Human Physiology BIOL3205 PDF

Summary

This document is a set of lecture notes on Human Physiology BIOL3205, covering sensory and motor nervous systems. The notes detail the general properties of these systems, along with pain and analgesic systems, and the structure of the peripheral nervous system.

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Human Physiology
BIOL3205
Sensory and motor nervous
systems

Prof. Chi Bun Chan
School of Biological Sciences
5N10 Kadoorie Biological Sciences
Building
[email protected]
39173823
 Lecture outline
General properties of the sensory and motor nervous system
Sensory receptors
Sensory coding
Pain and analgesic systems
Structure of the peripheral nervous system
(Para)Sympathetic nervous system
Reflex
 Why we can sense the world?
Achieve through the functioning of
sensory systems
Depends on special receptors that
can detect specific forms of energy
(e.g. light vs X-ray)
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Perception – the conscious
interpretation of the world based
on the sensory system, memory,
and other neural processes
Perceptions of the stimuli are not
absolute (e.g. water temperature of
the swimming pool)
 General properties of sensory system
Sense – a detection of stimulus (in the form of
physical energy)
Special senses – vision, hearing, taste, smell, and body
balance (special sensory system)
Somatic senses – touch, temperature, pain, itch, and
proprioception (Somatosensoty system)
Proprioception – awareness of body movement and
position in space
Sensory system can either be complex or simple
Single sensory neurons (pain)
Sense organs (ear and eye)
Sensory receptor (action potential firing) →
integration center (CNS) → conscious perception or
subconscious (without awareness)
 Classification of neurons
Classification according to functions
Afferent neurons
Somatic afferent
Visceral afferent
Interneuron
99%
All in CNS
Efferent neuron
 Sensory receptors and unit
Sensory receptors – specialized structures that
detect a specific form of energy from the Temperature Pressure Light
environment
Sensory receptor vs protein receptor
Can be nerve ending or separated cells
Sensory unit - single afferent neuron + receptor
Receptor field – an area over which an adequate

Sensory unit
stimulus can produce a response in the afferent
neuron
Types of receptors
Photoreceptor (light)
Chemoreceptor (chemical)
Thermoreceptor (temperature)
Mechanoreceptor (pressure)
Proprioceptor (gesture) Simple Complex Special sense
receptor receptor receptor
Nociceptor (damage/pain)
 Sensory transduction in neural
Sensory transduction – converts pathways
a sensory stimulus (modality)
into changes in member
potential (receptor potential)
Nerve ending → threshold → AP
action potential → CNS
Cells → transmitter → threshold of AP GP
neuron → action potential → CNS
Started as graded potential
Receptor adaption – a decrease
over time in the magnitude of
GP
the receptor potential in the
presence of a constant stimulus
1st, 2nd, and 3rd-order neurons
 Sensory coding
Sensory coding is an information
processing that differentiates the type,
strength, and location of the sensory
stimulus 3rd order 3rd order 3rd order
Sensory type is coded by the activated neuron neuron neuron

receptor and pathway when the stimulus is
applied. 2nd order 2nd order 2nd order
Misperception will be formed if a pathway is neuron neuron neuron
activated by non-specific stimuli
Perception of stimuli is not necessarily 1st order 1st order 1st order
based on a single sensory pathway but on neuron neuron neuron

a combination of pathway
Combination of pathways
Stimulus intensity
Stimulus location (acuity)
 Sensory coding
Frequency coding

Sensory coding differentiates the type,
strength, and location of the stimulus
Stimulus type
Misperception
Combination of pathways
Stimulus intensity Population coding
Frequency coding – frequency of AP
Population coding – no. of receptors activated
Stimulus location (acuity)
 Sensory coding
Sensory coding differentiates type,
No. of mechanoreceptors
strength and location of the stimulus ~ 400
~ 17,000
Stimulus type (1 mm)
(5 cm)

Misperception
Combination of pathways
Stimulus intensity
Frequency coding – frequency of AP
Population coding – no. of receptors activated
Stimulus location (acuity)
week
=> strong
or

Receptive field – area over which an adequate
stimulus can produce a response in the
afferent neuron
in a region
Time difference in generating action potential
 Sensory coding
Sensory coding differentiates type, strength
and location of the stimulus
Stimulus type
Receptors and pathway
Misperception
Combination of pathways
Stimulus intensity
Frequency coding – frequency of AP
Population coding – no. of receptors activated
Stimulus location (acuity)
Receptive field – area over which an adequate
stimulus can produce a response in the afferent
neuron
Size of receptive field – size α 1/acuity
Time difference in generating an action potential
 Thalamus
Thalamus is the “relay
station” for preliminary
processing of sensory input
Screens out insignificant
signals and routes the
important sensory impulses
to appropriate areas of the
somatosensory cortex
E.g. Parents in response to a
crying baby
Cannot distinguish the signal
intensity and location
 Physiology of pain
Classified according to
Duration - Fast pain (sharp pricking
sensation) vs slow pain (poorly
localized, dull aching sensation)
Location – referred pain
Indicates tissue damage
Avoids subsequent encounters with
potential damaging stimuli
Initiated by nociceptors
Mechanical nociceptors - cutting
Thermal nociceptors - temperature
Polymodal nociceptors - chemicals
 Endogenous analgesic
pathway
Pain pathways have different
destinations in the cortex, thalamus, and
reticular formation → not a single “pain
center”
Substance P is the major
neurotransmitter for the pain pathway
Built-in pain suppressing (analgesic)
system
Interneruons in the spinal cord releases
endogenous opioid (endorphins), which
acts on the opiate receptors to inhibit
the release of substance P
Morphine is a powerful analgesic
 Morphine as an analgesic
Morphine
Opioid

