This work may not be copied, distributed, displayed, published, reproduced, transmitted, modified, posted, sold, licensed, or used for commercial purposes. By downloading this file, you are agreeing to the publisher’s Terms & Conditions.

Article

Galantamine-Memantine Combination for Cognitive Impairments Due to Electroconvulsive Therapy, Traumatic Brain Injury, and Neurologic and Psychiatric Disorders: Kynurenic Acid and Mismatch Negativity Target Engagement

Maju Mathew Koola, MD

Published: March 1, 2018

Galantamine-Memantine Combination for Cognitive Impairments Due to Electroconvulsive Therapy, Traumatic Brain Injury, and Neurologic and Psychiatric Disorders:

Kynurenic Acid and Mismatch Negativity Target Engagement

Vertical divider

ABSTRACT

Cognitive impairments due to electroconvulsive therapy (ECT), traumatic brain injury (TBI), and neurologic and psychiatric disorders are prevalent. Cholinergic and glutamatergic pathways, α-7 nicotinic acetylcholine (α-7nACh) receptor, and N-methyl-d-aspartate (NMDA) receptor are potential pathophysiologic mechanisms in all of these conditions. Galantamine not only is an acetylcholinesterase inhibitor but has a dual mode of action as a α-7nACh receptor modulator as well. Memantine is a noncompetitive NMDA receptor antagonist. Galantamine and memantine are approved by the US Food and Drug Administration (FDA) for the treatment of Alzheimer’s disease (AD). Galantamine and memantine have shown efficacy for the treatment of ECT- and TBI-induced cognitive impairments. The kynurenine pathway (KP) metabolites are associated with ECT- and TBI-induced cognitive impairments and several neurologic and psychiatric disorders. Kynurenic acid (KYNA) is an antagonist to the α-7nACh and NMDA receptors. The galantamine-memantine combination has been shown to modulate several KP metabolites in schizophrenia, thereby improving several cognitive domains. There are no FDA-approved treatments for ECT-induced cognitive impairments or for cognitive impairments in neurologic and psychiatric disorders except AD. This article is timely because the pharmacology of cognition as a panacea for neuropsychiatric diseases was recently published. Hence, randomized controlled trials are warranted with this combination in these diseases, with KYNA and mismatch negativity as novel target engagement. Future positive studies may lead to standard of care, which is likely to significantly improve socio-occupational functioning.

Prim Care Companion CNS Disord 2018;20(2):17nr02235

To cite: Koola MM. Galantamine-memantine combination for cognitive impairments due to electroconvulsive therapy, traumatic brain injury, and neurologic and psychiatric disorders: kynurenic acid and mismatch negativity target engagement. Prim Care Companion CNS Disord. 2018;20(2):17nr02235.

To share: https://doi.org/10.4088/PCC.17nr02235

aDepartment of Psychiatry and Behavioral Sciences, George Washington University School of Medicine and Health Sciences, Washington, DC

*Corresponding author: Maju Mathew Koola, MD, Department of Psychiatry and Behavioral Sciences, George Washington University School of Medicine and Health Sciences, 2300 I St NW, Washington, DC 20037 ([email protected])

Cognitive impairments due to electroconvulsive therapy (ECT), traumatic brain injury (TBI), and several neurologic and psychiatric disorders are common. Cholinergic and glutamatergic pathways, α-7 nicotinic acetylcholine (α-7nACh) receptor, and N-methyl-d-aspartate (NMDA) receptor are potential pathophysiologic mechanisms for cognitive impairments. Galantamine not only is an acetylcholinesterase inhibitor (AChEI) but has a dual mode of action as a α-7nACh and α4β2 receptor modulator as well.1 Memantine is a noncompetitive NMDA receptor antagonist,2 which attenuates the neurotoxic tonic overstimulation of NMDA receptors by glutamate.3 Memantine modulates Kir6.2 activity (Kir6.2 is a major subunit of the ATP-sensitive K+ channels and functions in synaptic plasticity); it has been argued that the Kir6.2 channel is a novel therapeutic target to enhance cognition in people with Alzheimer’s disease (AD).4 Galantamine and memantine are approved by the US Food and Drug Administration (FDA) for the treatment of AD. In AD, galantamine 24 mg and memantine 28 mg daily are typically prescribed.5,6

The focus of this article is to shed light on cognitive impairments due to ECT, TBI, and neurologic and psychiatric disorders and the potential role of galantamine-memantine combination treatment with kynurenic acid (KYNA) and mismatch negativity (MMN) as target engagement.

PRECLINICAL EVIDENCE WITH GALANTAMINE-MEMANTINE COMBINATION

Seven preclinical studies7-13 have shown that the galantamine-memantine combination was effective for cognition; 5 studies9-13 have shown that the combination was significantly better than either medication alone and also provided synergistic benefits. This evidence may be translated to schizophrenia.14

CLINICAL EVIDENCE WITH GALANTAMINE-MEMANTINE COMBINATION IN ALZHEIMER’ S DISEASE AND SCHIZOPHRENIA

In a 53-year-old woman with AD,15 a combination of donepezil 5 mg and memantine 5 mg for 9 months was ineffective. The patient was switched from donepezil to galantamine (dose unknown). After 4 weeks, irritability and violence gradually decreased and disappeared.15 Cognition may not have improved because of the inadequate dose and duration of the combination. In a 2-year randomized controlled trial16 (RCT) with 232 elderly subjects with cognitive impairments, in those with AD prodrome (N = 39), a combination of galantamine and memantine significantly improved cognitive scores compared to galantamine alone at 6 months. Cognitive decline occurred after discontinuation of galantamine.16 In another study,17 galantamine-memantine combination (N = 53) was significantly better for cognition compared to donepezil-memantine (N = 61) in AD patients. Because the combination was effective in AD, it may be translated to treat cognitive impairments in schizophrenia.18 Several review articles19,20 have argued that this combination may be effective for cognitive impairments in schizophrenia. This effectiveness was corroborated in a small open-label study21 that showed cognitive enhancement in several domains with concurrent improvement in the kynurenine pathway (KP) metabolites. Finally, this combination is the standard of care in AD.

