BIOL 3301 Integration of Nervous System Function Fall 2024 PDF

Summary

This document is a lecture on the integration of the nervous system function. It covers learning objectives, sensation, types of sensory receptors, and sensory pathways. The lecture notes are organized by topics and include diagrams.

Full Transcript

Integration of Nervous
System Function

BIOL 3301
Kristen Winter, PhD
Learning Objectives
List the types of somatic and visceral sensory receptors,
tell where they are located, and describe how they
function in sensation
Describe the roles of receptor potentials and adaptation
Differentiate between primary and secondary receptors
Differentiate between tonic and phasic receptors
List the major ascending sensory tracts and state a
function for each
Describe the sensory and association areas of the
cerebral cortex and discuss their interactions
 Sensation
Process initiated by stimuli acting on sensory
receptors
Action potentials are generated by stimuli at the
sensory receptor and propagate along nerves to
the brain and spinal cord
Perception – conscious awareness of those
sensations
Results when the brain interprets the sensation-
generated action potentials in the cerebral cortex
Not all sensory information results in perception
Senses – means by which the brain receives
information about the environment and body
General senses
Special senses
 Senses
General senses – receptors distributed over a
large part of the body
Somatic senses – sensory information from the
body and environment
Touch
Pressure
Temperature
Pain
Proprioception – sense of body’s position and
movement
Visceral senses – information from internal organs
Pain
Pressure
Special senses – localized to specific organs
with specialized receptors
Smell
Taste
Vision
Hearing
Balance
 Types of Sensory Receptors
TABLE 14.1 Classification of the Senses

Classified based Types of Sense Receptor Type Initiation of Response Specific Examples
GENERAL SENSES

on Somatic
Touch Mechanoreceptors Compression of receptors

Types of Stroking Meissner corpuscle
Hair follicle receptor
Texture Merkel disk
stimulus they Vibration Pacinian corpuscle
Skin stretch Ruffini end organ
detect Itch, tickle Free nerve endings

Location in the
Pressure Mechanoreceptors Compression of receptors Merkel disk
Proprioception Mechanoreceptors Compression of receptors Free nerve endings
Pacinian corpuscle

body Muscle spindle
Golgi tendon organ

Receptor Temperature Thermoreceptors Temperature around nerve endings Free nerve endings
Cold receptors

structure Pain Nociceptors Irritation of nerve endings (e.g., mechanical,
Warm receptors
Free nerve endings
chemical, or thermal)

Visceral
Pain Nociceptors Irritation of nerve endings Free nerve endings
Pressure Mechanoreceptors Compression of receptors Pacinian corpuscle

SPECIAL SENSES
Smell Chemoreceptors Binding of molecules to membrane receptors Olfactory receptor
Taste Chemoreceptors Binding of molecules to membrane receptors Taste receptor
Vision Photoreceptors Chemical change in receptors initiated by light Rods and cones
Hearing Mechanoreceptors Bending of microvilli on receptor cells Hair cells
Balance Mechanoreceptors Bending of microvilli on receptor cells Hair cells
 Types of Sensory Receptors
Mechanoreceptors
Respond to mechanical force (compression, bending, stretching of cells)
Touch, pressure, proprioception, hearing, and balance
Chemoreceptors
Respond to chemicals
Smell and taste
Thermoreceptors
Respond to changes in temperatures
Sense of temperature
Photoreceptors
Respond to light
Vision
Nociceptors
Pain receptors
Respond to extreme, mechanical, chemical, and thermal stimuli
Can respond to more than one type of stimuli
Types of Sensory Receptors
Cutaneous receptors
Associated with the skin
Provide information about the external environment
Visceroreceptors
Associated with the viscera or organs
Provide information about the internal environment
Proprioceptors
Associate with joints, tendons, and other connective tissue
Provide information about body position, movement, and
extent of stretch or force of muscular contraction
Types of Sensory Receptors
TABLE 14.2 Structural Classification of General Sensory Receptors

Type of Receptor Structure Function
Free nerve Branching, no capsule Pain, itch, tickle, temperature, joint
ending movement, and proprioception

Merkel Consists of flattened expansions at the end of axons; each Light touch and superficial
disk expansion is associated with a Merkel cell pressure

