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Sensory receptor

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Title: Sensory receptor  
Author: World Heritage Encyclopedia
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Subject: Sensory system, Axon, Low arousal theory, Hypoesthesia, Integumentary system
Collection: Sensory Receptors
Publisher: World Heritage Encyclopedia

Sensory receptor

In a sensory transduction by creating graded potentials or action potentials in the same cell or in an adjacent one.

Structure of human sensory system


  • Functions 1
  • Classification 2
    • Adequate stimulus 2.1
    • Location 2.2
    • Morphology 2.3
    • Rate of adaptation 2.4
  • Innervation 3
  • See also 4
  • Additional images 5
  • References 6
  • External links 7


The sensory receptors involved in taste and smell contain receptor molecules that bind to specific chemicals. Odor receptors in olfactory receptor neurons, for example, are activated by interacting with molecular structures on the odor molecule. Similarly, taste receptors (gustatory receptors) in taste buds interact with chemicals in food to produce an action potential.

Other receptors such as mechanoreceptors and photoreceptors respond to physical stimuli. For example, photoreceptor cells contain specialized proteins such as rhodopsin to transduce the physical energy in light into electrical signals. Some types of mechanoreceptors fire action potentials when their membranes are physically stretched.

The sensory receptor functions are the first component in a sensory system.

Sensory receptors respond to specific stimulus modalities. The stimulus modality to which a sensory receptor responds is determined by the sensory receptor's adequate stimulus.

The sensory receptor responds to its stimulus modality by initiating sensory transduction. This may be accomplished by a net shift in the initial states of a receptor (see a picture of these putative states [1] with the biophysical description [2]).


Adequate stimulus

A sensory receptor's adequate stimulus is the stimulus modality for which it possesses the adequate sensory transduction apparatus. Adequate stimulus can be used to classify sensory receptors:

  • Ampullae of Lorenzini respond to electric fields, salinity, and to temperature, but function primarily as electroreceptors


Sensory receptors can be classified by location:


Somatic sensory receptors near the surface of the skin can usually be divided into two groups based on morphology:

Rate of adaptation

  • A tonic receptor is a sensory receptor that adapts slowly to a stimulus and continues to produce action potentials over the duration of the stimulus.[3] In this way it conveys information about the duration of the stimulus. Some tonic receptors are permanently active and indicate a background level. Examples of such tonic receptors are pain receptors, joint capsule, and muscle spindle.[4]
  • A phasic receptor is a sensory receptor that adapts rapidly to a stimulus. The response of the cell diminishes very quickly and then stops. It does not provide information on the duration of the stimulus;[3] instead some of them convey information on rapid changes in stimulus intensity and rate.[4] An example of a phasic receptor is the Pacinian corpuscle.


Different sensory receptors are innervated by different types of nerve fibers. Muscles and associated sensory receptors are innvervated by type I and II sensory fibers, while cutaneous receptors are innervated by Aβ, Aδ and C fibers.

See also

Additional images


  1. ^ Michael J. Gregory. "Sensory Systems". Clinton Community College. Retrieved 2013-06-06. 
  2. ^
  3. ^ a b,%2017%2018.ppt
  4. ^ a b

External links

  • Sensory Receptors at the US National Library of Medicine Medical Subject Headings (MeSH)
  • The major classes of somatic sensory receptors
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