ELECTROCONVULSIVE THERAPY

ECT is an effective treatment for a variety of psychiatric disorders. ECT is associated with retrograde amnesia (reduced ability to recall recent events) and anterograde amnesia (reduced ability for new learning). ECT-induced cognitive impairments22 are independent of postictal delirium23 and are prevalent. In a Swedish register-based study,24 subjective memory worsening immediately post-ECT was experienced in 26% of 1,212 patients. ECT-induced cognitive impairments are the major factor limiting its use in clinical practice.25 Bilateral ECT is more effective and faster acting but is associated with more cognitive impairments compared to unilateral ECT.25 There are no FDA-approved medications for ECT-induced cognitive impairments.

clinical points

  • Galantamine-memantine combination is the standard of care for the treatment of cognitive impairments in Alzheimer’s disease.
  • Randomized controlled trials are warranted with the galantamine-memantine combination in neuropsychiatric disorders, with kynurenic acid and mismatch negativity as target engagement.
  • Clinicians may consider this combination as off-label use, which is likely to significantly improve socio-occupational functioning.

Pathophysiology of ECT-Induced Cognitive Impairments

The exact mechanisms contributing to ECT-induced cognitive deficits are not well known; however, cholinergic26 and glutamatergic neurotransmission and NMDA receptor have been implicated27 among various other factors.

Clinical Trials With Galantamine for ECT-Induced Cognitive Impairments

In a study by Matthews and colleagues,28 9 consecutive ECT patients were given galantamine 4 mg twice daily throughout the course of their ECT treatments followed by a second cohort of 8 consecutive ECT patients who did not receive galantamine. Those who received galantamine performed significantly better on delayed memory and abstract reasoning items following ECT as measured by the Modified Mini-Mental Status Examination.29 This measure is an expanded version of the MiniMental State Examination (MMSE)30 that includes additional subtests (delayed recall, similarities, word generation) and has been shown to be effective in screening for cognitive impairments.31 In an RCT,32 39 inpatients diagnosed with major depressive disorder (MDD), bipolar depression, or schizoaffective disorder were randomized to galantamine or placebo. Medications were initiated 24 hours before starting ECT and continued throughout the course of ECT. Galantamine was started at 4 mg twice daily, whereas those assigned to the placebo group received an identical number of inactive tablets twice daily. The dose of galantamine was increased by 4 mg every 3 days to a target dose of 8 mg twice daily. The Repeatable Battery for the Assessment of Neuropsychological Status (RBANS),33 which assesses immediate memory, visuospatial construction, attention, language, and delayed memory, was administered at baseline and 24 to 48 hours after completing a course of ECT. Participants (N = 30; 12 on galantamine, 18 on placebo) had both pre- and posttreatment RBANS ratings. At discharge, those on galantamine scored significantly higher on the delayed memory item compared to the placebo group.32 Galantamine was safe and well tolerated in both studies.28,32

Clinical Trials With Memantine for ECT-Induced Cognitive Impairments

ECT-induced cognitive impairments may be due to seizure, which leads to irreversible neuron damage by increasing the effect of glutamate on NMDA receptors.34 On the basis of this hypothesis, memantine has been tried for ECT-induced cognitive impairments. In an RCT,35 patients with MDD for which ECT was indicated received either memantine 5 mg/day (N = 20) or placebo (N = 20). The patients received memantine or placebo for the whole period of ECT treatment starting the day before ECT and continuing until the fourth session of ECT (total of 8 days because ECT was given on alternate days). The MMSE was used for the assessment of cognition before and at the end of the study. Patients taking memantine scored significantly higher at the end of the ECT sessions compared to those receiving placebo on the MMSE (P = .02) and 3-item recall to test recent memory (P < .001).35 In another RCT,36 adult patients (N = 38) with bipolar disorder, MDD, schizophrenia, or schizoaffective disorder were randomized to memantine (10 mg/day initially and 20 mg/day at the end of the first week) or placebo during the ECT period. The cognitive functions were assessed 24 hours before and after ECT. The mean MMSE score relatively increased in the intervention group and showed a significant improvement with memantine (P < .001). The direct digit span score decreased in the control group, whereas no significant change was observed in the intervention group (P < .001). Backward memory span test scores decreased in the control group after the ECT sessions, whereas a relative increase was observed in the intervention group (P = .001).36 Memantine was well tolerated in both studies.35,36

In the study by Abbasinazari and colleagues,35 it is interesting to note how quickly memantine was effective despite patients receiving only 5 mg starting one day before the first ECT session for a total of 8 days. Memantine was effective despite using a low dose for a short duration. Hence, a higher dose and longer duration would be more effective. Although the 3-item score was significantly better in those taking memantine compared to placebo, even among those taking memantine, the score decreased from 2.9 to 2.6.35 This finding sheds light on the adequate dose of memantine and indicates that a higher dose may be needed. Perhaps memantine should be started a few days before the first ECT session. Maybe MMSE scores would have returned to baseline if they were measured a few weeks or months after the last ECT session. It is also unclear how long memantine should be continued and how frequently the dose needs to be titrated. The same holds true for galantamine use. Unfortunately, practice guidelines are lacking for the pharmacologic treatment of ECT-induced cognitive impairments.

Galantamine and memantine can be started together.21 Also, in elderly people with AD, the FDA approved the donepezil-memantine combination (Namzaric), which was found to be safe and well tolerated.

Clinical Implications

If RCTs find that the galantamine-memantine combination is effective, it may become the standard of care for ECT-induced cognitive impairments. With this combination, bilateral ECT may be administered more often. This treatment modality may be particularly beneficial for those who receive maintenance ECT. Retention deficits resolve only after 6 months; hence, 6-month RCTs are warranted. Also, the galantamine-memantine combination may be administered for 6 months after the last ECT session for faster recovery. This combination treatment may enhance socio-occupational functioning considerably. If cognitive impairments are prevented or treated adequately, there could be less refusal of ECT in real-world practice.

TRAUMATIC BRAIN INJURY

TBI is common and a major public health problem. TBI-related emergency department (ED) visits, hospitalizations, and deaths have increased over the past decade. In the United States, the total combined rates of TBI-related hospitalizations, ED visits, and deaths increased from 521.0 per 100,000 in 2001 to 823.7 per 100,000 in 2010 (data from the Centers for Disease Control and Prevention).37 Cognitive impairments due to TBI are common. In a survey,38 128 (22%) of 583 patients reported problems with cognition post-TBI.