Hair follicle Wrapped around hair follicles or extending along the hair axis; Light touch; responds to very slight
receptor each axon supplies several hairs, and each hair receives bending of the hair
branches from several neurons, resulting in considerable
overlap
Pacinian Onion-shaped capsule composed of several cell layers with a Deep cutaneous pressure, vibration,
corpuscle single central nerve process and proprioception

Meissner Several branches of a single axon associated with Two-point discrimination
corpuscle specialized Schwann cells and surrounded by a connective
tissue capsule
Ruffini end Branching axon with numerous small, terminal knobs Continuous touch or pressure;
organ surrounded by a connective tissue capsule responds to depression or stretch of
the skin
Muscle Three to 10 striated muscle fibers enclosed by a loose Proprioception associated with detection of
spindle connective tissue capsule, striated only at the ends, with muscle stretch; important for control of muscle
sensory nerve endings in the center tone

Golgi tendon Surrounds a bundle of tendon fasciculi and is enclosed by a Proprioception associated with the stretch
organ delicate of a tendon; important for control of
connective tissue capsule; nerve terminations are branched, muscle
with small swellings applied to individual tendon fasciculi contraction
 Free Nerve Endings
Simplest structure
Most common sensory receptor
Unspecialized neuronal
branches similar to dendrites
Distributed throughout most
parts of the body
Abundant in epithelial and
connective tissues
Detect pain, temperature, itch,
movement
 Merkel (Tactile) Disks
More complex than free nerve
endings
Consist of axonal branches that
end as flattened expansions each
associated with specialized
epithelial cell
Found in the basal layers of the
epidermis and dome-shaped
mounds of thickest epidermis in
hairy skin
Detect light touch and superficial
pressure
Skin displacement of less than 1 mm
Hair Follicle Receptors (Hair End
Organs)
Respond to slight bending
of the hair during light
touch
Very sensitive to low levels
of stimulation
Not well localized
Dendritic tree has several
hair follicle receptors
Receptive fields overlap
 Pacinian (Lamellated) Corpuscles
Complex structure
Multiple layers of tissue
surrounding a single
dendrite (like an onion)
Compression causes an
action potential
Located in subcutaneous
tissue
Respond to deep cutaneous
pressure and vibration
Associated with joints
Proprioceptive information
Meissner (Tactile) Corpuscles
Distributed throughout dermal
papillae
Involved in two-point discrimination
Ability to detect simultaneous
stimulation of Meissner corpuscles in
two distinct receptor fields by
touching at two points on the skin
Distance between two points varies
in different body regions (abundant
in tongue and finger tips, less in
back)
Evaluates texture of objects
 Ruffini End Organs
Located in dermis of the
skin
Primarily in the fingers
Respond to pressure on the
skin directly superficial to
receptor and stretch of
adjacent skin
Important for continuous
touch or pressure
 Muscle Spindles
3-10 specialized muscle fibers
located in skeletal muscles
Provide information about the
length of muscle
Important for control and tone
of postural muscles
Stretching of muscles
stimulates gamma motor
neurons and activates the
stretch reflex to increase
muscle tone
Golgi Tendon Organs
Proprioceptive receptors
associated with a tendon
near the junction between
muscle and tendon
Activated by increased
tendon tension caused by
contraction of muscle or
passive stretch of the
tendon
 Responses of Sensory Receptors
Receptor potential –
graded potential created
when a sensory receptor is
stimulated
Primary receptors –
sensory receptor cells that
conduct action potentials in
response to the receptor
potential
Secondary receptors –
have no axons or short, axon
like projections and only
produce receptor potentials
 Adaptation of Sensory Receptors
Adaptation – decreased
sensitivity to continued stimulus
Graded depolarization produced
by receptor potential adapts or
returns to resting level even
though stimulus is still being
applied
Tonic receptors – generate
action potentials as long as a
stimulus is applied and adapt
slowly
Merkel disks and Ruffini end organs
Phasic receptors – adapt rapidly
and are sensitive to changes in
stimuli
Pacinian and Meissner corpuscles
 Sensory Pathways
Transmit information form sensory receptors
to the CNS
Ascending spinal pathways – sensory
pathways involving the spinal cord
