found no relationship between psychiatric comorbidities and BDNF in subjects with SUDS (von Diemen et al., 2014).
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Data about psychotic symptoms indicate that BDNF levels did not differ significantly
between 'ecstasy dependent' and 'ecstasy addicted with signs of psychosis', although both were
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increased compared to controls (Angelucci et al., 2010a). Otherwise, a case report found a reduction in the BDNF level of patients in a psychotic episode induced by cocaine (Roncero et
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al., 2016). Therefore, it is not possible to rule out that psychotic and depressive symptoms may
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interfere in the BDNF levels because the data available to-date are inconclusive.
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Probably due to the large methodological differences in the included studies (ex:
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sampling, data collection protocol, etc.), there was high heterogeneity (80% or higher) for all analyses in our review. We therefore used subgroup and moderator analysis which found that
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certain potential sources (age, gender, duration of drug use, and the drug type and subtype) explained some of the heterogeneity. Moreover, we found only a limited number of studies
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evaluating certain PAS, such as heroin and ecstasy, which restricted our analysis of them. Considering the neurotrophic hypothesis, based on the assumption that the SUDs may be due
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to neuronal inability to develop an appropriate adaptive neuroplastic response (Altar, 1999; Bolaños and Nestler, 2004; Castrén, 2014; Russo et al., 2009; Sharma and Ceballos, 2016),
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strategies that restore drug-induced changes in BDNF levels can aid in reestablishing brain neuroplasticity and enhance treatment responses such as longer hospitalizations for detoxification, specific medications, cognitive rehabilitation, and therapeutic community (Clark and Beck, 2010; Erickson et al., 2011; Hoefer et al., 2014; Srinivasan et al., 2013). 5. Conclusion
In conclusion, the evidence of this review suggests that serum BDNF levels are lower among chronic drug users, and this could be related to the years and severity of drug dependence. Serum seems to be a more stable fluid for measuring BDNF than plasma. When interpreting BDNF levels in drug users, factors such as the biological sample (plasma or serum), drug type, pattern of drug use, psychiatric comorbidities, and polysubstance abuse
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should be considered. Although it appears that different drug classes affect BDNF levels in
different ways, their mechanisms of action on BDNF concentration are not yet fully
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understood. Nevertheless, the present study provides a better understanding of
neurophysiological factors and biomarkers in SUDs, which could lead to better treatment
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strategies such as adoption of more individualized therapeutic procedures. In addition,
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behavioral or pharmacological interventions aimed at improving neuroplasticity may be a
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promising pathway.
Author Disclosures
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Role of Funding Source
Funding for this study was provided by Research and Events Support Fund at Hospital de Clínicas de
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Porto Alegre (FIPE-HCPA). FIPE-HCPA had no further role in study design, in the collection, analysis and interpretation of data, in the writing of the report, and in the decision to submit the paper for
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publication.
Additional Financial support was provided by the Coordination for the Improvement of Higher Education Personnel (CAPES). As cited above, this institution had no further role in study design, in
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the collection, analysis and interpretation of data, in the writing of the report, and in the decision to submit the paper for publication as well. Contributors Felipe Ornell was involved with protocol development, hypothesis elaboration, search strategy
elaboration, search and selection of eligible studies, interpretation and discussion of data and results, writing and review of the manuscript. Fernanda Hansen was involved with protocol development, hypothesis elaboration, search strategy elaboration, assessment of methodological quality, interpretation and discussion of data and results, writing and review of the manuscript. Felipe Barreto Schuch was involved with construction of the data basis, conduction of the random
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effect meta-analyses, interpretation and discussion of data and results, writing and review of the manuscript. Fernando Pezzini Rebelatto was involved with data extraction, interpretation and
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discussion of data and results, writing and review of the manuscript. Ana Laura Tavares was involved with data extraction, assessment of methodological quality, interpretation and discussion of data and results, writing and review of the manuscript.
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Juliana Scherer was involved with the writing of the discussion of data and results, writing and review
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of the manuscript. Andrei Garziera Valerio assisted with search and selection of eligible studies,
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interpretation and discussion of data and results, writing and review of the manuscript. Flavio
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Pechansky was involved with discussion of data and results, writing and review of the manuscript.
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Felix Henrique Paim Kessler was involved with protocol development, hypothesis elaboration, search strategy elaboration, interpretation and discussion of data and results, writing and review of the
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manuscript. Lisia von Diemen contributed to protocol development, hypothesis elaboration, search strategy elaboration interpretation and discussion of data and results, writing and review of the
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manuscript. All authors contributed to and approved the final version of the manuscript.
Conflict of Interest
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The authors declare that they have no conflicts of interest.
Acknowledgements
We acknowledge all participants who took part in the present study, the FIPE-HCPA, CAPES and
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Postgraduate Program in Psychiatry and Behavioral Science, for providing funding to this research.
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Figure Legends Figure 1. Flow diagram of the meta-analysis of brain-derived neurotrophic factor (BDNF) in
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A
N
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individuals with substance use disorders.
A
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Figure 2. BDNF serum levels.
A ED
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N
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Figure 3. BDNF serum levels in alcohol users.
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Figure 4. BDNF serum levels in crack/cocaine users
I N U SC R
Study
Year
Drug
Withdrawal
Biological material
Cavus, S.Y.
2012
Alcohol
No
Serum
Yes 2011
Alcohol
No Yes
2012
Alcohol
Garcia-Marchena, N
2017
Alcohol
Geisel, O.
2016
Alcohol
PT Alcohol
CC E
2015
2011
Alcohol
29
Men
Baseline: 22.98 ± 7.95
24.2 ± 5.1
pg/mL
101
39
Mixed
ng/mL
16
16
Mixed
6 months (withdrawal): 31.9 ± 10.1 6 months (no withdrawal): 27.5 ± 10.4 Plasma: 1.27 ± 1.12
Plasma 1.52 ± 0.68
Yes
Serum
Serum: 35.3 ± 11.1
Serum: 26.9 ± 9.5
Yes
Plasma
127.35 ± 236.00
483.05 ± 451.87
pg/mL
91
55
Mixed
Yes
Serum
Placebo drug group (baseline): 3446.2 ± 3716.8 ± 1403.7 1285.8 Placebo drug group (T1): 3511.9 ± 1493.5 Placebo drug group (T2): 3796.7 ± 2047.4 Day 1: 647.67 ± 510.13 623.29 ± 303.03
pg/mL
28
10
Mixed
pg/mL
99
33
Men
ng/mL
65
39
Mixed
pg/mL
64
75
Men
Yes No
Serum
Yes
Day 7: 554.74 ± 398.25
Yes
Day 14: 653.81 ± 518.95
Joe, K-H.
2007
Alcohol
Yes
Plasma
Baseline (Without Delirium Tremens): 14.8 ± 4.7 12.3 ± 3.3 Baseline (With Delirium Tremens): 6.2 ± 2.6 Day 7 (Without Delirium TreMens): 13.4 ± 3.5 Day 7 (With Delirium TreMens): 8.9 ± 4.4 389.5 ± 501.7 822.5 ± 420.7
Lee, B.C.
2009
Alcohol
No
Plasma
3502.2 ± 1726.9
861.75 ± 478.9
pg/mL
41
41
Men
Meng, D.
2011
Alcohol
Yes
Serum
Baseline: 12.69 ± 4.79
Baseline: 11.76 ± 5.05
ng/mL
14
10
Men
Sönmez, MB
2016
Alcohol
No
Serum
Baseline: 39.56 ± 17.09
44.72 ± 17.52
ng/mL
34
32
Men
A
Huang, M-C.
31
Plasma /
Yes
Heberlein, A.
Controls Gender (n)
Yes
ED
D'Sa, C. (1)
Serum
M
No
Cases (n)
Day 7: 33.5 ± 8.8
A
Costa, M.A.
Mean BDNF ± Mean BDNF ± Standard Deviation Standard Deviation Unit (cases) (controls) Baseline: 52.9 ± 19 65.3 ± 15.9 ng/mL
No
Serum
No Yes Yes
Yes
Day 7: 47.02 ± 17.25
I N U SC R Day 14: 51.47 ± 15.46
Yes
2011
Alcohol
Alcohol
2008
Cannabis
D'Souza, D.C.
2009
Cannabis
Ke, X.
2014
Ketamine
Ricci, V.
2011
Ketamine
Angelucci, F. (2)
2007
Cocaine
Corominas-Roso, M.
2013
Cocaine
Women: 2.47 ± 0.64
Women 1.7 ± 0.9
Yes and No*
Men: 2.00 ± 0.71
Men 2.01 ± 0.72
ng/mL
51
31
Mixed
ng/mL
37
37
Mixed
No
Plasma /
Plasma: 4.77 ± 3.50
Plasma: 4.08 ± 4.00
No
Serum
Serum: 35.97 ± 10.49
Serum: 41.70 ± 11.49
Not described No
Serum
5984.23 ± 335.9
5683.62 ± 237.65
pg/mL
26
20
Mixed
Serum
2552 ± 4067
2552 ± 4932
pg/mL
9
14
Mixed
Not described No
Serum
9.5 ± 6.68
14.37 ± 6.07
ng/mL
93
39
Mixed
Serum
12.7 ± 5.48
6.159 ± 3.27
ng/mL
17
11
Mixed
Not described No
Serum
5182.46 ± 662.43
5433.32 ± 392.41
pg/mL
15
15
Mixed
Serum
Baseline: 51,676 ± 17.505
76,044 ± 32,661
ng/mL
23
46
Mixed
ED
Angelucci, F. (4)
Yes and No* Plasma
A
Zanardini, R.
