Einat Shapira scite author profile

Modern advances in neurotechnology rely on effectively harnessing physical tools and insights towards remote neural control, thereby creating major new scientific and therapeutic opportunities. Specifically, rapid temperature pulses were shown to increase membrane capacitance, causing capacitive currents that explain neural excitation, but the underlying biophysics is not well understood. Here, we show that an intramembrane thermal-mechanical effect wherein the phospholipid bilayer undergoes axial narrowing and lateral expansion accurately predicts a potentially universal thermal capacitance increase rate of ∼0.3%=°C. This capacitance increase and concurrent changes in the surface charge related fields lead to predictable exciting ionic displacement currents. The new MechanoElectrical Thermal Activation theory's predictions provide an excellent agreement with multiple experimental results and indirect estimates of latent biophysical quantities. Our results further highlight the role of electro-mechanics in neural excitation; they may also help illuminate subthreshold and novel physical cellular effects, and could potentially lead to advanced new methods for neural control.

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Sound-induced motility of outer hair cells explained by stochastic resonance in nanometric sensors in the lateral wall

Shapira

Pujol

Plaksin

et al. 2016

Physics in Medicine

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Einat Shapira

Thermal Transients Excite Neurons through Universal Intramembrane Mechanoelectrical Effects

Sound-induced motility of outer hair cells explained by stochastic resonance in nanometric sensors in the lateral wall

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