Abstract
Background
For decades, treatment of mood disorders, psychoses, anxiety and dementia have been confounded by limited efficacy and high rates of treatment resistance. Preclinical and clinical evidence have highlighted disruption of cholinergic signalling in several neuropsychiatric conditions and examined intervention strategies including acetylcholinesterase inhibitors and nicotinic receptor-targeted intervention. However, the effectiveness of these approaches is often curtailed by on-target side effects. Post mortem studies implicate muscarinic receptor dysregulation in neuropsychiatric pathophysiology; therefore, we conducted a systematic review and meta-analysis to investigate the therapeutic efficacy and safety of muscarinic receptor-targeted interventions in adults with neuropsychiatric disorders.
Methods
PubMed, EMBASE, PsycINFO, EBSCO and Web of Science were searched using relevant keywords from database inception to 7 August 2022. Randomised, double-blind, placebo-controlled studies were included if they investigated the effect of muscarinic receptor-targeted intervention in adults with a diagnosis of a neuropsychiatric disorder and were published in English. A narrative synthesis approach was adopted to describe the findings. Wherever three or more studies with a similar intervention were available, effect sizes were calculated, and a meta-analysis was performed. Cochrane risk-of-bias-2 tool was utilised to assess the risk of bias, and sensitivity analyses were performed to identify publication bias. Certainty analysis (high, moderate, low and/or very low) was conducted using GRADE criteria.
Results
Overall, 33 studies met the inclusion criteria and 5 were included in the meta-analysis. Despite a limited pool with several different interventions, we found therapeutic efficacy of xanomeline (M1/M4 agonist) in primary psychotic disorders plus behavioural and psychological symptoms of dementia. Scopolamine showed a significant antidepressant effect in a combined cohort of major depressive and bipolar disorders in the short-term outcome measure, but no effect following cessation of treatment. Results from bias assessments suggest “very low” certainty in the antidepressant effect of scopolamine. Critical limitations of the current literature included low power, high heterogeneity in the patient population and a lack of active comparators.
Conclusion
While the results are not definitive, findings on muscarinic receptor-targeted interventions in several mental disorders are promising in terms of efficacy and safety, specifically in treating schizophrenia, mood disorders, and behavioural and psychiatric symptoms of Alzheimer’s disease. However, orthosteric muscarinic receptor-targeted interventions are associated with a range of peripheral adverse effects that are thought to be mediated via M2/M3 receptors. The orthosteric binding site of muscarinic acetylcholine receptors is remarkably conserved, posing a challenge for subtype-selective interventions; nonetheless allosteric ligands with biased signalling pathways are now in development. We conclude that adequately powered prospective studies with subtype-selective interventions are required to determine the clinical effectiveness of muscarinic-receptor targeted interventions for the treatment of neuropsychiatric disorders.
Graphical Abstract
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Avoid common mistakes on your manuscript.
Acetylcholine imbalance is apparent across various psychiatric illnesses. |
Xanomeline improved positive and negative symptoms of schizophrenia. |
Scopolamine shows antidepressant effects in major depressive and bipolar disorder patients. |
1 Introduction
In the brain, the cholinergic system forms an intricate neural network with three segregated elements based on their localisation and projection pattern [1]; (1) long-range basal forebrain projections, critical for attention, learning, memory, decision-making [2, 3]; (2) projections from the brainstem, which modulate attention, sleep, and motor control [4]; and (3) cholinergic interneurons of the striatum, which play a crucial role in reward and motivation [4, 5]. At the cellular level, acetylcholine signalling is modulated by nicotinic (nAChR; ionotropic receptors) and muscarinic acetylcholine receptors (mAChR; G-protein coupled receptors). To date, there are five cloned mAChR subtypes (M1, M2, M3, M4, and M5). M1, M3 and M5 receptors couple primarily to Gq/11, stimulating phospholipase C and inositol phosphate, mediating an excitatory effect through intracellular calcium influx. In contrast, M2 and M4 are coupled with Gi/o, resulting in an inhibition of the downstream adenyl cyclase activation [6,7,8].
Due to its widespread innervation and diverse central function, the acetylcholine system has attracted attention as a target for new pharmacotherapies to treat neuropsychiatric disorders with overlapping symptomatology [9, 10]. In 2019, 1 in every 8 or 970 million people in the world suffered from a mental disorder [11]. In the USA, 18.1% (43.6 million) adults experience mental health problems annually [12]. Current clinical strategies to combat dysfunctional cholinergic signalling include acetylcholinesterase inhibitors to avoid the breakdown of Ach- and nAChR-targeted interventions. However, the clinical effectiveness of these compounds is curtailed by on-target adverse effects [13,14,15]. As detailed below, growing evidence suggests the apparent involvement of muscarinic receptors in certain neuropsychiatric illnesses, including major depressive disorder (MDD), bipolar disorder (BP), schizophrenia, dementia, Alzheimer’s disease (AD) and anxiety disorders [16].
1.1 Mood Disorders
The term mood disorder broadly defines all types of depression and BP. In the USA, an estimated 8.4% of adults will have at least one major depressive episode during their lifetime, with the prevalence rate higher in women (10.5%) than men (6.2%) [17]. Major depressive disorder is diagnosed when an individual has persistent feelings of sadness, anhedonia, worthlessness, lack of concentration, suicidal thoughts, appetite and sleep disturbances [18]. On the other hand, people with BP move between two states, from depression to mania. Treatment options mainly include pharmacological interventions such as antidepressants, anticonvulsants, mood stabilisers, and non-pharmacological approaches such as cognitive behavioural therapy, interpersonal psychotherapy, or a combination of these approaches [19]. Despite the accessibility of multiple treatment options, approximately 20–40% of people with MDD do not respond to the primary therapy, and the proportion of non-responders increases further for people with BP [20,21,22].