2017
M
Wilhelm, CJ
Yes
Day 12: 60,643 ± 22.607
2011
Cocaine
Yes
Serum
36.0 ± 9.2
25.8 ± 8.9
ng/mL
35
34
Mixed
Mardini, V
2017
Crack/cocaine
Not described
Serum
4.03 ± 4.48
6.67 ± 5.17
ng/mL
57
99
Women
CC E
PT
D'Sa, C. (2)
2015
Cocaine
Yes
Plasma
274.9 ± 200.3
269.4 ± 242.7
pg/mL
89
85
Mixed
Pianca, TG
2017
Crack/cocaine
No
Serum
Baseline: 17.87 ± 0.8
24.66 ± 1.02
ng/mL
90
81
Mixed
Narvaez, J.C.M.
2013
Crack/cocaine
von Diemen, L.
2014
Crack/cocaine
Viola, T.W.
2014
Crack/cocaine
A
Pedraz, M.
Yes Not described No
Day 21: 21.98 ± 1.07 Serum
14.21 ± 3.24
12.67 ± 3.74
ng/mL
53
50
Mixed
Serum
Baseline: 28.6 ± 11.0
39.5 ± 10.6
ng/mL
49
97
Men
8344.90 ± 2662.48
pg/mL
104
20
Women
Yes
Angelucci, F. (3)
2007
Opiate (heroin)
Chen, S.L.
2015
Heberlein, A. (1)
2011
No
Discharge: 35.5 ± 12.3 Plasma
Day 4: 13726.88 ± 5908.50
Yes
Day 11: 13101.84 ± 6507.44
Yes
Day 18: 14137.92 ± 7613.95 Serum
5091.59 ± 422.91
5433.32 ± 392.41
pg/mL
15
15
Mixed
Opiate (heroin)
Not described No
Plasma
10.1 ± 7.7
18.6 ± 9.4
ng/mL
172
102
Mixed
Opiate (heroin)
No
Serum
865.14 ± 358.8
556.62 ± 174.04
pg/mL
27
21
Men
I Opiate (heroin)
Luan, X
2017
Schuster, R.
N U SC R
Plasma
10.4 ± 7.823
16.7 ± 9.5
ng/mL
170
141
Mixed
Opiate (heroin)
Not described No
Serum
1692.94 ± 707.71
1194.46 ± 230.98
pg/mL
86
238
Mixed
2016
Opiate
No
Serum
48.25 ± 12.95
71.25 ± 17.43
ng/mL
30
51
Mixed
Tsai, M
2017
Opiate (heroin)
Yes
Serum
2835.8 ± 1340.7
2671.3 ± 2210.5
pg/mL
60
30
Men
Zhang, K.
2016
Opiate (heroin)
No
Serum
Baseline: 987.25 ± 915.26
52
Men
Yes
Baseline 3989.07 ± pg/mL 2018.87 After 26 weeks 4003.05 ± 2011.83 1241 ± 335.52 pg/mL
53
A
2017
72
90
Mixed
8.53 ± 0.572
ng/mL
23
19
Mixed
16.26 ± 4.72
ng/mL
59
59
Mixed
1.91 ± 0.8
ng/mL
53
31
Mixed
Chen, P.H.
2014
2015
No
Serum
After 26 weeks: 2491.54 ± 1397.32 Baseline (n=72): 1680 ± 577.37
No
Baseline (n=37): 1565 ± 511.4
Yes
One month (n=37): 1454 ± 555.7
MDMA (ecstasy)
Not described Not described Methamphetamine No
Serum
Non-psychotic: 11.28 ± 0.39 Psychotic:11.36 ± 0.51
Serum
Baseline: 9.84 ± 4.85
No
Acute phase: 9.32 ± 4.33
Yes
Subacute phase: 10.45 ± 5.41
Methamphetamine No
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Huckans, M
2010
Opiate (heroin)
ED
Angelucci, F. (1)
2014
PT
Zhang, J
M
Lu RB
Plasma
Yes
Active use: 2.36 ± 1.17 Withdrawal: 2.52 ± 1.30
2005
Methamphetamine Yes
Plasma
2536.25 ± 2310.49
1352.61 ± 1188.15
pg/mL
50
50
Men
Ren, W.
2016
Methamphetamine No
Serum
Baseline (n=179): 1460.28 ± 490.69
1241.27 ± 335.52
pg/mL
179
90
Mixed
1224.55 ± 365.27
pg/mL
194
378
Mixed
A
Kim, D.J.
Su, H
2015
No
Baseline (n=40): 1621.41 ± 591.07
Yes
One month (n=40): 1363.70 ± 580.59
Methamphetamine Yes
* 21 individuals were in active use and 30 in withdrawal at BDNF dosing.
Serum
1487.90 ± 507.18
I N U SC R
Analysis
n subgroups
n users
n controls
SMD 95%CI Lower and Upper limit
P value
Trim and fill adjusted ES
I²
Serum
44
2171
A
Table 2. Brain-derived neurotrophic factor (BDNF) levels from serum samples.
2484
-0.302
-0.62
0.02
0.02
-0.99 (95%CI -1.40 to -0.58) [15]
95.9
Withdrawn
15
559
683
-0.215
-0.64
0.21
0.35
-0.31 (95%CI -0.75 to 0.13) [1]
91.64
Active use
20
1255
1499
-0.627
-1.18
-0.06
0.02
-1.54 (95%CI -2.20 to -0.73) [8]
97.54
664
486
-0.442
-0.84
-0.03
0.03
-0.70 (95%CI -1.15 to -0.255) [3]
89.81
34
35
0.346
-1.01
1.70
0.61
N/A
85.27
Alcohol
15
Cannabis
2
Ketamine
2
ED
Drug subtype
M
User status
50
0.281
-1.80
2.36
0.79
N/A
95.08
394
565
-1.038
-2.00
-0.06
0.03
-1.78 (95%CI -2.92 to -0.65) [3]
97.59
8
446
654
-0.416
-1.24
0.41
0.32
Unchanged
95.88
1
23
19
5.723
4.35
7.09
<0.001
N/A
0
5
499
676
-0.95
0.61
0.67
Unchanged
96.96
Alcohol
8
297
215
-0.287
-1.01
0.43
0.43
-0.47 (95%CI -1.22 to 0.28) [1]
92.58
Crack/cocaine
3
107
177
0.076
-0.87
1.02
0.87
Unchanged
92.56
Heroin
2
88
142
-0.171
-1.52
1.17
0.80
N/A
95.69
Methamphetamine
2
67
149
-0.435
-1.86
0.99
0.55
N/A
95.40
Alcohol
7
367
271
-0.597
-1.03
-0.16
0.007
-0.83 (95%CI -1.31 to -0.35) [2]
84.38
Crack/cocaine
3
162
224
-3.107
-6.25
0.03
0.05
Unchanged
99.01
Cannabis
1
9
14
-0.381
-1.22
0.46
0.37
N/A
Heroin
5
268
452
-0.026
-1.28
1.23
0.98
Unchanged
Heroin
CC E
MDMA/Ecstasy
PT
110
9
Crack/cocaine
Methamphetamine
-0.170
A
Serum and withdrawn
Serum and active use Drug subtype
97.97
I 1
17
11
Methamphetamine
3
432
527
N U SC R
Ketamine
1.137
-0.001
0.53
2.22
0.001
N/A
-1.03
1.02
0.99
Unchanged
97.82
N subgroups
N participants
N controls
SMD 95%CI Lower and Upper limit
P value
Trim and fill adjusted ES
I²
Plasma
14
994
679
0.126
-0.33
0.59
0.59
Unchanged
94.49
595
448
-0.155
-0.65
0.34
0.86
Unchanged
92.51
399
231
0.521
-0.48
1.52
0.44
Unchanged
96.34
300
230
0.110
-0.73
0.95
0.69
0.33 (95%CI -0.56 to 1.23) [1]
94.82
285
125
0.583
-0.06
1.23
0.07
Unchanged
85.83
342
243
-0.866
-1.14
-0.58
<0.001
N/A
61.44
67
81
0.592
0.25
0.92
0.002
N/A
0
3
171
121
-0.870
-1.29
-0.44
0.001
Unchanged
58.24
2
187
105
0.398
-0.38
1.17
0.31
N/A
86.46
Heroin
1
170
141
-0.730
-0.96
-0.50
0.001
N/A
0
Methamphetamine
2
67
81
0.592
0.25
0.92
0.001
N/A
0
Alcohol
4
129
109
0.807
-0.20
1.81
0.18
Unchanged
92.04
Crack/cocaine
1
98
20
0.977
0.48
1.47
<0.001
N/A
0
Heroin
1
172
102
-1.015
-1.27
-0.75
<0.001
N/A
0
Withdrawn
8
Active use
6
ED
User status
Drug subtype 7
Crack/cocaine
3
Heroin
2
Methamphetamine
2
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Alcohol
M
Analysis
PT
A
Table 3. Brain-derived neurotrophic factor (BDNF) levels from plasma samples.
