Dynamic clamp study of Ih modulation of burst firing and delta oscillations in thalamocortical neurons in vitro.

The dynamic clamp technique was used in thalamocortical neurons of the rat and cat dorsal lateral geniculate nucleus in vitro to investigate the effects of the hyperpolarization-activated cation current, Ih, and of its neuromodulation on burst firing and delta oscillations. Specific block of endogenous Ih using 4-(N-ethyl-N-phenylamino)-1,2-dimethyl-6-(methylamino)pyridinium chloride (ZD7288) (300 microM) abolished the depolarizing "sag" response to negative current steps, markedly increased the latency and shortened the duration of the low-threshold Ca2+ potentials, and decreased the number of action potentials in the burst evoked by the low-threshold Ca2+ potential. Subsequent introduction of artificial Ih using the dynamic clamp re-instated the "sag" and all the original properties of the low-threshold Ca2+ potential. In the absence of ZD7288, introduction of artificial outward Ih with the intention of abolishing endogenous Ih removed the depolarizing "sag" and produced similar effects on the low-threshold Ca2+ potentials as those observed during the pharmacological block of Ih. Application of ZD7288 to thalamocortical neurons displaying delta oscillations led to a reduction in the voltage range of their existence or to a complete cessation of this behaviour. A subsequent introduction of artificial Ih re-enabled the generation of delta oscillations. In the presence of ZD7288, physiologically relevant positive shifts in the voltage-dependence of artificial Ih increased the amplitude and duration of the low-threshold Ca2+ potential and increased the likelihood of delta oscillations while negative shifts had opposite effects. These results highlight the important difference between the dependence of burst firing and oscillations on membrane potential and their dependence on the properties of Ih, and demonstrate that the modulation by Ih of low-threshold Ca2+ potentials and burst firing in thalamocortical neurons, as well as the ability of these neurons to generate delta oscillations, is more elaborate than previously described.