Abstract
The energy efficiency of neural signal transmission is important not only as a limiting factor in brain architecture, but it also influences the interpretation of functional brain imaging signals. Action potential generation in mammalian, versus invertebrate, axons is remarkably energy efficient. Here we demonstrate that this increase in energy efficiency is due largely to a warmer body temperature. Increases in temperature result in an exponential increase in energy efficiency for single action potentials by increasing the rate of Na+ channel inactivation, resulting in a marked reduction in overlap of the inward Na+, and outward K+, currents and a shortening of action potential duration. This increase in single spike efficiency is, however, counterbalanced by a temperature-dependent decrease in the amplitude and duration of the spike afterhyperpolarization, resulting in a nonlinear increase in the spike firing rate, particularly at temperatures above approximately 35°C. Interestingly, the total energy cost, as measured by the multiplication of total Na+ entry per spike and average firing rate in response to a constant input, reaches a global minimum between 37–42°C. Our results indicate that increases in temperature result in an unexpected increase in energy efficiency, especially near normal body temperature, thus allowing the brain to utilize an energy efficient neural code.
Highlights
It has long been assumed that this large energy consumption was due to the need to generate the electrical signals through which brain cells communicate: the action potentials
How is this energy efficiency obtained? Here we addressed this question by performing recordings and computational models of mammalian brain cells
The action potentials of warmblooded animals became remarkably energy efficient, owing to the increase in body temperature. These results indicate that mammalian brains, requiring a great deal of energy to operate, are more efficient than expected
Summary
Na+ entry into neurons, which must be returned to its extracellular location through the operation of the Na+/K+ ion pump by the expenditure of energy via hydrolysis of ATP, occurs through generation of action potentials ( along long intracortical, unmyelinated axons) and synaptic potentials during active signaling. These influxes of Na+ into neurons occur in addition to a background leak of Na+ ions through the neuronal membrane. To understand the energy costs of neuronal signaling in the cortex, it is essential to understand the entry of Na+ into neurons and neuronal processes during neuronal activity
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