Omega 3 Fatty Acid Trial

This study is being done to detect the metabolic changes that Omega 3 fatty acid treatment has on the brain and to find out whether magnetic resonance spectroscopy (MRS) scan can detect metabolic differences between bipolar patients and healthy control participants.

Bipolar disorder (BP) is a chronic, complex and highly heterogeneous disease that has been unrecognized or misdiagnosed in prepubertal children and adolescents. It is one of the most disabling forms of childhood psychopathology and carries a striking human and economic cost. A high percentage of children and adolescents with BP respond very poorly to existing treatments. There is a significant need for studies identifying the developmentally sensitive targets for novel therapeutic compounds for this truly disabling illness. A growing range of novel therapeutic options for the treatment of BP are under investigation. Highly unsaturated fatty acids of the omega-3 fatty acids are among the novel therapeutic compounds considered in the treatment of adult patients with BP. However, the mood-stabilizing efficacy and the neurometabolic effects of this naturally occurring dietary components have not been examined in pediatric patients with BP. The objective of this study is to identify magnetic resonance spectroscopic characteristics of adolescents with BP before and during a double-blind, placebo controlled combined omega-3 fatty and omega -6 fatty acid trial. We will compare the spectroscopic findings of the BP group with individually matched healthy comparison subjects before and after the omega-3/omega-6 fatty acid treatment. We will identify a well-described cohort of adolescents (age: 12-18) with BP without catatonic features, psychotic features, or other psychiatric comorbidity. Comorbidity with ADHD will be allowed since this might be a separate phenotype for pediatric BP. We will analyze the differences between BP subjects with comorbid ADHD, and BP subjects without ADHD. We will evaluate subjects with a novel magnetic resonance imaging technique, Magnetic Resonance Spectroscopic Imaging (MRSI). We will use a high-field 3T magnet to perform the MRSI acquisition, and apply a tissue volume correction technique to compare absolute metabolite concentrations rather than metabolite ratios. Previous studies found pronounced abnormalities in the frontal lobes, cingulate cortex, thalamus and basal ganglia of patients with BP. Thus, the region of interest in this study will include these anatomical areas with special emphasis given to prefrontal cortex and anterior cingulate cortex. To our knowledge, this will be the first study examining omega-3 fatty acid induced changes in the developing brain in vivo. The long-term goal of our research group is to identify the developmentally sensitive, trait and state related magnetic resonance spectroscopic markers of pediatric BP. The preliminary data obtained from this application will be used to design a larger scale, follow-up study to examine whether alterations in brain metabolite measures are clinical state or trait markers and to determine the developmental variability in the patterns of metabolic abnormalities. Such knowledge will provide powerful insight into developmentally sensitive targeted pharmacological interventions. Studying bipolar disorder early in its course will be important to minimize potentially confounding factors, such as the effects of long-term medication use and neurodegeneration related to chronic illness course and substance abuse. Based on the existing literature, we hypothesized that increased myoinositol levels will be detected in the regions of interests of adolescents with BP in comparison to healthy controls.