Carry a specific modalities
Names often indicate origin and termination
Names may indicate location in the CNS
Conscious sensory input
Spinothalamic tract of the anterolateral system
Dorsal-column/medial-lemniscal system
Unconscious sensory input
Anterolateral system (spinomesencephalic and
spinoreticular tracts)
Spinocerebellar tract
Anterolateral System
One of two major systems that convey cutaneous
system information to the brain
Includes three tracts
Spinothalamic tract – conscious perception of pain and
temperature information, light touch and pressure, tickle, and
itch sensations
Spinoreticular tract – carry pain and touch sensation that is
not consciously perceived to other parts of the brain
Spinomesencephalic tract – carry pain and touch sensation
that is not consciously perceived to other parts of the brain
 Spinothalamic Tract
Transmits sensory signals from peripheral receptors
to the cerebral cortex
Three neuron chain
Primary neurons – conduct action potentials from the
sensory receptor to the CNS (dorsal horn of the spinal
cord)
Axons form dorsal root of spinal nerve with cell bodies in dorsal root
ganglia
Synapse on interneurons
Secondary neurons – neurons in the spinal cord that
relay information to the brain
Axons decussate (cross) to the contralateral (opposite) side of the
spinal cord
Fibers enter the spinothalamic tract and ascend to the thalamus
where they synapse on tertiary neurons
Tertiary neurons – in the thalamus and relay information
to the somatosensory cortex of the cerebrum
Spinoreticular &
Spinomesencephalic Tracts
Ascend with the spinothalamic tract in the
spinal cord
Divert to the midbrain and other brainstem
nuclei
Some neurons of spinoreticular tracts do not
cross over and ascend on the ipsilateral (same)
side
Spinotectal tract – portion of the
spinomesencephalic tract that ends in the
superior colliculi of the midbrain
Transmits action potentials involved in reflexes that
turn the head and eyes toward cutaneous stimulation
 Dorsal-Column/Medial-Lemniscal
System
Consists of two pathways that carry sensations
of two-point discrimination, proprioception,
pressure, and vibration
Travels in the dorsal column of the spinal cord
and medial lemniscus of the brainstem
Dorsal column is divided into
Fasciculus gracilis – conveys sensation from
the lower part of the body, terminates in the
nucleus gracilis of medulla oblongata or with
neurons of the posterior spinocerebellar tracts
Fasciculus cuneatus – conveys sensation from
upper part of the body, terminates in nucleus
cuneatus of the medulla oblongata
 Dorsal-Column/Medial-Lemniscal
System
Primary neurons – in the dorsal root ganglia, have
largest cell bodies
Some primary neurons have axons enter the spinal cord and
ascend the entire length without crossing to the
contralateral side and synapse with secondary neurons in
the medulla oblongata
Other neurons synapse in the thoracic portion of the spinal
cord
Secondary neurons – exit nucleus gracilis and
nucleus cuneatus and cross to the opposite side of
the medulla oblongata at the decussations of the
medial lemniscus
Ascend through medial lemniscus to synapse with tertiary
neurons in the thalamus
Tertiary neurons – project to the primary
somatosensory cortex to the cerebrum
Trigeminothalamic Tract
Join the spinothalamic tract in the brainstem
Primarily consists of afferent fibers from the trigeminal nerve
(CN V), a few tactile afferent fibers from ear and tongue carried
by CN VII, IX, and sometimes CN X
Carries same information as spinothalamic tracts and dorsal-
column/medial-lemniscal system from the face, nasal cavity,
and oral cavity
Primary neurons – synapse with secondary neurons
Secondary neurons – decussate to the opposite side of the
brainstem and synapse on tertiary neurons in the thalamus
Tertiary neurons – project to primary somatosensory cortex
of the cerebrum
 Spinocerebellar Tracts
Carry proprioceptive information to the cerebellum
Compares information concerning actual movements
can be monitored and compared with cerebral
information representing intended movements
Posterior spinocerebellar tract
Carries information from the upper part of the body in
the thoracic and upper lumber regions
Contains uncrossed fibers entering the cerebellum
through the inferior cerebellar peduncle
Anterior spinocerebellar tract
Carries information form lower trunk and lower limbs
Contains both crossed and uncrossed nerve fibers that
enter the cerebellum through superior cerebellar
peduncle
Crossed fibers recross in the cerebellum