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The Resting Membrane Potential01:21

The Resting Membrane Potential

Overview
Resting Membrane Potential01:24

Resting Membrane Potential

The relative difference in electrical charge, or voltage, between the inside and the outside of a cell membrane, is called the membrane potential. It is generated by differences in permeability of the membrane to various ions and the concentrations of these ions across the membrane.
The Inside of a Neuron is More Negative
The membrane potential of a cell can be measured by inserting a microelectrode into a cell and comparing the charge to a reference electrode in the extracellular fluid. The...
Resting Potential Decay01:15

Resting Potential Decay

The resting membrane potential of a neuron (-70mV) is sustained due to the selective ion permeability of the membrane. At the resting potential, the membrane is slightly permeable to ions like sodium (Na+) and chloride (Cl−) and highly permeable to potassium ions (K+). Differences in the ions' concentration inside the cell compared to the outside are maintained by membrane transport proteins like channels and pumps.
At rest, the K+ is the main ion that moves across the membrane through...
Potentiometry: Membrane Electrodes01:15

Potentiometry: Membrane Electrodes

Membrane electrodes, also known as p-ion electrodes, use membranes that selectively interact with free analyte ions, generating a potential difference across the membrane. The resulting membrane potential, known as the asymmetry potential, is not zero even when analyte concentrations on both sides of the membrane are equal. The membrane's response is typically not selective to a single analyte but proportional to the concentration of all ions in the sample solution capable of interacting at the...
Graded Potential01:19

Graded Potential

Graded potentials are localized fluctuations in the cell membrane's electrical charge, commonly found in the dendrites of neurons. The magnitude of these potential changes depends on the strength of the initiating stimulus. In a membrane at its resting potential, a graded potential signifies a voltage shift either above -70 mV or below -70 mV.
Graded potentials fall into two categories: depolarizing and hyperpolarizing. Depolarizing graded potentials typically occur when sodium (Na+) or calcium...
Junction Potentials in Galvanic Cells01:21

Junction Potentials in Galvanic Cells

The Nernst equation, derived under the assumption of thermodynamic equilibrium, calculates the electromotive force (emf) as the sum of potential differences at phase boundaries in a reversible cell without a liquid junction. However, in irreversible cells such as the Daniell cell, an additional potential difference named the liquid-junction potential (EJ) arises across the interface of two electrolyte solutions due to different ion diffusion rates. This EJ represents the potential difference...

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Related Experiment Video

Updated: May 11, 2026

Measuring the Induced Membrane Voltage with Di-8-ANEPPS
05:52

Measuring the Induced Membrane Voltage with Di-8-ANEPPS

Published on: November 20, 2009

Membrane potential dynamics of grid cells.

Cristina Domnisoru1, Amina A Kinkhabwala, David W Tank

  • 1Princeton Neuroscience Institute, Princeton University, Princeton, New Jersey 08544, USA.

Nature
|February 12, 2013
PubMed
Summary
This summary is machine-generated.

Grid cells in the brain create spatial maps using depolarizing ramps, not theta amplitude modulations, to define firing fields. Theta oscillations, however, remain crucial for regulating the precise timing of neural spikes.

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Area of Science:

  • Neuroscience
  • Computational Neuroscience
  • Systems Neuroscience

Background:

  • Grid cells form a triangular lattice of firing fields crucial for spatial navigation.
  • Two main models exist: oscillatory interference (predicting theta amplitude modulations) and attractor networks (predicting slow depolarizing ramps).

Purpose of the Study:

  • To differentiate between oscillatory interference and attractor network models of grid cell function.
  • To investigate the intracellular mechanisms underlying grid cell firing and spatial representation.

Main Methods:

  • In vivo whole-cell recordings were performed in mice navigating a virtual reality linear track.
  • Intracellular membrane potentials of grid cells were directly measured during firing field traversals.

Main Results:

  • Grid cells exhibited large, reproducible depolarizing ramps strongly correlated with firing fields.
  • Intracellular theta oscillations influenced grid cell spike timing.
  • Theta amplitude modulations did not consistently determine firing field locations.

Conclusions:

  • Findings support attractor network models, where slow depolarizing ramps generate grid fields.
  • Theta oscillations primarily control spike timing rather than defining firing field locations.