In vitro strain-induced endothelial cell dysfunction determined by DNA synthesis
Rapid re-endothelialization following balloon angioplasty can reduce restenosis by inhibiting smooth muscle cell migration and proliferation. However, formation of a neointima following angioplasty can be inhibited due to endothelial cell dysfunction and denudation. The purpose of this study was to evaluate mechanical tensile stress as a cause of endothelial cell dysfunction. The Flexercell® strain unit was utilized to generate both short-term cyclic and static tensile strain on cultured bovine aortic endothelial cells (BAECs). Before analysis of this loading on BAECs, strain behaviour of the Flexercell® system and DNA assay conditions were optimized. This paper demonstrates that, when compared with unloaded controls, 4-h cyclic loading at 4 per cent elongation and 0.1 Hz, and static loading at 4 per cent elongation cause a 44 and 70 per cent decrease in DNA synthesis respectively. In a companion paper, it is demonstrated that low DNA synthesis levels in mechanically loaded cells can be increased by incubation with Ap4A and/or NO donors.