Plasma and withdrawn Drug subtype Alcohol
A
Crack/cocaine
Plasma and active use Drug subtype
I N U SC R
Table 4. Meta-regression of potential moderators brain-derived neurotrophic factor (BDNF) in substance use disorders. β
N studies
95%CI
P value
R²
A
Moderator User status
26
-0.009
-0.01
-0.00
<0.001
0.35
Mean age
26
0.065
0.00
0.12
0.02
0.05
Years of use
9
-0.021
-0.13
0.08
0.63
0.15
10
0.498
0.20
0.79
<0.001
0.04
23
-0.013
-0.02
-0.00
0.03
0.08
22
-0.028
-0.08
0.02
0.33
0.03
15
-0.020
-0.08
0.04
0.53
0.10
Age of the first use
10
0.058
-0.12
0.23
0.52
0.21
Length of abstinence
21
-0.466
-1.14
0.21
0.17
0.02
% of males
43
-0.009
-0.01
-0.01
<0.001
0.33
Mean age
43
0.009
-0.03
0.05
0.66
0.03
Years of use
22
0.003
-0.08
0.09
0.94
0.08
Age of the first use
21
0.268
0.01
0.45
0.005
0.06
Length of abstinence
17
-0.715
-1.60
0.17
0.11
0.10
% of males
14
-0.007
-0.01
0.00
0.26
0.05
Mean age
13
-0.009
-0.08
0.06
0.79
0.07
Age of the first use Length of abstinence
Mean age
CC E
Years of use
N/A
PT
Withdraw % of males
ED
% of males
M
Active use
Sample
A
Serum
Plasma
I Age of the first use
6
Length of abstinence
8
N U SC R
8
0.039
-0.06
0.14
0.47
0
0.021
-0.23
0.27
0.86
0
0.619
-0.41
1.65
0.32
0.12
A
CC E
PT
ED
M
A
Years of use
S0376-8716(18)30725-7 https://doi.org/10.1016/j.drugalcdep.2018.08.036 DAD 7161
To appear in:
Drug and Alcohol Dependence
Received date: Revised date: Accepted date:
15-6-2018 23-8-2018 29-8-2018
Please cite this article as: Ornell F, Hansen F, Schuch FB, Pezzini Rebelatto F, Tavares AL, Scherer JN, Valerio AG, Pechansky F, Paim Kessler FH, von Diemen L, Brain-derived neurotrophic factor in substance use disorders: A systematic review and meta-analysis, Drug and Alcohol Dependence (2018), https://doi.org/10.1016/j.drugalcdep.2018.08.036 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. 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.
Brain-derived neurotrophic factor in substance use disorders: A systematic review and meta-analysis*
Felipe Ornell a, b, f, Fernanda Hansen a, c, Felipe Barreto Schuch d, e, Fernando Pezzini Rebelatto a
, Ana Laura Tavares a, Juliana Nichterwitz Scherer
a, b
, Andrei Garziera Valerio a, Flavio
Pechansky a, b, Felix Henrique Paim Kessler a, b, Lisia von Diemen a, b a
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Center for Drug and Alcohol Research and Collaborating Center on Alcohol and Drugs,
Hospital de Clínicas de Porto Alegre, Federal University of Rio Grande do Sul, Rua Professor b
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Álvaro Alvim, 400, 90420-020, Porto Alegre, RS, Brazil
Postgraduate Program in Psychiatry and Behavioral Science, Federal University of Rio
Grande do Sul, Porto Alegre, RS, Brazil c
Department of Nutrition, Health Sciences Center, Federal University of Santa Catarina,
U
Florianópolis, SC, Brazil
Hospital de Clínicas de Porto Alegre, Porto Alegre, RS, Brazil
e
Universidade La Salle, Porto Alegre, RS, Brazil
M
A
N
d
Correspondence
ED
Felipe Ornell
Center for Drug and Alcohol Research and Collaborating Center on Alcohol and Drugs
PT
Hospital de Clínicas de Porto Alegre, Federal University of Rio Grande do Sul
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Rua Professor Álvaro Alvim, 400, 90420-020, Porto Alegre, RS, Brazil Phone: +55 51 33596488
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[email protected]; [email protected]
Highlights Patients with active drug use show lower serum brain-derived neurotropic factor (BDNF) than controls. There is no difference between BDNF levels of abstinence users and controls.
Alcohol and crack/cocaine users showed lower levels of serum BDNF than controls. Sex, age, and age of the first use influence BDNF levels in subjects with substance use disorders (SUDs).
Abstract
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Background: Brain-derived neurotrophic factor (BDNF) is associated with several neurodegenerative and psychiatric disorders. It is not clear, however, whether BDNF levels are
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modified in substance use disorders (SUDs).
Methods: We conducted a systematic search of electronic databases to identify studies comparing peripheral plasma or serum BDNF levels in adults with SUDs vs. non-user controls.
U
Forty studies were included in the meta-analysis involving a total of 2238 participants with
N
SUDs and 2574 controls.
A
Results: After trim and fill adjustment, current drug users presented lower serum BDNF levels
M
(SMD= -0.99, 95%CI -1.40 to -0.58, I2=95.9) than non-user controls. However, this difference
ED
disappears during withdrawal. Studies using serum or plasma BDNF samples have shown different results. Subgroup analysis revealed lower levels of serum BDNF in alcohol users
PT
(SMD= -0.70, 95%CI -1.15 to -0.25, I2=89.81) and crack/cocaine users (SMD= -1.78, 95%CI -2.92 to -0.65, I2=97.59) than controls. Meta-regression analysis revealed that gender, age, and
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age of first use moderate the effects of drug use in peripheral BDNF levels. Conclusions: Peripheral BDNF levels are decreased in the serum, but not the plasma, of active
A
drug users. Altogether, these findings suggest that BDNF levels may be related to acute use and addiction severity and also point to BDNF’s potential utility as a biomarker in this population.
Keywords: Biomarker; Substance Use Disorder; Brain-Derived Neurotrophic Factor; Meta-
Analysis; Alcohol; Crack-Cocaine
1. Introduction Drug addiction is a chronic disorder characterized by a set of cognitive, behavioral, and physiological symptoms that include continued use despite negative consequences as well as
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high rates of relapse (American Psychiatric Association, 2013; Wikler, 1973). Although it has been postulated that the chronic use of psychoactive-substances (PAS) entails changes in brain
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function and structure which lead to dysfunctional neuroadaptations (whether transitory or
permanent), the period of use and quantities necessary to provoke such alterations are unknown
U
(George and Koob, 2010; Seger, 2010; Volkow et al., 2011). A better understanding of these
N
neuroadaptations may lead to analytical tools that characterize interindividual variability in
A
drug abuse and treatment response (Büttner, 2011; Mendelson et al., 2011; Seger, 2010; Sinha,
M
2011).
In recent decades, significant advances have been made in the psychobiology of
ED
addictive disorders, which have reinforced the idea that addiction is a chronic disease characterized by structural and functional alterations in different brain systems (George and
PT
Koob, 2010; George et al., 2012; Goldstein and Volkow, 2002; Koob, 1992, 2000; Koob et al., 2004; Leshner, 1997; Sinha, 2011; Volkow et al., 2010). Brain-derived neurotrophic factor
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(BDNF) has been studied as a potential biomarker in several psychiatric disorders, including substance use disorder (SUD) (Autry and Monteggia, 2012; Nagahara and Tuszynski, 2011).
A
BDNF is the most abundant neurotrophin in the brain and is related to cell growth and differentiation, synaptic connectivity and neuroplasticity, modulation of neurotransmission and neuronal repair, neurogenic and neurodegenerative processes (Binder and Scharfman, 2004; Huang and Reichardt, 2001), and learning and memory (Bekinschtein et al., 2008). Pre-clinical and clinical evidence indicates that neurotrophins are involved in neuroadaptation to PAS as
well as different processes related to the mediation of behavioral effects including drug sensitization, craving, and relapse (Castrén, 2004; Grimm et al., 2003; Miguel-Hidalgo, 2009; Schmidt and Duman, 2010; Volkow et al., 2015). Since it freely crosses the blood-brain barrier, and its peripheral concentration is strongly correlated with concentrations found in the central nervous system, peripheral BDNF has been widely assessed in clinical studies (Karege et al.,
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2002; Pan et al., 1998).
Previous studies evaluating BDNF levels in individuals with SUDs have found different
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and even controversial results, which indicates that the variations could be related to drug type, usage patterns at the moment of testing, and stage of dependence (Angelucci et al., 2010a;
U
Cavus et al., 2012; Corominas-Roso et al., 2015; D'Sa et al., 2011; Huang et al., 2011; Ke et
N
al., 2014; Pedraz et al., 2015; Roncero et al., 2016; Sordi et al., 2014). In healthy social drinkers
A
submitted to an acute stress protocol, family history of alcohol use disorder and age at first
M
alcohol use were also related to a decrease in serum BDNF (Sharma et al., 2017). However, these studies have mostly involved small heterogeneous samples and
ED
evaluated only one type of drug, preventing comparison of BDNF levels between different substance users. To the authors’ knowledge, no systematic review has meta-analyzed the
PT
difference between BDNF levels in individuals with SUDs and controls. Therefore, the present study aims to: 1) compare peripheral serum and plasma levels of BDNF between individuals
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with SUDs and non-user controls, 2) determine whether this difference occurs in different drug types and subtypes, during withdrawal, and in blood fractions through subgroup analysis, and
A
3) explore, using meta-regressions, potential moderating factors. 2. Methods and materials The protocol developed for this meta-analytic review followed the recommendations of the PRISMA statement (Moher et al., 2009). Each element of the search, the selection of eligible studies (FO and AGV), and data extraction (FPR and ALT) were performed by two
authors. Disagreements were resolved through consensus and the opinion of a third author (LVD). 2.1 Search strategy We conducted a systematic search of all potentially eligible references, without language restrictions, in the PubMed/MEDLINE, EMBASE and PsycINFO databases. The
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search was performed on November 21, 2017. This search strategy was augmented by manually tracking the reference list of all retrieved publications to identify additional eligible studies.
