Cell-attached patch clamp measurement of macroscopic rapid inward sodium current in cultured heart cell reaggregates

Abstract

A megaohm seal, cell-attached patch clamp technique utilizing plastic suction pipettes for measuring macroscopic rapid inward sodium current (INa) was applied to cell membrane patches 30 to 100 micron2 in area at the periphery of reaggregates of myocardial cells from newborn rats cultured for 3 to 7 days. The reaggregates were composed of about 20 to several thousand of electrically well-coupled cells, the latter forming spheroidal reaggregates with a diameter of maximally 300 microns. This system was shown to guarantee satisfactory voltage-clamp control during ionic current measurements. The time and voltage dependence of the INa recorded during periods of up to 90 min was similar to that observed in single cardiac cell preparations from adult rats. INa inactivation was described by two time constants (tau h1, and tau h2). For maximal INa tau h1 and tau h2 had values of 1.5 +/- 0.25 ms and 8.7 +/- 3.9 ms (n = 4), respectively. The time course for recovery of INa from inactivation at the reaggregate resting potential exhibited also two time constants (tau re1 = 9.8 +/- 3 ms, tau re2 = 193 +/- 50 ms, n = 5). Estimated current density was about 10 pA/micron2. The concentration of tetrodotoxin needed to reduce maximal INa by 75% was 85 times lower in the reaggregates than it was in freshly isolated heart muscle cells from adult rats. The present system offers a combination of features that should make it well-suited for the study of both short- and long-term effects on the sodium channels in neonatal heart cells: Easy handling of the object, great electric stability, high time and amplitude resolution during ionic current measurements, and viability for at least one week.