Spinal cord injuries can abolish both motor and sensory function throughout the body.Spontaneous recovery after injury is limited and can vary substantially between individuals.Despite an abundance of therapeutic approaches that have shown promise in preclinical models, there is currently a lack of effective treatment strategies that have been translated to restore function after SCI in the human population. We hypothesized that sex and genetic background of injured individuals could impact how they respond to treatment strategies, presenting a barrier to translating therapies that are not tailored to the individual. One gene of particular interest is APOE, which has been extensively studied in the brain due to its allele-specific influences on synaptic plasticity, metabolism, inflammation, and neurodegeneration. Despite its prominence as a therapeutic target in brain injury and disease, little is known about how it influences neural plasticity and repair processes in the spinal cord. Utilizing humanized mice, we examined how the 3 and 4 alleles of APOE influence the efficacy of therapeutic intermittent hypoxia (IH) in inducing spinally-mediated plasticity after cervical SCI. IH is sufficient to enhance plasticity and restore motor function after experimental SCI in genetically similar rodent populations, but its effect in human subjects is more variable (Golder, 2005;Hayes et al., 2014). Our results demonstrate that both sex and APOE genotype determine the extent of respiratory motor plasticity that is elicited by IH, highlighting the importance of considering these clinically relevant variables when translating therapeutic approaches for the SCI community. 4 Significance StatementThere is currently a critical need for therapeutics that restore motor and sensory function effectively after cervical spinal cord injury. Although many therapeutic approaches, including intermittent hypoxia, are being investigated for their potential to enhance spinal plasticity and improve motor outcomes after SCI, it is unknown whether the efficacy of these treatment strategies is influenced by individuals' genetic background. Here we show that APOE genotype and sex both play a role in determining the propensity for motor plasticity in humanized mice after cervical SCI. These results indicate that sex and genetic background dictate how individuals respond to therapeutic approaches, thereby emphasizing the importance of developing personalized medicine for the diverse SCI population.
B cells, also known as B lymphocytes or lymphoid lineage cells, are a historically understudied cell population with regard to brain-related injuries and diseases. However, an increasing number of publications have begun to elucidate the different phenotypes and roles B cells can undertake during central nervous system (CNS) pathology, including following ischemic and hemorrhagic stroke. B cell phenotype is intrinsically linked to function following stroke, as they may be beneficial or detrimental depending on the subset, timing, and microenvironment. Factors such as age, sex, and presence of co-morbidity also influence the behavior of post-stroke B cells. The following review will briefly describe B cells from origination to senescence, explore B cell function by integrating decades of stroke research, differentiate between the known B cell subtypes and their respective activity, discuss some of the physiological influences on B cells as well as the influence of B cells on certain physiological functions, and highlight the differences between B cells in healthy and disease states with particular emphasis in the context of ischemic stroke.
Following an experimental C2 spinal cord hemisection in rats, there is a gradual spontaneous recovery of breathing function that can take place over time. Additionally, interventions at later time points are more effective after injury. What is not known is the mechanism mediating this observation. To begin to answer this question, we investigated the role of the gut microbiome after injury. Recent studies have emerged suggesting that the gut microbiome has critical implications on the proper functioning of the central nervous system (CNS). Indeed, gut dysbiosis, or a microbiome imbalance, can occur which can negatively impact the CNS. Neurotrauma, including spinal cord injury (SCI), can lead to acute gut dysbiosis and impaired recovery. It is our hypothesis that the composition of the gut microbiome is dynamic after injury with dysbiosis improving over time from an acute post‐SCI state. In this study, we build upon these initial studies and investigate the impact of cervical SCI on the gut microbiome over time and up to chronic timepoints. In order to test our hypothesis, we collected fecal samples before and up to 12 weeks after a C2 hemisection in adult female rats, in order to assess microbiome composition at various timepoints post injury. Preliminary results suggest that following cervical SCI, gut dysbiosis occurs immediately after injury but recovers by two months post injury. Future studies will classify bacterial identities and assess the impact of the post‐injury gut microbiome on recovery of respiratory motor function and plasticity.
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