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The search strategy is described in the supplementary material1. 2.2 Study selection
U
The included studies (1) evaluated individuals diagnosed with an SUD for alcohol or
N
an illicit drug according the DSM-5 or the ICD-10 (American Psychiatric Association, 2013;
A
WHO, 2013), (2) compared BDNF levels between individuals with SUDs and non-user
M
controls or were clinical trials using baseline data before drug treatment, and (3) measured peripheral BDNF levels. Excluded studies (1) involved participants with clinical or
ED
comorbidities (e.g., depression, HIV, Parkinson's disease, alzheimer or dementia) and (2) did not present original data (e.g., letters, posters, reviews, case reports, opinion pieces, or
PT
commentary). Studies with prescribed drugs (e.g., benzodiazepines) were not included in the search due to the difficulty of differentiating prescribed use vs. dependence and the high
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prevalence of primary psychiatric disorders. The authors came to a consensus on the final inclusion of references.
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2.3 Data extraction Two reviewers (FPR and ALT) independently extracted data on the control and SUD
groups (sample size, mean and standard deviation) from all included articles to prevent
1
Supplementary material can be found by accessing the online version of this paper at http://dx.doi.org and by entering doi:
potential errors. Data entry discrepancies were double-checked by the reviewers against the original published data, and a consensus was reached. We extracted information regarding the primary drug, psychiatric comorbidities, scales and/or questionnaires used to evaluate psychiatric symptoms or disorders, BDNF levels, biological sample used to measure peripheral BDNF levels (plasma vs. serum), and time of withdrawal when the BDNF levels were
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measured. Information about sex, mean age, age of first use, years of use, tobacco use, body mass index (BMI), and clinical diseases were also extracted. When necessary data were
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unavailable in an included study, requests were emailed to the corresponding author on two different occasions. In cases where multiple reports pertained to the same participants, we
U
included only the largest data set. When the data were available only in graphs, they were
A
2.4 Assessment of methodological quality
N
extracted using Plot Digitizer software, version 2.6.8 (http://plotdigitizer.sourceforge.net/).
M
The quality of the studies included in the systematic review was evaluated using the nine-item Newcastle-Ottawa Scale (NOS) for case-control studies (Wells et al., 2014).
ED
However, item three (“Equivalent non-response rate between groups”) was not used in quality assessment due to the purposes of this review. For comparability questions, age was set a priori
PT
as the most important matching or adjustment factor. The articles were evaluated with the Cochrane Collaboration tool, which assesses the risk of bias of randomized clinical trials in six
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domains (Cochrane Handbook) (Higgins et al., 2011). 2.5 Meta-analysis
A
We conducted random effect meta-analyses due to the anticipated heterogeneity across
studies. The analyses were performed using Comprehensive Meta-Analysis software version 3. The meta-analyses were conducted in three steps. First, a comparative meta-analysis was used to investigate differences in the BDNF levels of drug users vs. non-user controls. The standardized mean deviation (SMD) and the 95% confidence intervals (CI) of the effect size of
the difference were compared separately between serum and plasma BDNF levels. Second, we calculated the differences according to 1) withdrawal time (we considered withdrawal groups to be those with a minimum of 6 days of abstinence) and 2) drug subtype (cocaine or crack/cocaine, methamphetamine, alcohol, heroin, opiates, ketamine, cannabis, amphetamine derivative (±)-3, 4 methylenedioxymethamphetamine (MDMA/escstasy)) in users vs. non-user
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controls in subgroup analyses. Third, we investigated potential moderators of BDNF levels
with meta-regression analyses. The potential moderators of interest were mean age, percentage
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of males, withdrawal length, and years of drug use. We assessed heterogeneity using the I²
statistic for each analysis. Publication bias was verified with the Begg-Mazumdar and Egger
U
tests and adjusted using the Trim and Fill technique. The trim and fill method is a rank-based
N
data augmentation technique that can be used to estimate the number of studies missing from
A
a meta-analysis, adjust the effect removing the most extreme results on one side of the funnel
Duval and Tweedie, 2000).
ED
3. Results
M
plot, and augment the observed data until the funnel plot is more symmetric (Duval et al., 2000;
A total of 4175 studies were identified as potentially relevant, of which 91 were selected
PT
for review. After reading these papers in full and checking their reference lists for further relevant publications, a total of 50 articles were considered to meet the eligibility criteria and
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were included in this systematic review, of which 40 were included in the meta-analysis. Three papers were identified in hand-searches and were added to the analysis (Figure 1).
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3.1 Study and participants’ characteristics Forty unique studies with 58 arms were included (44 serum samples and 14 plasma
samples), totaling 2575 participants with SUDs and 2425 controls. The sample size of drug users ranged from 9 to 378. Thirteen studies evaluated BDNF levels in alcohol users (n=672), nine in crack/cocaine users (n=515), nine in opiate users (n=685), two in cannabis users (n=35),
five in methamphetamine users (n=3535), two in ketamine users (n=110), and one in MDMA/ecstasy users (n=23). Fourteen arms used data from plasma samples to measure BDNF levels (n=994, 399 in active use and 595 in withdrawal), while 44 used serum samples (n=2171, 1255 in active use and 559 in withdrawal). Out of the 40 studies included in the meta-analysis, 20 excluded subjects with psychiatric comorbidities, 13 reported the existence of
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comorbidities, and 7 did not present this information. Of the 40 studies that integrated this meta-analysis, 11 included only men, 27 included men and women, and 2 studies evaluated
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only women. The time of consumption among the users was: Alcohol = 15.32 (7.22), Heroin = 11.28 (7.60), Crack / cocaine = 7.76 (8.55), Methamphetamine = 9 (7.62), and MDMA =
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3.08. Further details of the included studies are summarized in Table 1.
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3.2 Study quality
A
3.2.1 Quality assessment with the NOS. Two authors (FH and AS) conducted the quality
M
assessment of the studies using The Newcastle-Ottawa Scale (NOS). This instrument is broadly used to assess the quality of non-randomized studies in meta-analyses (Wells et al., 2000,
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2011). The scores range from 0 to 9, with lower scores indicating lower study quality. In our paper, we classified the studies included from 0 to 8 stars because we believed the question
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regarding "non-response rate" did not apply to any of the studies, since there was no comparison between groups in this matter. Studies with quality scores lower than 3 were
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considered of low quality (Wu et al., 2015). According to NOS, the studies included presented a good quality evaluation (mean = 6.45, SD = 1.01). The quality assessment details can be
A
found in the supplementary materials 2. 3.2.2 Quality assessment with the Cochrane Collaboration’s Risk of Bias Tool. Although none of the eligible studies presented a high risk of bias, one had an uncertain
2, 3
Supplementary material can be found by accessing the online version of this paper at http://dx.doi.org and by entering doi:
risk of bias for allocation concealment and selective reporting (D'Souza et al., 2009), while another had an uncertain risk of bias for random sequence generation (Geisel et al., 2016). The quality assessment details can be found in the supplementary materials 3. 3.3 Meta-analyses We investigated BDNF levels in plasma or serum separately as different subgroups
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(Table 2 and Table 3). For each matrix, we investigated the specific role of current substance
use status (current use/withdrawal) and the drug subtype: alcohol, heroin, crack/cocaine,
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cannabis, ketamine, MDMA/ecstasy, or Methamphetamine. Powder cocaine and crack cocaine originate from the same active principle. Although the route of administration (inhaled and
U
smoked) changes the pharmacokinetics of the drug in the body, the pharmacodynamics are very
N
similar (Cone, 1995). Thus, we chose to analyze these substances together according to the
A
class of substance independent of the route of administration. We also investigated the role of
M
drug action and drug subtype for current users and those in withdrawal separately and did the same for both serum and plasma BDNF levels. The subgroup analyses are detailed below
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(Table 2 and Table 3). 3.4 Serum BDNF levels
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The 45 subgroups included a pooled total of 2171 blood samples from participants with SUDs and 2484 from controls, and significant differences in BDNF levels were found between
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them (SMD=-0.30, 95%CI -0.62 to 0.02, p=0.02, I2=95.9). No significant publication bias was identified in the Begg-Mazumdar (tau=-0.13, p=0.20) or Egger tests (intercept=-5.10, p=0.01).
A
However, the Duval and Tweedie trim and fill method was used to adjust the effect size to 0.99 (95%CI -1.40 to -0.58) by trimming eight studies. Detailed analysis of BDNF levels can be seen in Table 2; they will be briefly summarized below. 3.4.1 Subgroup analysis considering drug use status. Active users generally presented higher BDNF levels than controls (SMD= -0.62 95CI -1.18 to -0.06, p=0.02). After adjusting
for publication bias, decreased levels were found for serum BDNF levels in current users (SMD=-1.54, 95%CI -2.20 to -0.73) with eight studies trimmed. There were no differences in BDNF between drug users in withdrawal and controls (Table 2). 3.4.2 Subgroup analysis according to drug subtype. Compared to controls, lower BDNF levels were found in alcohol (SMD=-0.44, 95%CI -0.84 to -0.03, p=0.03, I2=89.81) and
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crack/cocaine users (SMD= -1.03, 95%CI -2.00 to -0.06 p=0.03, I2=97.59), although higher
levels were found in MDMA/Ecstasy users (SMD=5.72, 95%CI 4.35 to 7.09, p<0.001, I2=0).
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The adjusted differences between alcohol users and controls and between crack/cocaine users and controls were reduced to -0.70 (95%CI -1.15 to -0.25) and -1.78 (95%CI -2.92 to -0.65),
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respectively, after trimming 3 studies (Table 2).
