Abstract
Patients with schizophrenia experience a broad range of detrimental health outcomes resulting from illness severity, heterogeneity of disease, lifestyle behaviors, and adverse effects of antipsychotics. Because of these various factors, patients with schizophrenia have a much higher risk of cardiometabolic abnormalities than people without psychiatric illness. Although exposure to many antipsychotics increases cardiometabolic risk factors, mortality is higher in patients who are not treated versus those who are treated with antipsychotics. This indicates both direct and indirect benefits of adequately treated illness, as well as the need for beneficial medications that result in fewer cardiometabolic risk factors and comorbidities. The aim of the current narrative review was to outline the association between cardiometabolic dysfunction and schizophrenia, as well as discuss the confluence of factors that increase cardiometabolic risk in this patient population. An increased understanding of the pathophysiology of schizophrenia has guided discovery of novel treatments that do not directly target dopamine and that not only do not add, but may potentially minimize relevant cardiometabolic burden for these patients. Key discoveries that have advanced the understanding of the neural circuitry and pathophysiology of schizophrenia now provide possible pathways toward the development of new and effective treatments that may mitigate the risk of metabolic dysfunction in these patients. Novel targets and preclinical and clinical data on emerging treatments, such as glycine transport inhibitors, nicotinic and muscarinic receptor agonists, and trace amine-associated receptor-1 agonists, offer promise toward relevant therapeutic advancements. Numerous areas of investigation currently exist with the potential to considerably progress our knowledge and treatment of schizophrenia.
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Patients with schizophrenia are at higher risk for cardiometabolic abnormalities, such as hypertension, type 2 diabetes, obesity, and metabolic syndrome; current antipsychotics, which directly act on D2 receptors to modulate dopamine, may increase these risks. |
Recent advances in the understanding of the pathophysiology of schizophrenia, including the role of numerous nondopaminergic neurotransmitters, has guided discovery of novel treatments that do not directly target dopamine receptors and that also minimize cardiometabolic burden for these patients. |
Novel medications are beginning to emerge that have the propensity to considerably advance the treatment of schizophrenia and reduce patients’ cardiometabolic burden. |
1 Cardiometabolic Dysfunction and Schizophrenia
For every patient with schizophrenia, risk/benefit decisions that balance a number of medication-related concerns (e.g., metabolic, neurological, endocrine adverse effects) are important drivers of antipsychotic choice. Patients with schizophrenia are at higher risk for cardiometabolic abnormalities, such as hypertension, type 2 diabetes, obesity, and metabolic syndrome, due to a combination of lifestyle factors, illness severity, genetics/epigenetics, and adverse effects of psychiatric medications, especially antipsychotics [1,2,3,4,5,6]. A retrospective database study of over 55,000 US patients with schizophrenia found that ~ 66% had at least one cardiometabolic comorbidity and ~ 40% had two or more [7]. These comorbidities have a significant impact on quality of life and life span, with affected patients having a reduced life expectancy of 10–25 years compared with the general population, largely due to the two-fold increase in standard mortality rates for cardiovascular disease [2, 3, 7,8,9]. A recent meta-analysis of 135 studies has shown all-cause mortality was increased by 2.5-fold in people with schizophrenia versus any nonschizophrenia control group, with the largest risk observed in first-episode and incident, or earlier-phase, schizophrenia versus the general population [10].
While clinicians can control the iatrogenic contribution to cardiometabolic risk through judicious prescribing of lower cardiometabolic risk antipsychotics, such as aripiprazole, brexpiprazole, cariprazine, lumateperone, lurasidone, and ziprasidone, behavioral and environmental mechanisms associated with schizophrenia play a significant role in the development and presence of many comorbid conditions [2, 5, 6, 11,12,13]. Compared with demographically matched peers and patients without major psychiatric disorders, individuals with serious mental illnesses such as schizophrenia and bipolar disorder have higher rates of smoking, sedentary lifestyles, poor dietary habits, substance use, and medication nonadherence; moreover, these risk factors are often inadequately addressed because of lower rates of somatic healthcare access and utilization, a confluence of factors that increase the risk of cardiometabolic dysfunction [5, 14].
From a biological perspective, both schizophrenia and cardiometabolic diseases are highly heritable, with genetics accounting for at least 80% of the pathophysiology in schizophrenia [15, 16]. Investigating biological/genetic mechanisms underlying these conditions can be tricky because of the added interplay of behavioral- and treatment-based causes. However, evidence has suggested that polygenic and pleiotropic effects of genes/gene loci may regulate both schizophrenia and cardiometabolic diseases as well as the effects of medications, especially antipsychotics, on the risk for weight gain and cardiometabolic morbidity/mortality [2, 4, 5, 17,18,19,20]. Clinical evidence that the risk for cardiometabolic abnormalities may be inherent in serious mental disorders has been shown in metabolic studies of treatment-naïve patients with schizophrenia in whom dysfunctional glucose homeostasis, hypothalamic–pituitary–adrenal axis hyperactivity, autonomic nervous system dysfunction, increased levels of systemic inflammatory markers, and lipid abnormalities have all been demonstrable prior to antipsychotic exposure [4, 5, 21]. Recent analyses of possible genetic overlap between cardiometabolic traits and schizophrenia have found tentative polygenic associations between schizophrenia and abnormalities in glucose metabolism, adverse adipokine profile, increased waist-to-hip ratio, and visceral adipose tissue [18].
The implicit disease-related, behavioral, and biological factors that lead to cardiometabolic abnormalities in schizophrenia are exacerbated even more by the adverse metabolic effects of antipsychotic medications necessary to treat the primary disorder. Second-generation antipsychotic drugs (SGAs) are the standard of care for schizophrenia; however, many of the earliest agents in this class were associated with significant adverse metabolic and cardiovascular effects, such as weight gain, dyslipidemia, coronary heart disease, stroke, and glucose dysregulation [1, 2, 12, 22]. Olanzapine and especially clozapine have been associated with high levels of metabolic disruption but have also largely been considered among the most efficacious at preventing relapse in schizophrenia [23, 24]. For patients with treatment-resistant schizophrenia in particular, no viable alternatives to clozapine exist, and clinicians must assiduously monitor metabolic parameters during clozapine treatment. Literature exploring the use of metformin and glucagon-like peptide 1 (GLP-1) agonists to help mitigate clozapine’s metabolic risks provide evidence that these options are effective and well tolerated [25, 26]. Yet not all patients with schizophrenia are treatment resistant, and newer SGAs may have lower metabolic risks compared with older agents [12, 22]. A large network meta-analysis of over 100 controlled trials noted marked differences in metabolic adverse effects seen across all antipsychotics in the acute treatment of schizophrenia, indicating the need for individualized treatment based on the patient’s risk of metabolic complications (Fig. 1) [12].
Although cardiometabolic disease burden in patients with schizophrenia is related to high mortality and lower quality of life, the presence of cardiometabolic risk factors is also associated with poor psychiatric outcomes [27,28,29]. A prospective, population-based study of first-episode patients (N = 1230) demonstrated that both no exposure and high exposure to antipsychotic medications (all dispensed antipsychotics included except lithium) led to a higher risk of cardiovascular mortality versus low or moderate exposure, indicating the need for adequate dosing [30]. While exposure to antipsychotics increases cardiometabolic risk factors that can increase the risk of cardiovascular death, use of antipsychotics has been associated with a decreased risk of all-cause cardiovascular mortality versus no antipsychotic treatment in patients with schizophrenia [10, 31]. This seemingly paradoxical effect of antipsychotics on cardiovascular morbidity and mortality is likely due to better adherence to secondary and tertiary preventive interventions when appropriately treated with antipsychotics [32]. Not surprisingly, all-cause mortality is also higher in patients with schizophrenia not treated with antipsychotics compared with those receiving treatment, indicating that adequate treatment of the psychiatric disorder is crucial to minimizing natural and unnatural causes of death (e.g., suicide, accidents) [2, 30, 33].
The reduction of cardiometabolic risk in these patients relies on an understanding of how these increases in risk occur. Antipsychotic-related weight gain is one pathway to cardiometabolic dysfunction, and in first- and second-generation antipsychotics, there is a strong correlation between weight gain and H1 affinity, especially H1 blockade in the posterior hypothalamus [34, 35]. Antipsychotics that show the highest clinically relevant antagonism of H1 receptors at therapeutic doses stimulate hypothalamic processes that lead to increased appetite and metabolic disruptions [35, 36].
However, there is evidence for weight-independent mechanisms that also underly antipsychotic-related adverse cardiometabolic effects. Mechanisms implicated in these weight-independent effects include muscarinic receptor antagonism based on the role of muscarinic receptors in energy homeostasis and antipsychotic-induced metabolic adverse effects, especially M3 [12]. Various genes for histaminergic, serotonergic, adrenergic, and dopaminergic pathways have also been implicated in antipsychotic-induced weight gain and other metabolic disruptions [34, 36, 37]. For example, evidence suggests that polymorphisms in 5-HT2a and 5-HT2C receptors are associated with various types of metabolic dysfunction, such as obesity, glucose intolerance, and insulin resistance [35]. Serotonin receptors are commonly modulated by many antipsychotics and, therefore, may be another mechanism by which drug-induced metabolic dysfunction occurs.
The cardiometabolic adverse effects of D2-receptor-binding antipsychotics (antagonists and partial agonists) may partly be due to the impact of D2 binding on the ability of pancreatic beta cells to accurately sense glucose levels, resulting in hyperinsulinemia [38]. In addition, preclinical studies have demonstrated that selective D2/D3-blockade enhances insulin secretion, loss of D2-receptors results in glucose intolerance, and administration of haloperidol or olanzapine impairs central glucose effectiveness; however, it is worth acknowledging that the human data are less well developed [39, 40]. These drug-induced effects compound the difficulties in a population that is already predisposed to metabolic comorbidities due to genetic and lifestyle factors [4, 7, 21, 41]. Although SGA tolerability profiles have improved since oral risperidone was approved in the USA in 1993, a broadened understanding of the pathophysiology of schizophrenia has elicited exploration of agents with novel mechanisms that target glutamate, serotonin, acetylcholine, or GABA, and that do not directly target dopamine. These not only have the propensity to minimize cardiometabolic burden, but they may also radically reshape concerns about dopamine D2-related adverse effects as the price to pay for adequate management of the positive symptoms of schizophrenia. A deeper understanding of the neural circuitry and pathophysiology of schizophrenia through further study and new approaches to discovery of treatments would be a critical step in unveiling these novel mechanisms.
2 Neural Circuitry and Pathophysiology of Schizophrenia
For years, the main treatment paradigm for schizophrenia has been postsynaptic dopamine D2 receptor blockade. This has been standard of care since the discovery of chlorpromazine’s antipsychotic properties and the synthesis of other first-generation antipsychotics (FGAs) using animal behavioral assays [42]. Key discoveries confirming dopamine’s involvement included the realization that medications with dopamine D2 blockade were beneficial for positive symptoms and that exposure to dopamine agonists led to psychotomimetic effects [41, 43, 44]. D2-receptor-binding antipsychotics (antagonists and partial agonists) can, as discussed, have cardiometabolic adverse effects, which only compound the difficulties in a population who are already predisposed to these comorbidities [4, 7, 21, 41]. At the same time, although D2 receptor blockade is effective in reducing positive symptoms, ~ 30% of patients are treatment resistant and respond very poorly, if at all, to nonclozapine antipsychotics. Moreover, current antipsychotics provide only modest improvements in negative symptoms and cognitive function [45, 46]. Thus, the reduction of cardiometabolic risk in these patients is only one of many reasons that treatments with new mechanisms of action are needed.
