Branched-Chain Amino Acids Are Neuroprotective Against Traumatic Brain Injury and Enhance Rate of Recovery: Prophylactic Role for Contact Sports and Emergent Use.

Branched-chain amino acids (BCAAs) are known to be neurorestorative after traumatic brain injury (TBI). Despite clinically significant improvements in severe TBI patients given BCAAs after TBI, the approach is largely an unrecognized option. Further, TBI continues to be the most common cause of morbidity and mortality in adolescents and adults. To date, no study has evaluated whether BCAAs can be preventive or neuroprotective if taken before a TBI. We hypothesized that if BCAAs were elevated in the circulation before TBI, the brain would readily access the BCAAs and the severity of injury would be reduced. Before TBI induction with a standard weight-drop method, 50 adult mice were randomized into groups that were shams, untreated, and pre-treated, post-treated, or pre- + post-treated with BCAAs. Pre-treated mice received BCAAs through supplemented water and were dosed by oral gavage 45 min before TBI induction. All mice underwent beam walking to assess motor recovery, and the Morris water maze assessed cognitive function post-injury. On post-injury day 14, brains were harvested to assess levels of astrocytes and microglia with glial fibrillary acidic protein (GFAP) and ionized calcium-binding adapter molecule 1 (IBA-1) immunohistochemistry, respectively. Pre-treated and pre- +post-treated mice exhibited significantly better motor recovery and cognitive function than the other groups. The pre- + post-treated group had the best overall memory performance, whereas the pre-treated and post-treated groups only had limited improvements in memory compared to untreated animals. Pre- + post-treated brains had levels of GFAP that were similar to the sham group, whereas the pre-only and post-only groups showed increases. Although trends existed, no meaningful changes in IBA-1 were detected. This is the first study, animal or human, to demonstrate that BCAA are neuroprotective and substantiates their neurorestorative benefits after TBI, most likely through the important roles of BCAAs to glutamate homeostasis.

Ethanol has concentration-dependent effects on hypothalamic POMC neuronal excitability.

Alcohol abuse is a worldwide public health concern, yet the precise molecular targets of alcohol in the brain are still not fully understood. Alcohol may promote its euphoric and motivational effects, in part, by activating the endogenous opioid system. One particular component of this system consists of pro-opiomelanocortin (POMC) -producing neurons in the arcuate nucleus (ArcN) of the hypothalamus, which project to reward-related brain areas. To identify the physiological effects of ethanol on ArcN POMC neurons, we utilized whole cell patch-clamp recordings and bath application of ethanol (5-40 mM) to identify alterations in spontaneous baseline activity, rheobase, spiking characteristics, or intrinsic neuronal properties. We found that 10 mM ethanol increased the number of depolarization-induced spikes in the majority of recorded cells, whereas higher concentrations of ethanol (20-40 mM) decreased the number of spikes. Interestingly, we found that basal firing rates of ArcN POMC neurons may predict physiological responding to ethanol. Rheobase and spontaneous activity, measured by spontaneous excitatory post-synaptic potentials (EPSPs) at rest, were unchanged after exposure to ethanol, regardless of concentration. These results suggest that ethanol has concentration-dependent modulatory effects on ArcN POMC neuronal activity, which may be relevant to treatments for alcohol use disorders that target endogenous opioid systems.