Abstract

Introduction: Altered tissue mechanics in acute regional ischemia contribute to arrhythmias by a mechano-sensitive, Ca 2+ -dependent mechanism. This is facilitated by uncoupling of voltage-Ca 2+ dynamics, creating a vulnerable period (VP) in late repolarisation for stretch-induced arrhythmias (‘mechano-arrhythmogenicity’). However, cellular mechanisms driving mechano-arrhythmogenicity in acute ischemia are unknown. Objective: Define cellular mechanisms of mechano-arrhythmogenicity in the VP during acute ischemia in rabbit ventricular myocytes. Methods: Rabbit (♀, NZW) LV myocytes were transiently stretched (8-16% change in sarcomere length, 100 ms) during diastole or the VP in normal Tyrode (NT) or simulated ischemia (SI) solution (hyperkalemia, acidosis, metabolic inhibition). Drugs were used to buffer Ca 2+ (BAPTA), stabilise RyR (dantrolene), block mechano-sensitive TRPA1 channels (HC-030031), or block (DPI) or increase (bi-product of di-4-ANBDQPQ excitation) ROS production. Voltage-Ca 2+ was simultaneously monitored with fluorescent dyes (di-4-ANBDQPQ, Fluo-5F) and a single camera-optical splitter system. Results: SI shortened AP duration (APD NT =384 vs APD SI =219ms; p <0.0001) more than Ca 2+ transient duration (CaTD NT =424 vs CaTD SI =357 ms; p <0.0001) and increased the length of the VP (=CaTD-APD; VP NT =54 vs VP SI =146ms; n =50 cells for N NT =6 and N SI =14 rabbits ; p <0.0001). Mechano-arrhythmogenicity (single ectopy and complex sustained activity) was increased in SI compared to NT, but only for stretch in the VP (7 vs 1% of stretches; n =50, N =6 each ; p <0.005), and arrhythmias in the VP were proportionally more complex than those that occurred with stretch in diastole (100 vs 69%; n =50, N =6; p <0.05). Arrhythmia incidence in the VP during SI was reduced by BAPTA (2% of stretches; p <0.05), HC-030031 (1%; p <0.005), and DPI (2%; p <0.05), while dantrolene had no effect ( n =50, N =6 each). Fluorescence imaging during SI further increased mechano-arrhythmogenicity in both the VP and diastole (29 and 14%; n =42, N =4; p <0.05). Conclusions: Acute ischemia enhances cellular mechano-arrhythmogenicity specifically in the VP through a mechanism involving Ca 2+ , ROS, and TRPA1, suggesting potential targets for anti-arrhythmic therapy.

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