One driver for the development of SGAs was to utilize the model of clozapine, with high levels of 5-HT2A antagonism and low levels of D2 blockade, to mitigate extrapyramidal adverse effects commonly seen with FGAs. The unique efficacy of clozapine, despite low levels of postsynaptic D2 receptor occupancy, was the first hint that other neurotransmitter systems, such as acetylcholine, glutamate, and serotonin, are involved in antipsychotic response and, by extension, may underlie the pathophysiology of schizophrenia [41, 47]. The glutamate hypofunction hypothesis evolved based on observational and experimental studies noting that exposure to N-methyl-d-aspartate (NMDA) antagonists, such as phencyclidine, ketamine, and MK-801, induces psychosis, social withdrawal (a behavioral analog of negative symptoms), and cognitive dysfunction, which are the three core features of schizophrenia. Further research suggested that changes in cortico-limbic NMDA receptor-mediated neuronal transmission modulates downstream dopaminergic transmission via excitation of the striatal structures associated with positive psychosis symptoms [41, 45]. Serotonergic-mediated modulation of this circuitry involves serotonergic input from the raphe nucleus to the ventral tegmental area (VTA), which results in increased dopaminergic output to the striatum (Fig. 2) [48, 49]. The raphe nucleus also innervates the cortex, which could lead to hyperstimulation of cortical glutamate and possibly the hallucinations and delusions associated with psychosis [48]. The epithalamus comprises the dorsal portion of the diencephalon and includes the pineal gland, habenular nuclei, and the tracts that connect these structures [50, 51]. The epithalamus plays a crucial role for the dorsal diencephalic conduction system by conveying information from the limbic forebrain to the limbic midbrain [51, 52]. Signals from the pineal body regulate secretion of melatonin and pituitary hormones, with effects on energy conservation and utilization [53]. The medial habenular nucleus, which projects to structures such as the interpeduncular nucleus, pineal gland, and other midbrain structures, and the lateral habenular nucleus, which descends to GABAergic and dopaminergic neurons in the VTA, are involved in reward, cognitive flexibility, and emotion [50, 54,55,56,57,58]. These nuclei have been shown to have reduced volume and altered functional connectivity in patients with schizophrenia, suggesting a role in the pathogenesis of the disorder [54]. It has been suggested that the habenular nuclei may also control dopaminergic neurons in the VTA, such that excitation of the lateral habenular nucleus activates GABAergic neurons in the VTA resulting in an inhibition of dopaminergic transmission [54]. Thus, there are numerous pathways using various neurotransmitters that may alter regulation of the midbrain dopamine system in patients with schizophrenia.
Cross-sectional neuroimaging studies have suggested that poorer therapeutic responsiveness to D2-receptor modulation is associated with normal striatal dopamine synthesis but elevated anterior cingulate cortex (ACC) and striatal glutamate levels, which may indicate that, in some patients, increased glutamate in certain brain regions determines the level of efficacy of D2 blockade [59]. Further, a meta-analysis of 59 studies found that, compared with controls, patients with schizophrenia had excess glutamatergic transmission in several areas of the limbic system, suggesting that compounds that reduce glutamate, directly or indirectly, may offer therapeutic potential [60].
Much evidence has indicated that the pathophysiology of schizophrenia involves abnormal interactions between different brain regions, many of which are glutamatergic [61]. Magnetic resonance imaging studies have shown structural and functional impairments of the cortico-limbic system circuit, involving the amygdala, hippocampus, cingulate cortex, and prefrontal cortex (PFC), in patients with schizophrenia [62]. In healthy individuals, emotional processing involves interaction of the ventral and dorsal systems of this circuit, with the amygdala (ventral system) functioning in emotional information assessment, and the PFC and ACC (dorsal system), regulating emotional responses [63, 64]. In patients with schizophrenia, the abnormal regulation of emotions has been associated with the amygdala and ACC as well as the dorsal lateral PFC [62]. The hippocampus is a critical glutamatergic structure for learning, memory, and integration of information, and it is also involved in emotions such as anxiety and fear. In patients with schizophrenia, disrupted interaction between the PFC and hippocampus is thought to be the cause of cognitive deficits related to working memory, while the subsequent inputs from the hippocampus to the amygdala are likely to play a significant role in positive symptoms, especially delusions [65, 66]. In addition to glutamate, other neurotransmitters of the amygdala and limbic system include GABA, norepinephrine, and serotonin, all of which may be involved in the pathophysiology of schizophrenia in these areas.
Evidence for the antipsychotic effects of serotonin blockade, specifically 5-HT2A antagonism, includes the fact that clozapine is a potent 5-HT2A antagonist and that pimavanserin, a selective and potent 5-HT2A reverse agonist/antagonist devoid of any dopamine binding is effective for Parkinson’s disease psychosis [67, 68]. Clozapine’s metabolite, norclozapine, is a muscarinic agonist, and activation of muscarinic receptors through this metabolite may contribute to clozapine’s unique efficacy in treatment-resistant schizophrenia. Subsequent studies with experimental compounds found that activation of hippocampal interneurons via muscarinic M2 and M4 autoreceptors increases inhibitory postsynaptic currents in pyramidal neurons, which could normalize excitatory–inhibitory imbalances observed in schizophrenia via attenuation of pyramidal neuron hyperactivity as well as the resultant increase in VTA dopaminergic neurotransmission [69,70,71]. Additionally, muscarinic acetylcholine receptor activation in striatal interneurons can reduce cholinergic tone and subsequently striatal dopamine levels, offering another possible site of targeted dopamine modulation without the risk of cardiometabolic dysfunction [41].
The changes within these numerous circuits and cascades, starting with dysfunction in cortical glutamatergic transmission and ending in increased dopamine neurotransmission in the associative and adjacent sensorimotor striatum, are parts of the neuronal pathology seen in schizophrenia. These pathways thus offer multiple sites at which to target new treatments with greater efficacy and safety, with the broad array of targets offering various avenues of modulation. However, an ideal treatment would still need to be efficacious across a range of symptoms as well as have a safety profile that does not include the major neurologic, endocrine, and cardiometabolic adverse effects that are seen among drugs that are currently available [72].
3 Novel Targets and Emerging Treatments with Reduced Likelihood of Metabolic Disturbance
As FGAs, serotonin–dopamine antagonist and partial D2-agonist SGAs all act directly at D2 receptors, they all possess inherent risks for D2-related cardiometabolic, neurologic, and endocrine-related adverse effects; however, there are varying degrees of risk [11]. One strategy to improve the benefit–risk profile of these drugs has been to use combination treatments of SGAs with drugs that may decrease the risk of cardiometabolic adverse effects. One example is a Food and Drug Administration (FDA)-approved combination treatment for schizophrenia that includes the SGA olanzapine, a D2-receptor antagonist with additional effects on 5-HT, and samidorphan, a µ-opioid antagonist and partial κ- and δ-opioid agonist, which has been shown to reduce medication-induced weight gain and metabolic dysfunction [73]. Efficacy, as measured by the Positive and Negative Syndrome Scale (PANSS) and Clinical Global Impression Severity (CGI-S) scales, was intact, as significant reductions from baseline in both measures compared with placebo were observed, even with long-term combination treatment over 52 weeks [74]. In the 12–24 week studies designed to reduce the risk of weight gain, weight changes were consistent across trials, with data showing superiority of the olanzapine-samidorphan combination versus olanzapine [73, 75, 76]. Specifically, data indicated 37% lower weight gain and a 50% reduced likelihood of ≥ 7 and ≥ 10% body weight gain with combination treatment versus olanzapine monotherapy, with results extending to early phase patients [73, 75, 76]. In addition, in patients free of metabolic syndrome or hypertension, compared with olanzapine, the olanzapine–samidorphan combination minimized the incidence of metabolic syndrome and hypertension by approximately 50% [77]. These results, together with data from augmentation studies with metformin and the glucagon-like peptide-1 receptor agonist liraglutide, [25, 78,79,80,81,82] illustrate that treatment with available and effective antipsychotics combined with medications that may mitigate the metabolic adverse effects of these drugs may be one strategy by which to reduce the inherent risks associated with dopamine receptor-blocking medications. However, to further obviate the concerns about potential adverse consequences of D2 receptor blockade, non-postsynaptic dopamine receptor–modulating treatments that target alternative receptor systems implicated in the pathophysiology of schizophrenia have also been heavily studied.
3.1 Glutamate
The excitatory–inhibitory imbalance in cortical/hippocampal glutamatergic and hippocampal parvalbumin GABAergic interneuron neurotransmission were obvious targets for treatments to potentially address positive, negative, and cognitive symptoms of schizophrenia (Fig. 2) [83]. The NMDA receptor has co-agonist binding sites for glutamate and glycine, and the glycinergic site is also stimulated by d-serine. On the basis of the NMDA-hypofunction hypothesis of schizophrenia discussed above, facilitating NMDA receptor activity via adjunctive glycine or d-serine was studied, and initial clinical trials demonstrated improvements in both positive and negative symptoms; however, these findings could not be replicated in larger studies [41, 84,85,86]. Agonists of the glycine-modulatory site can either interact directly or indirectly with the glutamatergic system. d-cycloserine is an antibiotic metabolite that interacts directly with the NMDA glycine site as a partial agonist. In preclinical studies, administration of d-cycloserine has resulted in improved cognition, facilitated conditioned fear extinction, and improved memory consolidation and visual recognition memory [87]. Clinical studies with d-cycloserine have, however, been inconsistent, with some showing therapeutic efficacy for negative symptoms and cognition and others showing no effect. Explanations for the inconsistent results include insufficient central blood levels, drug–drug effects, a small therapeutic window for d-cycloserine, and possible neurotoxic effects.
Indirect effects at the glycine-modulatory site involve enhancement of synaptic glycine/d-serine through blocking astrocytic glycine transporters [87]. Studies with glycine transporter type 1 inhibitors have been investigated, but the most extensively studied, bitopertin, failed in phase 2 and phase 3 trials [88, 89]. Conversely, slowing d-serine metabolism using a d-amino acid oxidase inhibitor (DAAO) has shown early promise in patients with chronic schizophrenia, although recent trials for negative symptoms have not been positive [90, 91] (press release). Unfortunately, some inhibitors of d-serine metabolism show both poor bioavailability and inability to effectively cross the blood–brain barrier [92]. Nevertheless, luvadaxistat, a DAAO inhibitor, is currently being studied for cognitive impairment in schizophrenia [93, 94]. Furthermore, iclepertin, a glycine transporter-1 inhibitor separated from placebo in a phase 2 trial for cognition versus placebo (not statistically significant for functional improvement) [95], and is being tested in phase 3 trials for cognitive impairment in schizophrenia [94]. Table 1 outlines study designs, safety, and available metabolic results for all of the discussed emerging treatments.
3.2 Nicotinic and Muscarinic Receptor Agonists
As mentioned, cholinergic targets have been of interest, with preclinical and early proof-of-concept studies indicating that α7 nicotinic acetylcholine receptor (α7-nAChR) and muscarinic acetylcholine receptor (mAChR) activation results in antipsychotic/pro-cognitive effects in animal models, as well as improvements in positive and cognitive symptoms in patients with schizophrenia [96]. α7-nAChR agonists have been shown to reverse the hyperdopaminergic state in the methylazoxymethanol acetate development disruption rodent model of schizophrenia, likely through ventral hippocampal modulation of dopamine neuron population activity, and have been shown to contribute to the release of dopamine in the nucleus accumbens [97]. Postmortem immunohistochemical/binding studies show reduced levels of α7-nAChR in brain regions thought to be affected in schizophrenia (e.g., hippocampus, thalamus, cingulate cortex) [96]. Genetic studies also link dysfunction in the α7-nAChR to increased risk for schizophrenia, and nicotinic agonists can normalize many sensory processing deficits that occur in schizophrenia [98]. From these insights, nicotinic α7 receptor agonists were studied for many years for the treatment of positive and cognitive symptoms of schizophrenia, but with mixed results. Issues with dosing and subtype selectivity of α7-nAChR agonists may have been confounding factors in understanding the role of activation of this receptor in schizophrenia, and new ligands with more specificity were developed [i.e., full agonists, partial agonists, and positive allosteric modulators (PAMs)]. Results with these α7-nAChR agonists, however, have been inconclusive. In a meta-analysis of eight double-blind, placebo-controlled studies examining efficacy and safety of various α7-nAChR agonists in treating the negative and cognitive symptoms of schizophrenia, no significant effects of the agonists on cognitive function or negative symptoms were found over placebo [99]. DMXB-A is a partial α7-nACh agonist that showed improvements in attention and working memory as well as reductions in hippocampal neuronal hyperactivity in phase 2 clinical studies; however, no significant benefits were observed with a slow-release version of the drug [98]. Encenicline, another α7 partial agonist, had statistically significant benefits over placebo on multiple cognitive measures when administered as adjunctive treatment in patients with schizophrenia [100]. In phase 3 studies, however, encenicline had significant adverse effects and showed no treatment benefits for schizophrenia [98]. Similar inconsistent results have been observed following adjunctive treatment with α7-nAChR full agonists, and although positive allosteric modulators showed promise in preclinical studies, none have shown significant benefits in cognition or negative symptoms in phase 3 trials [41]. Further, a recent meta-analysis of 13 randomized controlled trials of adjunctive α7-nAChR agonists in schizophrenia found that no significant effects were observed in speed of processing, attention/vigilance, working memory, verbal learning, visual learning, social cognition, or problem solving versus placebo [101]. Thus, the role of α7-nAChR modulation in schizophrenia remains unclear, and additional well-controlled clinical trials will be necessary to provide a clearer picture of how this receptor can function in the treatment of the disorder.
