Tryptophan MRI in People With Schizophrenia and Healthy Controls

Phase 2

Completed

Conditions: Schizophrenia

Interventions: Drug: Tryptophan
Drug: Placebo

Registration Number: NCT02067975

Lead Sponsor: University of Maryland, Baltimore

Brief Summary: Kynurenic acid (KYNA) is a naturally occurring chemical in the brain. Studies with rodents indicate that levels of KYNA can impact levels of the neurotransmitters glutamate and dopamine. One way to reliably increase KYNA levels is by ingesting the amino acid tryptophan. Tryptophan is a normal part of the human diet. Tryptophan gets metabolized/changed to other chemicals in the body- including KYNA. By giving people 6 grams of tryptophan, the investigators will be able to increase the KYNA level in a controlled way. The investigators will then be able to study the effects of KYNA on neurotransmitters by using cognitive tests and magnetic resonance imaging techniques (measuring brain activity and brain chemistry using the MRI magnet). They will test people using tryptophan and also using a placebo to look for differences. The investigators will test healthy controls and people with schizophrenia to look for differences.

Detailed Description: There is emerging evidence to suggest that disturbances in the kynurenine pathway may be related to the pathophysiology of schizophrenia. Several post-mortem studies have documented specific abnormalities in the kynurenine pathway, including increased levels of kynurenine and kynurenic acid (KYNA) in the prefrontal cortex of people with schizophrenia (1-4). Increased levels of kynurenine and KYNA have also been observed in the cerebral spinal fluid (CSF) of people with this illness (5). In addition, post-mortem studies have documented changes in key enzymes, including increased expression of tryptophan 2,3-dioxygenase (2, 6) (TDO), which converts tryptophan to kynurenine, and reduced activity of kynurenine 3-monooxygenase (KMO) (4), which may shift metabolism towards enhanced KYNA formation. Finally, a number of genetic studies have implicated the KYNA pathway in this disease. Wonodi et al. (7) found decreased KMO gene expression in the frontal eye field of people with schizophrenia, and Holtze et al. (8) recently reported an association between a KMO SNP and CSF levels of KYNA. Notably, although the exact mechanism underlying the KP impairment in people with schizophrenia is unknown, immune and stress mechanisms have been implicated (7,9).

Increased KYNA may have a number of adverse consequences of importance in schizophrenia. In particular, KYNA is an antagonist of the α7 nicotinic and NMDA glutamate receptors. Dysfunctions of these receptors have been linked to the cognitive impairments and symptom manifestations observed in people with schizophrenia. The purpose of the proposed project is to examine the impact of increased brain KYNA on performance of cognitive tasks and related neuroimaging measures in people with DSM-5/DSM-IV-TR schizophrenia, schizophreniform, or schizoaffective disorder patients and healthy controls. In addition, the investigators will secondarily investigate the relationship of peripheral inflammatory markers and glucocorticoid levels as part of the HPA stress axis to examine relationships and shift to a Type 2 immune response in schizophrenia. Using tryptophan loading to increase KYNA levels, the study will test the hypothesis, based on complementary preliminary studies in rodents, that disease-related cognitive deficits in people with schizophrenia are preferentially susceptible to (further) elevations in KYNA levels.

The investigators hypothesize that tryptophan-induced elevations in brain KYNA levels will: 1) acutely impair performance on measures of verbal and visual memory, attention, working memory, and processing speed in people with schizophrenia; 2) alter dorsolateral-hippocampal activation and connectivity, which underlies the performance of the relational memory task; and 3) decrease mPFC MRS measures of glutamate, consistent with preclinical microdialysis data. In an exploratory framework, the investigators hypothesize that increased brain KYNA levels alter default network activation and connectivity, an effect which may be mediated by the action of KYNA on α7 nicotinic and/or NMDA receptors. The investigators will also investigate the extent to which cytokine and HPA axis peripheral measures are related to the effect of tryptophan-induced elevated KYNA levels on cognitive performance and fMRI and MRS measures. Comparisons with results from healthy controls will determine if participants with schizophrenia have an aberrant or exaggerated response to increased KYNA levels.

