Common antidepressant may change brain differently in depressed and non-depressed people
News Sep 05, 2015
A commonly prescribed antidepressant may alter brain structures in depressed and non-depressed individuals in very different ways, according to new research at Wake Forest Baptist Medical Center.
The study -- conducted in nonhuman primates with brain structures and functions similar to those of humans -- found that the antidepressant sertraline, a selective serotonin reuptake inhibitor (SSRI) marketed as Zoloft, significantly increased the volume of one brain region in depressed subjects but decreased the volume of two brain areas in non-depressed subjects.
"These observations are important for human health because Zoloft is widely prescribed for a number of disorders other than depression," said Carol A. Shively, Ph.D., professor of pathology-comparative medicine at Wake Forest Baptist and lead author of the study, published in the current online issue of the journal Neuropharmacology.
In the study, 41 middle-aged female monkeys were fed a diet formulated to replicate that consumed by many Americans for 18 months, during which time depressive behavior in the animals was recorded. Female monkeys were chosen for this study because depression is nearly twice as common in women as men and the use of antidepressants is most common in women ages 40 to 59.
After the 18-month pre-study phase, the monkeys were divided into two groups balanced for body weight, body mass index and depressive behavior. For the next 18 months, 21 monkeys received sertraline in daily doses comparable to those taken by humans while a group of 20 received a placebo. This treatment regimen is analogous to a human taking an antidepressant for approximately five years.
MRI images taken at the end of the treatment phase revealed that in depressed subjects the drug significantly increased the volume of one region of the brain, the anterior cingulate cortex, while decreasing the volume of this same region and the hippocampus in non-depressed subjects. Both of these areas are highly interconnected with other areas of the brain; are critical in a wide array of functions including memory, learning, spatial navigation, will, motivation and emotion; and are implicated in major depressive disorder.
In humans, Shively said, volume differences in neural structures have been noted in depressed and non-depressed individuals, with the most commonly reported differences being smaller volumes of the cingulate cortex and hippocampus in depressed people. One potential mechanism through which drugs such as Zoloft can be effective as antidepressants is by promoting neuron growth and connectivity in these brain regions.
But SSRIs, including Zoloft, are prescribed for a variety of disorders besides depression, including bulimia, hot flashes, obsessive-compulsive disorder, post-traumatic stress disorder, stroke recovery and sexual dysfunction, and there are no studies of the effects of these drugs on brain volumes in individuals not diagnosed with depression.
"The study's findings regarding the different effects of sertraline on brain-region volumes in depressed versus non-depressed subjects are compelling," Shively said. "But given the number of different disorders for which SSRIs are prescribed, the findings need to be investigated further in patient populations to see if these drugs produce similar effects in humans."
Note: Material may have been edited for length and content. For further information, please contact the cited source.
Shively CA et al. Long term sertraline effects on neural structures in depressed and nondepressed adult female nonhuman primates. Neuropharmacology, Published December 2015. doi: 10.1016/j.neuropharm.2015.06.011
NeuroTrauma Sciences and Henry Ford Health System Announce Agreements for Neurological Injury ResearchNews
Research indicates exosomes have therapeutic potential for improving recovery after stroke, traumatic brain injury.READ MORE
Orexin Neurons are Promising Target for Medications to Treat Binge EatingNews
The researchers studied female rats fed a control diet or a sugary, high-fat diet that causes weight gain and binge eating patterns.READ MORE
Convergence of Synaptic Signals is Mediated by a Protein Critical for Learning and MemoryNews
Researchers show that protein Kinase C is a novel information integrator, keeping tabs on the recent history of neighboring synapses while simultaneously monitoring local synaptic inputREAD MORE