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I/R injury occurs during stroke and TBI. It represents a complex pathological event including several processes that can lead to cell membrane disruption, cellular dysfunction and death. The reintroduction of blood flow after the ischemic event may cause detrimental injury to the brain beyond the harm caused by ischemia itself and, therefore, represents a clinical challenge. This so-called I/R injury damages cells in a variety of ways including poration of cell membranes. Hence, methods to improve the endogenous membrane resealing capacity are crucial to prevent neuronal injury.
In the present work, treatment during reoxygenation with the probably most studied CCMS, P188, was investigated in an in-vitro simulation of stroke and TBI in primary isolated cortical mouse neurons. P188 offers a unique hydrophilic/lipophilic character that has been reported to protect different cells and tissues in various experimental settings against I/R and mechanical injury by sealing membranes. The aim of this study was to establish an in-vitro stroke and TBI model and further investigate if P188 directly interacts with neurons after compression and H/R (simulated I/R) injury, when administered at the start of reoxygenation.
The outcome of this treatment was evaluated in regard to cell number/viability, mitochondrial viability, membrane damage by LDH release and FM1-43 incorporation as well as activation of apoptosis by Caspase 3. It could be demonstrated that 5 hours hypoxia ± compression with 2 hours reoxygenation appear to be a suitable model for testing novel treatments. Compared to normoxic cells not exposed to compression, cell number and mitochondrial viability decreased, whereas membrane injury by LDH per total/FM1-43 dye incorporation and Caspase 3 activity increased in cells exposed to hypoxic conditions ± compression followed by reoxygenation.
However, it could not be shown that P188 is capable to protect isolated neurons from H/R and/or compression injury when administered purely as a postconditioning agent. It therefore seems likely that P188 does not directly affect isolated neurons. Yet, it may be able to provide neuronal protection in a different experimental setting.
In conclusion, this work contributes a new model of simulated stroke and TBI in-vitro. In addition, further knowledge about the impact of P188 on injured neurons can be gained. The extent to which the in-vitro results can be transferred to in-vivo mechanisms is yet unclear and offers opportunities for further investigations.