While nicotinic strategies have been disappointing to date, muscarinic agonism has now moved to the forefront of viable non-postsynaptic antidopaminergic antipsychotic mechanisms with positive data in clinical trials. There are five known G protein-coupled human muscarinic receptor subtypes (M1–M5) that are widely distributed in the central nervous system [102, 103]. These receptor subtypes are subdivided into two classes based on their coupling to G protein-dependent signal transduction pathways. M1, M3, and M5 are located mostly postsynaptically and are stimulatory, coupling primarily through Gq/11 to stimulate phospholipase C, which releases inositol 1,4,5-trisphosphate (IP3) [104, 105]. IP3 release increases intracellular calcium, resulting in greater excitatory postsynaptic currents. M2 and M4, which make up the second class of mAChRs, are located mostly presynaptically and are inhibitory, coupling with Gi/o, which inhibits adenylate cyclase and leads to a decrease in cyclic adenosine monophosphate (cAMP), resulting in suppression of neuronal excitation [104, 105]. Elucidating and isolating the individual mechanisms of action of these receptors in schizophrenia is a challenge in part because the orthosteric binding site is highly conserved across all five receptor subtypes, making synthesis of selective ligands difficult [104, 105].
The various subtypes of muscarinic AChRs seem to play a unique role in the pathophysiology of schizophrenia and in modulation of striatal dopamine release. The distribution of muscarinic AChRs is not uniform throughout the brain, with the M1 and M4 receptors being predominantly expressed in the striatum [104]. Striatal cholinergic interneurons (SCIs) tonically inhibit striatal dopamine release, primarily through the M4 receptor [106, 107]. These neurons play a crucial role in regulating the activity of other striatal neurons, particularly the medium spiny neurons (MSNs), which are the main striatal output neurons [108]. Studies have implicated dysfunction in SCIs (e.g., alterations in density, morphology, and gene expression) in patients with schizophrenia, which could result in abnormal cholinergic signaling in the striatum [109]. Numerous consequences of this imbalance in signaling are possible. For example, increased cholinergic activity in the striatum due to dysfunction of SCIs could lead to excessive inhibition of MSNs [104]. This increased inhibition could disrupt the normal balance between the direct and indirect dopaminergic pathways of the basal ganglia circuitry that are involved in numerous processes including motor control and cognition, as well as positive and negative symptoms observed in schizophrenia [110]. Modulation of dopamine release in the striatum through cholinergic signaling may, thus, result in an imbalance between dopamine and acetylcholine, which may have significant impact in the pathophysiology of schizophrenia.
In terms of dopaminergic input to the striatum, M5 AChRs on the cell bodies of dopaminergic neurons in the VTA receive cholinergic input from the laterodorsal tegmental (LDT) and the pedunculopontine (PPT) nuclei (Fig. 3A) [105]. Stimulation of the LDT triggers a long-term increase in dopamine release from the VTA to the nucleus accumbens in the ventral striatum, another area implicated as having dysfunctional dopamine neurotransmission in schizophrenia [111, 112]. This sustained increase in dopamine release is not observed in M5 knockout mice, likely due to a lack of excitatory M5 receptors located on the dopaminergic VTA neurons in these mice [111, 112]. While M5 AChRs serve to increase dopaminergic release from the VTA, activation of upstream midbrain M4 autoreceptors may decrease dopaminergic output through attenuation of acetylcholine release from LDT and PPT inputs (Fig. 3A) [105, 107]. In the nucleus accumbens, M4 autoreceptors on cholinergic interneurons regulate acetylcholine release, which indirectly modulates the release of dopamine through nicotinic autoreceptors on the dopaminergic neurons (Fig. 3B) [108]. This modulation of release is complex, resulting in an interneuronal fine tuning of dopamine that depends on the amount of dopamine release. During low-frequency dopamine firing, activation of these nAChRs may result in excitatory stimulation and increased dopamine release. However, during high-frequency dopamine firing, activation of these nACh autoreceptors suppresses dopamine release in the nucleus accumbens. At the same time, M5 AChRs located on the dopaminergic neuron can also directly decrease the release of dopamine in the nucleus accumbens (Fig. 3B). Localization of these AChRs in the VTA, nucleus accumbens, and ventral striatum, along with evidence of their various effects, indicates that AChRs have the propensity to regulate dopaminergic transmission in numerous subtle ways that could have sizeable implications for patients with schizophrenia.
Preclinical studies in muscarinic knockout mice have demonstrated the importance of muscarinic receptors in the pathophysiology of schizophrenia, especially of the M1 and M4 subtypes [106, 113]. Multiple studies of postmortem brains from patients with schizophrenia and healthy controls have shown that patients with schizophrenia had significantly lower expression of M1/M4 receptors in various areas of the hippocampus and PFC than brains of those who had no history of psychiatric illness; across these studies, ~ 25% of patients expressed ~ 75% lower levels of the M1 receptor compared with control individuals [114,115,116]. M1 receptor-mediated modulation of psychosis may be due to regulation of top-down cortical circuits, modulation of the excitability of striatal neurons, and/or enhanced collateralization between basal ganglia pathways [117]. More specifically, disinhibition of excitatory output from the frontal cortex may lead to hyperstimulation of mesocorticolimbic neurons, including in the associative striatum, resulting in positive symptoms of schizophrenia. The M1 receptor is expressed on cortical GABAergic neurons that connect to the primary output neurons of the frontal cortex, such that when M1 receptors are activated they increase GABA release onto cortical pyramidal neurons leading to decreased glutamatergic input to the midbrain dopamine neurons [117]. Functionally, M1 activation in the hippocampus/forebrain potentiates NMDA receptor currents, which play a considerable role in the regulation of cognitive functions and neural circuitry that is disrupted in schizophrenia, suggesting that modulation of M1 AChRs may have effects on cognitive and psychotic deficits present in schizophrenia [96]. M4 receptors are also highly expressed in the central nervous system (CNS) as pre- or postsynaptic autoreceptors in the hippocampus, cortex, limbic system, and basal ganglia, and have been implicated in regulating dopaminergic neurons involved in movement and cognition [104, 107].
Studies in rodent models confirmed the antipsychotic activity of xanomeline, an orthosteric M1/M4 agonist. Results showed reduced dopamine firing in the VTA, reversal of dopamine agonist-induced disruptions, and low likelihood of inducing catalepsy with xanomeline [118,119,120]. In addition, radioligand binding studies have shown that xanomeline is a 5-HT1A and 5-HT1b agonist, which may allow for benefits in cognition; however, these results have not been fully confirmed [121, 122]. The preclinical profile of xanomeline indicates that binding is nonselective, while the functional effects are much more selective [118, 120, 123,124,125,126]. In early clinical trials, xanomeline was shown to significantly improve cognitive function and psychotic behaviors in patients with Alzheimer’s disease (N = 343); however, gastrointestinal adverse events (AEs) suggested tolerability issues with treatment [124, 127]. These results have been similar to those seen in patients with schizophrenia.
An exploratory 4 week, double-blind, placebo-controlled study was conducted to assess the efficacy of xanomeline on various clinical outcomes in patients with schizophrenia (N = 20) [103]. Results showed statistically significant improvements with xanomeline versus placebo in Positive and Negative Syndrome Scale (PANSS) total score, positive and negative symptom subscale scores, and Clinical Global Impression (CGI) scores. No significant extrapyramidal symptoms were detected. Unfortunately, similar to the study of xanomeline in Alzheimer’s disease, gastrointestinal AEs were reported more frequently in the xanomeline groups versus those on placebo, although most were mild or moderate with none leading to discontinuation of treatment. No significant metabolic or weight changes were reported with xanomeline treatment compared with placebo. Although this was a small pilot study, these data indicated that xanomeline should be further investigated as a potential new treatment for schizophrenia that may not induce the metabolic and extrapyramidal AEs observed with current antidopaminergic antipsychotics. Nevertheless, the risk of syncope, nausea, and vomiting, among other peripheral procholinergic AEs, stalled the further development of xanomeline.
More recently, however, the efficacy and safety of xanomeline combined with the non-centrally active anticholinergic trospium, added to neutralize the peripheral pro-cholinergic AEs, was assessed in a 5 week phase 2 trial in adults with acute exacerbations of schizophrenia [128]. Treatment with xanomeline–trospium resulted in greater improvements in PANSS positive and negative symptom subscores, categorical CGI severity (CGI-S) scores, and PANSS Marder negative symptom subscore at week 5 compared with placebo (Fig. 4A–E). The effect size for reduction in total PANSS score was in the high–medium range, 0.75, hypothesized to possibly be related to a very low placebo response (Fig. 4F). The incidence of cholinergic/anticholinergic AEs was higher in the active treatment group versus placebo, including gastrointestinal AEs; however, the percentage of patients who discontinued treatment were similar across both groups, and no discontinuations in the xanomeline–trospium group occurred due to gastrointestinal AEs (Table 2). Additionally, no differences in weight gain, somnolence, restlessness, or extrapyramidal symptoms were observed across the two groups. These study results provide positive evidence for the use of xanomeline–trospium as an alternative treatment for schizophrenia that does not appear to induce the metabolic or extrapyramidal AEs seen with many of the dopaminergic antipsychotics. Lastly, topline results of the phase 3 trial in adults with an acute exacerbation of schizophrenia were announced in a press release on 8 August 2022 [129]. Like the phase 2b study, this was a 5 week, fixed titration, double-blind, placebo-controlled inpatient trial, but in this study, 252 adults were randomized in a 1:1 manner to xanomeline-trospium or placebo. The results confirmed the findings of the phase 2b trial, with an effect size for reduction in total PANSS score in the medium range (Cohen’s d = 0.61), and a similar efficacy and tolerability profile as reported for the 2b trial. Overall discontinuation rates were similar between treatment and placebo groups (25% versus 21%), and discontinuation rates related to adverse effects were also similar between the two groups (xanomeline–trospium 7% versus placebo 6%).
Emraclidine (CVL-231) is a muscarinic M4-selective PAM in development for schizophrenia [130]. While the orthosteric site is highly conserved across all five muscarinic receptor subtypes, the allosteric sites vary considerably, thereby allowing a targeted approach to modulating M4 activity through the use of allosteric binding sites. A small phase 1b study in 81 adults with acutely exacerbated schizophrenia demonstrated statistically significant and clinically meaningful antipsychotic effects, both with the 30 mg once daily and 20 mg twice daily doses, in PANSS total, positive, and negative scores. Emraclidine was generally well tolerated, with a similar incidence of treatment-emergent AEs (TEAEs) to placebo, including only few peripheral procholinergic AEs and no weight gain or extrapyramidal symptoms.
Taken together, these data indicate that modulation of mAChRs should be further explored as a mechanism for the treatment of schizophrenia, as it could lead to benefits in various symptoms without causing many of the AEs seen with currently available antipsychotics. However, further studies are necessary to better understand the true potential for this mechanism of treatment across different symptom domains and patient subgroups with schizophrenia.