The involvement of the acetylcholine system in mood disorders was proposed in 1950, following a study in which psychiatric patients developed depressive-like symptoms after administration of acetylcholine esterase inhibitors [23]. Subsequently, this was assisted by studies showing that depressive symptoms were exaggerated in patients with MDD after administration of physostigmine, an acetylcholinesterase inhibitor [24, 25]. A PET study using [18F]FP-TZTP, a selective M2 ligand, found reduced receptor availability in the anterior cingulate cortex of patients with BP and MDD [26]. Similarly, haplotype analysis also suggests a possible involvement of M2 receptors in patients with depression [27]. To date, only one study measured M3 receptors and found a decrease in density in the frontal but not in the parietal and prefrontal cortex. Collectively, these data provide considerable support for region-specific differences in M2 or M3 receptors in patients with mood disorders, but no apparent regulation of M1 receptor [28, 29].
1.2 Primary Psychotic Disorders
As defined by the International Classification of Diseases 11th Revision (ICD-11), primary psychotic disorders encompass schizophrenia, schizoaffective disorder, and other psychotic disorders. The prevalence of schizophrenia and related psychotic disorders range from 0.25 to 0.64% in the USA, based on a household survey, clinical diagnostic examinations, and health records [30,31,32]. Schizophrenia is a potentially devastating disorder with the following symptoms: positive (psychotic) symptoms such as disorganised thoughts, hallucination, delusion; negative symptoms consisting of social withdrawal, affective flattening, alogia, anhedonia; and cognitive impairments in all domains. A vital issue with conventional antipsychotics is limited efficacy for negative symptoms and cognitive impairments, with predominant focus to date on the monoamine hypothesis [33, 34]. Even second-generation neuroleptics, including clozapine and olanzapine, produce only modest improvement in people with chronic and refractory illness [35, 36].
Initial investigation for the function of muscarinic receptors in schizophrenia was conducted using human post mortem brain tissue and radioligand binding assays. These results revealed region-specific alterations in M1 and M4 muscarinic receptors in the striatum, prefrontal cortex, hippocampus, anterior cingulate and superior temporal gyrus [37,38,39,40]. Studies employing receptor-specific antibodies, in situ hybridisation, and tomographic imaging revealed a region-specific negative correlation between muscarinic receptor availability and symptoms of schizophrenia [40, 41]. Notably, scopolamine (non-selective muscarinic receptor antagonist) induces psychotic-like symptoms, referred to as "anti-muscarinic syndrome" [42, 43]. Based on available evidence from tomographic imaging and post mortem studies, it was proposed that combined agonism of M1 and M4 receptors may be more efficacious given that a subgroup of people with schizophrenia also showed M1 muscarinic receptor deficiency, known as muscarinic receptor deficit schizophrenia (MRDS) [44]. Moreover, intervention with agonist action at M4 receptors also produced cognitive enhancement and anti-psychotic-like effects in animal models of the schizophrenia [45, 46]. This is a growing area of development with several pharmaceutical companies pursuing active muscarinic programmes (Table 1) for psychiatric disorders, including Karuna therapeutics (KarXT (Xanomeline+Trospium); NCT04659161), Sosei Heptares (HTL0016878; NCT03244228, NCT04849286, NCT04935320) and Cerevel therapeutics (Emraclidine: NCT05227703, NCT05227690).
1.3 Dementia/Alzheimer’s Disease
The clinical syndrome of dementia consists of several subtypes, including AD, vascular, frontotemporal and dementia with Lewy bodies. Alzheimer’s Disease contributes to 60–70% of cases [47]. Globally, 55 million individuals have dementia, which is expected to rise to 139 million by 2050 [47]. Along with cognitive impairment, 97% of patients also experience neuropsychiatric symptoms [48], also referred to as ‘behavioural and psychological symptoms of dementia (BPSD)’, which include lack of motivation, psychotic symptoms, depression, anxiety, agitation, and impulsivity [49, 50]. Current drug therapy for BPSD consists of atypical antipsychotics, antidepressants and anticonvulsants, which may cause severe adverse effects such as excessive sedation, orthostatic hypotension and cognitive slowing [51].
The cholinergic hypothesis of AD suggests that degeneration of cholinergic innervations in the cortex and hippocampus substantially contributes to cognitive dysfunction. In fact, the role of the acetylcholine system in learning and memory was first identified 50 years ago, when the muscarinic receptor antagonist scopolamine produced cognitive impairment in rats [52]. Clinical observation found acetylcholine esterase inhibitors such as tacrine, rivastigmine, donepezil and galantamine improved both cognition and behavioural and psychiatric symptoms. Unfortunately, dose-dependent adverse effects attributed to non-selective activation of acetylcholine receptors in both the central and peripheral nervous system restrict clinical utility [53].
Preclinical and post mortem findings also implicate muscarinic receptors in BPSD [54, 55]. Out of all five subtypes, M1 receptor is most abundantly expressed in the prefrontal cortex and hippocampus [56]. Recently, M1 muscarinic receptors have been postulated to be potential therapeutic agents for both cognitive and non-cognitive symptoms of AD [57, 58]. Additionally, the M4 receptor may also represent a potential target for BPSD because of its widespread expression in the cortex, striatum, thalamus and hippocampus, key brain regulators for emotional processing and motivation [59]. Collectively, these results highlight the potential of muscarinic receptors in the regulation of cognitive and behavioural symptoms observed in AD patients [59].
