Inactivation of sodium channels underlies reversible neuropathy during critical illness in rats
Kevin R. Novak, … , Jaffar Khan, Mark M. Rich
Kevin R. Novak, … , Jaffar Khan, Mark M. Rich
Published April 1, 2009
Citation Information: J Clin Invest. 2009;119(5):1150-1158. https://doi.org/10.1172/JCI36570.
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Research Article Neuroscience

Inactivation of sodium channels underlies reversible neuropathy during critical illness in rats

Abstract

Neuropathy and myopathy can cause weakness during critical illness. To determine whether reduced excitability of peripheral nerves, rather than degeneration, is the mechanism underlying acute neuropathy in critically ill patients, we prospectively followed patients during the acute phase of critical illness and early recovery and assessed nerve conduction. During the period of early recovery from critical illness, patients recovered from neuropathy within days. This rapidly reversible neuropathy has not to our knowledge been previously described in critically ill patients and may be a novel type of neuropathy. In vivo intracellular recordings from dorsal root axons in septic rats revealed reduced action potential amplitude, demonstrating that reduced excitability of nerve was the mechanism underlying neuropathy. When action potentials were triggered by hyperpolarizing pulses, their amplitudes largely recovered, indicating that inactivation of sodium channels was an important contributor to reduced excitability. There was no depolarization of axon resting potential in septic rats, which ruled out a contribution of resting potential to the increased inactivation of sodium channels. Our data suggest that a hyperpolarized shift in the voltage dependence of sodium channel inactivation causes increased sodium inactivation and reduced excitability. Acquired sodium channelopathy may be the mechanism underlying acute neuropathy in critically ill patients.

Authors

Kevin R. Novak, Paul Nardelli, Tim C. Cope, Gregory Filatov, Jonathan D. Glass, Jaffar Khan, Mark M. Rich

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Figure 4

Increase in action potential amplitude following anode break excitation suggests that inactivation of sodium channels is an important contributor to reduced excitability.

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Increase in action potential amplitude following anode break excitation ...
(A) Examples of depolarization-induced (rheobase) and anode break–induced action potentials from individual axons in septic rats 3 days following induction of sepsis. In axon 1, the small action potential following rheobase excitation gets much larger after anode break. In axon 2, the large action potential following rheobase excitation is only modestly larger following anode break. The horizontal line represents 0 mV. (B) Plot of the mean (±SEM) increase in action potential amplitude following anode break excitation for untreated and septic axons. The increase in action potential amplitude following anode break was greater in septic axons with small action potentials (P < 0.01 vs. both axons from untreated rats and axons from septic rats with normal action potentials; n = 58 normal action potentials [AP] from untreated rats, n = 15 small action potentials from septic rats, and n = 18 normal action potentials from septic rats). (C) Plot of the percent increase in action potential amplitude following anode break versus rheobase action potential amplitude. The increase in action potential amplitude following anode break is inversely correlated with rheobase action potential amplitude in septic rats (r = –0.78, P < 0.01, solid line). In control rats, there was also a relationship, but it was not as strong (r = –0.63, P < 0.01, dashed line). (D) The increase in action potential amplitude following anode break is not related to resting potential (r = 0.04, P = 0.69 for axons from septic rats).