Funding Information:

Funded by the National Institute of Mental Health (NIMH)

Grant Number- 1P50MH103222-01

Principal Investigator- Robert Schwarcz, PhD

Project Title- Kynurenic Acid and Cognitive Abnormalities in Schizophrenia

Program Officer Full Name- Steven Zalcamn

External Org# Name- University of Maryland, Baltimore

Recruitment & Eligibility

Status: COMPLETED

Sex: All

Target Recruitment: 93

Inclusion Criteria

Not provided

Exclusion Criteria

DSM-IV-TR/DSM-5 substance abuse in the last month or substance dependence in the last 6 months (documented by SCID)
Calgary Depression Scale total score ≥ 10 at baseline
Current smoker (expired CO ≥ 10 ppm)
Current use of nicotine replacement therapy or other nicotine products
Pregnancy or breast feeding
Post-menopausal women will not be included due to changes in the HPA axis expression and hormonal effects on cognition. In women over the age of 45, menopausal status will be evaluated clinically
Excessive self-reported daily caffeine intake, defined as intake exceeding 1000 mg or the equivalent of 8 cups of coffee
Active disorders that have been reported to affect tryptophan metabolism or interfere with absorption will be excluded (Acute Intermittent Porphyria, Celiac Disease, Crohn's Disease, Irritable Bowel Syndrome
History of an organic brain disorder; mental retardation; or a medical condition, whose pathology or treatment could alter cognition
Claustrophobia
Metal in body that will interfere with MR imaging
Treatment with monoamine oxidase inhibitors, migraine headache medications (triptans) and dextromethorphan

Study & Design

Study Type: INTERVENTIONAL

Study Design: CROSSOVER

Arm && Interventions

Group	Intervention	Description
Healthy Controls	Placebo	All participants will receive both 6gm of tryptophan at least two weeks apart at time zero of 7 hour visits 2 and 3, and will also receive Placebo will be a liquid drink without tryptophan. 6mg at least two weeks apart at time zero of the 7 hour visits 2 and 3. The order in which participants receive either placebo or tryptophan will be randomized (ie. placebo first study visit day tryptophan on second study day, or tryptophan on first study day and placebo on second study day)
Schizophrenia Related Disorders	Placebo	All participants will receive both 6gm of tryptophan at least two weeks apart at time zero of 7 hour visits 2 and 3, and will also receive Placebo will be a liquid drink without tryptophan. 6mg at least two weeks apart at time zero of the 7 hour visits 2 and 3. The order in which participants receive either placebo or tryptophan will be randomized (ie. placebo first study visit day tryptophan on second study day, or tryptophan on first study day and placebo on second study day)
Schizophrenia Related Disorders	Tryptophan	All participants will receive both 6gm of tryptophan at least two weeks apart at time zero of 7 hour visits 2 and 3, and will also receive Placebo will be a liquid drink without tryptophan. 6mg at least two weeks apart at time zero of the 7 hour visits 2 and 3. The order in which participants receive either placebo or tryptophan will be randomized (ie. placebo first study visit day tryptophan on second study day, or tryptophan on first study day and placebo on second study day)
Healthy Controls	Tryptophan	All participants will receive both 6gm of tryptophan at least two weeks apart at time zero of 7 hour visits 2 and 3, and will also receive Placebo will be a liquid drink without tryptophan. 6mg at least two weeks apart at time zero of the 7 hour visits 2 and 3. The order in which participants receive either placebo or tryptophan will be randomized (ie. placebo first study visit day tryptophan on second study day, or tryptophan on first study day and placebo on second study day)

Primary Outcome Measures

Name	Time	Method
Change in Verbal Memory Scores From Baseline to 4 Hours Post-Treatment	The order in which participants received either the tryptophan or placebo was randomized. The HVLT was administered 90 minutes prior to treatment and 4 hours post treatment. There were at least two weeks between the challenge days.	The following assessment was used to assess the outcome measure: the Hopkins Verbal Learning Test-Revised (HVLT-R). HVLT total scores range from 0 to 36. In order to conduct group comparisons, the HVLT raw total scores are converted to a t-score (range: -10 to 80). The mean t-scores for each condition are below (see outcome measure data table). Higher scores represent better performance. Participants performed the same task before pre- and post-treatment with Tryptophan and again with placebo (2 weeks between conditions). Change in scores pre- and post-treatment were compared between the Tryptophan and placebo conditions.

Secondary Outcome Measures