1.4 Anxiety Disorders
Anxiety disorders are a group of psychiatric disorders comprised of generalised anxiety, panic disorders and various phobias (such as social phobia or claustrophobia). Data from the National Comorbidity Survey Replication suggest that 31.1% of US adults experience an anxiety disorder at least once in their lifetime [60]. A preclinical study revealed pro-depressive and anxiogenic-like effects following infusion of pilocarpine (a cholinergic agonist) in rats. In this study, pilocarpine was infused directly into ventral tegmental area (VTA), as mAChR in the midbrain are critical regulators of anxiety-like behaviour [61]. In contrast, the non-selective mAChR antagonist scopolamine attenuated chronic stress-induced anxiety-like behaviour in mice following intra-hippocampal administration [62]. Additionally, a recent study showed that direct infusion of a selective M5 negative allosteric modulator into the VTA can modulate both depressive-like and anxiety-related behaviours in rats, implying a potential role for M5 receptors in the regulation of anxiety-like behaviour [63].
Given this evidence, we therefore aimed to systematically review findings from randomised controlled trials (RCTs) assessing the therapeutic effectiveness of muscarinic-receptor targeted interventions in adults with neuropsychiatric disorders, including mood disorders, primary psychotic disorders, dementia/AD, and anxiety disorders.
2 Methods
2.1 Protocol and Registration
The study was registered with the International Prospective Register of Systematic Reviews (PROSPERO: CRD42021236260) and followed the Preferred Reporting Items for Systematic Reviews and Meta-Analysis guidelines (PRISMA) statement [64]. To limit the number of studies retained for screening, each step adhered to the PRISMA statement.
2.2 Detailed Search Strategy
Comprehensive systematic computer-based searches were carried out in PubMed, EMBASE, PsycINFO, EBSCO, and Web of Science, from database inception to the 31st of August 2021, with no date or publication type limitation. Different combinations of keywords along with synonyms and word variants of keywords were used to create a comprehensive search strategy. Relevant search terms included: ("Muscarinic") AND ("Mental Health" OR "Mental disorder" OR "Psychiatric disease" OR "Psychiatric illness" OR "Psychiatric disorder" OR "Psychological disorder" OR "Behaviour disorder" OR "Behavior disorder" OR "Psychosis" OR "Schizophrenics" OR "Schizophrenia" OR "Mental illness" OR "Psychotic disorder" OR "Schizoaffective disorder" OR "Depression" OR "Depressive" OR "Anxiety" OR "Neurotic disorder" OR "Habit" OR "Impulsive disorder" OR "Bipolar disorder" OR "Bipolar" OR "Mood disorder" OR "Learning" OR "Memory" OR "Attention" OR "Neuropsychiatric disorder" OR "Obsessive-compulsive disorder" OR "Personality disorder" OR “Dementia” OR “Alzheimer”) AND ("Human" OR "Participants "OR "Subjects" OR "Clinical") in the title, abstract, and keywords. We also manually searched the bibliography of eligible studies and full-text reviews for relevant papers if not incorporated in the primary search strategy. Searches were re-run before submission on 7th August 2022.
2.3 Inclusion Criteria
Articles qualified for inclusion if they: (1) investigated the effect of muscarinic receptor-targeted interventions; (2) included adults with a Diagnostic and Statistical Manual of Mental Disorders (DSM)/ICD diagnosis of neuropsychiatric disorder (schizophrenia, psychotic disorder, schizoaffective disorders, mood (affective) disorder, depression, mania, bipolar disorder, neurotic disorders, anxiety disorder, obsessive-compulsive disorder, habit and impulse behaviour, personality disorder), OR patients with dementia/AD (where the symptomatic measures are both cognitive and non-cognitive function or neuropsychological test); (3) had a comparison group (inactive placebo/active placebo); and (4) were published in English-language in a peer-reviewed journal. There were no restrictions to sample sizes, demographics, trial type (i.e., parallel or crossover) or type of intervention (agonist/antagonist). After initial title and abstract screening, only empirical articles were included in the full-text screening. For further inclusion in the meta-analysis, trials needed to be: (1) randomised controlled trials; (2) have no repeated participants; and (3) measure psychiatric symptoms on a validated disorder-specific psychometric scale.
Full-text articles were excluded if they: (1) were other systematic reviews or meta-analyses, conference proceedings published as abstract only, case reports, book chapters or animal study; and (2) lacked randomisation details (i.e., whether treatment allocation was randomised) (3) Published in other than English language. We also excluded studies where the population of interest were adolescents and children aged ≤ 17 years or adults with dementia and AD where cognition was the only outcome measure.
2.4 Study Selection
Full-text articles were screened by two independent reviewers (SV and AAG) using the web-based systematic review tool Covidence (Veritas Health Innovation, Melbourne, Australia). Any disagreement between the two reviewers was resolved via discussion to achieve consensus.
2.5 Data Extraction and Outcome Included in the Qualitative Synthesis
A custom datasheet was generated using Microsoft Excel, and all relevant data were extracted by the primary reviewer (SV). All extracted data were verified independently by a second reviewer (AAG). The following study characteristics were extracted: (1) lead author; (2) publication year; (3) country; (4) sample size; (5) sample demographics (age, sex, and ethnicity); (6) study settings; and (7) participant characteristics (any co-morbidity or treatment status). In addition, details of mAChR interventions were extracted, including (1) name of the drug and mechanism of action; (2) dose; (3) route of administration; (4) washout period; (5) frequency; (6) experimental design; (7) comparison group used; (8) adverse effects; (9) retention rates; and (10) main findings of the trial.
The primary outcome measures were the mean and standard deviation of the after-treatment symptomology measurement for active and placebo interventions. We also included studies where rapid eye movement (REM) sleep alteration was a diagnostic measure. It has been hypothesised that REM sleep alterations in depression aid in the progression of depressive symptoms, including cognitive distortions and negative self-esteem [65].
2.6 Quality and Risk of Bias Assessment
The quality of studies included for analysis was assessed using the Cochrane risk of bias assessment tool (ROB-2) for randomised controlled trials [66]. Cochrane ROB-2 assesses five individual domains for bias: (1) randomisation process; (2) deviations from intended interventions; (3) missing outcome data; (4) measurement of the outcome; and (5) selection of the reported result. Each individual category was ranked as low risk, some concern or high risk of bias. Two independent reviewers (SV and AAG) assessed the risk of bias, any disagreements were solved by discussion.