3.3 Trace Amine-Associated Receptor 1 Agonists
Another target that may lead to promising treatments for schizophrenia is agonism of trace amine-associated receptor 1 (TAAR1). TAAR1 is a G protein-coupled receptor discovered in 2001 that is activated by endogenous trace amines and interacts functionally with dopamine and serotonin receptors [41, 131,132,133]. Endogenous levels of trace amines in the CNS are very low (several hundred-fold lower than monoamine neurotransmitters) [134]. The regional expression of mammalian TAAR1 receptors shows their presence in the PFC, striatum, amygdala, nucleus accumbens, VTA, and dorsal raphe, all of which are implicated in the pathophysiology of schizophrenia [131, 134, 135]. Genetically, the TAAR family of receptors have been localized to human chromosome 6q23.2, a putative susceptibility locus for schizophrenia; moreover, several rare variants in TAAR1 have been observed in both patients with psychiatric and metabolic disorders [134,135,136]. TAAR1 may also be activated by monoamine neurotransmitters, such as dopamine, serotonin, norepinephrine, and some of their metabolites [134, 135, 137]. Activation of TAAR1 may modulate presynaptic dopamine synthesis, producing antipsychotic effects, and may also induce changes in D2 receptor-mediated signaling through the formation of heterodimers that are internalized from the cell surface to inside the cell [137,138,139].
Results from TAAR1-knockout mice studies and trials showing that selective TAAR1 agonism inhibits both dopaminergic and serotonergic neuronal activity led to further studies characterizing the role of TAAR1 in the modulation of monoaminergic circuits (Fig. 5) [139,140,141,142]. TAAR1 is an intracellular Gαs-coupled receptor that stimulates adenylyl cyclase and increases production of cAMP, which can lead to protein kinase A and protein kinase C phosphorylation; these kinases regulate many cognitive processes that are disrupted in schizophrenia (e.g., attention, decision-making) [132, 133, 143, 144]. Although TAAR1 receptors are bound to intracellular ligands, a recent in vitro study with the TAAR1 agonist SEP-363856 (ulotaront) indicates that agonists can activate the TAAR1–D2 receptor complex at the cell surface plasma membrane [137]. This surface activation results in recruitment of the G-protein Gαs and stimulation of G-protein-coupled inwardly rectifying potassium channels, which is one putative mechanism by which TAAR1 agonism may reduce dopaminergic activity in the VTA [134, 137]. A G-protein-independent, β-arrestin2-mediated pathway may be affected once TAAR1 and D2 receptors form heterodimers. Formation of these heterodimers causes a shift from cAMP accumulation with TAAR1 alone to β-arrestin2 recruitment with the D2 heterodimers. This process could have important implications, given the increasing recognition of the role played by non-G-protein-coupled pathways in the pathophysiology of schizophrenia [135, 145].
Other proposed active heterodimerizations between TAAR1 and G-protein-coupled receptors include 5-HT1B, 5-HT2A, and 5-HT1A; however, the specific effects of these receptors in schizophrenia are not yet fully understood [134]. Behavioral deficits induced by NMDA receptor antagonists PCP, L-687, 414, and ketamine can be attenuated by TAAR1 agonists [134, 146]. Thus far, TAAR1 agonists have shown no direct affinity for NMDA receptors or any monoamine receptor beyond those discussed. Although TAAR1 seems to modulate a number of neurotransmitter systems indirectly [147], there is no evidence of direct binding to these receptors. There is preclinical evidence that TAAR1 may modulate inflammatory cytokine production, is expressed in human macrophages, and is involved in immunomodulation [148, 149]. However, the manner in which this activity may affect metabolic dysfunction and symptoms of schizophrenia is not yet clear and requires further elucidation. The underlying mechanisms behind this effect require further elucidation but may either involve modulation of glutamate-mediated transmission directly or effects on dopaminergic circuits, which lie downstream of cortical/hippocampal inputs. As stated earlier, cortical glutamatergic neurotransmission partly underlies the pathophysiology of schizophrenia, and the effects of TAAR1 on this circuitry has the propensity to reduce cognitive impairment through modulation of excitatory/inhibitory imbalances mediated by glutamate dysfunction in the cortex.
Of note, TAAR1 is also expressed in the β-cells of the pancreas, the stomach, and the small intestine [143, 150]. TAAR1 activation has been shown to reduce food intake, control glucose, delay gastric emptying, and, likely due to its colocalization with GLP-1 in the duodenum, may regulate hormone secretion that modulates gastric function and nutrient absorption (Fig. 6) [143]. TAAR1 also has the propensity to reduce metabolic dysfunction, in that TAAR1 agonism promotes antidiabetic signaling via a Gαs-mediated pathway [150]. This pathway results in increased insulin secretion, improved β-cell function, and β-cell proliferation. In addition, TAAR1 agonists do not induce weight gain and can protect against olanzapine-induced weight gain [131]. Reduction in brain monoaminergic signaling via TAAR1 agonism also leads to reduced binge eating and impulsive behavior, which can both contribute to mitigating obesity and metabolic disease [150]. This effect is thought to occur via TAAR1-mediated downregulation of dopamine reward circuits. These findings further highlight the therapeutic potential of TAAR1. The combined effects of TAAR1-mediated reductions in binge eating, beneficial TAAR1 effects on pancreatic β-cells, insulin, gastric emptying, glucose control, and the many mechanisms by which TAAR1 can attenuate the symptoms of schizophrenia make it an exciting possible new target for treatment.
Following the identification of various preclinical pharmacological characteristics, two TAAR1 agonists are in development for the treatment of schizophrenia, with one already showing therapeutic potential in patients with schizophrenia. Ralmitaront (RO6889450) is a TAAR1 partial agonist, with more antagonism than agonist activity, that was in phase 2 development (NCT03669640). Two double-blind, placebo-controlled, randomized trials were underway to examine the preliminary efficacy and safety of ralmitaront in patients with schizophrenia (NCT03669640 and NCT04512066). However, a recent press release indicated that in both trials, ralmitaront missed its primary endpoint versus placebo, the reduction in total PANSS scores, and is no longer being studied [151].
Ulotaront (SEP-363856) is a TAAR1 agonist with functional 5-HT1A agonist activity that was discovered based in part on a mechanism-independent approach using the in vivo phenotypic SmartCube® platform (PsychoGenics, Paramus, NJ, USA) and artificial intelligence (AI) algorithms [140, 152]. This approach involves training the AI system on the signature of known psychotropics (e.g., antipsychotics, antidepressants, anxiolytic) using over 2000 behavioral outcomes (e.g., activity, grooming). Importantly, this discovery process specifically eliminated molecules with D2 or 5-HT2A antagonism (antitargets) prior to animal behavioral screening. Ulotaront has been shown to inhibit dorsal raphe serotonergic neuronal firing and attenuate phencyclidine-induced hyperactivity in rodent models [140, 153]. In terms of cardiometabolic issues, preclinical data have shown that rats switched from olanzapine to ulotaront showed rapid reversal of olanzapine-induced weight gain and food intake compared with placebo (Fig. 7), supporting previous studies showing that TAAR1 agonism can reverse cardiometabolic dysfunction [131].
In 2020, data were published from a phase 2, randomized, flexible-dose, placebo-controlled, 4 week inpatient study of ulotaront in 245 acutely psychotic adult patients with schizophrenia [140]. Results for the primary endpoint showed a mean change from baseline in PANSS total score at week 4 that was significantly greater than placebo, with a least squares (LS) mean difference of − 7.5 between ulotaront and placebo (Fig. 8). Of note, statistically significant separation from placebo did not occur until week 3 for total symptoms and week 4 for CGI-S score, an interesting finding that requires further exploration once phase 3 results are available.
AEs with ulotaront were similar to those with placebo, including with respect to extrapyramidal symptoms (3.3 versus 3.2%, respectively), the percentage of patients who had to use medication to treat extrapyramidal symptoms, and results on movement disorder scales [140]. Changes in body weight, lipid levels, glucose, and prolactin were similar across treatment groups, and no other changes in metabolic laboratory or electrocardiogram results were observed. These safety data are consistent with expected results in the absence of D2-binding with ulotaront. However, although no adverse metabolic changes were observed, longer and larger studies are necessary to further investigate the effects of ulotaront on cardiometabolic parameters. This study had one interesting limitation, namely, that patients over 40 years of age and those with greater illness chronicity (≥ 2 previous hospitalizations for schizophrenia exacerbations) were not included [140]. However, in the phase 3 trial program of ulotaront, the age range was extended to 60 years of age.
A 26 week open-label extension (OLE) was performed to provide more data on efficacy and safety (e.g., long-term metabolic changes) [152]. Over 26 weeks, ulotaront treatment resulted in mean (95% CI) change from baseline in PANSS total score of − 22.6 (− 25.6 to − 19.6; effect size, 1.46); however, this should be interpreted with caution due to the open-label nature of OLEs and the lack of a control. Nevertheless, even following 6 months of treatment with ulotaront, only slight changes from baseline in body weight [mean (SD), − 0.3 (3.7) kg], cholesterol (median, − 2.0 mg/dL), triglycerides (median, − 5.0 mg/dL), and prolactin (female median, − 3.4 ng/mL; male median, − 2.7 ng/mL) were observed. On the basis of available clinical data and its unique mechanism of action, ulotaront is a promising new agent that is in phase 3 development for the treatment of schizophrenia. Taken together, the TAAR1 agonists represent a novel pharmacologic class that may be effective in the treatment of schizophrenia without both cardiometabolic adverse effects and the typical side effects stemming from blockade of D2 signaling.
4 Conclusions
It is important to again note that medications are but one input into the overall metabolic burden associated with schizophrenia. As stated, there are also direct underlying biological components of the illness itself (e.g., inflammatory/neuroendocrine factors, genetics) as well as lifestyle elements, often driven by economic necessity, which make a significant contribution to the metabolic dysfunction observed in these patients. Because patients with schizophrenia have this increased risk for cardiometabolic abnormalities, despite antipsychotic exposure, the effects of novel medications on cardiometabolic status beyond neutrality (i.e., improvement in patients’ existing comorbidities) are of great importance. Thus far, for the newer compounds discussed above, appropriate long-term results for cardiometabolic effects have not yet been released, with the exception of continued cardiometabolic neutrality in a 6 month open-label extension study with ulotaront [152]. Although short-term clinical and preclinical data regarding effects such as weight gain, glucose control, and lipid levels may be an indication of how these drugs may perform in patients with schizophrenia, long-term clinical results will be of great interest.
Future investigations should include examination of the effects of novel medications on cardiometabolic comorbidities, negative and cognitive symptoms, functionality, quality of life, and relapse prevention in patients with schizophrenia. Medications that also provide improvements in treatment-resistant patients and those with multiple diagnoses (e.g., substance use, depression) would be advantageous. The potential for genotyping/subtyping patients with schizophrenia is also an area of interest for future research, as a fuller understanding of the heterogeneity within the disease is a critical aspect in attaining success in individualized treatment.
Replication of acute efficacy and safety findings for all of the novel treatments currently under investigation in further phase 3 trials will be of interest. The effects of illness duration and prior antidopaminergic treatments on the effects of any newly introduced drugs will also be beneficial in learning how best to utilize these therapies. The efficacy and safety of muscarinic agonists/positive allosteric modulators and TAAR1 agonists, when coadministered with postsynaptic D2 blockers, would be of interest since it is possible that concomitant treatment of these novel agents with postsynaptic dopamine antagonists/partial agonists could ameliorate residual positive and/or negative symptoms. The possibility of TAAR1 agonist add-on therapy benefiting patients with insufficient response to currently available dopamine receptor blocking agents is quite intriguing based on preclinical data. Although the initial focus of the development program has been on patients with acute psychotic exacerbation, a TAAR1 adjunctive study of patients with residual psychotic symptoms despite ongoing dopamine receptor blocking treatment would be of great interest. Combination treatment may also allow for reduced dosing of current dopamine-blocking antipsychotics, thereby mitigating D2 antagonism-related adverse effects, and possibly leading to a decrease in antipsychotic-induced cardiometabolic abnormalities, insofar as they are dose dependent [22].
With a newly emerging understanding of the complex mechanisms underlying schizophrenia and metabolic dysfunction, future studies of medications with novel mechanisms of action and their effects on psychosis and cardiometabolic dysfunction may lead to considerable advancements in the treatment of schizophrenia.
References
De Hert M, Detraux J, van Winkel R, Yu W, Correll CU. Metabolic and cardiovascular adverse effects associated with antipsychotic drugs. Nat Rev Endocrinol. 2011;8(2):114–26. https://doi.org/10.1038/nrendo.2011.156.
