Hippocampal volume in healthy controls given 3-day stress doses of hydrocortisone.

In animal models, corticosterone elevations are associated with hippocampal changes that can be prevented with phenytoin. In humans, Cushing's syndrome and long-term prescription corticosteroid use are associated with a reduction in the hippocampal volume. However, little is known about the effects of short-term corticosteroid administration on the hippocampus. The current report examines changes in the hippocampal volume during a brief hydrocortisone exposure and whether volumetric changes can be blocked by phenytoin. A randomized, double-blind, placebo-controlled, within-subject crossover study was conducted in healthy adults (n=17). Participants received hydrocortisone (160 mg/day)/placebo, phenytoin/placebo, both medications together, or placebo/placebo, with 21-day washouts between the conditions. Structural MRI scans and cortisol levels were obtained following each medication condition. No significant difference in the total brain volume was observed with hydrocortisone. However, hydrocortisone was associated with a significant 1.69% reduction in the total hippocampal volume compared with placebo. Phenytoin blocked the volume reduction associated with hydrocortisone. Reduction in hippocampal volume correlated with the change in cortisol levels (r=-0.58, P=0.03). To our knowledge, this is the first report of structural hippocampal changes with brief corticosteroid exposure. The correlation between the change in hippocampal volume and cortisol level suggests that the volume changes are related to cortisol elevation. Although the findings from this pilot study need replication, they suggest that the reductions in hippocampal volume occur even during brief exposure to corticosteroids, and that hippocampal changes can, as in animal models, be blocked by phenytoin. The results may have implications both for understanding the response of the hippocampus to stress as well as for patients receiving prescription corticosteroids.

Cognitive changes associated with ADT: a review of the literature.

The use of androgen deprivation therapy (ADT) has increased since the early 1990s after early detection efforts and greater use of the prostate-specific antigen (PSA) test. Although ADT is associated with favorable clinical outcomes, ADT has been associated with an increased risk for cardiovascular disease, increased serum cholesterol, triglycerides, insulin resistance, body mass index and fat body mass. Here we review findings from 11 clinical studies examining the effects of ADT on cognition as measured by standardized tests in cognitive domains such as verbal and spatial memory. Most of these studies have important limitations, including small sample sizes, suboptimal control groups and baseline group differences in confounding factors. Despite these limitations, the best designed studies, those comparing patients on ADT to healthy controls, generally suggest that spatial memory might be especially sensitive to the effects of ADT. Critically, to date there is only one study involving random assignment of ADT versus close clinical observation. That study revealed a decrease in verbal memory with ADT, but was limited in sample size and did not include a measure of spatial memory. A recent observational study revealed no substantial evidence of cognitive impairment with ADT, even in the domain of verbal memory. Like the randomized study, however, this large observational study lacked a measure of spatial memory. Overall, the studies with the best controls suggest a potential negative impact of ADT on spatial memory, and perhaps verbal memory, and a need for continued investigation of the impact of ADT on cognition, particularly in these two cognitive domains.

Sex-specific associations between peripheral oxytocin and emotion perception in schizophrenia.

BACKGROUND: We previously reported that higher levels of peripheral oxytocin are associated with lower levels of positive, general, and overall symptoms in women but not in men with schizophrenia. Here we investigate the influence of sex, sex steroid hormone fluctuations, and peripheral oxytocin levels on emotional processing in men and women with schizophrenia. METHOD: Twenty-two women with schizophrenia and 31 female controls completed the Penn Emotion Acuity Test (PEAT), a facial emotion recognition and perception task, during two menstrual cycle phases: 1) early follicular (Days 2-4; low estrogen/progesterone) and 2) midluteal (Days 20-22; high estrogen/progesterone). Twenty-six males with schizophrenia and 26 male controls completed testing at comparable intervals. We obtained plasma hormone assays of estrogen, progesterone, testosterone, and oxytocin. RESULTS: No sex differences were noted on the PEAT. Plasma oxytocin levels did not fluctuate across phases of the menstrual cycle. However, female patients and controls more accurately identified facial emotions during the early follicular versus midluteal phase (p<0.05). Higher oxytocin levels related to perceiving faces as happier in both female patients (r=-0.46, p=0.04) and controls (r=-0.40, p=0.04) but not in men. CONCLUSION: Like healthy women, women with schizophrenia demonstrate menstrual-cycle dependent fluctuations in recognizing emotional cues. Like healthy women, female patients with higher levels of oxytocin perceived faces as happier. Future studies need to address whether this sex-specific relationship is associated with trust and other positive emotions, and whether exogenous oxytocin might enhance mood states and social interaction in female or all schizophrenia patients.