Phase response curves of subthalamic neurons measured with synaptic input and current injection

Abstract: Farries MA, Wilson CJ. Phase response curves of subthalamic neurons measured with synaptic input and current injection. J Neurophysiol 108: 1822-1837. First published July 11, 2012 doi:10.1152/jn.00053.2012.-Infinitesimal phase response curves (iPRCs) provide a simple description of the response of repetitively firing neurons and may be used to predict responses to any pattern of synaptic input. Their simplicity makes them useful for understanding the dynamics of neurons when certain conditions are met. For e… Show more

“…The equilibrium potentials for the ion species are as follows: E Na ϭ ϩ50 mV, E K ϭ Ϫ90 mV, E Ca ϭ ϩ100 mV, and E leak ϭ Ϫ60 mV. The capacitance C was 100 pF, comparable to the effective cell capacitances estimated from the membrane potential change caused in STN cells by small current pulses used in our companion article (Farries and Wilson 2012; 109 Ϯ 27 pF, range 57-191 pF, n ϭ 66 cells; see below). Both inactivating (spiking) and persistent Na ϩ conductances were modeled with instantaneous activation; that is, their activation states were direct functions of voltage equal to their steady-state activation:…”

“…The methods for slice preparation, perforated-patch recording, and data analysis are described in the companion article (Farries and Wilson 2012).…”

“…In the case of synaptic input, the stimulus current waveform must be inferred from the membrane potential trajectory. The EPSP waveform is isolated by subtracting the average spontaneous voltage trajectory from the trajectory with EPSPs, as described in our companion article (Farries and Wilson 2012). The time derivative of this isolated EPSP voltage trajectory provides an estimate of the underlying synaptic current.…”

“…Subthalamic nucleus (STN) neurons are autonomously active, and their response to excitatory synaptic input appears to be well described by experimentally measured iPRCs (in the companion paper to this article: Farries and Wilson 2012). We developed a biophysical model of STN neurons to help us understand the structure of their iPRCs and to see why iPRCs appear to work so well as a predictor of their response to synaptic input.…”

“…We devised an experimental approach that allowed us to test theoretically predicted iPRCs against iPRCs estimated from the response to excitatory postsynaptic potentials (EPSPs) or injected current. We used this approach to address a number of questions raised by our data on experimentally estimated iPRCs, including the divergence between estimates made with synaptic and current pulse stimuli and the great diversity iPRC structure we encountered (Farries and Wilson 2012). This work has applications beyond the study of autonomously oscillating neurons and their response to weak perturbations; it provides new insights into how intrinsic properties shape a neuron's response to synaptic input.…”

Biophysical basis of the phase response curve of subthalamic neurons with generalization to other cell types

“…The equilibrium potentials for the ion species are as follows: E Na ϭ ϩ50 mV, E K ϭ Ϫ90 mV, E Ca ϭ ϩ100 mV, and E leak ϭ Ϫ60 mV. The capacitance C was 100 pF, comparable to the effective cell capacitances estimated from the membrane potential change caused in STN cells by small current pulses used in our companion article (Farries and Wilson 2012; 109 Ϯ 27 pF, range 57-191 pF, n ϭ 66 cells; see below). Both inactivating (spiking) and persistent Na ϩ conductances were modeled with instantaneous activation; that is, their activation states were direct functions of voltage equal to their steady-state activation:…”

“…The methods for slice preparation, perforated-patch recording, and data analysis are described in the companion article (Farries and Wilson 2012).…”

“…In the case of synaptic input, the stimulus current waveform must be inferred from the membrane potential trajectory. The EPSP waveform is isolated by subtracting the average spontaneous voltage trajectory from the trajectory with EPSPs, as described in our companion article (Farries and Wilson 2012). The time derivative of this isolated EPSP voltage trajectory provides an estimate of the underlying synaptic current.…”

“…Subthalamic nucleus (STN) neurons are autonomously active, and their response to excitatory synaptic input appears to be well described by experimentally measured iPRCs (in the companion paper to this article: Farries and Wilson 2012). We developed a biophysical model of STN neurons to help us understand the structure of their iPRCs and to see why iPRCs appear to work so well as a predictor of their response to synaptic input.…”

“…We devised an experimental approach that allowed us to test theoretically predicted iPRCs against iPRCs estimated from the response to excitatory postsynaptic potentials (EPSPs) or injected current. We used this approach to address a number of questions raised by our data on experimentally estimated iPRCs, including the divergence between estimates made with synaptic and current pulse stimuli and the great diversity iPRC structure we encountered (Farries and Wilson 2012). This work has applications beyond the study of autonomously oscillating neurons and their response to weak perturbations; it provides new insights into how intrinsic properties shape a neuron's response to synaptic input.…”

Biophysical basis of the phase response curve of subthalamic neurons with generalization to other cell types

Phase Response Curves (PRCs)

Evidence of two modes of spiking evoked in human firing motoneurones by Ia afferent electrical stimulation