Correll CU, Detraux J, De Lepeleire J, De Hert M. Effects of antipsychotics, antidepressants and mood stabilizers on risk for physical diseases in people with schizophrenia, depression and bipolar disorder. World Psychiatry. 2015;14(2):119–36. https://doi.org/10.1002/wps.20204.
De Hert M, Correll CU, Bobes J, Cetkovich-Bakmas M, Cohen D, Asai I, et al. Physical illness in patients with severe mental disorders. I. prevalence, impact of medications and disparities in health care. World Psychiatry. 2011;10(1):52–77. https://doi.org/10.1002/j.2051-5545.2011.tb00014.x.
Pillinger T, Beck K, Gobjila C, Donocik JG, Jauhar S, Howes OD. Impaired glucose homeostasis in first-episode schizophrenia: a systematic review and meta-analysis. JAMA Psychiat. 2017;74(3):261–9. https://doi.org/10.1001/jamapsychiatry.2016.3803.
De Hert M, Detraux J, Vancampfort D. The intriguing relationship between coronary heart disease and mental disorders. Dialog Clin Neurosci. 2018;20(1):31–40. https://doi.org/10.31887/DCNS.2018.20.1/mdehert.
Smith J, Griffiths LA, Band M, Horne D. Cardiometabolic risk in first episode psychosis patients. Front Endocrinol (Lausanne). 2020;11: 564240. https://doi.org/10.3389/fendo.2020.564240.
Correll CU, Ng-Mak DS, Stafkey-Mailey D, Farrelly E, Rajagopalan K, Loebel A. Cardiometabolic comorbidities, readmission, and costs in schizophrenia and bipolar disorder: a real-world analysis. Ann Gen Psychiatry. 2017;16:9. https://doi.org/10.1186/s12991-017-0133-7.
Nordentoft M, Wahlbeck K, Hällgren J, Westman J, Osby U, Alinaghizadeh H, et al. Excess mortality, causes of death and life expectancy in 270,770 patients with recent onset of mental disorders in Denmark, Finland and Sweden. PLoS ONE. 2013;8(1): e55176. https://doi.org/10.1371/journal.pone.0055176.
Hennekens CH, Hennekens AR, Hollar D, Casey DE. Schizophrenia and increased risks of cardiovascular disease. Am Heart J. 2005;150(6):1115–21. https://doi.org/10.1016/j.ahj.2005.02.007.
Correll CU, Solmi M, Croatto G, Schneider LK, Rohani-Montez SC, Fairley L, et al. Mortality in people with schizophrenia: a systematic review and meta-analysis of relative risk and aggravating or attenuating factors. World Psychiatry. 2022;21(2):248–71. https://doi.org/10.1002/wps.20994.
Huhn M, Nikolakopoulou A, Schneider-Thoma J, Krause M, Samara M, Peter N, et al. Comparative efficacy and tolerability of 32 oral antipsychotics for the acute treatment of adults with multi-episode schizophrenia: a systematic review and network meta-analysis. Lancet. 2019;394(10202):939–51. https://doi.org/10.1016/s0140-6736(19)31135-3.
Pillinger T, McCutcheon RA, Vano L, Mizuno Y, Arumuham A, Hindley G, et al. Comparative effects of 18 antipsychotics on metabolic function in patients with schizophrenia, predictors of metabolic dysregulation, and association with psychopathology: a systematic review and network meta-analysis. Lancet Psychiatry. 2020;7(1):64–77. https://doi.org/10.1016/s2215-0366(19)30416-x.
Burschinski A, Schneider-Thoma J, Chiocchia V, Schestag K, Wang D, Siafis S, et al. Metabolic side effects in persons with schizophrenia during mid- to long-term treatment with antipsychotics: a network meta-analysis of randomized controlled trials. World Psychiatry. 2023;22(1):116–28. https://doi.org/10.1002/wps.21036.
Solmi M, Fiedorowicz J, Poddighe L, Delogu M, Miola A, Høye A, et al. Disparities in screening and treatment of cardiovascular diseases in patients with mental disorders across the world: systematic review and meta-analysis of 47 observational studies. Am J Psychiatry. 2021;178(9):793–803. https://doi.org/10.1176/appi.ajp.2021.21010031.
Cardno AG, Gottesman II. Twin studies of schizophrenia: from bow-and-arrow concordances to star wars mx and functional genomics. Am J Med Genet. 2000;97(1):12–7.
Misiak B, Stramecki F, Gawęda Ł, Prochwicz K, Sąsiadek MM, Moustafa AA, et al. Interactions between variation in candidate genes and environmental factors in the etiology of schizophrenia and bipolar disorder: a systematic review. Mol Neurobiol. 2018;55(6):5075–100. https://doi.org/10.1007/s12035-017-0708-y.
Lin PI, Shuldiner AR. Rethinking the genetic basis for comorbidity of schizophrenia and type 2 diabetes. Schizophr Res. 2010;123(2–3):234–43. https://doi.org/10.1016/j.schres.2010.08.022.
So HC, Chau KL, Ao FK, Mo CH, Sham PC. Exploring shared genetic bases and causal relationships of schizophrenia and bipolar disorder with 28 cardiovascular and metabolic traits. Psychol Med. 2019;49(8):1286–98. https://doi.org/10.1017/s0033291718001812.
Zhang JP, Lencz T, Zhang RX, Nitta M, Maayan L, John M, et al. Pharmacogenetic associations of antipsychotic drug-related weight gain: a systematic review and meta-analysis. Schizophr Bull. 2016;42(6):1418–37. https://doi.org/10.1093/schbul/sbw058.
Correll CU, Lencz T, Malhotra AK. Antipsychotic drugs and obesity. Trends Mol Med. 2011;17(2):97–107. https://doi.org/10.1016/j.molmed.2010.10.010.
Pillinger T, Beck K, Stubbs B, Howes OD. Cholesterol and triglyceride levels in first-episode psychosis: systematic review and meta-analysis. Br J Psychiatry. 2017;211(6):339–49. https://doi.org/10.1192/bjp.bp.117.200907.
Wu H, Siafis S, Hamza T, Schneider-Thoma J, Davis JM, Salanti G, et al. Antipsychotic-induced weight gain: dose–response meta-analysis of randomized controlled trials. Schizophr Bull. 2022;48(3):643–54. https://doi.org/10.1093/schbul/sbac001.
Masuda T, Misawa F, Takase M, Kane JM, Correll CU. Association with hospitalization and all-cause discontinuation among patients with schizophrenia on clozapine vs other oral second-generation antipsychotics: a systematic review and meta-analysis of cohort studies. JAMA Psychiat. 2019;76(10):1052–62. https://doi.org/10.1001/jamapsychiatry.2019.1702.
Ostuzzi G, Bertolini F, Tedeschi F, Vita G, Brambilla P, Del Fabro L, et al. Oral and long-acting antipsychotics for relapse prevention in schizophrenia-spectrum disorders: a network meta-analysis of 92 randomized trials including 22,645 participants. World Psychiatry. 2022;21(2):295–307. https://doi.org/10.1002/wps.20972.
Siskind D, Hahn M, Correll CU, Fink-Jensen A, Russell AW, Bak N, et al. Glucagon-like peptide-1 receptor agonists for antipsychotic-associated cardio-metabolic risk factors: a systematic review and individual participant data meta-analysis. Diabetes Obes Metab. 2019;21(2):293–302. https://doi.org/10.1111/dom.13522.
Meyer JM, Stahl SM. The clozapine handbook. Cambridge: Cambridge University Press; 2019.
Hagi K, Nosaka T, Dickinson D, Lindenmayer JP, Lee J, Friedman J, et al. Association between cardiovascular risk factors and cognitive impairment in people with schizophrenia: a systematic review and meta-analysis. JAMA Psychiat. 2021;78(5):510–8. https://doi.org/10.1001/jamapsychiatry.2021.0015.
Manu P, Khan S, Radhakrishnan R, Russ MJ, Kane JM, Correll CU. Body mass index identified as an independent predictor of psychiatric readmission. J Clin Psychiatry. 2014;75(6):e573–7. https://doi.org/10.4088/JCP.13m08795.
Godin O, Leboyer M, Schürhoff F, Llorca PM, Boyer L, Andre M, et al. Metabolic syndrome and illness severity predict relapse at 1-year follow-up in schizophrenia: the FACE-SZ cohort. J Clin Psychiatry. 2018;79(6):17m12007. https://doi.org/10.4088/JCP.17m12007.
Torniainen M, Mittendorfer-Rutz E, Tanskanen A, Björkenstam C, Suvisaari J, Alexanderson K, et al. Antipsychotic treatment and mortality in schizophrenia. Schizophr Bull. 2015;41(3):656–63. https://doi.org/10.1093/schbul/sbu164.
Taipale H, Tanskanen A, Mehtälä J, Vattulainen P, Correll CU, Tiihonen J. 20-year follow-up study of physical morbidity and mortality in relationship to antipsychotic treatment in a nationwide cohort of 62,250 patients with schizophrenia (FIN20). World Psychiatry. 2020;19(1):61–8. https://doi.org/10.1002/wps.20699.
Solmi M, Tiihonen J, Lähteenvuo M, Tanskanen A, Correll CU, Taipale H. Antipsychotics use is associated with greater adherence to cardiometabolic medications in patients with schizophrenia: results from a nationwide, within-subject design study. Schizophr Bull. 2022;48(1):166–75. https://doi.org/10.1093/schbul/sbab087.
Tiihonen J, Lönnqvist J, Wahlbeck K, Klaukka T, Niskanen L, Tanskanen A, et al. 11-year follow-up of mortality in patients with schizophrenia: a population-based cohort study (FIN11 study). Lancet. 2009;374(9690):620–7. https://doi.org/10.1016/s0140-6736(09)60742-x.
Kroeze WK, Hufeisen SJ, Popadak BA, Renock SM, Steinberg S, Ernsberger P, et al. H1-histamine receptor affinity predicts short-term weight gain for typical and atypical antipsychotic drugs. Neuropsychopharmacology. 2003;28(3):519–26. https://doi.org/10.1038/sj.npp.1300027.
Freyberg Z, Aslanoglou D, Shah R, Ballon JS. Intrinsic and antipsychotic drug-induced metabolic dysfunction in schizophrenia. Front Neurosci. 2017;11:432. https://doi.org/10.3389/fnins.2017.00432.
Kim SF, Huang AS, Snowman AM, Teuscher C, Snyder SH. From the cover: antipsychotic drug-induced weight gain mediated by histamine H1 receptor-linked activation of hypothalamic AMP-kinase. Proc Natl Acad Sci USA. 2007;104(9):3456–9. https://doi.org/10.1073/pnas.0611417104.
Lett TA, Wallace TJ, Chowdhury NI, Tiwari AK, Kennedy JL, Müller DJ. Pharmacogenetics of antipsychotic-induced weight gain: review and clinical implications. Mol Psychiatry. 2012;17(3):242–66. https://doi.org/10.1038/mp.2011.109.
Nash AI. Crosstalk between insulin and dopamine signaling: a basis for the metabolic effects of antipsychotic drugs. J Chem Neuroanat. 2017;83–84:59–68. https://doi.org/10.1016/j.jchemneu.2016.07.010.
Hahn M, Chintoh A, Giacca A, Xu L, Lam L, Mann S, et al. Atypical antipsychotics and effects of muscarinic, serotonergic, dopaminergic and histaminergic receptor binding on insulin secretion in vivo: an animal model. Schizophr Res. 2011;131(1–3):90–5. https://doi.org/10.1016/j.schres.2011.06.004.
Castellani LN, Pereira S, Kowalchuk C, Asgariroozbehani R, Singh R, Wu S, et al. Antipsychotics impair regulation of glucose metabolism by central glucose. Mol Psychiatry. 2022;27(11):4741–53. https://doi.org/10.1038/s41380-022-01798-y.
Gomes FV, Grace AA. Beyond dopamine receptor antagonism: new targets for schizophrenia treatment and prevention. Int J Mol Sci. 2021;22(9):4467. https://doi.org/10.3390/ijms22094467.
