Sensory Receptors — Chapter 10.2

01

Introduction

Our perceptions of signals within our bodies and of the world around us are mediated by a complex system of sensory receptors that detect such stimuli as touch, sound, light, pain, cold, and warmth.

The purpose of this chapter is to discuss the basic mechanisms by which these receptors change sensory stimuli into nerve signals that are then conveyed to and processed in the central nervous system.

In this chapter, we discuss the function of a few specific types of receptors, primarily peripheral mechanoreceptors, to illustrate some of the principles by which receptors operate.

Glossary of Terms

Osmolality: A measure of the concentration or osmoles of solute per kilogram of solvent
Osmoreceptor: Sensory receptor that detects changes in osmotic pressure in the blood; found in the hypothalamus, involved in regulating body fluid volume
Transmembrane potential: Difference in voltage between the interior and exterior of a cell

Differential Sensitivity of Receptors

Each type of receptor is highly sensitive to one type of stimulus for which it is designed and yet is almost nonresponsive to other types of sensory stimuli.

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Rods & Cones

Highly responsive to light, almost completely nonresponsive to heat, cold, pressure, or chemical changes in the blood.

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Osmoreceptors

Detect minute changes in osmolality of body fluids in the supraoptic nuclei of the hypothalamus, but have never been known to respond to sound.

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Pain Receptors

Almost never stimulated by usual touch or pressure, but become highly active the moment tactile stimuli become severe enough to damage tissues.

"Each nerve tract terminates at a specific point in the central nervous system, and the type of sensation felt when a nerve fiber is stimulated is determined by the point in the nervous system to which the fiber leads."

Labeled Line Principle Specificity of nerve fibers for transmitting only one modality of sensation

Law of Projection The impression of a specific stimulus arising when a specific nerve fiber is stimulated anywhere along its path to the brain

02

Types of Sensory Receptors

Five basic types of sensory receptors are classified by the type of stimulus they detect:

I

Mechanoreceptors

Detect mechanical compression or stretching of the receptor or of tissues adjacent to the receptor.

Subtypes:

Free nerve endings — epidermis and dermis
Pacinian corpuscle — deep pressure, vibration
Meissner's corpuscle — light touch, texture
Ruffini endings — skin stretch, sustained pressure
Krause end bulbs — cold, light touch
Hair follicle receptors — hair movement
Muscle spindles — muscle length
Golgi tendon organs — muscle tension

II

Thermoreceptors

Detect changes in temperature, with some receptors detecting cold and others warmth.

Subtypes:

Cold receptors — respond to temperatures below ~30°C; free nerve endings; A-delta fibers
Warm receptors — respond to temperatures above ~30°C; free nerve endings; C fibers

Key fact: Thermoreceptors are free nerve endings — they lack the specialized encapsulated structures seen in mechanoreceptors.

III

Nociceptors

Pain receptors that detect physical or chemical damage occurring in the tissues.

Characteristics:

Free nerve endings — no specialized encapsulation
Pricking pain — transmitted by A-delta (Group III) fibers
Aching pain — transmitted by C (Group IV) fibers
Respond to mechanical, thermal, and chemical stimuli
Probably never fully adapt — unlike mechanoreceptors

IV

Electromagnetic Receptors

Detect light on the retina of the eye.

Subtypes:

Rods — detect dim light; no color discrimination; ~120 million per retina
Cones — detect bright light and color; concentrated in fovea; ~6 million per retina

Differential sensitivity example: Rods and cones are highly responsive to light but almost completely nonresponsive to normal ranges of heat, cold, pressure on the eyeballs, or chemical changes in the blood.

V

Chemoreceptors

Detect chemical stimuli including taste, smell, and blood chemistry.

Locations & Functions:

Taste buds — taste in the mouth
Olfactory epithelium — smell in the nose
Aortic & carotid bodies — oxygen level in arterial blood
Hypothalamus — osmolality of body fluids
Medulla — CO₂ concentration, pH
Hypothalamus/medulla — blood glucose, amino acids, fatty acids

03

Receptor Potential

When a sensory receptor is stimulated, the membrane permeability changes, allowing ions to flow and creating a local electrical signal called the receptor potential.

Unlike action potentials, receptor potentials are graded — their amplitude is proportional to the strength of the stimulus. When the receptor potential reaches threshold (~−55 mV), it triggers action potentials in the attached nerve fiber.