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3.4.3 Subgroup analysis according to drug subtype among users in withdrawal. No
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significant differences were found among the BDNF serum levels of users in withdrawal, even
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when analyzed according to drug subtype (Table 2).
3.4.4 Subgroup analysis according to drug subtype among active users. Lower BDNF
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levels were found in alcohol (SMD=-0.59, 95%CI -1.03to -0.16, p=0.007, I2=84.38) and crack/cocaine users (SMD=-3,10, 95%CI -6.25 to 003, p=0.05, I2=99.01), while higher BDNF
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levels were found in ketamine users (SMD=1.13, 95%CI 0.53 to 2.22, p=0.001, I2=0). For active alcohol users, the effect size, adjusted for publication bias, was -0.83 (95%CI -1.31 to -
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0.35) after trimming two studies (Table 2). 3.5 Plasma BDNF levels
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Fourteen arms, including 994 blood samples from drug users and 679 from controls,
were compared; no significant differences were found between them (SMD=0.12, 95%CI -0.33 to 0.59, p=0.59, I2=94.49). Significant publication bias was identified in the Begg-Mazumdar (tau=0.38, p=0.04) and Egger tests (intercept=7.38, p=0.01). However, adjustments with the Duval and Tweedie trim and fill method were not made. A detailed analysis of plasma BDNF
levels can be seen in Table 3, and they are briefly summarized below. 3.5.1 Subgroup analysis according to drug use status. No significant differences were found in BDNF plasma level between active users and controls or between users in withdrawal and controls (Table 3). 3.5.2 Subgroup analysis according to drug subtype. Methamphetamine users had
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higher BDNF levels than controls (SMD=0.59, 95%CI 0.25 to 0.92, p=0.002, I2=0), and
crack/cocaine users also tended to have higher BDNF levels than controls (SMD=0.58, CI -
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0.06 to 1.23, p=0.07, l2=85.83), while heroin users had lower BDNF levels than controls (SMD= -0.86, 95%CI -1.14 to -0.58, p<0.001, I2=61.44) (Table 3).
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3.5.3 Subgroup analysis according to drug subtype among users in withdrawal. Lower
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BDNF levels were found among alcohol users (SMD=-0.87, 95%CI -1.29 to -0.44, p=0.001 l2=58.24), while higher BDNF levels were found among methamphetamine users (SMD=0.59,
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95%CI 0.25 to 0.92, p=0.001, I2=0). No analysis of this subgroup was adjusted for publication bias (Table 3).
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3.5.4 Subgroup analysis according to drug subtype among active users. In the crack/cocaine group, plasma BDNF was higher than controls (SMD=0.97, 95%CI, 0.48 to 1.47,
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p<0.001, I2=0), while in the heroin group it was lower (SMD=-1.01, 95%CI, -1.27 to -0.75
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p<0.001, I2=0); however, only one study was involved in the heroin analysis (Table 3). 3.6 Meta-regressions of potential moderators Among active users, sex (k=26, β=-0.009, 95%CI -0.01 to -0.00, p<0.001, R2=0.35),
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age (k=26, β=0.06 95%CI 0.00 to -0.12, p=0.02, R2=0.05) and age of the first use (k=10, β=0.49, 95%CI 0.20 to 0.79, p<0.001, R2=0.004) moderated the difference in BDNF levels between drug users and healthy controls. For users in withdrawal, the percent of males (k=23, β=-0.013, 95%CI -0.02 to -0.79, p=0.03, R2=0.08) was the only moderating variable for differences in BDNF levels among drug users and controls. The full details of the tested models
can be found in Table 4. 4. Discussion To the best of our knowledge, this is the first meta-analysis to compare peripheral BDNF levels in individuals with SUDs and non-user controls, and its main finding was that BDNF levels were lower in individuals with SUDs. Subanalysis showed that this reduction was
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related to active drug use, to alcohol and crack/cocaine use, and to serum samples (regardless
of drug type and active use or withdrawal). Age of first drug use, years of use, and male gender
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were found to be moderators in meta-regression analysis, supporting the hypothesis that BDNF levels are modified in individuals with SUDs.
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These results corroborate prior evidence that BDNF is a reliable biomarker for other
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psychiatric and neurodegenerative disorders (Angelucci et al., 2010b; Ciammola et al., 2007;
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Connor et al., 1997; Fernandes et al., 2014; Fernandes et al., 2011; Fernandes et al., 2015a;
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Fernandes et al., 2015b; Kishi et al., 2017; Krabbe et al., 2007; Lee et al., 2009; Munkholm et al., 2016; Murer et al., 2001; Polyakova et al., 2015; Qin et al., 2017; Salas-Magaña et al.,
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2017; Ventriglia et al., 2013; Yasutake et al., 2006; Zuccato and Cattaneo, 2009). For example, in bipolar disorder, depressive disorder, suicide, and schizophrenia, lower BDNF levels were
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observed in symptomatic phases than in euthymic subjects and healthy controls (Fernandes et al., 2014; Fernandes et al., 2011; Fernandes et al., 2015a; Fernandes et al., 2015b; Kishi et al.,
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2017; Munkholm et al., 2016; Polyakova et al., 2015; Salas-Magaña et al., 2017). The lack of significant difference in BDNF levels between cases in withdrawal and controls also agrees
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with previous evidence from other psychiatric disorders, where BDNF increased in asymptomatic periods to levels similar to those of controls (Fernandes et al., 2015a; Polyakova et al., 2015). Benzodiazepine-dependent patients with major depression diagnoses also showed similar BDNF levels compared to controls after completion of benzodiazepine withdrawal (Heberlein et al., 2010). However, in this same study, the BDNF levels of the patients were
increased in relation to the controls at baseline, diverging from our findings. This may be due to treatment with antidepressants, which may increase levels of BDNF (Shimizu et al., 2003). Nevertheless, while acute administration of benzodiazepine-like drugs generates a significant reduction in expression and level of BDNF in the hippocampus, repeated administration failed to influence BDNF expression in this brain area involved in drug-related plasticity (Licata et
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al., 2013).
The apparent contradiction in peripheral BDNF levels (plasma vs. serum) could be
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explained by different analytical mechanisms (Fernandes et al., 2015a; Fernandes et al., 2015b;
Fujimura et al., 2002) and phases of the disease, e.g., chronic exposure and withdrawal (Barker
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et al., 2015). These results were more consistent in crack/cocaine and alcohol users. In
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ketamine and MDMA/ecstasy users, the observed differences are not generalizable, since the
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analysis only included one study. These findings agree with previous pre-clinical and clinical
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studies (Barker et al., 2015). Studies with voluntary administration protocols have found that acute use of alcohol and cocaine transiently increases brain BDNF levels, although prolonged
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and excessive use lead to a robust reduction in BDNF expression. Nevertheless, after discontinuing use, animal studies indicate that BDNF levels return to baseline (Geoffroy and
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Noble, 2017; Graham et al., 2007; Li and Wolf, 2015; Logrip et al., 2015). Corroborating the hypothesis of transient drug-induced changes in BDNF, a study with rats submitted to a
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protocol of acute benzodiazepine administration verified that BDNF returned to near baseline levels after 40 hours (Huopaniemi et al., 2004). Pre-clinical and clinical studies suggest that
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BDNF could vary in different stages of drug use (e.g. acute, chronic, recovery) and could be associated with cumulative neurological damage (Gama et al., 2013; Grande et al., 2012; Kapczinski et al., 2014; Kapczinski et al., 2008). We also verified that peripheral BDNF levels varied according to the drug used, possibly due to factors such as the substance’s mechanism of action, the pattern and duration
of drug use, the user’s clinical and psychiatric comorbidities, and polysubstance use. In crack/cocaine users, for example, polysubstance use is very common: 77% and 85% report alcohol and tobacco consumption, respectively, in the last year (Bastos and Bertoni, 2014). Hilburn et al. found differences in serum BDNF levels among alcohol, cocaine, and methamphetamine users in relation to craving and duration of withdrawal (Hilburn et al., 2011).
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In young ecstasy users, who had fewer years of use and less frequent use, BDNF was higher at
baseline, which could indicate that they were in the initial phase of the disease (Zhang et al.,
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2014). Another study involving controlled administration of THC found higher serum BDNF in healthy controls than in subjects who had previously used cannabis (D'Souza et al., 2009),
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which indicates that recreational and chronic drug use have different effects on BDNF levels.
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Our meta-regressions showed that serum BDNF levels are moderated by sex, years of
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use, and age of first use, which corroborates previous findings that age and sex affect stored
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and circulating levels of BDNF in peripheral blood (Lommatzsch et al., 2005b). In psychiatric disorders, such as bipolar disorder and schizophrenia, meta-analyses have already shown that
Fernandes et al., 2015b).
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age and disease duration are associated with lower BDNF levels (Fernandes et al., 2011;
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It has been demonstrated that homeostatic functioning is disturbed during the course of mental disorders, and the central nervous system reorganizes itself. Although in the short term
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such reorganization can indicate a functional response mechanism, in the long term it can cause dysfunctional and pathological alterations (allostatic load), resulting in inappropriate response
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(Kapczinski et al., 2008; McEwen, 1998a, 1998b, 2000, 2002, 2003; McEwen and Wingfield, 2003). Moreover, in advanced stages, inappropriate responses can persist even during remission (Berk et al., 2011). In SUDs, the chronic use of PAS generates repeated overactivation of the dopaminergic pathway, leading to neuroadaptive mechanisms that may cause dysregulation in the brain reward system and in BDNF regulation.