Lehmann HE, Ban TA. The history of the psychopharmacology of schizophrenia. Can J Psychiatry. 1997;42(2):152–62. https://doi.org/10.1177/070674379704200205.
Seeman P, Lee T, Chau-Wong M, Wong K. Antipsychotic drug doses and neuroleptic/dopamine receptors. Nature. 1976;261(5562):717–9. https://doi.org/10.1038/261717a0.
Creese I, Burt DR, Snyder SH. Dopamine receptor binding predicts clinical and pharmacological potencies of antischizophrenic drugs. Science. 1976;192(4238):481–3. https://doi.org/10.1126/science.3854.
Howes O, McCutcheon R, Stone J. Glutamate and dopamine in schizophrenia: an update for the 21st century. J Psychopharmacol. 2015;29(2):97–115. https://doi.org/10.1177/0269881114563634.
Potkin SG, Kane JM, Correll CU, Lindenmayer JP, Agid O, Marder SR, et al. The neurobiology of treatment-resistant schizophrenia: paths to antipsychotic resistance and a roadmap for future research. NPJ Schizophr. 2020;6(1):1. https://doi.org/10.1038/s41537-019-0090-z.
Yang AC, Tsai SJ. New targets for schizophrenia treatment beyond the dopamine hypothesis. Int J Mol Sci. 2017;18(8):1689. https://doi.org/10.3390/ijms18081689.
Stahl SM. Beyond the dopamine hypothesis of schizophrenia to three neural networks of psychosis: dopamine, serotonin, and glutamate. CNS Spectr. 2018;23(3):187–91. https://doi.org/10.1017/s1092852918001013.
Sumiyoshi T, Kunugi H, Nakagome K. Serotonin and dopamine receptors in motivational and cognitive disturbances of schizophrenia. Front Neurosci. 2014;8:395. https://doi.org/10.3389/fnins.2014.00395.
Hikosaka O, Sesack SR, Lecourtier L, Shepard PD. Habenula: crossroad between the basal ganglia and the limbic system. J Neurosci. 2008;28(46):11825–9. https://doi.org/10.1523/jneurosci.3463-08.2008.
Andres KH, von Düring M, Veh RW. Subnuclear organization of the rat habenular complexes. J Comp Neurol. 1999;407(1):130–50. https://doi.org/10.1002/(sici)1096-9861(19990428)407:1%3c130::aid-cne10%3e3.0.co;2-8.
Sutherland RJ. The dorsal diencephalic conduction system: a review of the anatomy and functions of the habenular complex. Neurosci Biobehav Rev. 1982;6(1):1–13. https://doi.org/10.1016/0149-7634(82)90003-3.
Goldman BD. Mammalian photoperiodic system: formal properties and neuroendocrine mechanisms of photoperiodic time measurement. J Biol Rhythms. 2001;16(4):283–301. https://doi.org/10.1177/074873001129001980.
Zhang L, Wang H, Luan S, Yang S, Wang Z, Wang J, et al. Altered volume and functional connectivity of the habenula in schizophrenia. Front Hum Neurosci. 2017;11:636. https://doi.org/10.3389/fnhum.2017.00636.
Baker PM, Jhou T, Li B, Matsumoto M, Mizumori SJ, Stephenson-Jones M, et al. The lateral habenula circuitry: reward processing and cognitive control. J Neurosci. 2016;36(45):11482–8. https://doi.org/10.1523/jneurosci.2350-16.2016.
Zhao H, Zhang BL, Yang SJ, Rusak B. The role of lateral habenula-dorsal raphe nucleus circuits in higher brain functions and psychiatric illness. Behav Brain Res. 2015;277:89–98. https://doi.org/10.1016/j.bbr.2014.09.016.
Meye FJ, Lecca S, Valentinova K, Mameli M. Synaptic and cellular profile of neurons in the lateral habenula. Front Hum Neurosci. 2013;7:860. https://doi.org/10.3389/fnhum.2013.00860.
Viswanath H, Carter AQ, Baldwin PR, Molfese DL, Salas R. The medial habenula: still neglected. Front Hum Neurosci. 2013;7:931. https://doi.org/10.3389/fnhum.2013.00931.
Egerton A, Murphy A, Donocik J, Anton A, Barker GJ, Collier T, et al. Dopamine and glutamate in antipsychotic-responsive compared with antipsychotic-nonresponsive psychosis: a multicenter positron emission tomography and magnetic resonance spectroscopy study (STRATA). Schizophr Bull. 2021;47(2):505–16. https://doi.org/10.1093/schbul/sbaa128.
Merritt K, Egerton A, Kempton MJ, Taylor MJ, McGuire PK. Nature of glutamate alterations in schizophrenia: a meta-analysis of proton magnetic resonance spectroscopy studies. JAMA Psychiat. 2016;73(7):665–74. https://doi.org/10.1001/jamapsychiatry.2016.0442.
Zhou Y, Fan L, Qiu C, Jiang T. Prefrontal cortex and the dysconnectivity hypothesis of schizophrenia. Neurosci Bull. 2015;31(2):207–19. https://doi.org/10.1007/s12264-014-1502-8.
Comte M, Zendjidjian XY, Coull JT, Cancel A, Boutet C, Schneider FC, et al. Impaired cortico-limbic functional connectivity in schizophrenia patients during emotion processing. Soc Cogn Affect Neurosci. 2018;13(4):381–90. https://doi.org/10.1093/scan/nsx083.
Phillips ML, Drevets WC, Rauch SL, Lane R. Neurobiology of emotion perception I: the neural basis of normal emotion perception. Biol Psychiatry. 2003;54(5):504–14. https://doi.org/10.1016/s0006-3223(03)00168-9.
Phillips ML, Ladouceur CD, Drevets WC. A neural model of voluntary and automatic emotion regulation: implications for understanding the pathophysiology and neurodevelopment of bipolar disorder. Mol Psychiatry. 2008;13(9):833–57. https://doi.org/10.1038/mp.2008.65.
Wang X, Yin Z, Sun Q, Jiang X, Chao L, Dai X, et al. Comparative study on the functional connectivity of amygdala and hippocampal neural circuits in patients with first-episode schizophrenia and other high-risk populations. Front Psychiatry. 2021;12: 627198. https://doi.org/10.3389/fpsyt.2021.627198.
Weinberger DR, Berman KF, Suddath R, Torrey EF. Evidence of dysfunction of a prefrontal-limbic network in schizophrenia: a magnetic resonance imaging and regional cerebral blood flow study of discordant monozygotic twins. Am J Psychiatry. 1992;149(7):890–7. https://doi.org/10.1176/ajp.149.7.890.
Meltzer HY. The role of serotonin in antipsychotic drug action. Neuropsychopharmacology. 1999;21(2 Suppl):106s-s115. https://doi.org/10.1016/s0893-133x(99)00046-9.
Patel RS, Bhela J, Tahir M, Pisati SR, Hossain S. Pimavanserin in Parkinson’s disease-induced psychosis: a literature review. Cureus. 2019;11(7): e5257. https://doi.org/10.7759/cureus.5257.
Hajós M, Hurst RS, Hoffmann WE, Krause M, Wall TM, Higdon NR, et al. The selective alpha7 nicotinic acetylcholine receptor agonist PNU-282987 [N-[(3R)-1-Azabicyclo[2.2.2]oct-3-yl]-4-chlorobenzamide hydrochloride] enhances GABAergic synaptic activity in brain slices and restores auditory gating deficits in anesthetized rats. J Pharmacol Exp Ther. 2005;312(3):1213–22. https://doi.org/10.1124/jpet.104.076968.
Sudweeks SN, Yakel JL. Functional and molecular characterization of neuronal nicotinic ACh receptors in rat CA1 hippocampal neurons. J Physiol. 2000;527(3):515–28. https://doi.org/10.1111/j.1469-7793.2000.00515.x.
Caton M, Ochoa ELM, Barrantes FJ. The role of nicotinic cholinergic neurotransmission in delusional thinking. NPJ Schizophr. 2020;6(1):16. https://doi.org/10.1038/s41537-020-0105-9.
Correll CU. What are we looking for in new antipsychotics? J Clin Psychiatry. 2011;72(Suppl 1):9–13. https://doi.org/10.4088/JCP.10075su1.02.
Correll CU, Newcomer JW, Silverman B, DiPetrillo L, Graham C, Jiang Y, et al. Effects of olanzapine combined with samidorphan on weight gain in schizophrenia: a 24-week phase 3 study. Am J Psychiatry. 2020;177(12):1168–78. https://doi.org/10.1176/appi.ajp.2020.19121279.
Alkermes I. LYBALVI™ (olanzapine and samidorphan) tablets, for oral use [prescribing information]. Waltham: Alkermes, Inc.; 2021.
Martin WF, Correll CU, Weiden PJ, Jiang Y, Pathak S, DiPetrillo L, et al. Mitigation of olanzapine-induced weight gain with samidorphan, an opioid antagonist: a randomized double-blind phase 2 study in patients with schizophrenia. Am J Psychiatry. 2019;176(6):457–67. https://doi.org/10.1176/appi.ajp.2018.18030280.
Kahn RS, Silverman BL, DiPetrillo L, Graham C, Jiang Y, Yin J, et al. A phase 3, multicenter study to assess the 1-year safety and tolerability of a combination of olanzapine and samidorphan in patients with schizophrenia: results from the ENLIGHTEN-2 long-term extension. Schizophr Res. 2021;232:45–53. https://doi.org/10.1016/j.schres.2021.04.009.
Correll CU, Stein E, Graham C, DiPetrillo L, Akerman S, Stanford AD, et al. Reduction in multiple cardiometabolic risk factors with combined olanzapine/samidorphan compared with olanzapine: post hoc analyses from a 24-week phase 3 study. Schizophr Bull. 2023;49(2):454–63. https://doi.org/10.1093/schbul/sbac144.
Vancampfort D, Firth J, Correll CU, Solmi M, Siskind D, De Hert M, et al. The impact of pharmacological and non-pharmacological interventions to improve physical health outcomes in people with schizophrenia: a meta-review of meta-analyses of randomized controlled trials. World Psychiatry. 2019;18(1):53–66. https://doi.org/10.1002/wps.20614.
Cernea S, Dima L, Correll CU, Manu P. Pharmacological management of glucose dysregulation in patients treated with second-generation antipsychotics. Drugs. 2020;80(17):1763–81. https://doi.org/10.1007/s40265-020-01393-x.
Correll CU, Sikich L, Reeves G, Johnson J, Keeton C, Spanos M, et al. Metformin add-on vs. antipsychotic switch vs. continued antipsychotic treatment plus healthy lifestyle education in overweight or obese youth with severe mental illness: results from the IMPACT trial. World Psychiatry. 2020;19(1):69–80. https://doi.org/10.1002/wps.20714.
Larsen JR, Vedtofte L, Jakobsen MSL, Jespersen HR, Jakobsen MI, Svensson CK, et al. Effect of liraglutide treatment on prediabetes and overweight or obesity in clozapine- or olanzapine-treated patients with schizophrenia spectrum disorder: a randomized clinical trial. JAMA Psychiat. 2017;74(7):719–28. https://doi.org/10.1001/jamapsychiatry.2017.1220.
Svensson CK, Larsen JR, Vedtofte L, Jakobsen MSL, Jespersen HR, Jakobsen MI, et al. One-year follow-up on liraglutide treatment for prediabetes and overweight/obesity in clozapine- or olanzapine-treated patients. Acta Psychiatr Scand. 2019;139(1):26–36. https://doi.org/10.1111/acps.12982.
Sonnenschein SF, Gomes FV, Grace AA. Dysregulation of midbrain dopamine system and the pathophysiology of schizophrenia. Front Psychiatry. 2020;11:613. https://doi.org/10.3389/fpsyt.2020.00613.
Buchanan RW, Javitt DC, Marder SR, Schooler NR, Gold JM, McMahon RP, et al. The Cognitive and Negative Symptoms in Schizophrenia Trial (CONSIST): the efficacy of glutamatergic agents for negative symptoms and cognitive impairments. Am J Psychiatry. 2007;164(10):1593–602. https://doi.org/10.1176/appi.ajp.2007.06081358.
