Endothelial dysfunction induced by hydroxyl radicals – the hidden face of biodegradable Fe-based materials for coronary stents
(2020) Materials science & engineering. C, Materials for biological applications — Vol. 112, p. 110938 [1-11] (2020)
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- Authors
Scarcello, Eleonora 
Lobysheva, Irina Lison, Dominique
- Abstract
- Fe-based materials are currently considered for manufacturing biodegradable coronary stents. Here we show that Fe has a strong potential to generate hydroxyl radicals (HO·) during corrosion. This HO· generation, but not corrosion, can be inhibited by catalase. Oxidative stress was observed (increased HO-1 expression) in aortic rings after direct exposure to Fe, but not in the presence of catalase or after indirect exposure. This oxidative stress response induced an uncoupling of eNOS in, and a consequent reduced NO production by endothelial cells exposed to Fe. In isolated rat aortic rings NO production was also reduced by HO· generated during Fe corrosion, as indicated by the protective role of catalase. Finally, all these mechanisms contributed to impaired endothelium- dependent relaxation in aortic rings caused by HO· generated during the direct contact with Fe. This deleterious impact of Fe corrosion on the endothelial function should be integrated when considering the use of biodegradable Fe-based alloys for vascular implants.
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Citations
Scarcello, E., Lobysheva, I., Bouzin, C., Jacques, P., Lison, D., & Dessy, C. (2020). Endothelial dysfunction induced by hydroxyl radicals – the hidden face of biodegradable Fe-based materials for coronary stents. Materials science & engineering. C, Materials for biological applications, 112, 110938 [1-11]. https://doi.org/10.1016/j.msec.2020.110938 (Original work published 2020)