Mutual entrainment and electrical coupling as mechanisms for synchronous firing of rabbit sino-atrial pace-maker cells.

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Mutual entrainment and electrical coupling as mechanisms for synchronous firing of rabbit sino-atrial pace-maker cells.

J Jalife

The mechanisms of synchronous firing of cardiac pace-makerswere studied using thin (0.3-0.5 mm) rabbit sino-atrial (s.a.)node strips placed in a three-compartment tissue bath. Superfusionof the central segment (1 mm in length) with ion-free sucrosesolution permitted the electrical insulation of the externalsegments and the development of two independent pace-maker 'centres':one fast (F); one slow (S). An external shunt pathway was usedto modulate the degree of coupling between F and S. Superfusionof the central segment with Tyrode solution containing heptanol(3.5 mM) instead of sucrose induced progressive decrease inthe amplitude of responses in this segment and led to progressiveloss of F:S synchronization. Eventually the two pace-makersbecame totally independent from each other. These changes werereversible upon wash-out of heptanol. When a pace-maker centrewas within the range of influence of local circuit (i.e. electronic)currents from the pace-maker in the opposite side of the sucrose(or heptanol) compartment, its period was prolonged or abbreviated,depending on phase and frequency relations. Dynamic F:S interactionsat various degrees of electrical coupling resulted in mutualentrainment with both pace-makers beating at simple harmonic(i.e. 1:1, 2:1, 1:2, etc.) or more complex (3:2, 5:4, etc.)ratios that depended on the degree of coupling and the intrinsicperiods of the individual pace-maker centres. The patterns ofsynchronization could be predicted by the phasic sensitivityof each pace-maker to brief electrotonic inputs. The resultssuggest that when two individual pace-maker cells are connectedthrough low resistance junctions, the period resulting fromtheir mutual entrainment should be a function of their respectiveintrinsic frequencies, their phase relations and the degreeof electrical coupling. The data further suggest that the heartbeat is initiated by a 'democratic' type of synchronous firingof cells in the s.a. node, with each pace-maker cell contributingto an aggregate signal and involving mutual entrainment betweencells.

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