The impact of age and sex in our results is in line with previous investigations of stored and circulating BDNF levels in peripheral blood (Lommatzsch et al., 2005b). Elderly women, for example, seem to have higher BDNF levels than men (Bus et al., 2011), which may result from sex-related hormonal differences. Estrogen, for instance, interferes in BDNF expression and causes variations in the menstrual cycle (Erickson et al., 2010; Lewis, 2006; Lommatzsch
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et al., 2005b). It is noteworthy that the only study with an all-female sample found higher
BDNF levels in crack/cocaine users during early withdrawal than in controls, and more than
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half of the women had some additional psychiatric comorbidity (Viola et al., 2014).
According to previous studies, the severity of drug dependence can also affect BDNF
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levels (Costa et al., 2011; D'Sa et al., 2011; Huang et al., 2011; Sordi et al., 2014). Even among
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individuals using the same substance, there are differences in BDNF levels according to the
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severity of drug use and prognosis (Corominas-Roso et al., 2015; Corominas-Roso et al., 2013;
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D'Sa et al., 2011; Scherer et al., 2015). In alcohol users, for example, significantly lower BDNF levels were found in individuals with delirium tremens than users without this condition and
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controls, and these levels persisted even after detoxification (Huang et al., 2011). In another study that followed patients for 180 days after detoxification, the serum BDNF levels of
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patients who maintained abstinence were higher than both baseline values and patients who relapsed during this period (Costa et al., 2011). Similarly, Scherer et al. found an association
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between higher BDNF levels and better clinical outcomes in crack users during detoxification (2015). Thus, during treatment, BDNF levels approaching those of controls may be associated
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with better clinical outcomes (Duman and Monteggia, 2006; Zuccato and Cattaneo, 2009). Moreover, studies with other psychiatric populations have also reported similar results: in bipolar patients, for example, different serum BDNF levels in the early and late stages have been reported. Our results also revealed differences in peripheral BDNF levels between serum and
plasma. Only two of the forty studies included in this investigation evaluated serum and plasma samples simultaneously, and they found intra-individual and intra-group variations (D'Sa et al., 2012; Zanardini et al., 2011). This difference has also been demonstrated in studies with other psychiatric disorders (Bocchio-Chiavetto et al., 2010; Piccinni et al., 2008; Polyakova et al., 2015; Salas-Magaña et al., 2017). A previous meta-analysis of subjects with major depression
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found lower serum BDNF levels and no significant differences in plasma levels, indicating that
the BDNF levels in these biological samples are not correlated (Bocchio-Chiavetto et al.,
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2010). Several hypotheses could help clarify this discrepancy in peripheral BDNF level
between biological samples. First, the origin of BDNF in the blood is not completely known.
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Although the brain is believed to be the main source of circulating peripheral BDNF, it is also
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produced in other regions (Azoulay et al., 2005; Donovan et al., 1995; Kerschensteiner et al.,
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1999; Nakahashi et al., 2000; Rasmussen et al., 2009; Sohrabji and Lewis, 2006; Yamamoto
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and Gurney, 1990). While plasma BDNF derives mainly from lymphocytes, endothelial cells, monocytes, and non-neural peripheral cells, including vascular smooth muscle cells (Donovan
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et al., 1995; Nakahashi et al., 2000), serum BDNF is probably related to the total amount of BDNF stored and released by platelets during the blood clotting process (Fujimura et al., 2002;
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Lommatzsch et al., 2005a), which generates a serum BDNF concentration up to 50 times higher than that in plasma (Fujimura et al., 2002; Lommatzsch et al., 2005a). Furthermore, while
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plasma BDNF has a half-life of less than an hour, platelets circulate for up to 11 days (Kishino et al., 2001; Poduslo and Curran, 1996). Considering that platelets contain the majority of the
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circulating BDNF in the blood, some investigations point out that serum levels seem to better reflect the amount of BDNF in whole blood and are thus a more reliable marker (Fujimura et al., 2002; Lommatzsch et al., 2005a; Serra-Millàs, 2016; Trajkovska et al., 2007). BDNF measurement is subject to variability in both plasma and serum due to biological, methodological, and analytical factors. The methodology used for collection and storage may
affect the stability of the sample (Bocchio-Chiavetto et al., 2010; Bus et al., 2011; Trajkovska et al., 2007; Zuccato et al., 2011). In plasma, the time between sample collection and processing, centrifugation conditions (Fujimura et al., 2002; Zuccato et al., 2011), and choice of anticoagulant can also interfere with the results. While ethylenediaminetetraacetic acid could increase BDNF detection due to platelet release (Lommatzsch et al., 2005a; Lommatzsch and
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Virchow, 2006), the use of heparin could result in up to a 60% decrease in plasma detection
(Begliuomini et al., 2007). Thus, plasma is considered to represent short-term BDNF content,
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while serum represents long-term BDNF content (Polyakova et al., 2015).
It should be pointed out that we found important limitations in the studies included in
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this review. Tobacco, for example, which is associated with increased peripheral BDNF, was
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not controlled in 39% of the studies (Hashimoto et al., 2006; Jamal et al., 2015). Moreover,
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several studies showed no information about the possible confounding effects of psychiatric
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comorbidities. Many studies did not exclude or did not report the existence of psychiatric comorbidities.
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The high prevalence of comorbid psychiatric disorders among subjects with SUDs is well-described in previous studies (Alcorn et al., 2013; Compton et al., 2005; Falck et al., 2004;
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Kessler et al., 1994; Narvaez et al., 2014; Pavarin, 2006; Sartor et al., 2014; Toftdahl et al., 2015). Thus, the exclusion of psychiatric comorbidities would not represent a real sample.
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Moreover, we excluded studies whose samples were based on other psychiatric disorders as main diagnosis; however, we did not exclude studies in which comorbidities were secondary
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or stabilized at the time of evaluation. It is emphasized that a minimum period of abstinence is necessary for an accurate diagnosis and to differentiate effects resulting from drug use. Studies with methamphetamine-dependent patients and depression symptoms showed significantly lower BDNF levels compared to those with no depression symptoms (Ren et al., 2017), and depressive patients with or without alcohol dependence have significantly lower
serum BDNF levels than healthy subjects. Nonetheless, no significant difference was found in the
serum
BDNF
levels
of
depressive
patients
comparing
subjects
with
and
without alcohol dependence (Umene-Nakano et al., 2009). In studies of our group, we found no relationship between psychiatric comorbidities and BDNF in subjects with SUDS (von Diemen et al., 2014).
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Data about psychotic symptoms indicate that BDNF levels did not differ significantly
between 'ecstasy dependent' and 'ecstasy addicted with signs of psychosis', although both were
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increased compared to controls (Angelucci et al., 2010a). Otherwise, a case report found a reduction in the BDNF level of patients in a psychotic episode induced by cocaine (Roncero et
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al., 2016). Therefore, it is not possible to rule out that psychotic and depressive symptoms may
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interfere in the BDNF levels because the data available to-date are inconclusive.
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Probably due to the large methodological differences in the included studies (ex:
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sampling, data collection protocol, etc.), there was high heterogeneity (80% or higher) for all analyses in our review. We therefore used subgroup and moderator analysis which found that
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certain potential sources (age, gender, duration of drug use, and the drug type and subtype) explained some of the heterogeneity. Moreover, we found only a limited number of studies
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evaluating certain PAS, such as heroin and ecstasy, which restricted our analysis of them. Considering the neurotrophic hypothesis, based on the assumption that the SUDs may be due
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to neuronal inability to develop an appropriate adaptive neuroplastic response (Altar, 1999; Bolaños and Nestler, 2004; Castrén, 2014; Russo et al., 2009; Sharma and Ceballos, 2016),
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strategies that restore drug-induced changes in BDNF levels can aid in reestablishing brain neuroplasticity and enhance treatment responses such as longer hospitalizations for detoxification, specific medications, cognitive rehabilitation, and therapeutic community (Clark and Beck, 2010; Erickson et al., 2011; Hoefer et al., 2014; Srinivasan et al., 2013). 5. Conclusion
In conclusion, the evidence of this review suggests that serum BDNF levels are lower among chronic drug users, and this could be related to the years and severity of drug dependence. Serum seems to be a more stable fluid for measuring BDNF than plasma. When interpreting BDNF levels in drug users, factors such as the biological sample (plasma or serum), drug type, pattern of drug use, psychiatric comorbidities, and polysubstance abuse
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should be considered. Although it appears that different drug classes affect BDNF levels in
different ways, their mechanisms of action on BDNF concentration are not yet fully
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understood. Nevertheless, the present study provides a better understanding of
neurophysiological factors and biomarkers in SUDs, which could lead to better treatment
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strategies such as adoption of more individualized therapeutic procedures. In addition,
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behavioral or pharmacological interventions aimed at improving neuroplasticity may be a
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promising pathway.
Author Disclosures
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Role of Funding Source
Funding for this study was provided by Research and Events Support Fund at Hospital de Clínicas de
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Porto Alegre (FIPE-HCPA). FIPE-HCPA had no further role in study design, in the collection, analysis and interpretation of data, in the writing of the report, and in the decision to submit the paper for
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publication.
Additional Financial support was provided by the Coordination for the Improvement of Higher Education Personnel (CAPES). As cited above, this institution had no further role in study design, in
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the collection, analysis and interpretation of data, in the writing of the report, and in the decision to submit the paper for publication as well. Contributors Felipe Ornell was involved with protocol development, hypothesis elaboration, search strategy
elaboration, search and selection of eligible studies, interpretation and discussion of data and results, writing and review of the manuscript. Fernanda Hansen was involved with protocol development, hypothesis elaboration, search strategy elaboration, assessment of methodological quality, interpretation and discussion of data and results, writing and review of the manuscript. Felipe Barreto Schuch was involved with construction of the data basis, conduction of the random
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effect meta-analyses, interpretation and discussion of data and results, writing and review of the manuscript. Fernando Pezzini Rebelatto was involved with data extraction, interpretation and
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discussion of data and results, writing and review of the manuscript. Ana Laura Tavares was involved with data extraction, assessment of methodological quality, interpretation and discussion of data and results, writing and review of the manuscript.