Pathophysiology of TBI-Induced Cognitive Impairments

The choline acetyltransferase activity was reduced in the temporal lobe, cingulate, and parietal areas of the neocortex in 16 postmortem human brains following head injuries compared to 8 controls who died of causes other than central nervous system pathology.39 In addition to the cholinergic system, the glutamatergic system and NMDA receptors have been implicated in the pathophysiology of TBI.40,41 Increased level of extracellular glutamate following TBI causes overstimulation of glutamate receptors, leading to neuronal cell death. Glutamate transporter, GLT-1, may be critical in preventing spillover of glutamate between adjacent synapses, thereby regulating intersynaptic glutamatergic and GABAergic transmission.42 A down-regulation of GLT-1 and GLAST (another glutamate transporter) levels in the ipsilateral and contralateral cerebral cortex is associated with a rise in cerebrospinal fluid glutamate levels, reaching a maximum at 48 hours following the injury.43 Most patients arrive at the hospital for treatment several hours after the insult; thus, the beneficial use of medications can be very limited.44 Therefore, early intervention is key. Neuropsychological tests were unable to distinguish cognitive impairments in schizophrenia versus TBI.45 Unfortunately, there are no FDA-approved medications for TBI-induced cognitive impairments.

Preclinical Evidence With Galantamine for TBI-Induced Cognitive Impairments

Galantamine enhanced cognitive recovery in adult male rats after TBI.46 Rats with TBI treated with galantamine showed significant improvements in the Morris water maze, novel object recognition, and context-specific fear memory tasks.47

Clinical Evidence With Galantamine for TBI-Induced Cognitive Impairments

Galantamine 5 mg twice daily was effective for TBI-induced cognitive impairments in 30 patients in an outpatient clinic.48 In a 28-year-old woman with severe TBI,49 galantamine 8 mg daily improved cognitive symptoms; she also had psychosis secondary to TBI. Galantamine may be particularly beneficial in people who have both TBI-induced cognitive impairments and psychosis.50 However, in a 35-year-old man, galantamine 8 mg/day for 1 week did not improve cognition as measured by the MMSE.51 The authors50 argued that this lack of improvement could have been due to inadequate dose and duration; also, this patient had history of multiple TBIs. In a 38-year-old man with basal ganglia hemorrhage, galantamine 8 mg/day was started for cognitive impairments.52 Galantamine was gradually increased to 24 mg/day after 6 weeks. The patient had significant improvement in cognition after 2 months. Despite these improvements, there was no significant improvement on a number of executive functions such as abstract reasoning, and he had low cognitive tolerance for dealing with novel situations and challenges.52

Preclinical Evidence With Memantine for TBI-Induced Cognitive Impairments

In one study, TBI induced in adult rats led to significant neuronal death in the hippocampal CA2 and CA3 regions.53 Treatment of rats with memantine immediately after the injury significantly prevented the neuronal loss in both CA2 and CA3 regions.53 Vorwerk and colleagues54 assessed ganglion cell survival and extracellular glutamate levels from 1 to 28 days after optic nerve crush in Long-Evans rats. The optic nerve crush led to a rise in extracellular glutamate, which was blocked by treatment with memantine. Changes in the function of synaptic versus extrasynaptic GluN2B-containing NMDA receptors after mechanical stretch injury in rat cortical neurons were evaluated in another study.55 Treatment with memantine after TBI prevented injury-induced increases in calcium-permeable AMPA receptor-mediated activity.55

Intracranial hemorrhage due to TBI or ruptured cerebral aneurysm is characterized by major neurologic damage and a high mortality rate. Mouse cortical axons degenerated less after exposure to lysed blood in neuronal cultures enriched with both memantine and vitamin D compared to control medium and cultures enriched with only memantine or vitamin D.56 A combination treatment of 17β-estradiol and memantine was more neuroprotective than either monotherapy in a rat hippocampal slice culture model of TBI.57 In another study58 of a rat model of experimental TBI, an intravenous bolus dose of a combination of memantine and 17β-estradiol was administered. The combination was neuroprotective by increasing neuronal survival and decreasing neuronal degeneration in the hippocampus and cortex ipsilateral to injury.58 This synergistic action may be the result of memantine blocking a deleterious 17β-estradiol—mediated enhancement of NMDA receptors. The melatonin (free radical scavenger)—memantine combination reduced brain injury after TBI in mice compared to either melatonin or memantine59; mechanisms were decreased DNA fragmentation, iNOS activity, p38 phosphorylation, ERK-1/2 phosphorylation, and SAPK/JNK-1/2 phosphorylation.

Rat hippocampal slice cultures received 2 stretch injuries 24 hours apart in one study60; injury resulted in significant cell death, loss of long-term potentiation (LTP), and astrogliosis compared with uninjured samples. Mice were subjected to repetitive TBI (4 injuries in 4 days) and randomized to memantine or vehicle. Memantine administration 1 hour following each injury significantly reduced the effect of repetitive TBI for all outcome measures. Compared to vehicle-treated mice, memantine-treated mice had reduced tau phosphorylation at acute time points after injury and less glial activation and LTP deficit 1 month after injury.60 This finding is clinically relevant because repetitive TBI is common in sports concussions and results in significant cognitive impairments.

Clinical Evidence With Memantine for TBI-Induced Cognitive Impairments

In a 24-week study,61 10 patients with severe TBI and 11 patients with mild TBI were treated with memantine or piracetam. Memantine had a positive and stable effect on a broad spectrum of cognitive disturbances, while the effect of piracetam was observed only for some cognitive functions and was short term.61 In another study,62 patients with TBI who received memantine (N = 22) had significantly reduced serum neuron-specific enolase (a marker of neuronal damage) levels by day 7 and marked improvement in their Glasgow Coma Scale scores on day 3 compared to controls (N = 19) who received standard TBI treatment. Memantine may be particularly beneficial in athletes and soldiers in combat who suffer functional impairment and neurodegenerative sequelae after multiple concussions.63

KYNURENINE PATHWAY

KYNA is an antagonist to the α-7nACh and NMDA receptors. Galantamine-memantine combination may counteract the effects of KYNA, thereby improving cognition.19-21 ECT administered for 14 days was associated with significant changes in the NMDA receptor complex in rat cortex.64 This manifest as a reduction in the potency of glycine to inhibit the binding of 5,7-dichloro[3H]KYNA to strychnine-insensitive glycine receptors.64 Treatment with ECT in 19 patients with MDD was associated with a significant decrease in the plasma concentrations of tryptophan (TRP), kynurenine (KYN), and quinolinic acid (QUIN), whereas concentrations of KYNA did not change.65 The QUIN/KYNA ratio was found to significantly decrease in ECT-treated patients. There was a significant inverse correlation between symptom severity and KYN concentrations at baseline.65 In 19 patients with unipolar or bipolar depression, there was a significant increase in KYNA, KYN/TRP, KYNA/KYN, and KYNA/3-hydroxykynurenine ratios post-ECT.66 KYN and KYN/TRP ratios were significantly negatively associated with total depression scores over time.66 In another study,67 before ECT, KYNA concentrations were lower in 50 patients with MDD, bipolar depression, or schizoaffective disorder than in 48 healthy controls. There were no significant changes in those concentrations compared with the baseline concentration during ECT.67

