Longitudinal Effects of Mild Traumatic Brain Injury on the Gut Microbiome and Acoustic Startle Response in Male and Female Rats.

Traumatic brain injuries (TBI) frequently occur and can lead to lasting negative cognitive, physical, and mental health outcomes. The biological response to even mild TBIs (mTBI) includes well-characterized inflammatory sequelae that start immediately post-injury, remain for weeks, and can develop into long-term systemic inflammation. Studies have shown that TBI influences multiple physiological systems, including the gastrointestinal tract, through bidirectional communication modulated, in part, by the gut microbiome. Brainstem functioning post-TBI, as measured by acoustic startle sensorimotor processing, might play a role in this feedback loop. The current study investigated pre- to post-TBI (lateral fluid percussion injury model) changes in microbial communities and acoustic startle response in male and female rats. That is, the influence of mTBI on gut microbiome and sensorimotor processing was explored to examine: 1) overall and sex-specific differences in the gut microbiome and taxa in response to mTBI; 2) overall and sex-specific differences in sensorimotor processing following mTBI; and 3) associations between the gut microbiome and sensorimotor processing. Results showed mTBI had a limited effect on microbial diversity overall, and the same was observed in males and females independently. Yet, mTBI was associated with differences in 13 genus-level taxa. Further evaluation highlighted that 11 of the 13 genus-level taxa were sex-specific, with several being known to have short-chain fatty acid-producing capabilities. Alterations in sensorimotor processing were identified following mTBI; however, no sex-specific differences were evident. In addition, no associations were observed between sensorimotor processing and the gut microbiome. This study contributes longitudinal and sex-specific findings to the growing body of research examining the diverse effects of mTBI on the brain and gut microbial communities.