Evaluating Microglia Dynamics in Blast and Impact-Induced Neurotrauma and Assessing the Role of Hemostatic Nanoparticles in Microglia Activation
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Abstract
Traumatic brain injury (TBI) is a major medical concern that has demonstrated to be particularly challenging to treat because of the disparity amongst injury modes and severities. Increased use of explosive devices during combat has caused blast TBI (bTBI) to become a widespread consequence in military and Veteran populations, and impact-related trauma from contact-related sports or motor vehicle accidents has made mild impact-induced TBIs (concussion) a major health problem. There is a high risk for those who have sustained a TBI to develop behavioral and cognitive disorders following injury, and these symptoms can present as delayed onset, causing diagnosis to be a major feat when planning for treatment and long-term healthcare. Both preclinical and clinical studies report the neuropathological changes following TBI, yet investigating the distinct mechanistic changes in blast and impact trauma that contribute to pathological disparities has yet to be elucidated.
Microglia dynamics play a key role in initiating the inflammatory response after injury, as microglia become activated by undergoing morphological changes that influence their function in the injured brain, and unique signaling pathways influence their functional inflammatory states. While previous literature report on the unique responses of microglia, their mediated-inflammatory responses are still not well defined. This work aimed to investigate the acute and subacute responses of microglia to injury through their diverse activation states following blast and impact trauma. The work herein employed rodent models to investigate these changes, finding that microglia activation was spatially and temporally heterogeneous within and across injury paradigms. Three days following bTBI, activated microglia in the cortex displayed morphologies similar to microglia that are known to increase their interactions with dysfunctional synapses, while dystrophic microglia were prevalent in the hippocampus seven days following injury. Moreover, transhemispheric changes in microglia activation were noted following impact TBI, with stressed/primed microglia responding to immune challenges of the cortex at three days, whereas a unique morphological state that was markedly different from those traditionally reported in CNS injury and disease was present within the hippocampus three- and seven-days following injury. State-of-the-art cell sorting techniques were used for in vivo analysis of microglia, which also exhibited that functional changes of microglia vary between injury paradigms, providing insight into how differences in primary insult may elicit distinct signaling pathways involved in microglia-mediated inflammatory responses. These in vivo studies were then crucial in understanding the malleable responses of microglia to complex injuries such as "blast plus impact" TBI, indicating that phenotypic changes in microglia following this injury are also unique and spatially heterogeneous. To date, therapeutic efforts for TBI are limited due to the lack of understanding the underlying mechanisms that influence TBI pathology. This work also investigated novel therapeutic targets, noting that administration of polyester nanoparticles restored microglia to baseline levels following impact. The fundamental research presented in this study is innovative and advantageous as it can provide essential data into targeted and personalized treatments that can improve long-term healthcare and ultimately, the quality of life for those suffering from a TBI.