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Juliana Scherer was involved with the writing of the discussion of data and results, writing and review
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of the manuscript. Andrei Garziera Valerio assisted with search and selection of eligible studies,
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interpretation and discussion of data and results, writing and review of the manuscript. Flavio
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Pechansky was involved with discussion of data and results, writing and review of the manuscript.
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Felix Henrique Paim Kessler was involved with protocol development, hypothesis elaboration, search strategy elaboration, interpretation and discussion of data and results, writing and review of the
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manuscript. Lisia von Diemen contributed to protocol development, hypothesis elaboration, search strategy elaboration interpretation and discussion of data and results, writing and review of the
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manuscript. All authors contributed to and approved the final version of the manuscript.
Conflict of Interest
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The authors declare that they have no conflicts of interest.
Acknowledgements
We acknowledge all participants who took part in the present study, the FIPE-HCPA, CAPES and
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Postgraduate Program in Psychiatry and Behavioral Science, for providing funding to this research.
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Wikler, A., 1973. Dynamics of drug dependence. Implications of a conditioning theory for research and treatment. Arch. Gen. Psychiatry 28, 611-616.
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Yasutake, C., Kuroda, K., Yanagawa, T., Okamura, T., Yoneda, H., 2006. Serum BDNF, TNFalpha and IL-1beta levels in dementia patients: Comparison between Alzheimer's disease and vascular dementia. Eur. Arch. Psychiatry Clin. Neurosci. 256, 402-406.
Zanardini, R., Fontana, A., Pagano, R., Mazzaro, E., Bergamasco, F., Romagnosi, G., Gennarelli, M., Bocchio-Chiavetto, L., 2011. Alterations of brain-derived neurotrophic factor serum levels in patients with alcohol dependence. Alcohol. Clin. Exp. Res. 35, 1529-1533. Zhang, J., Zhang, X., Su, H., Tao, J., Xie, Y., Han, B., Lu, Y., Wei, Y., Sun, H., Wang, Y., Wu,
IP T
W., Zou, S., Liang, H., Zoghbi, A.W., Tang, W., He, J., 2014. Increased serum brain-
derived neurotrophic factor levels during opiate withdrawal. Neurosci. Lett. 571, 61-
SC R
65.
Zuccato, C., Cattaneo, E., 2009. Brain-derived neurotrophic factor in neurodegenerative
U
diseases. Nat. Rev. Neurol. 5, 311-322.
N
Zuccato, C., Marullo, M., Vitali, B., Tarditi, A., Mariotti, C., Valenza, M., Lahiri, N., Wild,
A
E.J., Sassone, J., Ciammola, A., Bachoud-Lèvi, A.C., Tabrizi, S.J., Di Donato, S.,
A
CC E
PT
ED
disease. PLoS One 6, e22966.
M
Cattaneo, E., 2011. Brain-derived neurotrophic factor in patients with Huntington's
Figure Legends Figure 1. Flow diagram of the meta-analysis of brain-derived neurotrophic factor (BDNF) in
ED
M
A
N
U
SC R
IP T
individuals with substance use disorders.
A
CC E
PT
Figure 2. BDNF serum levels.
A ED
PT
CC E
IP T
SC R
U
N
A
M
A
N
U
SC R
IP T
Figure 3. BDNF serum levels in alcohol users.
A
CC E
PT
ED
M
Figure 4. BDNF serum levels in crack/cocaine users
I N U SC R
Study
Year
Drug
Withdrawal
Biological material
Cavus, S.Y.
2012
Alcohol
No
Serum
Yes 2011
Alcohol
No Yes
2012
Alcohol
Garcia-Marchena, N
2017
Alcohol
Geisel, O.
2016
Alcohol
PT Alcohol
CC E
2015
2011
Alcohol
29
Men
Baseline: 22.98 ± 7.95
24.2 ± 5.1
pg/mL
101
39
Mixed
ng/mL
16
16
Mixed
6 months (withdrawal): 31.9 ± 10.1 6 months (no withdrawal): 27.5 ± 10.4 Plasma: 1.27 ± 1.12
Plasma 1.52 ± 0.68
Yes
Serum
Serum: 35.3 ± 11.1
Serum: 26.9 ± 9.5
Yes
Plasma
127.35 ± 236.00
483.05 ± 451.87
pg/mL
91
55
Mixed
Yes
Serum
Placebo drug group (baseline): 3446.2 ± 3716.8 ± 1403.7 1285.8 Placebo drug group (T1): 3511.9 ± 1493.5 Placebo drug group (T2): 3796.7 ± 2047.4 Day 1: 647.67 ± 510.13 623.29 ± 303.03
pg/mL
28
10
Mixed
pg/mL
99
33
Men
ng/mL
65
39
Mixed
pg/mL
64
75
Men
Yes No
Serum
Yes
Day 7: 554.74 ± 398.25
Yes
Day 14: 653.81 ± 518.95
Joe, K-H.
2007
Alcohol
Yes
Plasma
Baseline (Without Delirium Tremens): 14.8 ± 4.7 12.3 ± 3.3 Baseline (With Delirium Tremens): 6.2 ± 2.6 Day 7 (Without Delirium TreMens): 13.4 ± 3.5 Day 7 (With Delirium TreMens): 8.9 ± 4.4 389.5 ± 501.7 822.5 ± 420.7
Lee, B.C.
2009
Alcohol
No
Plasma
3502.2 ± 1726.9
861.75 ± 478.9
pg/mL
41
41
Men
Meng, D.
2011
Alcohol
Yes
Serum
Baseline: 12.69 ± 4.79
Baseline: 11.76 ± 5.05
ng/mL
14
10
Men
Sönmez, MB
2016
Alcohol
No
Serum
Baseline: 39.56 ± 17.09
44.72 ± 17.52
ng/mL
34
32
Men
A
Huang, M-C.
31
Plasma /
Yes
Heberlein, A.
Controls Gender (n)
Yes
ED
D'Sa, C. (1)
Serum
M
No
Cases (n)
Day 7: 33.5 ± 8.8
A
Costa, M.A.
Mean BDNF ± Mean BDNF ± Standard Deviation Standard Deviation Unit (cases) (controls) Baseline: 52.9 ± 19 65.3 ± 15.9 ng/mL
No
Serum
No Yes Yes
Yes
Day 7: 47.02 ± 17.25
I N U SC R Day 14: 51.47 ± 15.46
Yes
2011
Alcohol
Alcohol
2008
Cannabis
D'Souza, D.C.
2009
Cannabis
Ke, X.
2014
Ketamine
Ricci, V.
2011
Ketamine
Angelucci, F. (2)
2007
Cocaine
Corominas-Roso, M.
2013
Cocaine
Women: 2.47 ± 0.64
Women 1.7 ± 0.9
Yes and No*
Men: 2.00 ± 0.71
Men 2.01 ± 0.72
ng/mL
51
31
Mixed
ng/mL
37
37
Mixed
No
Plasma /
Plasma: 4.77 ± 3.50
Plasma: 4.08 ± 4.00
No
Serum
Serum: 35.97 ± 10.49
Serum: 41.70 ± 11.49
Not described No
Serum
5984.23 ± 335.9
5683.62 ± 237.65
pg/mL
26
20
Mixed
Serum
2552 ± 4067
2552 ± 4932
pg/mL
9
14
Mixed
Not described No
Serum
9.5 ± 6.68
14.37 ± 6.07
ng/mL
93
39
Mixed
Serum
12.7 ± 5.48
6.159 ± 3.27
ng/mL
17
11
Mixed
Not described No
Serum
5182.46 ± 662.43
5433.32 ± 392.41
pg/mL
15
15
Mixed
Serum
Baseline: 51,676 ± 17.505
76,044 ± 32,661
ng/mL
23
46
Mixed
ED
Angelucci, F. (4)
Yes and No* Plasma
A
Zanardini, R.
2017
M
Wilhelm, CJ
Yes
Day 12: 60,643 ± 22.607
2011
Cocaine
Yes
Serum
36.0 ± 9.2
25.8 ± 8.9
ng/mL
35
34
Mixed
Mardini, V
2017
Crack/cocaine
Not described
Serum
4.03 ± 4.48
6.67 ± 5.17
ng/mL
57
99
Women
CC E
PT
D'Sa, C. (2)
2015
Cocaine
Yes
Plasma
274.9 ± 200.3
269.4 ± 242.7
pg/mL
89
85
Mixed
Pianca, TG
2017
Crack/cocaine
No
Serum
Baseline: 17.87 ± 0.8
24.66 ± 1.02
ng/mL
90
81
Mixed
Narvaez, J.C.M.
2013
Crack/cocaine
von Diemen, L.
2014
Crack/cocaine
Viola, T.W.
2014
Crack/cocaine
A
Pedraz, M.
Yes Not described No
Day 21: 21.98 ± 1.07 Serum
14.21 ± 3.24
12.67 ± 3.74
ng/mL
53
50
Mixed
Serum
Baseline: 28.6 ± 11.0
39.5 ± 10.6
ng/mL
49
97
Men
8344.90 ± 2662.48
pg/mL
104
20
Women
Yes
Angelucci, F. (3)
2007
Opiate (heroin)
Chen, S.L.