In 28 patients with severe TBI, cerebrospinal fluid (CSF) KYN, KYNA, and QUIN were elevated, whereas TRP, anthranilic acid (AA), and 3-hydroxyanthranilic acid (3HAA) remained unchanged.68 The ratios of QUIN/KYN, QUIN/KYNA, KYNA/KYN, and 3HAA/AA revealed that QUIN concentrations were significantly higher than KYN and KYNA, which is suggestive of increased neurotoxicity.68 Amplified (indoleamine 2,3-dioxygenase-1 [IDO1] kynurenase [KYNase]) RNA expression was demonstrated in postmortem brains, and enhanced IDO1 protein coincided with overt tissue damage. QUIN concentrations in the CSF were significantly higher in patients with unfavorable outcomes and inversely correlated with Glasgow Outcome Scale scores.68

Cerebrovascular Accident (Stroke)

Cognitive impairments are common poststroke. Of 105 patients with chronic stroke, 60% had cognitive impairments.69 In 149 patients with stroke, those with poor outcomes had higher mean KYN/TRP ratios than patients with more favorable outcomes.70 Studies with galantamine and memantine for stroke are scarce; however, these 2 medications have been found to be promising treatments for poststroke cognitive impairments.71 Hence, the galantamine-memantine combination may be more effective than either medication alone.

OTHER NEUROLOGIC AND PSYCHIATRIC DISORDERS

The KP is involved in schizophrenia,72 depression,73 bipolar disorder,74 autism spectrum disorder,75 Down’s syndrome,76 Huntington’s disease,77 HIV/AIDS dementia complex,78,79 Parkinson’s disease,80 multiple sclerosis,81 amyotrophic lateral sclerosis,82 epilepsy,83 and brain tumors.84 Thus, the galantamine-memantine combination may be effective for cognitive impairments in these disorders as well. There are no studies conducted with galantamine or memantine in chronic traumatic encephalopathy. This combination may be effective in chronic traumatic encephalopathy, and future studies are warranted.

NEGATIVE SYMPTOMS

In a study by Oka et al,85 36 patients with AD who did not respond to donepezil were switched to galantamine and followed for 24 weeks. Apathy, irritability, aberrant motor symptoms, and executive functioning improved significantly.85 In the 28-year-old woman with severe TBI mentioned previously who was treated with galantamine, affective flattening and alogia significantly improved.49 In a 43-year-old man with treatment-refractory schizophrenia, galantamine was associated with a persistent reduction of negative symptoms over the 2-month period of its administration when added to a stable regimen of atypical antipsychotic medications.86 The patient received galantamine 24 mg for 2 weeks (6 weeks for titration). He had a 50% decrease in the total Scale for the Assessment of Negative Symptoms (SANS); negative symptoms worsened with galantamine discontinuation.86 Another treatment-refractory male patient with schizophrenia received galantamine 24 mg for 3 months.87 The patient had global improvement of apathy in the total score on the Marin Apathy Evaluation Scale. In addition, the patient also showed improvements in affective nonresponsivity, anergia, and ability to enjoy sexual interests and activities.87 In a phase 2 clinical trial,88 31 participants with schizophrenia received 3-(2,4-dimethoxybenzylidene) anabaseine (DMXB-A), which is a partial α-7 nicotinic agonist. Those who received DMXB-A 150 mg twice daily had significant improvement in SANS total score and anhedonia and alogia scores compared to DMXB-A 75 mg twice daily and placebo.88 In an RCT89 with galantamine in schizophrenia (N = 86), galantamine significantly improved alogia compared to placebo. This finding is not surprising because galantamine has been shown to improve primary progressive aphasia in frontotemporal dementia.90 In 45 patients with chronic poststroke, galantamine administration had a beneficial effect on aphasia.91 Medications with α-7 nicotinic action consistently improve alogia, which is an intriguing finding; mechanism of action is unknown.

Memantine treatment reversed anhedonia in stressed rats.92 Memantine was administered in neonatal rats with early maternal deprivation; social interaction was significantly enhanced in adult rats.93

In a 52-year-old man with schizophrenia, memantine 20 mg daily decreased SANS scores from 96 to 70 (avolition-apathy: −8) and anhedonia-asociality (−7), affective flattening (−7), alogia (−1), and attention (−3) in 4 months.94 In a 72-year-old woman with schizophrenia taking aripiprazole with no obvious psychosis, depression, or extrapyramidal signs, memantine 10 mg/day improved asociality and alogia.95 Negative symptoms became worse when memantine was stopped and improved with reintroduction of memantine.95 In an RCT,96 memantine was also effective for aphasia in 28 patients with chronic poststroke. In another study,97 participants with deficit schizophrenia (N = 40) showed increased IgA responses to xanthurenic acid, picolinic acid, and quinolinic acid and relatively lowered IgA responses to KYNA and anthranilic acid compared to healthy controls (N = 40) and patients with nondeficit schizophrenia (N = 40). In a meta-analysis98 of 8 RCTs in schizophrenia (N = 448), memantine significantly improved negative symptoms compared to placebo (standardized MD [SMD] = 0.96, P = .006).

In a 6-week open-label study21 of the galantamine-memantine combination in schizophrenia, SANS total score improved from 5 to 0 in 1 participant. This finding is suggestive of improvement of primary negative symptoms, because at baseline, the Brief Psychiatric Rating Scale psychosis, Calgary Depression Scale for Schizophrenia, and the Simpson-Angus Scale scores were 4, 0, and 0, respectively.21 Negative symptoms are common in the neurologic and psychiatric disorders described previously. Use of galantamine-memantine combination to treat negative symptoms is an additional benefit to patients.

MISMATCH NEGATIVITY

MMN is the functioning of the auditory sensory memory system indexed by the generation of a well-defined event-related potential. MMN is a biomarker of NMDA99 and α-7nACh100 receptor dysfunction in schizophrenia. MMN is a translatable brain marker toward early intervention for psychosis.101 In a 6-year follow-up study102 comparing 48 participants with clinical high risk for psychosis and 47 healthy controls, MMN at baseline was a robust predictor of functional recovery. In another study103 with 25 participants with schizophrenia, 21 first-degree relatives of participants with schizophrenia, and 29 healthy controls, MMN was a stronger predictor of functional outcome than cognition.  Memantine enhanced MMN in 13 healthy subjects,104 in rodents,105 and in 41 people with schizophrenia.106 No studies have been conducted with galantamine on MMN. However, interactive effects of α-7nACh and NMDA receptors on MMN were recently published.107 Therefore, the galantamine-memantine combination may significantly enhance the MMN amplitude more than either medication alone.  

