Carbon Monoxide Effects on Electrophysiological Mechanisms of Ventricular Arrhythmogenesis

Increased dissolved carbon monoxide decreases $I_{Ca,L} I_{KI}$ and $I_{Kr}$ and increases late $I_{Na}$ currents in rat and guinea pig patch-clamped isolated ventricular myocytes. Action potentials are prolonged. These effects are reproduced by scaling the currents in the Gattoni et al., 2016 (rat) and Luo and Rudy, 1994 (guinea-pig) cell models. Using the same scaling of currents in the O‘Hara-Rudy (2011) models the endo-, mid-myo- and epi-cardial APD90 is prolonged. CO abolishes alternans in endo-, and induces alternans in mid-myo -cardial cell models at cycle lengths < 280ms. In the homogenous human ventricular tissue models these CO effects decrease epi-, endocardial conduction velocities from 0.4 to 0.32m/s, and increase the widths of the vulnerable windows by +9%, +8%. In the ventricular wall model (a third each of endo-, mid-myo- and epicardial) CO increased transmural propagation times from 44 to 55 ms and maximal difference in propagating APD from 68 to 73 ms. The computed effects of CO on human ventricular tissue are pro-arrhythmogenic.