Heresco-Levy U, Ermilov M, Lichtenberg P, Bar G, Javitt DC. High-dose glycine added to olanzapine and risperidone for the treatment of schizophrenia. Biol Psychiatry. 2004;55(2):165–71. https://doi.org/10.1016/s0006-3223(03)00707-8.
Correll CU, Rubio JM, Inczedy-Farkas G, Birnbaum ML, Kane JM, Leucht S. Efficacy of 42 pharmacologic cotreatment strategies added to antipsychotic monotherapy in schizophrenia: systematic overview and quality appraisal of the meta-analytic evidence. JAMA Psychiat. 2017;74(7):675–84. https://doi.org/10.1001/jamapsychiatry.2017.0624.
Pei JC, Luo DZ, Gau SS, Chang CY, Lai WS. Directly and indirectly targeting the glycine modulatory site to modulate NMDA receptor function to address unmet medical needs of patients with schizophrenia. Front Psychiatry. 2021;12: 742058. https://doi.org/10.3389/fpsyt.2021.742058.
Umbricht D, Alberati D, Martin-Facklam M, Borroni E, Youssef EA, Ostland M, et al. Effect of bitopertin, a glycine reuptake inhibitor, on negative symptoms of schizophrenia: a randomized, double-blind, proof-of-concept study. JAMA Psychiat. 2014;71(6):637–46. https://doi.org/10.1001/jamapsychiatry.2014.163.
Bugarski-Kirola D, Wang A, Abi-Saab D, Blättler T. A phase II/III trial of bitopertin monotherapy compared with placebo in patients with an acute exacerbation of schizophrenia—results from the CandleLyte study. Eur Neuropsychopharmacol. 2014;24(7):1024–36. https://doi.org/10.1016/j.euroneuro.2014.03.007.
Krogmann A, Peters L, von Hardenberg L, Bödeker K, Nöhles VB, Correll CU. Keeping up with the therapeutic advances in schizophrenia: a review of novel and emerging pharmacological entities. CNS Spectr. 2019;24(S1):38–69. https://doi.org/10.1017/s109285291900124x.
Neurocrine Biosciences I. Neurocrine biosciences announces top-line results from phase II INTERACT study evaluating luvadaxistat (NBI-1065844) for the treatment of negative symptoms and cognitive impairment associated with schizophrenia (CIAS). 2021. [cited April 29, 2022]. https://www.prnewswire.com/news-releases/neurocrine-biosciences-announces-top-line-results-from-phase-ii-interact-study-evaluating-luvadaxistat-nbi-1065844-for-the-treatment-of-negative-symptoms-and-cognitive-impairment-associated-with-schizophrenia-cias-301238086.html.
Molla G. Competitive inhibitors unveil structure/function relationships in human d-amino acid oxidase. Front Mol Biosci. 2017;4:80. https://doi.org/10.3389/fmolb.2017.00080.
O’Donnell P, Dong C, Murthy V, Asgharnejad M, Du X, Summerfelt A, et al. The d-amino acid oxidase inhibitor luvadaxistat improves mismatch negativity in patients with schizophrenia in a randomized trial. Neuropsychopharmacology. 2023;48:1052–59. https://doi.org/10.1038/s41386-023-01560-0.
Correll CU, Solmi M, Cortese S, Fava M, Højlund M, Kraemer HC, et al. The future of psychopharmacology: a critical appraisal of ongoing phase 2/3 trials, and of some current trends aiming to de-risk trial programmes of novel agents. World Psychiatry. 2023;22(1):48–74. https://doi.org/10.1002/wps.21056.
Fleischhacker WW, Podhorna J, Gröschl M, Hake S, Zhao Y, Huang S, et al. Efficacy and safety of the novel glycine transporter inhibitor BI 425809 once daily in patients with schizophrenia: a double-blind, randomised, placebo-controlled phase 2 study. Lancet Psychiatry. 2021;8(3):191–201. https://doi.org/10.1016/s2215-0366(20)30513-7.
Jones CK, Byun N, Bubser M. Muscarinic and nicotinic acetylcholine receptor agonists and allosteric modulators for the treatment of schizophrenia. Neuropsychopharmacology. 2012;37(1):16–42. https://doi.org/10.1038/npp.2011.199.
Neves GA, Grace AA. α7 nicotinic receptor-modulating agents reverse the hyperdopaminergic tone in the MAM model of schizophrenia. Neuropsychopharmacology. 2018;43(8):1712–20. https://doi.org/10.1038/s41386-018-0066-0.
Tregellas JR, Wylie KP. Alpha7 nicotinic receptors as therapeutic targets in schizophrenia. Nicotine Tob Res. 2019;21(3):349–56. https://doi.org/10.1093/ntr/nty034.
Jin Y, Wang Q, Wang Y, Liu M, Sun A, Geng Z, et al. Alpha7 nAChR agonists for cognitive deficit and negative symptoms in schizophrenia: a meta-analysis of randomized double-blind controlled trials. Shanghai Arch Psychiatry. 2017;29(4):191–9. https://doi.org/10.11919/j.issn.1002-0829.217044.
Keefe RS, Meltzer HA, Dgetluck N, Gawryl M, Koenig G, Moebius HJ, et al. Randomized, double-blind, placebo-controlled study of encenicline, an α7 nicotinic acetylcholine receptor agonist, as a treatment for cognitive impairment in schizophrenia. Neuropsychopharmacology. 2015;40(13):3053–60. https://doi.org/10.1038/npp.2015.176.
Recio-Barbero M, Segarra R, Zabala A, González-Fraile E, González-Pinto A, Ballesteros J. Cognitive enhancers in schizophrenia: a systematic review and meta-analysis of alpha-7 nicotinic acetylcholine receptor agonists for cognitive deficits and negative symptoms. Front Psychiatry. 2021;12: 631589. https://doi.org/10.3389/fpsyt.2021.631589.
Gibbons A, Dean B. The cholinergic system: an emerging drug target for schizophrenia. Curr Pharm Des. 2016;22(14):2124–33. https://doi.org/10.2174/1381612822666160127114010.
Shekhar A, Potter WZ, Lightfoot J, Lienemann J, Dubé S, Mallinckrodt C, et al. Selective muscarinic receptor agonist xanomeline as a novel treatment approach for schizophrenia. Am J Psychiatry. 2008;165(8):1033–9. https://doi.org/10.1176/appi.ajp.2008.06091591.
Paul SM, Yohn SE, Popiolek M, Miller AC, Felder CC. Muscarinic acetylcholine receptor agonists as novel treatments for schizophrenia. Am J Psychiatry. 2022;179:611–27. https://doi.org/10.1176/appi.ajp.21101083.
Wess J, Eglen RM, Gautam D. Muscarinic acetylcholine receptors: mutant mice provide new insights for drug development. Nat Rev Drug Discov. 2007;6(9):721–33. https://doi.org/10.1038/nrd2379.
Raedler TJ, Bymaster FP, Tandon R, Copolov D, Dean B. Towards a muscarinic hypothesis of schizophrenia. Mol Psychiatry. 2007;12(3):232–46. https://doi.org/10.1038/sj.mp.4001924.
Tzavara ET, Bymaster FP, Davis RJ, Wade MR, Perry KW, Wess J, et al. M4 muscarinic receptors regulate the dynamics of cholinergic and dopaminergic neurotransmission: relevance to the pathophysiology and treatment of related CNS pathologies. FASEB J. 2004;18(12):1410–2. https://doi.org/10.1096/fj.04-1575fje.
Sulzer D, Cragg SJ, Rice ME. Striatal dopamine neurotransmission: regulation of release and uptake. Basal Ganglia. 2016;6(3):123–48. https://doi.org/10.1016/j.baga.2016.02.001.
Scarr E, Dean B. Muscarinic receptors: do they have a role in the pathology and treatment of schizophrenia? J Neurochem. 2008;107(5):1188–95. https://doi.org/10.1111/j.1471-4159.2008.05711.x.
Acharya S, Kim KM. Roles of the functional interaction between brain cholinergic and dopaminergic systems in the pathogenesis and treatment of schizophrenia and Parkinson’s disease. Int J Mol Sci. 2021;22(9):4299. https://doi.org/10.3390/ijms22094299.
Forster GL, Yeomans JS, Takeuchi J, Blaha CD. M5 muscarinic receptors are required for prolonged accumbal dopamine release after electrical stimulation of the pons in mice. J Neurosci. 2002;22(1):Rc190. https://doi.org/10.1523/JNEUROSCI.22-01-j0001.2002.
McCollum LA, Walker CK, Roche JK, Roberts RC. Elevated excitatory input to the nucleus accumbens in schizophrenia: a postmortem ultrastructural study. Schizophr Bull. 2015;41(5):1123–32. https://doi.org/10.1093/schbul/sbv030.
Felder CC, Bymaster FP, Ward J, DeLapp N. Therapeutic opportunities for muscarinic receptors in the central nervous system. J Med Chem. 2000;43(23):4333–53. https://doi.org/10.1021/jm990607u.
Crook JM, Tomaskovic-Crook E, Copolov DL, Dean B. Decreased muscarinic receptor binding in subjects with schizophrenia: a study of the human hippocampal formation. Biol Psychiatry. 2000;48(5):381–8. https://doi.org/10.1016/s0006-3223(00)00918-5.
Crook JM, Tomaskovic-Crook E, Copolov DL, Dean B. Low muscarinic receptor binding in prefrontal cortex from subjects with schizophrenia: a study of Brodmann’s areas 8, 9, 10, and 46 and the effects of neuroleptic drug treatment. Am J Psychiatry. 2001;158(6):918–25. https://doi.org/10.1176/appi.ajp.158.6.918.
van der Westhuizen ET, Choy KHC, Valant C, McKenzie-Nickson S, Bradley SJ, Tobin AB, et al. Fine tuning muscarinic acetylcholine receptor signaling through allostery and bias. Front Pharmacol. 2020;11: 606656. https://doi.org/10.3389/fphar.2020.606656.
Yohn SE, Weiden PJ, Felder CC, Stahl SM. Muscarinic acetylcholine receptors for psychotic disorders: bench-side to clinic. Trends Pharmacol Sci. 2022;43(12):1098–112. https://doi.org/10.1016/j.tips.2022.09.006.
Stanhope KJ, Mirza NR, Bickerdike MJ, Bright JL, Harrington NR, Hesselink MB, et al. The muscarinic receptor agonist xanomeline has an antipsychotic-like profile in the rat. J Pharmacol Exp Ther. 2001;299(2):782–92.
Shannon HE, Hart JC, Bymaster FP, Calligaro DO, DeLapp NW, Mitch CH, et al. Muscarinic receptor agonists, like dopamine receptor antagonist antipsychotics, inhibit conditioned avoidance response in rats. J Pharmacol Exp Ther. 1999;290(2):901–7.
Shannon HE, Rasmussen K, Bymaster FP, Hart JC, Peters SC, Swedberg MD, et al. Xanomeline, an M(1)/M(4) preferring muscarinic cholinergic receptor agonist, produces antipsychotic-like activity in rats and mice. Schizophr Res. 2000;42(3):249–59. https://doi.org/10.1016/s0920-9964(99)00138-3.
Watson J, Brough S, Coldwell MC, Gager T, Ho M, Hunter AJ, et al. Functional effects of the muscarinic receptor agonist, xanomeline, at 5-HT1 and 5-HT2 receptors. Br J Pharmacol. 1998;125(7):1413–20. https://doi.org/10.1038/sj.bjp.0702201.
Odagaki Y, Kinoshita M, Ota T. Comparative analysis of pharmacological properties of xanomeline and N-desmethylclozapine in rat brain membranes. J Psychopharmacol. 2016;30(9):896–912. https://doi.org/10.1177/0269881116658989.
Bonifazi A, Yano H, Del Bello F, Farande A, Quaglia W, Petrelli R, et al. Synthesis and biological evaluation of a novel series of heterobivalent muscarinic ligands based on xanomeline and 1-[3-(4-butylpiperidin-1-yl)propyl]-1,2,3,4-tetrahydroquinolin-2-one (77-LH-28-1). J Med Chem. 2014;57(21):9065–77. https://doi.org/10.1021/jm501173q.