CONCLUSIONS AND FUTURE DIRECTIONS

There is considerable evidence from preclinical and clinical studies for cognitive enhancement with either galantamine or memantine. However, many studies showed an improvement but not recovery. In several studies, various combination treatments were effective. Galantamine-memantine combination treatment was effective for cognition in AD and showed synergistic benefit in animals. Considering these findings, RCTs are warranted with the galantamine-memantine combination, which may be synergistically better than either medication alone, for ECT-induced cognitive impairments, TBI, and neurologic and psychiatric disorders. This article is timely because the pharmacology of cognition as a panacea for neuropsychiatric diseases was recently published.108 Positive phase 3 studies may lead to FDA approval for these indications, which is likely to lead to greater clinical utility. This may lead to a significant improvement in patients’ functioning in the real world, with KYNA and MMN as target engagement.

Submitted: October 20, 2017; accepted November 24, 2017.

Published online: March 1, 2018.

Potential conflicts of interest: None.

Funding/support: None.

REFERENCES

1. Samochocki M, Zerlin M, Jostock R, et al. Galantamine is an allosterically potentiating ligand of the human alpha4/beta2 nAChR. Acta Neurol Scand suppl. 2000;102(s176):68-73. PubMed CrossRef

2. Johnson JW, Kotermanski SE. Mechanism of action of memantine. Curr Opin Pharmacol. 2006;6(1):61-67. PubMed CrossRef

3. Parsons CG, Danysz W, Quack G. Memantine is a clinically well tolerated N-methyl-D-aspartate (NMDA) receptor antagonist: a review of preclinical data. Neuropharmacology. 1999;38(6):735-767. PubMed CrossRef

4. Moriguchi S, Ishizuka T, Yabuki Y, et al. Blockade of the KATP channel Kir6.2 by memantine represents a novel mechanism relevant to Alzheimer’s disease therapy [published online ahead of print October 25, 2016]. Mol Psychiatry. 2018;23(2):211-221. PubMed CrossRef in press

5. Razadyne [package insert]. Titusville, NJ: Janssen Pharmaceuticals; 2013.

6. Namenda [package insert]. Irvine, CA: Allergan; 2016.

7. Woodruff-Pak DS, Tobia MJ, Jiao X, et al. Preclinical investigation of the functional effects of memantine and memantine combined with galantamine or donepezil. Neuropsychopharmacology. 2007;32(6):1284-1294. PubMed CrossRef

8. Lorrio S, Negredo P, Roda JM, et al. Effects of memantine and galantamine given separately or in association, on memory and hippocampal neuronal loss after transient global cerebral ischemia in gerbils. Brain Res. 2009;1254:128-137. PubMed CrossRef

9. Busquet P, Capurro V, Cavalli A, et al. Synergistic effects of galantamine and memantine in attenuating scopolamine-induced amnesia in mice. J Pharmacol Sci. 2012;120(4):305-309. PubMed CrossRef

10. Lopes JP, Tarozzo G, Reggiani A, et al. Galantamine potentiates the neuroprotective effect of memantine against NMDA-induced excitotoxicity. Brain Behav. 2013;3(2):67-74. PubMed CrossRef

11. Schneider JS, Pioli EY, Jianzhong Y, et al. Effects of memantine and galantamine on cognitive performance in aged rhesus macaques. Neurobiol Aging. 2013;34(4):1126-1132. PubMed CrossRef

12. Nikiforuk A, Potasiewicz A, Kos T, et al. The combination of memantine and galantamine improves cognition in rats: the synergistic role of the α7 nicotinic acetylcholine and NMDA receptors. Behav Brain Res. 2016;313:214-218. PubMed CrossRef

13. Reggiani AM, Simoni E, Caporaso R, et al. In vivo characterization of ARN14140, a memantine/galantamine-based multi-target compound for Alzheimer’s disease. Sci Rep. 2016;6(1):33172. PubMed CrossRef

14. Koola MM. Galantamine and memantine combination for cognition: enough or more than enough to translate from murines and macaques to men with schizophrenia [published online ahead of print November 11, 2017]? Asian J Psychiatr. PubMed CrossRef

15. Hamuro A. Combination therapy with galantamine and memantine improves behavioral and psychological symptoms of dementia (BPSD) in patients with early-onset Alzheimer’s disease. Aust N Z J Psychiatry. 2013;47(6):583. PubMed CrossRef

16. Peters O, Lorenz D, Fesche A, et al. A combination of galantamine and memantine modifies cognitive function in subjects with amnestic MCI. J Nutr Health Aging. 2012;16(6):544-548. PubMed CrossRef

17. Matsuzono K, Hishikawa N, Ohta Y, et al. Combination therapy of cholinesterase inhibitor (donepezil or galantamine) plus memantine in the Okayama Memantine Study. J Alzheimers Dis. 2015;45(3):771-780. PubMed CrossRef

18. Koola M. Parsaik. Galantamine-Memantine Combination Effective in Dementia: Translate to Dementia Praecox? Schizophr Res Cogn. 2018;12:8-10. CrossRef

19. Koola MM, Buchanan RW, Pillai A, et al. Potential role of the combination of galantamine and memantine to improve cognition in schizophrenia. Schizophr Res. 2014;157(1-3):84-89. PubMed CrossRef

20. Koola MM. Kynurenine pathway and cognitive impairments in schizophrenia: pharmacogenetics of galantamine and memantine. Schizophr Res Cogn. 2016;4(4):4-9. PubMed CrossRef

21. Koola MM, Sklar J, Davis W, et al. Kynurenine pathway in schizophrenia: galantamine and memantine combination for cognitive impairments [published online ahead of print July 10, 2017]. Schizophr Res. PubMed CrossRef

22. Frith CD, Stevens M, Johnstone E, et al. Effects of ECT and depression on various aspects of memory. Br J Psychiatry. 1983;142(6):610-617. PubMed CrossRef

23. Porter R, Heenan H, Reeves J. Early effects of electroconvulsive therapy on cognitive function. J ECT. 2008;24(1):35-39. PubMed CrossRef

24. Brus O, Nordanskog P, Båve U, et al. Subjective memory immediately following electroconvulsive therapy. J ECT. 2017;33(2):96-103. PubMed CrossRef

25. Sackeim HA, Prudic J, Fuller R, et al. The cognitive effects of electroconvulsive therapy in community settings. Neuropsychopharmacology. 2007;32(1):244-254. PubMed CrossRef