1

Stimulus applied

Mechanical, thermal, or chemical stimulus deforms the receptor membrane

2

Ion channels open

Membrane permeability increases; Na⁺ flows in, causing local depolarization

3

Receptor potential generated

Graded, decremental potential spreads to the first Node of Ranvier

4

Action potentials fired

If threshold is reached, all-or-none action potentials propagate along the nerve fiber

Receptor Potential vs. Action Potentials

Receptor Potential

Action Potentials

Threshold (−55 mV)

The Pacinian Corpuscle — A Model Receptor

The Pacinian corpuscle is the best-studied mechanoreceptor. Its onion-like lamellar structure filters out slow stimuli, making it respond only to rapid vibration.

Unmyelinated central nerve ending inside the capsule
Myelinated just before leaving the corpuscle
Deformation opens Na⁺ channels → receptor potential
Local circuit currents flow to the Node of Ranvier
Action potential generated at the node if threshold is reached

Stimulus Strength vs. Receptor Potential

Sigmoidal relationship: amplitude increases rapidly at first, then progressively less rapidly at high stimulus strength. (Data from Loewenstein, 1961)

04

Adaptation of Receptors

All sensory receptors adapt — they decrease their response to sustained stimuli. The rate of adaptation varies dramatically between receptor types.

Adaptation Rates of Different Receptors

Joint capsule receptors

Muscle spindle

Pacinian corpuscle

Hair receptor

Rapidly Adapting

Phasic Receptors

Signal change in stimulus. Fire at onset (and offset) but not during sustained stimulation.

Pacinian corpuscle — drops to near 0 within 1 second
Hair receptors — respond to movement, not sustained deflection
Meissner's corpuscles — texture and slip detection

Slowly Adapting

Tonic Receptors

Signal sustained stimulus. Continue firing throughout stimulation, encoding intensity.

Muscle spindles — continuous position feedback
Ruffini endings — sustained skin stretch
Joint capsule receptors — joint position
Pain receptors — probably never fully adapt

Clinical note: Some physiologists believe that baroreceptors adapt very slowly or not at all — providing continuous blood pressure monitoring.

05

Nerve Fiber Classification

Nerve fibers come in all sizes between 0.5 and 20 μm in diameter — the larger the diameter, the greater the conducting velocity. The range of conducting velocities is between 0.5 and 120 m/second.

General Classification (A, B, C)

← Larger diameter / Faster Smaller diameter / Slower →

Aα

12–20 μm · 70–120 m/s

Aβ

5–12 μm · 30–70 m/s

Aγ

3–6 μm · 15–30 m/s

Aδ

1–5 μm · 5–30 m/s

C

0.2–1.5 μm · 0.5–2 m/s

Click a fiber type to see details

Sensory Classification (Groups I–IV)

Group	General Type	Diameter (μm)	Velocity (m/s)	Sensory Function
Ia	Aα	12–20	70–120	Muscle spindle primary endings (proprioception)
Ib	Aα	12–20	70–120	Golgi tendon organs (muscle tension)
II	Aβ	5–12	30–70	Muscle spindle secondary endings; touch, vibration, pressure
III	Aδ	1–5	5–30	Temperature (cold); pricking pain; crude touch
IV	C	0.2–1.5	0.5–2	Aching pain; warmth; itch; crude touch

Speed in Perspective

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120 m/s

Fastest Aα fiber — covers a football field in 1 second

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0.5 m/s

Slowest C fiber — takes ~2 seconds from big toe to spinal cord

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240×

Difference between fastest and slowest fiber conduction

06

Signal Summation & Receptive Fields

Receptive Field

The area of skin (or other tissue) from which a single sensory neuron can be activated. Receptive fields can be as large as 5 cm in diameter for some pain fibers.

Spatial Summation

A stronger stimulus activates more nerve fibers simultaneously — the signal is encoded by the number of active fibers. A pinprick activates many pain fibers in the surrounding area, with the periphery of the field having more nerve endings than the center.

Temporal Summation

Signal strength is also encoded by increasing the frequency of nerve impulses in each fiber. As stimulus strength increases, action potentials fire more rapidly.

Temporal Summation

Translation of signal strength into a frequency-modulated series of nerve impulses

Summary of Receptor Properties

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Differential Sensitivity

Each receptor type responds maximally to one specific stimulus modality

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Labeled Line Principle

Ordered projection to the cortex — each fiber leads to a specific brain region

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Graded Responses

Receptor potentials are proportional to stimulus intensity

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Adaptable

Receptors decrease their response to sustained stimuli over time

07

Self-Quiz

Test your understanding of sensory receptors. Select the best answer for each question.