2.7 Data Synthesis and Analysis
For the systematic review, a narrative synthesis approach was utilised to describe findings from included studies. There are four significant steps included in the Cochrane guidelines [67]. The first step was to develop a hypothesis about the mechanism of intervention. Alteration in acetylcholine release has been widely observed across various neuropsychiatric disorders, and muscarinic receptors modulate the release of acetylcholine both pre- and post-synaptically. Based on these facts, the question was framed. In the next step, we performed a pilot search for relevant studies. In addition to data extraction, discrepancies and factors influencing results were also interrogated to follow step 3. A significant challenge with narrative synthesis is the lack of transparency, which increases the likelihood of bias and reduces the robustness of findings. To prevent that, methods were pre-specified in the PROSPERO protocol and strictly followed.
Meta-analyses were performed with the help of Cochrane Review Manager software (Revman Version 5.4, The Cochrane Collaboration 2020). The standardised mean difference (SMD) was used as an outcome measure. The SMD was calculated as the difference in mean outcome between placebo and active intervention, divided by the pooled standard deviation of outcome among participants. In the absence of standard deviation, it was calculated from the number of participants, p-values and standard error. We used pre-crossover data from crossover trials to mimic the parallel trials. By assuming study level variability, we used a random-effects model. A Forest plot was generated to visualise the individual contribution of the study, and I2 statistics were computed to assess heterogeneity between studies, where < 40% was considered low heterogeneity while > 40% represents moderate to substantial (< 60%) heterogeneity. Leave-one-out sensitivity analyses were performed to estimate influence and bias, whereby SMD values were calculated by discarding one different observation each time. Meta-regression and funnel plots were considered inappropriate for this study as less than ten studies were included in the quantitative analysis [68]. To assess our confidence in meta-analysis effect estimates, the certainty of the evidence was judged by using the grading of recommendation assessment, development, and evaluation (GRADE) system using the GRADEpro GDT web application (Grade Pro GDT, 2020). The assessed criteria were risk of bias, consistency, directness, precision, and publication bias (Table 2).
3 Results
3.1 Selection of Studies
Initial database searches yielded 4368 potential articles, of which 2525 duplicates were removed (Fig. 1). Following title and abstract screening, full-text for the remaining 287 articles were reviewed for eligibility; of these, 254 were excluded for various reasons (e.g., inappropriate outcome measures, no information about randomisation, conference abstracts and other reviews). In total, 33 studies were included in the systematic review. Five studies were included in the meta-analysis. Table 1 represents the characteristics of each included muscarinic-receptor targeted intervention. Table 3 summarises the study characteristics of the 33 trials included. Studies were divided into groups based on disorder; 17 studies on mood disorders, 7 on primary psychotic disorders, 5 studies on dementia/AD, 2 on anxiety disorders, and the remaining 2 articles included people with both psychotic and mood disorders.
3.2 Quality and Risk of Bias
Table 3 and Fig. 2 show the ROB-2 quality assessment for each study. Seven studies were rated as high risk of bias, 15 had some concerns, and 11 were rated as low risk of bias. The percentage similarities between the two reviewers were 82%, and the kappa score was 0.76 indicating substantial agreement. All studies included were randomised, placebo-controlled double-blind trials, except one, where the study was pseudo-randomised [69]. The main limitation across studies was poorly described randomisation details. Only 10 trials explicitly described randomisation methods, and 13 described allocation concealment. The second prime reason for some concern was the lack of information about assessors’ blinding, which may lead to bias in study results. In seven studies, the dropout rate exceeded 20% [69,70,71,72,73]. In two studies, the key reason was adverse events, especially in the high-dose group. The reason for dropout was unavailable for two studies. Despite one having a significant effect on the overall visual analogue score (VAS) in people with depression, the reason for dropout was not given [69, 70]. Shekhar and colleagues (2008) reported that participants dropped out in both arms [71]. The KarXT clinical trial mentioned several reasons, including adverse events, consent withdrawal, withdrawal by an investigator, and forgetting to follow-up [72].
3.3 Mood Disorders
Among the 19 studies in people with MDD or BP (Tables 3 and 4), 11 were conducted in the USA, 6 in Germany, one in Iran and one in China. A total of 538 participants ranging in age from 18 to 72 years, and 66% were female. In all, 12 studies investigated the effect of scopolamine, 5 studies RS-86 and 2 studies investigated the impact of biperiden. Seven scopolamine studies administered the medication intravenously, of which six showed that scopolamine effectively reduced depressive symptoms [74,75,76,77,78,79]. Further, when administered orally, scopolamine also reduced depressive symptoms in one study [80]. However, a more recent study exhibited no significant difference between scopolamine and placebo treatments post-intravenous administration [81]. In agreement with a more recent study, intramuscular scopolamine injection did not produce a significant difference compared to placebo [82]. However, in all the previous studies, symptom measurement was performed after every three infusions, whereas results were obtained 28 days after scopolamine injections in the intramuscular study. Acute biperiden administration reduced depressive symptoms compared to the placebo group [83]. In contrast, participants who received biperiden for 4 weeks did not significantly differ from placebo [84].
People with MDD frequently display sleep abnormalities, specifically reduced REM latency and heightened REM density [85, 86]. The remaining mood disorder studies focused on muscarinic receptor interventions in the modulation of REM sleep in people with depression. The muscarinic receptor agonist RS-86 reduced REM latency and enhanced REM density in depressed patients compared to placebo [87,88,89]. Conversely, REM latency was increased in response to the muscarinic receptor antagonist scopolamine compared to placebo [90, 91].