26. Lerer B. Studies on the role of brain cholinergic systems in the therapeutic mechanisms and adverse effects of ECT and lithium. Biol Psychiatry. 1985;20(1):20-40. PubMed CrossRef

27. Chamberlin E, Tsai GE. A glutamatergic model of ECT-induced memory dysfunction. Harv Rev Psychiatry. 1998;5(6):307-317. PubMed CrossRef

28. Matthews JD, Blais M, Park L, et al. The impact of galantamine on cognition and mood during electroconvulsive therapy: a pilot study. J Psychiatr Res. 2008;42(7):526-531. PubMed CrossRef

29. Teng EL, Chui HC. The Modified Mini-Mental Status (3MS) examination. J Clin Psychiatry. 1987;48:314-318. PubMed

30. Folstein MF, Folstein SE, McHugh PR. Mini-mental state: a practical method for grading the cognitive state of patients for clinician. J Psychiatr Res. 1975;12(3):189-198. PubMed CrossRef

31. Jones TG, Schinka JA, Vanderploeg RD, et al. 3MS normative data for the elderly. Arch Clin Neuropsychol. 2002;17(2):171-177. PubMed CrossRef

32. Matthews JD, Siefert CJ, Blais MA, et al. A double-blind, placebo-controlled study of the impact of galantamine on anterograde memory impairment during electroconvulsive therapy. J ECT. 2013;29(3):170-178. PubMed CrossRef

33. Randolph C, Tierney MC, Mohr E, et al. The Repeatable Battery for the Assessment of Neuropsychological Status (RBANS): preliminary clinical validity. J Clin Exp Neuropsychol. 1998;20(3):310-319. PubMed CrossRef

34. Waxman EA, Lynch DR. N-methyl-D-aspartate receptor subtypes: multiple roles in excitotoxicity and neurological disease. Neuroscientist. 2005;11(1):37-49. PubMed CrossRef

35. Abbasinazari M, Adib-Eshgh L, Rostami A, et al. Memantine in the prevention or alleviation of electroconvulsive therapy induces cognitive disorders: a placebo controlled trial. Asian J Psychiatr. 2015;15:5-9. PubMed CrossRef

36. Alizadeh NS, Maroufi A, Jamshidi M, et al. Effect of memantine on cognitive performance in patients under electroconvulsive therapy: a double-blind randomized clinical trial. Clin Neuropharmacol. 2015;38(6):236-240. PubMed CrossRef

37. Centers for Disease Control and Prevention. Traumatic brain injury and concussion. CDC website. https://www.cdc.gov/traumaticbraininjury/data/index.html. Accessed February 13, 2018.

38. Brown AW, Moessner AM, Mandrekar J, et al. A survey of very-long-term outcomes after traumatic brain injury among members of a population-based incident cohort. J Neurotrauma. 2011;28(2):167-176. PubMed CrossRef

39. Murdoch I, Perry EK, Court JA, et al. Cortical cholinergic dysfunction after human head injury. J Neurotrauma. 1998;15(5):295-305. PubMed CrossRef

40. Faden AI, Demediuk P, Panter SS, et al. The role of excitatory amino acids and NMDA receptors in traumatic brain injury. Science. 1989;244(4906):798-800. PubMed CrossRef

41. Obrenovitch TP, Urenjak J. Is high extracellular glutamate the key to excitotoxicity in traumatic brain injury? J Neurotrauma. 1997;14(10):677-698. PubMed CrossRef

42. Sullivan R, Rauen T, Fischer F, et al. Cloning, transport properties, and differential localization of two splice variants of GLT-1 in the rat CNS: implications for CNS glutamate homeostasis. Glia. 2004;45(2):155-169. PubMed CrossRef

43. van Landeghem FK, Stover JF, Bechmann I, et al. Early expression of glutamate transporter proteins in ramified microglia after controlled cortical impact injury in the rat. Glia. 2001;35(3):167-179. PubMed CrossRef

44. Yi JH, Hazell AS. Excitotoxic mechanisms and the role of astrocytic glutamate transporters in traumatic brain injury. Neurochem Int. 2006;48(5):394-403. PubMed CrossRef

45. Heaton RK, Baade LE, Johnson KL. Neuropsychological test results associated with psychiatric disorders in adults. Psychol Bull. 1978;85(1):141-162. PubMed CrossRef

46. de la Tremblaye PB, Bondi CO, Lajud N, et al. Galantamine and environmental enrichment enhance cognitive recovery after experimental traumatic brain injury but do not confer additional benefits when combined. J Neurotrauma. 2017;34(8):1610-1622. PubMed CrossRef

47. Zhao J, Hylin MJ, Kobori N, et al. Post-injury administration of galantamine reduces traumatic brain injury pathology and improves outcome [published online ahead of print December 18, 2017]. J Neurotrauma. 2018;35(2):362-374. PubMed CrossRef

48. Tenovuo O. Central acetylcholinesterase inhibitors in the treatment of chronic traumatic brain injury-clinical experience in 111 patients. Prog Neuropsychopharmacol Biol Psychiatry. 2005;29(1):61-67. PubMed CrossRef

49. Bennouna M, Greene VB, Defranoux L. Adjuvant galantamine to risperidone improves negative and cognitive symptoms in a patient presenting with schizophrenia like psychosis after traumatic brain injury. J Clin Psychopharmacol. 2005;25(5):505-507. PubMed CrossRef

50. Bennouna M, Greene VB, Defranoux L. Cholinergic hypothesis in psychosis following traumatic brain injury and cholinergic hypothesis in schizophrenia: a link? Encephale. 2007;33(4):616-620. PubMed CrossRef

51. Johnson B, Sai Lai Sey M, Bhalerao S. Results of galantamine treatment in acute traumatic brain injury. Psychosomatics. 2007;48(2):177-178. PubMed CrossRef

52. Al Owesie RM, Morton CS. Psychopharmacologic intervention after hemorrhagic basal ganglia damage. J Neurol Sci. 2012;322(1-2):77-78. PubMed CrossRef

53. Rao VL, Dogan A, Todd KG, et al. Neuroprotection by memantine, a non-competitive NMDA receptor antagonist after traumatic brain injury in rats. Brain Res. 2001;911(1):96-100. PubMed CrossRef

54. Vorwerk CK, Zurakowski D, McDermott LM, et al. Effects of axonal injury on ganglion cell survival and glutamate homeostasis. Brain Res Bull. 2004;62(6):485-490. PubMed CrossRef

