They are EP (evoked potential), VEP (visually evoked potential), VER (visual evoked response), and pVER (indicating that this potential is pattern-elicited). Many abbreviations are also used, although they are not strictly correct. This potential has clinical application and is used to objectively measure refraction, visual acuity, amblyopia, binocular anomalies and help in the diagnosis of some demyelinating diseases (e.g. Recording requires repetition of the stimulus and a computer synchronized with the onset of that stimulus, to average out the background noise produced by the spontaneous brain potentials (e.g. Visual evoked cortical potential (VECP) An electrical potential measured at the level of the occipital cortex in response to a light stimulation. Transmembrane potential See resting membrane potential. Standing potential of the eye See resting potential of the eye. dark potential of the eye standing potential of the eye. This potential is used in recording the electrooculogram. It is of the order of several mV in humans.
Resting potential of the eye A direct current potential which exists between the anterior and posterior poles of the eye, the cornea being positive relative to the back of the eye. See depolarization hyperpolarization action potential tonus. membrane potential transmembrane potential. The inside of the cell is usually about −70 mV compared to the outside, but this value depends on the quantity of potassium (mainly), sodium and chloride ions on both sides of the membrane, and the permeability to these ions of the membrane itself. Resting membrane potential Difference in direct current potential between the inside and outside of a living cell. The ganglion cells respond with action potentials. the inside of the membrane becomes more negative with respect to the outside. The photoreceptors and the bipolar cells produce a receptor potential but, surprisingly, it is a hyperpolarization, i.e. This is a graded type of response with an amplitude proportional to the intensity of the stimulus ( graded potential). Receptor potential Difference in potential occurring in a receptor in response to a stimulus. These potentials are presumed to originate from the vicinity of the inner plexiform layer of the retina (probably the amacrine cells) and may reflect disturbances of that part of the retina. The amplitude of these oscillatory responses is usually enhanced by a filtering technique.
(OP) Subwaves of low amplitude but high frequency (70-140 Hz) superimposed on the b-wave of the electroretinogram. Membrane potential See resting membrane potential. If the neuron becomes depolarized to threshold an action potential is triggered in its axon. The amplitude of the response varies with the intensity of the stimulus. in the photoreceptors) generated by a neuron in response to a stimulus. Graded potential A depolarization or a hyperpolarization (e.g.
It is primarily, in man, a cone-generated potential. It is completed within 1.5 ms and is followed by the a-wave of the ERG. See adaptation Schwann cell neuron receptor potential resting membrane potential synapse.ĭark potential of the eye See resting potential of the eye.Įarly receptor potential (ERP) This is an early rapid response that can be detected when the retina is stimulated with an intense flash of light, approximately 10 6 times brighter than that required to elicit the ERG. The action potential travels as a wave in both directions from the point of stimulation and the speed is faster in myelinated than in unmyelinated nerve fibres. The action potential is followed by an inexcitable period called the refractory period, which usually lasts one or two milliseconds. The whole process takes less than one millisecond and its amplitude is always the same (all or none law) for a given axon, whatever the magnitude of the stimulus. The voltage changes from about −70 mV to +40 mV and then falls rapidly back to the resting membrane potential as the sodium pump regains its effect. The sodium pump (or sodium/potassium pump) which transports most sodium ions outside the cell and potassium ions inside the cell ceases to function and the sodium ions rush in making the interior of the axon a positive voltage with respect to the outside. The stimulus must be above a certain threshold value to have an effect. It is typically measured in volts.Īction potential The electric current generated in an axon of a nerve cell in response to a stimulus. The amount of energy required to transfer a unit of positive charge from one point in an electrical field to another (potential difference).