2015
Heberlein, A. (1)
2011
No
Discharge: 35.5 ± 12.3 Plasma
Day 4: 13726.88 ± 5908.50
Yes
Day 11: 13101.84 ± 6507.44
Yes
Day 18: 14137.92 ± 7613.95 Serum
5091.59 ± 422.91
5433.32 ± 392.41
pg/mL
15
15
Mixed
Opiate (heroin)
Not described No
Plasma
10.1 ± 7.7
18.6 ± 9.4
ng/mL
172
102
Mixed
Opiate (heroin)
No
Serum
865.14 ± 358.8
556.62 ± 174.04
pg/mL
27
21
Men
I Opiate (heroin)
Luan, X
2017
Schuster, R.
N U SC R
Plasma
10.4 ± 7.823
16.7 ± 9.5
ng/mL
170
141
Mixed
Opiate (heroin)
Not described No
Serum
1692.94 ± 707.71
1194.46 ± 230.98
pg/mL
86
238
Mixed
2016
Opiate
No
Serum
48.25 ± 12.95
71.25 ± 17.43
ng/mL
30
51
Mixed
Tsai, M
2017
Opiate (heroin)
Yes
Serum
2835.8 ± 1340.7
2671.3 ± 2210.5
pg/mL
60
30
Men
Zhang, K.
2016
Opiate (heroin)
No
Serum
Baseline: 987.25 ± 915.26
52
Men
Yes
Baseline 3989.07 ± pg/mL 2018.87 After 26 weeks 4003.05 ± 2011.83 1241 ± 335.52 pg/mL
53
A
2017
72
90
Mixed
8.53 ± 0.572
ng/mL
23
19
Mixed
16.26 ± 4.72
ng/mL
59
59
Mixed
1.91 ± 0.8
ng/mL
53
31
Mixed
Chen, P.H.
2014
2015
No
Serum
After 26 weeks: 2491.54 ± 1397.32 Baseline (n=72): 1680 ± 577.37
No
Baseline (n=37): 1565 ± 511.4
Yes
One month (n=37): 1454 ± 555.7
MDMA (ecstasy)
Not described Not described Methamphetamine No
Serum
Non-psychotic: 11.28 ± 0.39 Psychotic:11.36 ± 0.51
Serum
Baseline: 9.84 ± 4.85
No
Acute phase: 9.32 ± 4.33
Yes
Subacute phase: 10.45 ± 5.41
Methamphetamine No
CC E
Huckans, M
2010
Opiate (heroin)
ED
Angelucci, F. (1)
2014
PT
Zhang, J
M
Lu RB
Plasma
Yes
Active use: 2.36 ± 1.17 Withdrawal: 2.52 ± 1.30
2005
Methamphetamine Yes
Plasma
2536.25 ± 2310.49
1352.61 ± 1188.15
pg/mL
50
50
Men
Ren, W.
2016
Methamphetamine No
Serum
Baseline (n=179): 1460.28 ± 490.69
1241.27 ± 335.52
pg/mL
179
90
Mixed
1224.55 ± 365.27
pg/mL
194
378
Mixed
A
Kim, D.J.
Su, H
2015
No
Baseline (n=40): 1621.41 ± 591.07
Yes
One month (n=40): 1363.70 ± 580.59
Methamphetamine Yes
* 21 individuals were in active use and 30 in withdrawal at BDNF dosing.
Serum
1487.90 ± 507.18
I N U SC R
Analysis
n subgroups
n users
n controls
SMD 95%CI Lower and Upper limit
P value
Trim and fill adjusted ES
I²
Serum
44
2171
A
Table 2. Brain-derived neurotrophic factor (BDNF) levels from serum samples.
2484
-0.302
-0.62
0.02
0.02
-0.99 (95%CI -1.40 to -0.58) [15]
95.9
Withdrawn
15
559
683
-0.215
-0.64
0.21
0.35
-0.31 (95%CI -0.75 to 0.13) [1]
91.64
Active use
20
1255
1499
-0.627
-1.18
-0.06
0.02
-1.54 (95%CI -2.20 to -0.73) [8]
97.54
664
486
-0.442
-0.84
-0.03
0.03
-0.70 (95%CI -1.15 to -0.255) [3]
89.81
34
35
0.346
-1.01
1.70
0.61
N/A
85.27
Alcohol
15
Cannabis
2
Ketamine
2
ED
Drug subtype
M
User status
50
0.281
-1.80
2.36
0.79
N/A
95.08
394
565
-1.038
-2.00
-0.06
0.03
-1.78 (95%CI -2.92 to -0.65) [3]
97.59
8
446
654
-0.416
-1.24
0.41
0.32
Unchanged
95.88
1
23
19
5.723
4.35
7.09
<0.001
N/A
0
5
499
676
-0.95
0.61
0.67
Unchanged
96.96
Alcohol
8
297
215
-0.287
-1.01
0.43
0.43
-0.47 (95%CI -1.22 to 0.28) [1]
92.58
Crack/cocaine
3
107
177
0.076
-0.87
1.02
0.87
Unchanged
92.56
Heroin
2
88
142
-0.171
-1.52
1.17
0.80
N/A
95.69
Methamphetamine
2
67
149
-0.435
-1.86
0.99
0.55
N/A
95.40
Alcohol
7
367
271
-0.597
-1.03
-0.16
0.007
-0.83 (95%CI -1.31 to -0.35) [2]
84.38
Crack/cocaine
3
162
224
-3.107
-6.25
0.03
0.05
Unchanged
99.01
Cannabis
1
9
14
-0.381
-1.22
0.46
0.37
N/A
Heroin
5
268
452
-0.026
-1.28
1.23
0.98
Unchanged
Heroin
CC E
MDMA/Ecstasy
PT
110
9
Crack/cocaine
Methamphetamine
-0.170
A
Serum and withdrawn
Serum and active use Drug subtype
97.97
I 1
17
11
Methamphetamine
3
432
527
N U SC R
Ketamine
1.137
-0.001
0.53
2.22
0.001
N/A
-1.03
1.02
0.99
Unchanged
97.82
N subgroups
N participants
N controls
SMD 95%CI Lower and Upper limit
P value
Trim and fill adjusted ES
I²
Plasma
14
994
679
0.126
-0.33
0.59
0.59
Unchanged
94.49
595
448
-0.155
-0.65
0.34
0.86
Unchanged
92.51
399
231
0.521
-0.48
1.52
0.44
Unchanged
96.34
300
230
0.110
-0.73
0.95
0.69
0.33 (95%CI -0.56 to 1.23) [1]
94.82
285
125
0.583
-0.06
1.23
0.07
Unchanged
85.83
342
243
-0.866
-1.14
-0.58
<0.001
N/A
61.44
67
81
0.592
0.25
0.92
0.002
N/A
0
3
171
121
-0.870
-1.29
-0.44
0.001
Unchanged
58.24
2
187
105
0.398
-0.38
1.17
0.31
N/A
86.46
Heroin
1
170
141
-0.730
-0.96
-0.50
0.001
N/A
0
Methamphetamine
2
67
81
0.592
0.25
0.92
0.001
N/A
0
Alcohol
4
129
109
0.807
-0.20
1.81
0.18
Unchanged
92.04
Crack/cocaine
1
98
20
0.977
0.48
1.47
<0.001
N/A
0
Heroin
1
172
102
-1.015
-1.27
-0.75
<0.001
N/A
0
Withdrawn
8
Active use
6
ED
User status
Drug subtype 7
Crack/cocaine
3
Heroin
2
Methamphetamine
2
CC E
Alcohol
M
Analysis
PT
A
Table 3. Brain-derived neurotrophic factor (BDNF) levels from plasma samples.
Plasma and withdrawn Drug subtype Alcohol
A
Crack/cocaine
Plasma and active use Drug subtype
I N U SC R
Table 4. Meta-regression of potential moderators brain-derived neurotrophic factor (BDNF) in substance use disorders. β
N studies
95%CI
P value
R²
A
Moderator User status
26
-0.009
-0.01
-0.00
<0.001
0.35
Mean age
26
0.065
0.00
0.12
0.02
0.05
Years of use
9
-0.021
-0.13
0.08
0.63
0.15
10
0.498
0.20
0.79
<0.001
0.04
23
-0.013
-0.02
-0.00
0.03
0.08
22
-0.028
-0.08
0.02
0.33
0.03
15
-0.020
-0.08
0.04
0.53
0.10
Age of the first use
10
0.058
-0.12
0.23
0.52
0.21
Length of abstinence
21
-0.466
-1.14
0.21
0.17
0.02
% of males
43
-0.009
-0.01
-0.01
<0.001
0.33
Mean age
43
0.009
-0.03
0.05
0.66
0.03
Years of use
22
0.003
-0.08
0.09
0.94
0.08
Age of the first use
21
0.268
0.01
0.45
0.005
0.06
Length of abstinence
17
-0.715
-1.60
0.17
0.11
0.10
% of males
14
-0.007
-0.01
0.00
0.26
0.05
Mean age
13
-0.009
-0.08
0.06
0.79
0.07
Age of the first use Length of abstinence
Mean age
CC E
Years of use
N/A
PT
Withdraw % of males
ED
% of males
M
Active use
Sample
A
Serum
Plasma
I Age of the first use
6
Length of abstinence
8
N U SC R
8
0.039
-0.06
0.14
0.47
0
0.021
-0.23
0.27
0.86
0
0.619
-0.41
1.65
0.32
0.12
A
CC E
PT
ED
M
A
Years of use