55. Ferrario CR, Ndukwe BO, Ren J, et al. Stretch injury selectively enhances extrasynaptic, GluN2B-containing NMDA receptor function in cortical neurons. J Neurophysiol. 2013;110(1):131-140. PubMed CrossRef

56. Charier D, Beauchet O, Bell M, et al. Memantine plus vitamin D prevents axonal degeneration caused by lysed blood. ACS Chem Neurosci. 2015;6(3):393-397. PubMed CrossRef

57. Lamprecht MR, Morrison B 3rd. A combination therapy of 17β-estradiol and memantine is more neuroprotective than monotherapies in an organotypic brain slice culture model of traumatic brain injury. J Neurotrauma. 2015;32(17):1361-1368. PubMed CrossRef

58. Day NL, Carle MS, Floyd CL. Post-injury administration of a combination of memantine and 17β-estradiol is protective in a rat model of traumatic brain injury . Neurochem Int. 2017;111:57-58. PubMed CrossRef

59. Kelestemur T, Yulug B, Caglayan AB, et al. Targeting different pathophysiological events after traumatic brain injury in mice: role of melatonin and memantine. Neurosci Lett. 2016;612:92-97. PubMed CrossRef

60. Effgen GB, Morrison B 3rd. Memantine reduced cell death, astrogliosis, and functional deficits in an in vitro model of repetitive mild traumatic brain injury. J Neurotrauma. 2017;34(4):934-942. PubMed CrossRef

61. Litvinenko IV, Emelin AIu, Vorob’ ev SV, et al. Clinical features of the formation and possibilities of treatment of posttraumatic cognitive disturbances. Zh Nevrol Psikhiatr Im S S Korsakova. 2010;110(12):60-66. PubMed

62. Mokhtari M, Nayeb-Aghaei H, Kouchek M, et al. Effect of memantine on serum levels of neuron-specific enolase and on the Glasgow coma scale in patients with moderate traumatic brain injury. J Clin Pharmacol. 2018;58(1):42-47. PubMed CrossRef

63. Mei Z, Qiu J, Alcon S, et al. Memantine improves outcomes after repetitive traumatic brain injury. Behav Brain Res. 2018;340:195-204. PubMed CrossRef

64. Paul IA, Layer RT, Skolnick P, et al. Adaptation of the NMDA receptor in rat cortex following chronic electroconvulsive shock or imipramine. Eur J Pharmacol. 1993;247(3):305-311. PubMed CrossRef

65. Schwieler L, Samuelsson M, Frye MA, et al. Electroconvulsive therapy suppresses the neurotoxic branch of the kynurenine pathway in treatment-resistant depressed patients. J Neuroinflammation. 2016;13(1):51. PubMed CrossRef

66. Guloksuz S, Arts B, Walter S, et al. The impact of electroconvulsive therapy on the tryptophan-kynurenine metabolic pathway. Brain Behav Immun. 2015;48:48-52. PubMed CrossRef

67. Olajossy M, Olajossy B, Wnuk S, et al. Blood serum concentrations of kynurenic acid in patients diagnosed with recurrent depressive disorder, depression in bipolar disorder, and schizoaffective disorder treated with electroconvulsive therapy. Psychiatr Pol. 2017;51(3):455-468. PubMed CrossRef

68. Yan EB, Frugier T, Lim CK, et al. Activation of the kynurenine pathway and increased production of the excitotoxin quinolinic acid following traumatic brain injury in humans. J Neuroinflammation. 2015;12(1):110. PubMed CrossRef

69. Nakling AE, Aarsland D, Næss H, et al. Cognitive deficits in chronic stroke patients: neuropsychological assessment, depression, and self-reports. Dement Geriatr Cogn Dis Extra. 2017;7(2):283-296. PubMed CrossRef

70. Brouns R, Verkerk R, Aerts T, et al. The role of tryptophan catabolism along the kynurenine pathway in acute ischemic stroke. Neurochem Res. 2010;35(9):1315-1322. PubMed CrossRef

71. Beristain X, Golombievski E. Pharmacotherapy to enhance cognitive and motor recovery following stroke. Drugs Aging. 2015;32(10):765-772. PubMed CrossRef

72. Wonodi I, Schwarcz R. Cortical kynurenine pathway metabolism: a novel target for cognitive enhancement in schizophrenia. Schizophr Bull. 2010;36(2):211-218. PubMed CrossRef

73. Hestad KA, Engedal K, Whist JE, et al. The relationships among tryptophan, kynurenine, indoleamine 2,3-dioxygenase, depression, and neuropsychological performance. Front Psychol. 2017;8:1561. PubMed CrossRef

74. Olsson SK, Samuelsson M, Saetre P, et al. Elevated levels of kynurenic acid in the cerebrospinal fluid of patients with bipolar disorder. J Psychiatry Neurosci. 2010;35(3):195-199. PubMed CrossRef

75. Lim CK, Essa MM, de Paula Martins R, et al. Altered kynurenine pathway metabolism in autism: implication for immune-induced glutamatergic activity. Autism Res. 2016;9(6):621-631. PubMed CrossRef

76. Baran H, Cairns N, Lubec B, et al. Increased kynurenic acid levels and decreased brain kynurenine aminotransferase I in patients with Down syndrome. Life Sci. 1996;58(21):1891-1899. PubMed CrossRef

77. Jauch D, Urbańska EM, Guidetti P, et al. Dysfunction of brain kynurenic acid metabolism in Huntington’s disease: focus on kynurenine aminotransferases. J Neurol Sci. 1995;130(1):39-47. PubMed CrossRef

78. Guillemin GJ, Kerr SJ, Brew BJ. Involvement of quinolinic acid in AIDS dementia complex. Neurotox Res. 2005;7(1-2):103-123. PubMed CrossRef

79. Atlas A, Gisslén M, Nordin C, et al. Acute psychotic symptoms in HIV-1 infected patients are associated with increased levels of kynurenic acid in cerebrospinal fluid. Brain Behav Immun. 2007;21(1):86-91. PubMed CrossRef

80. Zádori D, Klivényi P, Toldi J, et al. Kynurenines in Parkinson’s disease: therapeutic perspectives. J Neural Transm (Vienna). 2012;119(2):275-283. PubMed CrossRef

81. Lim CK, Brew BJ, Sundaram G, et al. Understanding the roles of the kynurenine pathway in multiple sclerosis progression. Int J Tryptophan Res. 2010;3:157-167. PubMed CrossRef

82. Lee JM, Tan V, Lovejoy D, et al. Involvement of quinolinic acid in the neuropathogenesis of amyotrophic lateral sclerosis. Neuropharmacology. 2017;112:346-364. PubMed CrossRef