3.4 Primary Psychotic Disorders
Nine studies examined the effect of muscarinic receptor interventions in primary psychotic disorders (Tables 3 and 5). Six studies included people with schizophrenia, two with unspecified psychotic disorders, and one with schizophrenia and schizoaffective disorder. The sample sizes ranged from 11 to 182 participants, for a total of 361 participants (age range: 19–65 years; 31.2% female participants). Biperiden treatment was administered in four studies, and one for each of scopolamine, xanomeline, and KarXT. In the remaining two studies, RS-86 was used to measure disrupted sleep parameters in psychiatric patients but not for primary psychiatric symptom measurements.
Administration of biperiden (4 mg, orally) produced significant impairment in Weschler memory scale, Benton visual retention test and paired-associate learning on Cambridge Neuropsychological Test Automated Battery in people with a primary psychotic disorder compared with controls [92, 93]. In contrast, one of the four studies showed no changes in Mini-Mental State Examination [93, 94]. Additionally, no significant difference was found in positive and negative symptoms [95]. Like biperiden, scopolamine had no significant impact on anxiety and depressive symptoms in subjects with a psychotic disorder [73], suggesting the potential efficacy of scopolamine is limited to patients with mood disorders.
Shekhar et al. 2008, studied the efficaciousness of xanomeline in subjects with schizophrenia, finding a beneficial effect of xanomeline in both positive and negative symptoms compared with placebo [71]. In the cognitive domain, improvements were most robustly observed in verbal and short-term memory function. In line with xanomeline, the response to KarXT treatment in schizophrenia demonstrated a lower score on the positive and negative syndrome scale, clinical global impressions scale-improvement, and Marder negative symptoms scale [72].
Two studies also examined the effect of RS-86 on sleep parameters in schizophrenia patients compared to placebo [87, 96]. Similar to observations in individuals with depressive disorders, RS-86 significantly reduced REM latency in this population compared with placebo [87, 96].
3.5 Dementia/Alzheimer’s Disease
In total, five studies were included, investigating muscarinic-receptor-targeted interventions in cognitive and psychiatric symptoms of dementia. Among them, four studies included patients with mild to moderate AD, and one study included probable AD participants. Probable AD was diagnosed when a patient had cognitive gradual decline without a history of illness that could cause mental impairment without AD [97]. All studies were performed in the USA. The number of patients varied from 8 to 66, while two studies had 343 participants (age range 60–82 years, 57.5% females) [98, 99]. Trial durations ranged from 8 days to 24 weeks, and interventions included RS-86, Lu 25-109, and xanomeline tartrate. Data for outcome measures were analysed using intention-to-treat to prevent attrition bias. Participant characteristics and outcome interventions information are summarised in Tables 3 and 6.
Two studies with RS-86, one assessing cognitive and psychiatric symptoms on the Alzheimer’s Disease Assessment Scale (ADAS) [100] and another one with neuropsychiatric tests including verbal memory, a visuospatial form of memory and attention [101] did not find a significant difference in any of the scales compared to placebo. One study investigated the efficacy of Lu25-109 using the activities of the daily living scale, behaviour symptom scale and cognition subscale of ADAS, and found no significant change [102]. Two large studies of medium quality assessed xanomeline tartrate. One study found a substantial difference in the neuropsychological test battery but not in the cognitive subscale of AD [98]. In another study, psychiatric symptoms were also assessed along with cognition, and the intervention group with the highest dose significantly improved BPSD compared to placebo and lower dose groups. At the same time, ADAS-cognition score was unaffected [99].
3.6 Anxiety Disorders
To date, only two clinical trials have examined the effect of muscarinic receptor-targeted interventions in anxiety disorders – one in people with panic disorder and one in people with social anxiety disorder [70, 103] (Tables 3 and 7). The sample size in the two studies was 12 and 66 participants, respectively (age range 18–55 years, 54% female). The first study found that biperiden was effective in reducing anxiety symptom severity in people with panic disorder against placebo [70]. In contrast, the second study showed that scopolamine had no effect on self-reported social anxiety disorder symptoms. However, scopolamine caused a significant reduction in skin conductance responses, which are a less subjective measure of anxiety levels. In addition, this study examined a combination of scopolamine and exposure therapy, where scopolamine augmented extinction in severely anxious participants, highlighting the importance of muscarinic receptors in anxiety-related behaviour [103]. The same study also showed that scopolamine increased the error rate in the mnemonic similarity task at the dose of 0.5 mg, suggesting impaired cognition.
3.7 Meta-Analysis
Five studies were incorporated in the meta-analysis of the antidepressant effect of scopolamine in a combined cohort of MDD and BP patients (Fig. 3). Three of the studies were crossover [74, 75, 81], and two were parallel design [80, 82]. Due to the possible carry-over effects of scopolamine, we used the last observation of pre-crossover data (following the 3rd scopolamine administration). In the parallel study, we used the 4th observation to equalise the observation parameters with crossover trials. In all four studies mentioned above, outcome measures were available after three infusion days. The results available for the fifth study were at a different time point (after 28 days), so we performed a sub-group analysis. Overall, a non-significant anti-depressant effect was observed for studies of scopolamine compared with placebo (5 studies, N = 147) (SMD = − 0.53; 95% CI = [− 1.33, 0.27]; z = 1.29, p = 0.20) with substantial heterogeneity (I2 = 80%). However, when sub-group analysis was performed, all studies with a short duration of 3 days showed a significant anti-depressant effect (4 studies, N = 103) (SMD = −0.81; 95% CI = [− 1.57, − 0.06]; z = 2.12, p = 0.03) with substantially higher heterogeneity (I2 = 67%). This became non-significant when including the study with 28 days of observation (1 study, N = 44) (SMD = 0.58; 95% CI = [− 0.02, 1.19]; z = 1.88, p = 0.06). Within the short-term duration studies (symptoms measured after 3 days), leave-one-out sensitivity analyses indicated significant changes in inferences leaving out study 1 [75] and study 3 [80], whereby removal of these studies increased the p-value (p = 0.11).