Opium poppy

Opium
Opioids are substances that act on
opioid receptors
Morphine is a type of opioid
Pain killer
Why rubbing the hurt site?
Sensory information can be modulated to affect
the final perception
Done at the synapse of neural pathway
Gate-control theory – Somatic signals of
nonpainful sources can inhibit signals of pain at
the spinal level
Inhibitory interneuron modulates the signal
transmission along the nociceptor pathway
Simultaneous nonpainful mechanical stimulation
activates the inhibitory pathway
Transcutaneous electrical nerve stimulation
(TENS)
 2nd

Can we sense the damage
neuron

of internal organ?
Referred pain – activation of nociceptors in
the viscera
1st order
pain perceived at a location other than the site neuron
of the painful stimulus/ origin
Misinterpreted as pain from the body
surface (‘referred”)
E.g. Heart attack
Caused by the common 2nd order neuron
that receives the same input from two 1st
order neurons
Mixed with past-experience
 Classification of neurons
Classification according to function
Afferent neurons Inhibitory
neuron
Somatic afferent
Visceral afferent
Interneuron
99%
All in CNS
Efferent neuron
 Peripheral nervous system (PNS)
PNS controls muscle and glands
Somatic nervous system – voluntary action (muscle)
Autonomic nervous system – involuntary actions

·
(smooth muscle, glands)
Sympathetic nervous system (thoracic and lumbar
origin)
Parasympathetic nervous system (cranial and
sacral)
Dual innervation – exert opposite effects in a particular
organ
Systemic level – increases the activity of one organ but
reduces the activity of the other organ
Two-neuron chain – Preganglionic fiber, postganglionic
fiber
Ganglion – a cluster of neuronal cell bodies outside the
CNS
Organization of PNS
Locations of sympathetic and
parasympathetic ganglion
Parasympathetic
ganglion
 Anatomical comparison of sympathetic
and parasympathetic system
Origin Achtylcholzu

Location of ganglion
Length of pre- and
Thoracic and Lumbar
Norepinephrine

post-ganglionic fiber
Neurotransmitter
=> into
blood
vessel
Cranial and sacral

Auto
 Functional characteristics of
autonomous nervous system
Both systems are partially active (sympathetic or
sympathetic tone) under the basal status
The two systems are reciprocally controlled (increase
of one system, decrease of another)
Sympathetic fiber firing ↑ - sympathetic dominance
Parasympathetic fiber firing ↑ - parasympathetic
dominance
Sympathetic dominance – prepare for an emergency
or stressful situations (Fight-or-flight)
Parasympathertic dominance – for general
housekeeping (rest-and-digest)
Precise control of the organ’s activity (accelerator
and brake)
 Comparison of types of neurons
↑

F
I J

(https://www.slideshare.net/ShubhamRoy10/ans-sympathetic-and-
parasympathetic)
 Control of autonomous
nervous system
Prefrontal cortex (Fight or flight)
Hypothalamus is a collection of nuclei that
integrates the homeostatic functions (internal
environment)
Links autonomous system and the endocrine
system
Controls – body temp, thirst and urine, food
intake, pituitary hormone secretion, uterine
contraction, and milk production, smooth
muscle contraction, emotion, sleep-wake cycle
Limbic system (cortex, basal nuclei, thalamus,
hypothalamus) - emotion
Medulla
Pons
Limbic system
Spinal cord
 Consistent and predictable Reflex Withdrawal reflex

Response that occurs automatically without conscious
effort
Cranial reflex (integrated by the brain)
Hypothalamus/brain stem-initiated response (e.g. pupil dilation)
Spinal reflex (integrated by spinal cord)
withdraw reflex
Can be overrided by the cortex
Innate (simple or basic) vs conditioned (a result of
learning) reflex Stretch reflex

Reflex arc – the neuronal pathway that controls reflex
Somatic reflex arc (motor neurons to skeletal muscle)
Visceral reflex arc (autonomic nervous system to smooth
muscle)
Monosynaptic vs polysynaptic reflex
Not every reflex activity involves a reflex arc
Hormone response X
Local response: blood pressure Y
 Basal nuclei
Voluntary movement involves the cortex,
thalamus, basal nuclei, and cerebellum
Basal nuclei masses of grey matter located deep
within the cerebral white matter
Functions
Inhibiting the muscle tone throughout the body
Suppressing the useless, unwanted patterns of
movement
Helping and monitoring slow and sustained muscle
contractions related to posture and support
Network of the motor cortex, thalamus, and basal
nuclei
Cortex – initiates the movement
Thalamus - reinforces the motor behavior
Basal nuclei – exerting inhibitor effect on the thalamus
Cerebellum - posture
Parkinson’s disease - gradual destruction of
neurons that release dopamine in the basal nuclei
 Summary
General components of sensory and motor nervous systems
Sensory signal transduction and integration
Pain and analgesic systems
Structural and functional differentiation of the sympathetic and
parasympathetic nervous system
Reflex actions
Neural pathway of voluntary movement