Abstract

Oxidative stress has been implicated in pathogenesis of hypoxia and ischemia/reperfusion (I/R) injury. In previous studies, we have shown that the antioxidant CAPE exerted cardioprotection in an isolated rat heart I (30 min)/R (60 min) injury model. In this study, we further evaluated the effects of CAPE on oxidative stress and hypoxia‐induced cell damage. We evaluated the inhibition of absorbance in the phorbol 12‐myristate 13‐acetate (30 nM) induced superoxide production spectrophotometrically in isolated rat neutrophils via reduction of exogenous cytochrome C. We found that CAPE (0.5 μM–40 μM; n=4–13) reduced phorbol 12‐myristate 13‐acetate induced neutrophil superoxide release dose‐dependently from 29±3% to 95±2%. In a rat hind limb I (30 min)/R (60 min) model, blood hydrogen peroxide levels serves as an indicator of blood oxidative stress and was measured in real‐time via a hydrogen peroxide microsensor (100 μm) inserted into both femoral veins (one served as sham, the other as I/R). We found that in the control group, I/R significantly increased blood hydrogen peroxide levels to 2.1±0.8 μM relative to the sham limb at 60 minutes reperfusion when saline was given at the beginning of reperfusion (n=5). By contrast, CAPE when given at reperfusion (40 μM, n=5) significantly reduced blood hydrogen peroxide levels from 30 min reperfusion and throughout the rest of experiment (p<0.05). The relative change was −0.4±0.3 μM between the I/R and sham limbs at 60 minutes reperfusion. In H9C2 rat myoblast cells, cobalt chloride simulated hypoxia and induced cell damage. Tetrazolium, which can differentiate metabolically active and inactive cells/tissues, was used to measure cell damage by measuring absorbance at 450 nm. We found that incubation of cobalt chloride (800 μM, n=8) for 24 hr induced 55±5% cell death. By contrast, pretreatment of CAPE (0.5 μM–10 μM; n=1–3) for 24 hr dose‐dependently improved cell survival up to 30±9% relative to cobalt chloride treatment. In summary, this study suggests that CAPE attenuates oxidative stress from neutrophils and I/R, which may contribute to improvement in cell survival under hypoxia conditions.Support or Funding InformationThis study was supported by Division of Research and Department of Bio‐Medical Sciences at Philadelphia College of Osteopathic Medicine.

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