In contrast, scopolamine had no overall effect on anxiety in individuals with mood disorders (3 studies, SMD = − 0.33; 95% CI = [− 1.10, 0.45]; z = 0.83, p = 0.41), and moderate heterogeneity (I2 = 56%) (Fig. 4). Leave-one-out sensitivity analyses showed that omitting study 3 [81] decreased the p-value significantly (from 0.41 to 0.04). Using GRADE analysis, we rated the certainty of scopolamine’s antidepressant and anxiolytic effect as “very low” in people with mood disorders.
3.8 Reported Adverse Events
Adverse events were most commonly reported with scopolamine treatment, even at a low dose (0.004 mg/kg). Common adverse events were dry mouth, dry skin, dry mucus membranes, constipation, drowsiness, blurred vision, light-headedness, dizziness, hypotension, fatigue, feeling drugged [74,75,76, 80, 81, 103]. At higher doses (0.5 mg/kg), scopolamine also showed a reduction in pulse and increased psychiatric symptoms such as visual hallucinations, disorganised speech, and cognitive impairments at the acute drug response phase [69]. Only two studies reported adverse events during biperiden treatment, including mild dry mouth (also reported in the placebo group) and constipation [84, 94]. In studies of primary psychotic disorders, xanomeline increased salivation, diarrhoea, nausea, vomiting, gastrointestinal distress, dizziness, liver function, sweating, and flatulence, likely through the activation of peripheral muscarinic acetylcholine receptors [71]. However, a few patients from the placebo group also showed some gastric disturbances. When xanomeline was combined with trospium (KarXT), side effects were minimal but included nausea, constipation, dry mouth, vomiting and dyspepsia [72]. No severe adverse incidents were stated in any of the studies. Increased salivation was the only adverse effect reported with oral RS-86 administration in MDD patients [104]. In contrast, side effects were higher in AD patients, including, diaphoresis, hypersalivation, depressed mood, confusion, prolonged P-R interval and tremors [100].
4 Discussion
This systematic review and meta-analysis examined the therapeutic efficacy of muscarinic-targeted interventions for neuropsychiatric disorders. Here, we reviewed 33 clinical trials to examine their effectiveness in treating mood, primary psychotic, dementia, or anxiety disorders. The most common medications tested for mood disorders were the non-selective muscarinic antagonist scopolamine, and biperiden, an M1 mAChR preferring antagonist. Meta-analysis revealed that scopolamine did not show significant improvement in depressive symptoms compared to placebo. For schizophrenia, most studies used biperiden, followed by the M1/M4 mAChR preferring agonist xanomeline and the antagonist scopolamine. Xanomeline significantly reduced positive and negative symptoms; however, safety was improved when combined with a peripheral mAChR antagonist trospium (KarXT). Neither scopolamine nor repeated-dose biperiden improved symptoms in people with schizophrenia. In patients with AD, treatments included RS-86, xanomeline tartrate and Lu 25-109; only xanomeline significantly improved psychiatric and behavioural symptoms of AD. No conclusive findings can be drawn for anxiety disorders as only two clinical trials were available, and neither examined the same compound.
4.1 Mood Disorders
The most substantial evidence of efficacy for muscarinic-targeted interventions was observed in mood disorders. Eight RCTs reported scopolamine's efficacy relative to placebo in patients with mood disorders regardless of diagnosis. The effect was rapid as symptom alleviation was seen 3–5 days following the first scopolamine administration [74, 105]. Compared to typical antidepressants, which can take several weeks to become effective, this time span is beneficial to individuals with depression [74]. The rapid antidepressant effect of scopolamine was observed in both sexes; however, one study showed the magnitude was higher in women than men, which may be driven by renal elimination rate. Although there are no studies examining pharmacokinetic differences of scopolamine in men versus women, results from drugs with weak anticholinergic activity such as amantadine and digoxin suggest slower clearance in females compared to males, due to sex differences in renal tubule secretion by organic cation transporters [106]. A second possibility is p-glycoprotein transporter polymorphisms may lead to variability in efficacy [76, 107]. This potential difference may also be explained by sex differences observed in the A/T 1890 SNP in CHRM2 [108].
One study documented substantial symptom improvement when scopolamine was combined with the selective serotonin reuptake inhibitor (SSRI) citalopram, rather than citalopram alone, despite no evidence of interactions between SSRI and anticholinergic agents [80]. On the other hand, scopolamine failed to alleviate depressive symptoms in treatment-resistant patients with higher severity Montgomery-Åsberg Depression Rating Scale scores [81]. Three reasons have been suggested to explain treatment-resistance [109]. First, pathophysiological adaptations are more serious, so standard doses are ineffective. Second, progressive neurobiological changes alter the diagnosis. For example, a patient initially presented with MDD, and subsequently BP or worsening symptoms emerged. A drug targeting the initial diagnosis may not generate an appropriate therapeutic response in such cases. Third, different underlying neurobiological mechanisms may exist between treatment-responsive and treatment-resistant patients. All the studies from Furey and colleagues displayed scopolamine's antidepressant effect at a low dose (0.004 mg) [74,75,76,77,78,79]. In contrast, Newhouse et al. (1988) showed no significant difference in Beck depression inventory score at a higher dose range (0.1–0.5 mg) [69]. One plausible reason for this difference is pseudo-resistance, where some treatments display a bell-shaped dose-response curve. Pseudo-resistance can be defined as a patient being non-responsive to the treatment, but the criteria for treatment resistance are not fulfilled [109].
