Predictions and experimental tests of a new biophysical model of the mammalian respiratory oscillator.

Previously our computational modeling studies (Phillips et al., 2019) proposed that neuronal persistent sodium current (I(NaP)) and calcium-activated non-selective cation current (I(CAN)) are key biophysical factors that, respectively, generate inspiratory rhythm and burst pattern in the mammalian preBötzinger complex (preBötC) respiratory oscillator isolated in vitro. Here, we experimentally tested and confirmed three predictions of the model from new simulations concerning the roles of I(NaP) and I(CAN): (1) I(NaP) and I(CAN) blockade have opposite effects on the relationship between network excitability and preBötC rhythmic activity; (2) I(NaP) is essential for preBötC rhythmogenesis; and (3) I(CAN) is essential for generating the amplitude of rhythmic output but not rhythm generation. These predictions were confirmed via optogenetic manipulations of preBötC network excitability during graded I(NaP) or I(CAN) blockade by pharmacological manipulations in slices in vitro containing the rhythmically active preBötC from the medulla oblongata of neonatal mice. Our results support and advance the hypothesis that I(NaP) and I(CAN) mechanistically underlie rhythm and inspiratory burst pattern generation, respectively, in the isolated preBötC.