A patient with diabetic neuropathy says: "I can't feel my feet." Why? Sensory receptors and their nerve fibers are damaged β the body loses its ability to detect stimuli.
Sensory receptors are the body's interface with the external & internal world
They convert physical/chemical stimuli into electrical nerve signals
Without them: no pain, no touch, no vision, no hearing, no balance
They are the starting point of ALL sensory pathways in the nervous system
Studied in Chapter 47 β Guyton & Hall, 14th Edition
Definition & Basic Concept
Definition
Sensory receptors are specialized structures that detect specific stimuli from the environment or body and convert them into electrical signals (receptor potentials) transmitted to the CNS.
Each receptor is highly sensitive to ONE specific type of stimulus
Q1. Which sensory receptor adapts MOST RAPIDLY to a sustained stimulus?
AMuscle spindle
BPacinian corpuscle
CRuffini's endings
DBaroreceptors
β± Think before you turn to the next slide for the answer!
MCQ 1 β Answer
Q1. Which sensory receptor adapts MOST RAPIDLY to a sustained stimulus?
AMuscle spindle
Bβ Pacinian corpuscle
CRuffini's endings
DBaroreceptors
π Explanation:
The Pacinian corpuscle adapts to extinction within a few hundredths of a second. It is a viscoelastic structure β fluid redistributes rapidly, removing the deforming force from the central fiber. It detects only rapid changes (vibration 30β800 Hz), not sustained pressure. (Guyton & Hall, Ch. 47)
MCQ 2 of 5Interactive Question
Q2. The 'Labeled Line Principle' states that the modality of sensation is determined by:
AThe type of stimulus applied to the receptor
BThe frequency of action potentials in the nerve fiber
CThe specific point in the CNS where the nerve fiber terminates
DThe diameter of the nerve fiber carrying the signal
β± Think before you turn to the next slide for the answer!
MCQ 2 β Answer
Q2. The 'Labeled Line Principle' states that the modality of sensation is determined by:
AThe type of stimulus applied to the receptor
BThe frequency of action potentials in the nerve fiber
Cβ The specific point in the CNS where the nerve fiber terminates
DThe diameter of the nerve fiber carrying the signal
π Explanation:
Each nerve fiber terminates at a specific point in the CNS. The type of sensation felt depends on WHERE the fiber leads β not what stimulus excited it. A pain fiber stimulated by electricity still causes pain. Vision fibers β visual cortex; auditory fibers β auditory cortex. (Guyton & Hall, Ch. 47)
MCQ 3 of 5Interactive Question
Q3. Which nerve fiber type carries ACHING PAIN and WARMTH sensations?
AType AΞ± fibers (Group Ia)
BType AΞ² fibers (Group II)
CType AΞ΄ fibers (Group III)
DType C fibers (Group IV)
β± Think before you turn to the next slide for the answer!
MCQ 3 β Answer
Q3. Which nerve fiber type carries ACHING PAIN and WARMTH sensations?
AType AΞ± fibers (Group Ia)
BType AΞ² fibers (Group II)
CType AΞ΄ fibers (Group III)
Dβ Type C fibers (Group IV)
π Explanation:
Type C fibers (Group IV) are unmyelinated, 0.2β1.5 ΞΌm diameter, conducting at 0.5β2 m/sec. They carry aching/burning pain, warmth, itch, and crude touch. AΞ΄ (Group III) carries pricking pain and cold. C fibers constitute >50% of sensory fibers in peripheral nerves. (Guyton & Hall, Ch. 47)
MCQ 4 of 5Interactive Question
Q4. A patient cannot detect vibration at 200 Hz in the fingertips. Which receptor is most likely damaged?
AMeissner's corpuscles
BRuffini's endings
CPacinian corpuscles
DFree nerve endings
β± Think before you turn to the next slide for the answer!
MCQ 4 β Answer
Q4. A patient cannot detect vibration at 200 Hz in the fingertips. Which receptor is most likely damaged?
AMeissner's corpuscles
BRuffini's endings
Cβ Pacinian corpuscles
DFree nerve endings
π Explanation:
Pacinian corpuscles detect vibrations from 30β800 Hz via type AΞ² fibers. Meissner's corpuscles detect low-frequency vibration (2β80 Hz). At 200 Hz, Pacinian corpuscles are the primary detectors. They are found in deep skin and fascial tissues and adapt within hundredths of a second. (Guyton & Hall, Ch. 47 & 48)
MCQ 5 of 5Interactive Question
Q5. The mechanism that PREVENTS runaway excitation in the nervous system (e.g., epilepsy) is:
ASpatial summation of inhibitory signals
BSynaptic fatigue and inhibitory circuits
CRapid adaptation of all sensory receptors
DTemporal summation of excitatory signals
β± Think before you turn to the next slide for the answer!
MCQ 5 β Answer
Q5. The mechanism that PREVENTS runaway excitation in the nervous system (e.g., epilepsy) is:
ASpatial summation of inhibitory signals
Bβ Synaptic fatigue and inhibitory circuits
CRapid adaptation of all sensory receptors
DTemporal summation of excitatory signals
π Explanation:
Two mechanisms prevent runaway excitation: (1) Inhibitory feedback circuits β return from termini back to initial neurons; (2) Synaptic fatigue β progressive weakening of transmission with overuse. In epilepsy, these mechanisms fail β reverberatory circuits fire uncontrollably. Synaptic fatigue eventually terminates the seizure. (Guyton & Hall, Ch. 47)
Take-Home Messages
15 types of receptors: Mechano-, Thermo-, Noci-, Electromagnetic, Chemo-
2Labeled Line Principle: sensation type = CNS destination, not stimulus type
3Receptor potential β Action potential when threshold is exceeded
1. Hall JE, Hall ME. Guyton and Hall Textbook of Medical Physiology, 14th Edition. Elsevier; 2021.
Chapter 47: Sensory Receptors, Neuronal Circuits for Processing Information (pp. 587β598)
Chapter 48: Somatic Sensations: I. General Organization, Tactile and Position Senses (pp. 599β614)
2. Kandel ER, Schwartz JH, Jessell TM, et al. Principles of Neural Science, 5th Edition. McGraw-Hill; 2013.
3. Delmas P, Hao J, Rodat-Despoix L. Molecular mechanisms of mechanotransduction in mammalian sensory neurons. Nat Rev Neurosci. 2011;12(3):139-153.
4. Bennett DL, Clark AJ, Huang J, et al. The role of voltage-gated sodium channels in pain signaling. Physiol Rev. 2019;99(2):1079-1151.
5. Robertson CE, Baron-Cohen S. Sensory perception in autism. Nat Rev Neurosci. 2017;18(11):671-684.