Lastly, the antidepressant effect of scopolamine was non-significant in the meta-analysis, and this result contradicts the findings from another review. From the sub-group analysis, it was also evident that significant alleviation of depressive symptoms is observed after 3 days; however, after 28 days it is no longer significant [110]. Various reasons suggest extreme caution should be taken before scopolamine is recommended as a therapeutic agent. The latter review included different papers which had the same datasets, and they also mentioned this as the biggest limitation. We excluded those studies because the number of repeated participants is much higher than the newly enrolled participants. For example, in the study with the highest sample size (N = 62) [78], data from 52 participants were previously reported [74,75,76]. Second, the significant antidepressant effect from short-duration studies of scopolamine did not survive our sensitivity analyses, which were not performed by McCaffery and colleagues. Third, GRADE analysis suggested a “very low” certainty of the evidence. Fourth, most scopolamine trials were conducted by the same group of authors. Lastly, the majority of studies were either acute or short-term problems (< 6 weeks); it should be noted that chronic use of scopolamine shows abuse liability [111] and can have significant impact on memory [112]. Therefore, while these data suggest scopolamine may help reduce depressive symptoms in individuals with mood disorders, the dose and route of administration need to be optimised to obtain a clinical response that can produce beneficial results without limiting on-target side effects. More independent replication with a larger sample size would be required to confirm the findings. In the future, novel allosteric modulators, which selectively target central M2 or M3 mAChR with negligible peripheral side effects might show clinical effectiveness in patients with mood disorders [113].
In addition, two RCTs examined the effectiveness of biperiden. Acute biperiden administration showed a significant antidepressant effect. However, a 6-week trial did not demonstrate the substantial antidepressant effect of biperiden compared with placebo [84]. From a clinical perspective, however, long-term M1 receptor antagonism is likely to be problematic, as detailed below. Results from RS-86 studies showed reduction in REM-latency and increase in REM-density, suggesting a possible role of muscarinic receptors in sleep disturbances accompanied by MDD.
4.2 Primary Psychotic Disorders
Muscarinic targeted inventions showed promising results in schizophrenia and psychotic disorders, particularly alleviating positive and negative symptoms. However, there were not enough RCTs to perform a meta-analysis, highlighting the need for additional trials to ascertain the efficacy of such interventions fully. Preliminary data from studies using biperiden suggest that antagonism of the M1 receptor produces mild to moderate impairment in learning and memory processes in subjects with primary psychotic disorders [92, 93]. As mentioned, biperiden is an M1 mAChR preferring antagonist, and cognitive impairment results suggest that down-regulation of the M1 receptor could be a significant contributor to cognitive symptoms of schizophrenia. Although scopolamine has been used to generate “cognitive dysfunction”, it has been observed that, along with cognitive dysfunction, scopolamine also produces impairment in attention and motivation [114]. This effect is due to the non-selective nature of scopolamine. Based on these findings, it was proposed that scopolamine could be used to model cognition dysfunction in AD. Notably, biperiden could be a “cleaner” way to develop a “cholinergic deficit model of cognitive dysfunction” [114]. Previous literature indicates that cognitive impairment may be a vulnerability marker for psychotic disorders as it is also observed in healthy people with high genetic risk [115]. On the contrary to biperiden, xanomeline, an M1/M4 receptor orthosteric agonist, showed significant improvement in positive and negative symptoms of schizophrenia [71]. However, the therapeutic use of xanomeline is limited due to severe gastric side effects, driven by its potential to bind to peripheral muscarinic receptors. The combination of xanomeline with trospium (KarXT) shows a similar therapeutic potential of xanomeline in treating psychotic disorders, with minor side effects compared to xanomeline alone, due to the ability of trospium to block peripheral muscarinic receptors without crossing the blood-brain barrier and thereby alleviate gastrointestinal side effects [72]. Indeed, KarXT has recently shown positive results in the Phase 3 EMERGENT-2 Trial (see https://investors.karunatx.com/news-releases/news-release-details/karuna-therapeutics-announces-positive-results-phase-3-emergent). Based on the KarXT results, M1/M4 receptor-targeted treatments appear to be a novel potential therapeutic approach in primary psychotic disorder patients. In addition to KarXT, a Phase 1b clinical trial is ongoing for the positive allosteric modulator of M4 receptor, emraclidine in patients with schizophrenia and is expected to finish by 2024 (NCT05227703, NCT05227690). Notably, when targeting the orthosteric site, it is essential to consider that drug response to the orthosteric agonist of the M1 receptor was altered in the subgroup of patients with MRDS phenotype. Still, no difference was observed in response to an allosteric agonists, suggesting that positive allosteric modulators with bias signalling may provide a better approach for all types of schizophrenic patients [116]. In this regard, there are several preclinical studies that support positive allosteric modulators of M4 receptors as novel anti-psychotics [117, 118]. For RS-86 in schizophrenia, a significant decline in REM latency was observed, which is similar to the depression [87, 96], while the results for REM density are the opposite. The authors speculated that this REM latency reduction is due to subpopulations of people with schizophrenia also having secondary depression. In a subsequent study, no significant difference emerged when samples were split with and without secondary depression [87, 96], which suggests that REM latency measurement alone is not a sufficient marker to conclude any specific neuropsychiatric disorder.
4.3 Dementia/Alzheimer’s Disease
RS-86 was ineffective for cognition and psychiatric symptoms in patients with mild to moderate AD. Even the highest tolerable dose of 10 mg showed no significant improvement [119]. Similar to RS-86, Lu 25-109 failed to produce a significant difference in cognitive or behavioural symptoms of AD; rather, symptoms worsened at the highest dose of 300 mg, relative to placebo. A potential reason could be that Lu 25-109 also acts as an M2/M3 receptor antagonist, leading to a higher discontinuation rate [102]. There is evidence that xanomeline tartrate (75 mg, TID) is effective for psychiatric symptoms [99]. The results were equivocal for cognitive symptoms as improvement was observed in the neuropsychological test battery but not from the ADAS-cognition subscale [98]. Also, there was a difference in MMSE scores across treatment groups during baseline measurement, which can be a confounding factor for measuring actual treatment effect. The primary concern across most of the dementia studies is the lack of assessor’s blinding information.