Bymaster FP, Whitesitt CA, Shannon HE, DeLapp N, Ward JS, Calligaro DO, et al. Xanomeline: a selective muscarinic agonist for the treatment of Alzheimer's disease. Drug Dev Res. 1997;40(2):158–70. https://doi.org/10.1002/(SICI)1098-2299(199702)40:2<158::AID-DDR6>3.0.CO;2-K.
Newman-Tancredi A, Kleven MS. Comparative pharmacology of antipsychotics possessing combined dopamine D2 and serotonin 5-HT1A receptor properties. Psychopharmacology. 2011;216(4):451–73. https://doi.org/10.1007/s00213-011-2247-y.
Hagan JJ, Jones DN. Predicting drug efficacy for cognitive deficits in schizophrenia. Schizophr Bull. 2005;31(4):830–53. https://doi.org/10.1093/schbul/sbi058.
Bodick NC, Offen WW, Levey AI, Cutler NR, Gauthier SG, Satlin A, et al. Effects of xanomeline, a selective muscarinic receptor agonist, on cognitive function and behavioral symptoms in Alzheimer disease. Arch Neurol. 1997;54(4):465–73. https://doi.org/10.1001/archneur.1997.00550160091022.
Brannan SK, Sawchak S, Miller AC, Lieberman JA, Paul SM, Breier A. Muscarinic cholinergic receptor agonist and peripheral antagonist for schizophrenia. N Engl J Med. 2021;384(8):717–26. https://doi.org/10.1056/NEJMoa2017015.
Karuna Therapeutics, Inc. Karuna Therapeutics announces positive results from phase 3 EMERGENT-2 trial of KarXT in schizophrenia. 2022. [cited August 25, 2022]. https://investors.karunatx.com/news-releases/news-release-details/karuna-therapeutics-announces-positive-results-phase-3-emergent.
Krystal JH, Kane JM, Correll CU, Walling DP, Leoni M, Duvvuri S, et al. Emraclidine, a novel positive allosteric modulator of cholinergic M4 receptors, for the treatment of schizophrenia: a two-part, randomised, double-blind, placebo-controlled, phase 1b trial. Lancet. 2022;400(10369):2210–20. https://doi.org/10.1016/s0140-6736(22)01990-0.
Revel FG, Moreau JL, Pouzet B, Mory R, Bradaia A, Buchy D, et al. A new perspective for schizophrenia: TAAR1 agonists reveal antipsychotic- and antidepressant-like activity, improve cognition and control body weight. Mol Psychiatry. 2013;18(5):543–56. https://doi.org/10.1038/mp.2012.57.
Borowsky B, Adham N, Jones KA, Raddatz R, Artymyshyn R, Ogozalek KL, et al. Trace amines: identification of a family of mammalian G protein-coupled receptors. Proc Natl Acad Sci USA. 2001;98(16):8966–71. https://doi.org/10.1073/pnas.151105198.
Bunzow JR, Sonders MS, Arttamangkul S, Harrison LM, Zhang G, Quigley DI, et al. Amphetamine, 3,4-methylenedioxymethamphetamine, lysergic acid diethylamide, and metabolites of the catecholamine neurotransmitters are agonists of a rat trace amine receptor. Mol Pharmacol. 2001;60(6):1181–8. https://doi.org/10.1124/mol.60.6.1181.
Dedic N, Dworak H, Zeni C, Rutigliano G, Howes OD. Therapeutic potential of TAAR1 agonists in schizophrenia: evidence from preclinical models and clinical studies. Int J Mol Sci. 2021;22(24):13185. https://doi.org/10.3390/ijms222413185.
Gainetdinov RR, Hoener MC, Berry MD. Trace amines and their receptors. Pharmacol Rev. 2018;70(3):549–620. https://doi.org/10.1124/pr.117.015305.
Rutigliano G, Zucchi R. Molecular variants in human trace amine-associated receptors and their implications in mental and metabolic disorders. Cell Mol Neurobiol. 2020;40(2):239–55. https://doi.org/10.1007/s10571-019-00743-y.
Saarinen M, Mantas I, Flais I, Ågren R, Sahlholm K, Millan MJ, et al. TAAR1 dependent and independent actions of the potential antipsychotic and dual TAAR1/5-HT(1A) receptor agonist SEP-383856. Neuropsychopharmacology. 2022. https://doi.org/10.1038/s41386-022-01421-2.
Espinoza S, Salahpour A, Masri B, Sotnikova TD, Messa M, Barak LS, et al. Functional interaction between trace amine-associated receptor 1 and dopamine D2 receptor. Mol Pharmacol. 2011;80(3):416–25. https://doi.org/10.1124/mol.111.073304.
Lindemann L, Meyer CA, Jeanneau K, Bradaia A, Ozmen L, Bluethmann H, et al. Trace amine-associated receptor 1 modulates dopaminergic activity. J Pharmacol Exp Ther. 2008;324(3):948–56. https://doi.org/10.1124/jpet.107.132647.
Koblan KS, Kent J, Hopkins SC, Krystal JH, Cheng H, Goldman R, et al. A non-D2-receptor-binding drug for the treatment of schizophrenia. N Engl J Med. 2020;382(16):1497–506. https://doi.org/10.1056/NEJMoa1911772.
Wolinsky TD, Swanson CJ, Smith KE, Zhong H, Borowsky B, Seeman P, et al. The trace amine 1 receptor knockout mouse: an animal model with relevance to schizophrenia. Genes Brain Behav. 2007;6(7):628–39. https://doi.org/10.1111/j.1601-183X.2006.00292.x.
Revel FG, Moreau JL, Gainetdinov RR, Bradaia A, Sotnikova TD, Mory R, et al. TAAR1 activation modulates monoaminergic neurotransmission, preventing hyperdopaminergic and hypoglutamatergic activity. Proc Natl Acad Sci USA. 2011;108(20):8485–90. https://doi.org/10.1073/pnas.1103029108.
Berry MD, Gainetdinov RR, Hoener MC, Shahid M. Pharmacology of human trace amine-associated receptors: therapeutic opportunities and challenges. Pharmacol Ther. 2017;180:161–80. https://doi.org/10.1016/j.pharmthera.2017.07.002.
McGuire JL, Hammond JH, Yates SD, Chen D, Haroutunian V, Meador-Woodruff JH, et al. Altered serine/threonine kinase activity in schizophrenia. Brain Res. 2014;1568:42–54. https://doi.org/10.1016/j.brainres.2014.04.029.
Harmeier A, Obermueller S, Meyer CA, Revel FG, Buchy D, Chaboz S, et al. Trace amine-associated receptor 1 activation silences GSK3β signaling of TAAR1 and D2R heteromers. Eur Neuropsychopharmacol. 2015;25(11):2049–61. https://doi.org/10.1016/j.euroneuro.2015.08.011.
Heffernan MLR, Herman LW, Brown S, Jones PG, Shao L, Hewitt MC, et al. Ulotaront: a TAAR1 agonist for the treatment of schizophrenia. ACS Med Chem Lett. 2022;13(1):92–8. https://doi.org/10.1021/acsmedchemlett.1c00527.
Rutigliano G, Accorroni A, Zucchi R. The case for TAAR1 as a modulator of central nervous system function. Front Pharmacol. 2017;8:987. https://doi.org/10.3389/fphar.2017.00987.
Barnes DA, Galloway DA, Hoener MC, Berry MD, Moore CS. TAAR1 expression in human macrophages and brain tissue: a potential novel facet of MS neuroinflammation. Int J Mol Sci. 2021;22(21):11576. https://doi.org/10.3390/ijms222111576.
Christian SL, Berry MD. Trace amine-associated receptors as novel therapeutic targets for immunomodulatory disorders. Front Pharmacol. 2018;9:680. https://doi.org/10.3389/fphar.2018.00680.
Michael ES, Covic L, Kuliopulos A. Trace amine-associated receptor 1 (TAAR1) promotes anti-diabetic signaling in insulin-secreting cells. J Biol Chem. 2019;294(12):4401–11. https://doi.org/10.1074/jbc.RA118.005464.
Ghost. Scoop: Roche scraps one of two schizophrenia PhII trials due to missed primary endpoint. 2022. [cited August 29, 2022]. https://www.hotstock-insights.com/scoop-roche-scraps-one-of-two-schizophrenia-phii-trials-due-to-missed-primary-endpoint/.
Correll CU, Koblan KS, Hopkins SC, Li Y, Heather D, Goldman R, et al. Safety and effectiveness of ulotaront (SEP-363856) in schizophrenia: results of a 6-month, open-label extension study. NPJ Schizophr. 2021;7(1):63. https://doi.org/10.1038/s41537-021-00190-z.
Dedic N, Jones PG, Hopkins SC, Lew R, Shao L, Campbell JE, et al. SEP-363856, a novel psychotropic agent with a unique, non-D(2) receptor mechanism of action. J Pharmacol Exp Ther. 2019;371(1):1–14. https://doi.org/10.1124/jpet.119.260281.
Dedic N, Jones PG, Hajos-Korcsok E, Synan C, Wu S, Anacker C, et al. TAAR1 agonist ulotaront improves glycemic control and reduces body weight in rodent models of diabetes, obesity and iatrogenic weight gain [poster]. Presented at Schizophrenia International Research Society Congress, April 6–10, 2022, Florence, Italy; 2022.
Acknowledgements
Sumitomo Pharma America, Inc. (formerly Sunovion), discovered ulotaront in collaboration with PsychoGenics based in part on a mechanism-independent approach using the in vivo phenotypic SmartCube® platform and associated artificial intelligence algorithms. This manuscript was prepared according to the International Society for Medical Publication Professionals’ “Good Publication Practice for Communicating Company-Sponsored Medical Research: GPP3”.
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Medical writing and editorial assistance, including preparing the outline and draft, incorporating revisions, literature searching, and journal styling, were provided by Debika Chatterjea, PhD, and Stephen Bublitz, ELS, of PharmaWrite, LLC (Princeton, NJ, USA), and were funded by Sumitomo Pharma America, Inc. and Otsuka Pharmaceuticals Development & Commercialization, Inc.
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Dr. Meyer has been a consultant and/or advisor to or has received honoraria from Acadia, Alkermes, AbbVie, Cerevel, Intra-Cellular, Karuna, Neurocrine, Noven, Otsuka, Relmada, Sunovion, and Teva. Dr. Correll has been a consultant and/or advisor to or has received honoraria from AbbVie, Acadia, Alkermes, Allergan, Angelini, Aristo, Boehringer-Ingelheim, Cardio Diagnostics, Cerevel, CNX Therapeutics, Compass Pathways, Darnitsa, Gedeon Richter, Hikma, Holmusk, Intra-Cellular Therapies, Janssen/J&J, Karuna, LB Pharma, Lundbeck, MedAvante-ProPhase, MedInCell, Merck, Mindpax, Mitsubishi Tanabe Pharma, Mylan, Neurocrine, Newron, Noven, Otsuka, Pharmabrain, PPD Biotech, Recordati, Relmada, Reviva, Rovi, Seqirus, SK Life Science, Sunovion, Sun Pharma, Supernus, Takeda, Teva, and Viatris. He provided expert testimony for Janssen and Otsuka. He served on a Data Safety Monitoring Board for Lundbeck, Relmada, Reviva, Rovi, Supernus, and Teva. He has received grant support from Janssen and Takeda. He is a stock option holder of Cardio Diagnostics, Mindpax, LB Pharma, and Quantic. He received support for travel, manuscript preparation or other reason from Angelini, Gedeon Richter, Janssen/J&J, Karuna, Lundbeck, Mylan, Otsuka, Recordati, Sunovion, Teva, and Viatris. He has received payment for lectures including service on speakers bureaus from AbbVie, Angelini, Aristo, Damitsa, Gedeon Richter, Hikma, Intra-Cellular Therapies, Janssen/J&J, Lundbeck, Mitsubishi Tanabe Pharma, Mylan, Otsuka, Recordati, Seqirus, Sunovion, Takeda, and Viatris.
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Meyer, J.M., Correll, C.U. Increased Metabolic Potential, Efficacy, and Safety of Emerging Treatments in Schizophrenia. CNS Drugs 37, 545–570 (2023). https://doi.org/10.1007/s40263-023-01022-7
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DOI: https://doi.org/10.1007/s40263-023-01022-7