Abstract
BackgroundDespite the prevalent use of the ex vivo brain slice preparation in neurophysiology research, a reliable method for judging tissue viability ― and thus suitability of a slice for inclusion in an experiment ― is lacking. The utility of indirect electrophysiological measures of tissue health is model-specific and needs to be used cautiously. In this study, we verify a more direct test of slice viability, based on tissue oxygen consumption rate. New methodWe hypothesised that the minimum intra-slice partial pressure of oxygen (pO2min) would correlate with tissue oxygen consumption rate, providing an accessible method for reliably assessing tissue viability status. Using mouse brain cortex slices, we measured tissue oxygen consumption rate using a Fick’s law diffusion–consumption model applied to full intra-tissue pO2 profiles and compared this to pO2min and 2,3,5-triphenol tetrazolium chloride (TTC) viability staining. ResultsTissue pO2min correlated strongly with oxygen consumption rate in both neurophysiological active and quiescent tissue (in “no-magnesium” and “normal” artificial cerebrospinal fluid, respectively) (R2 =49.7% and 42.1%, respectively). Both correlated with TTC viability stain. Oxygen consumption rate was positively related to the frequency of seizure-like event activity in no-magnesium artificial cerebrospinal fluid (R2 = 44.8%). Comparison with existing methodsWhile measurement of tissue oxygen levels and oxygen consumption is not new, intra-tissue pO2min is a novel approach to assess brain slice viability. ConclusionThe results confirm that tissue oxygen minimum pO2min is a robust metric for estimating tissue viability status — the lower the pO2min, the healthier the tissue.
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