In summary, except for xanomeline, no other muscarinic receptor agonist with a higher selectivity for the M1 receptor produced significant improvement in behavioural or psychiatric symptoms of dementia. These results are in line with other previous trials with oxotremorine, pilocarpine and RS-86 [102]. Favourable results from xanomeline suggest a potential role of the M4 receptor in behavioural and psychiatric disturbances associated with dementia. The hypothesis behind antipsychotic efficacy is that activating the M4 receptor reduces hyperdopaminergic activity, an effect confirmed in patients with schizophrenia [59]. Xanomeline may also attenuate the beta-amyloid plaque burden by increasing the secretion of non-amyloidogenic form of precursor protein and may thereby slow down the disease progression [99].
4.4 Anxiety Disorders
Results concerning anxiety disorders are equivocal. Scopolamine treatment did not significantly differ in self-reported distress in public speaking compared to placebo [103]. In contrast, scopolamine administration reduced anxiety rating scale scores in people with mood disorders relative to placebo [74]. While these preliminary studies show some promising results, no conclusions can be drawn, and additional studies are needed to determine the role of muscarinic receptors in anxiety disorders. Preclinical studies point out the possible involvement of the M5 receptor in anxiety [63].
4.5 Strengths and Limitations
In this systematic review, all included studies were randomised (except one pseudo-randomised study), placebo-controlled and double-blind studies. These are considered to produce highest quality of evidence for medical research. A recent review showed a role for cholinergic therapeutics in depressive/manic symptoms [110]. However, they included interventions that can also target nicotinic receptors. So, to our knowledge, this is the first systematic review with a registered protocol assessing the exclusive role of muscarinic receptor-targeted interventions in neuropsychiatric disorders. For risk of bias assessment, we used Cochrane ROB-2 software. Cochrane ROB-2 is a structured tool that helps assess bias in each domain of the study, such as trial design, conduct and reporting rather than overall RCT. To identify publication bias, we undertook sensitivity analyses. We also performed GRADE analysis for meta-analysis findings, a critical approach in assessing the certainty of evidence. A shortcoming in the available data is that only five studies were included for meta-analysis, so we cannot formally evaluate bias due to missing results (such as funnel plot generation) and meta-regression. However, sensitivity analyses allowed us to assess the robustness of the findings.
There are critical limitations in the literature reviewed in the present study. First, sample sizes were small (N < 30) in most included articles; caution is required as underpowered studies may increase error and reduce reliability. Second, numerous studies used different doses and routes of administration. While many studies focused on repeated dosing, some tested acute administration. Acute treatment with biperiden showed improvement in depressive symptoms, and opposite to that, studies lasting 6 weeks failed to see this same efficacy, highlighting the need for optimal treatment protocols. Third, most studies did not report the ethnicity of participants, which can be a limiting factor for the generalisability of findings [120]. Lastly, active comparators/controls are lacking in a number of studies. For instance, in dementia studies, higher rates of adverse events in the treatment but not the placebo condition may have unblinded both participants and assessors; thus, having no active placebo can compromise the integrity of the trial [98, 99].
5 Conclusion and Future Directions
While the results are not yet definitive, findings on muscarinic receptor-targeted interventions in several mental disorders are promising in efficacy and safety, specifically in treating schizophrenia, mood disorders such as MDD and BP and behavioural and psychiatric symptoms of AD. However, several methodological discrepancies question the ability to generalise findings. The most favourable evidence is the combination of M1/M4 agonist xanomeline and trospium (although inconclusive for meta-analysis) in schizophrenia because of a higher safety profile. Weak evidence also tentatively suggests a role for scopolamine in mood disorders, more specifically major depressive and bipolar disorders. For BPSD only xanomeline tartare showed significant improvement, but more evidence is required to validate the results.
In conclusion, the major challenge with orthosteric muscarinic receptor-targeted interventions is a wide range of peripheral adverse effects thought to be mediated via binding to M2/M3 receptors. The orthosteric binding site of mAChR is remarkably conserved, making it challenging to develop subtype-selective interventions. However, many allosteric ligands with biased signalling pathways are in development [16]. Positive allosteric modulators are compounds that increase the co-bound orthosteric pharmacological effect of the ligand. Allosteric modulators with biased signalling pathways can achieve subtype selectivity and be devoid of side effects (off-target or on-target), a key attribute for targeting mAChR in psychiatric disorders [121]. Comprehensive knowledge of pathways and their engagement in the disease could change the therapeutic use of muscarinic targeted interventions. Despite representing a critical target for neuropsychiatric disorders, most of the included studies in this review were less contemporary and receptor non-selective, which makes it difficult to predict clinical effectiveness. In future studies, more subtype-selective interventions are needed to establish clinical effectiveness with limited side effects.
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SV was supported by Melbourne International Research Scholarship. LCW is supported by an NHMRC emerging leader fellowship (GNT2008344). AAG is supported by an NCCRED Seed Funding Grant and Medical Research Future Fund (MRFF). We acknowledge the Victorian State Government Operational Infrastructure Programme. Open Access funding enabled and organized by CAUL and its Member Institutions.
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Vaidya, S., Guerin, A.A., Walker, L.C. et al. Clinical Effectiveness of Muscarinic Receptor-Targeted Interventions in Neuropsychiatric Disorders: A Systematic Review. CNS Drugs 36, 1171–1206 (2022). https://doi.org/10.1007/s40263-022-00964-8
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DOI: https://doi.org/10.1007/s40263-022-00964-8