83. Liimatainen S, Lehtimäki K, Raitala A, et al. Increased indoleamine 2,3-dioxygenase (IDO) activity in idiopathic generalized epilepsy. Epilepsy Res. 2011;94(3):206-212. PubMed CrossRef

84. Zhai L, Dey M, Lauing KL, et al. The kynurenine to tryptophan ratio as a prognostic tool for glioblastoma patients enrolling in immunotherapy. J Clin Neurosci. 2015;22(12):1964-1968. PubMed CrossRef

85. Oka M, Nakaaki S, Negi A, et al. Predicting the neural effect of switching from donepezil to galantamine based on single-photon emission computed tomography findings in patients with Alzheimer’s disease. Psychogeriatrics. 2016;16(2):121-134. PubMed CrossRef

86. Rosse RB, Deutsch SI. Adjuvant galantamine administration improves negative symptoms in a patient with treatment-refractory schizophrenia. Clin Neuropharmacol. 2002;25(5):272-275. PubMed CrossRef

87. Arnold DS, Rosse RB, Dickinson D, et al. Adjuvant therapeutic effects of galantamine on apathy in a schizophrenia patient. J Clin Psychiatry. 2004;65(12):1723-1724. PubMed CrossRef

88. Freedman R, Olincy A, Buchanan RW, et al. Initial phase 2 trial of a nicotinic agonist in schizophrenia. Am J Psychiatry. 2008;165(8):1040-1047. PubMed CrossRef

89. Buchanan RW, Conley RR, Dickinson D, et al. Galantamine for the treatment of cognitive impairments in people with schizophrenia. Am J Psychiatry. 2008;165(1):82-89. PubMed CrossRef

90. Kertesz A, Morlog D, Light M, et al. Galantamine in frontotemporal dementia and primary progressive aphasia. Dement Geriatr Cogn Disord. 2008;25(2):178-185. PubMed CrossRef

91. Hong JM, Shin DH, Lim TS, et al. Galantamine administration in chronic post-stroke aphasia. J Neurol Neurosurg Psychiatry. 2012;83(7):675-680. PubMed CrossRef

92. Réus GZ, Abelaira HM, Stringari RB, et al. Memantine treatment reverses anhedonia, normalizes corticosterone levels and increases BDNF levels in the prefrontal cortex induced by chronic mild stress in rats. Metab Brain Dis. 2012;27(2):175-182. PubMed CrossRef

93. Uribe E, Sánchez-Mendoza E, Nieves N, et al. Neonatal administration of memantine enhances social cognition in adult rats subjected to early maternal deprivation. Exp Neurobiol. 2016;25(6):328-332. PubMed CrossRef

94. Paraschakis A. Tackling negative symptoms of schizophrenia with memantine. Case Rep Psychiatry. 2014; 2014:384783. PubMed

95. Pondé MP, Novaes CM. Aripiprazole worsening positive symptoms and memantine reducing negative symptoms in a patient with paranoid schizophrenia. Rev Bras Psiquiatr. 2007;29(1):92. PubMed CrossRef

96. Barbancho MA, Berthier ML, Navas-Sánchez P, et al. Bilateral brain reorganization with memantine and constraint-induced aphasia therapy in chronic post-stroke aphasia: An ERP study. Brain Lang. 2015;145-146:1-10. PubMed CrossRef

97. Kanchanatawan B, Sirivichayakul S, Ruxrungtham K, et al. Deficit, but not nondeficit, schizophrenia is characterized by mucosa-associated activation of the tryptophan catabolite (TRYCAT) pathway with highly specific increases in iga responses directed to picolinic, xanthurenic, and quinolinic acid [published online ahead of print February 8, 2017]. Mol Neurobiol. PubMed CrossRef

98. Kishi T, Matsuda Y, Iwata N. Memantine add-on to antipsychotic treatment for residual negative and cognitive symptoms of schizophrenia: a meta-analysis. Psychopharmacology (Berl). 2017;234(14):2113-2125. PubMed CrossRef

99. Javitt DC, Steinschneider M, Schroeder CE, et al. Role of cortical N-methyl-D-aspartate receptors in auditory sensory memory and mismatch negativity generation: implications for schizophrenia. Proc Natl Acad Sci U S A. 1996;93(21):11962-11967. PubMed CrossRef

100. Dulude L, Labelle A, Knott VJ. Acute nicotine alteration of sensory memory impairment in smokers with schizophrenia. J Clin Psychopharmacol. 2010;30(5):541-548. PubMed CrossRef

101. Nagai T, Tada M, Kirihara K, et al. Mismatch negativity as a "translatable" brain marker toward early intervention for psychosis: a review. Front Psychiatry. 2013;4:115. PubMed CrossRef

102. Kim M, Lee TH, Yoon YB, et al. Predicting remission in subjects at clinical high risk for psychosis using mismatch negativity [published online ahead of print July 31, 2017]. Schizophr Bull. PubMed CrossRef

103. Lee SH, Sung K, Lee KS, et al. Mismatch negativity is a stronger indicator of functional outcomes than neurocognition or theory of mind in patients with schizophrenia. Prog Neuropsychopharmacol Biol Psychiatry. 2014;48:213-219. PubMed CrossRef

104. Korostenskaja M, Nikulin VV, Kicić D, et al. Effects of NMDA receptor antagonist memantine on mismatch negativity. Brain Res Bull. 2007;72(4-6):275-283. PubMed CrossRef

105. Tikhonravov D, Neuvonen T, Pertovaara A, et al. Dose-related effects of memantine on a mismatch negativity-like response in anesthetized rats. Neuroscience. 2010;167(4):1175-1182. PubMed CrossRef

106. Swerdlow NR, Bhakta S, Chou HH, et al. Memantine effects on aensorimotor gating and mismatch negativity in patients with chronic psychosis. Neuropsychopharmacology. 2016;41(2):419-430. PubMed CrossRef

107. Hamilton HK, D’ Souza DC, Ford JM, et al. Interactive effects of an N-methyl-d-aspartate receptor antagonist and a nicotinic acetylcholine receptor agonist on mismatch negativity: implications for schizophrenia. Schizophr Res. 2018;191:87-94. PubMed CrossRef

108. Bailey SJ, Neill JC, Moran PM. Pharmacology of cognition: a panacea for neuropsychiatric disease? Br J Pharmacol. 2017;174(19):3133-3135. PubMed

Related Articles

Volume: 20

Quick Links: Neurologic and Neurocognitive , Traumatic Brain Injury

$40.00

Buy this Article as a PDF