J C Hancox1, J S Mitcheson. 1. Department of Physiology, School of Medical Science, University of Bristol, United Kingdom. jules.hancox@bristol.ac.uk
Abstract
OBJECTIVE: To review findings from the authors' laboratory in studies of electrophysiological properties of single rod- and spindle-shaped myocytes from rabbit atrioventricular node (AVN). DESIGN: Single cells were isolated from the AVN of the rabbit heart with the use of enzymatic and mechanical dispersion. For recording, cells were superfused with a Tyrode's solution at 33 to 37 degrees C, and recordings were made with microelectrodes or patch pipettes under 'current' or voltage' clamp conditions. Results are expressed as mean +/- SEM. RESULTS: AVN cells had a mean membrane capacitance of 40 +/- 3.9 pF and membrane resistance of 565 +/- 167 M omega (n = 9). Spontaneously active cells exhibited pacemaker activity showing a clear diastolic depolarization and overshooting action potential (AP) with a relatively slow upstroke velocity (7.4 +/- 0.9 V/s, n = 6) and a maximum diastolic potential of -70.5 +/- 2.9 mV. Under voltage clamp conditions, depolarizing pulses from 40 mV elicited L-type calcium currents sensitive to inhibition by nifedipine and managanese or cadmium ions, which could also block spontaneous APs. Depolarizing pulses also activated delayed rectifier potassium current (IK). IK showed rapid activation, and IK 'tails' in AVN cells were blocked by 5 microM E4031, consistent with the rapidly activating subtype of IK (IKr). IK was similar in AVN and ventricular myocytes, except for the time-course of deactivation, which was faster in AVN cells. In 80% to 90% of cells, hyperpolarizing voltage steps activated a small time-independent current. Ten per cent to 20% of cells showed the hyperpolarization-activated current (I(f)), but I(f) amplitude was only significant at potentials more negative than the pacemaker potential. AVN cells showed an apparent absence of inwardly rectifying potassium current. CONCLUSIONS: The high membrane resistance of AVN cells suggests that only small changes in ionic currents could significantly affect membrane potential. L-type calcium current is important in generating the AP upstroke, and IKr may play a role in both AP repolarization and diastolic depolarization. The ionic basis underlying spontaneous activity is not yet clear, but in some cells I(f) is not required because cells without I(f) can generate spontaneous APs.
OBJECTIVE: To review findings from the authors' laboratory in studies of electrophysiological properties of single rod- and spindle-shaped myocytes from rabbit atrioventricular node (AVN). DESIGN: Single cells were isolated from the AVN of the rabbit heart with the use of enzymatic and mechanical dispersion. For recording, cells were superfused with a Tyrode's solution at 33 to 37 degrees C, and recordings were made with microelectrodes or patch pipettes under 'current' or voltage' clamp conditions. Results are expressed as mean +/- SEM. RESULTS: AVN cells had a mean membrane capacitance of 40 +/- 3.9 pF and membrane resistance of 565 +/- 167 M omega (n = 9). Spontaneously active cells exhibited pacemaker activity showing a clear diastolic depolarization and overshooting action potential (AP) with a relatively slow upstroke velocity (7.4 +/- 0.9 V/s, n = 6) and a maximum diastolic potential of -70.5 +/- 2.9 mV. Under voltage clamp conditions, depolarizing pulses from 40 mV elicited L-typecalcium currents sensitive to inhibition by nifedipine and managanese or cadmium ions, which could also block spontaneous APs. Depolarizing pulses also activated delayed rectifier potassium current (IK). IK showed rapid activation, and IK 'tails' in AVN cells were blocked by 5 microM E4031, consistent with the rapidly activating subtype of IK (IKr). IK was similar in AVN and ventricular myocytes, except for the time-course of deactivation, which was faster in AVN cells. In 80% to 90% of cells, hyperpolarizing voltage steps activated a small time-independent current. Ten per cent to 20% of cells showed the hyperpolarization-activated current (I(f)), but I(f) amplitude was only significant at potentials more negative than the pacemaker potential. AVN cells showed an apparent absence of inwardly rectifying potassium current. CONCLUSIONS: The high membrane resistance of AVN cells suggests that only small changes in ionic currents could significantly affect membrane potential. L-typecalcium current is important in generating the AP upstroke, and IKr may play a role in both AP repolarization and diastolic depolarization. The ionic basis underlying spontaneous activity is not yet clear, but in some cells I(f) is not required because cells without I(f) can generate spontaneous APs.
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