Introduction to Nervous System 2024W1 PDF

Summary

This document provides an introduction to the nervous system, covering its functional organization, neuron structure and classification, neuroglial cells, myelin formation, and the principles of establishing resting membrane potentials. The text features learning objectives and a thorough explanation of key concepts.

Full Transcript

Introduction to
Nervous System

Textbook Chapter: 6

Paige Jackson, MPT, MKIN, CSCS
Learning Objectives

Describe the functional organization of the nervous system
Describe the structural and functional classification of neurons
Identify and describe the function of neuroglial cells
Describe the structure, function, and formation of myelin
Describe the regeneration of neurons after injury or interference
Review the basic characteristics of the plasma membrane
Explain the principles underlying the establishment of resting
membrane potential and the concept of equilibrium potential
Functions of Nervous System

Sensing (sensory)

Understanding (integration)

Action (motor / response)
Functional Organization of Nervous System
Central Nervous System (CNS)
Central nervous system Peripheral nervous system

Brain
Peripheral Nervous System (PNS) Somatic Sensory

Afferent Division Visceral Sensory

Special Sensory
Subdivisions within PNS
all have sensory and motor neurons

1. Somatic Somatic Motor
Efferent Division
Spinal Cord
Autonomic Motor
2. Autonomic Sympathetic
Parasympathetic
Enteric

3. Enteric*
Functional Organization of Nervous System
Nervous System Cells

Two main types of cells:

1. Neurons

2. Neuroglial Cells
Neurons: anatomy

Soma – cell body
Dendrites
Long projections from soma
Receive information/signals
Dendritic spines increase surface area

Axon
Long process from soma
Relays information/signals out
Axon hillock
area of neuron that connects soma to axon
Electrical signal initiated here
Axon terminal
End of each branch of the axon
Synapses with another cell (communicates via neurotransmitters)
Neuron Development

Neurogenesis

Neuroprogenitor cells

Neuroblast

Growth cone
Neurons: structural classification
Unipolar Bipolar Multipolar

trigger zone
Neurons: functional classification

Neurons are classified into 3 groups
based on their function:

1. Sensory / Afferent

2. Integrative / Interneurons

3. Motor / Efferent
Nerve vs. Neuron

Neuron is a single nerve cell

Nerve

Epineurium

Perineurium

Endoneurium

àendoneurium vs neurolemma
Nerve – the “funny bone”

Funny bone
Neuroglial Cells
Neuroglial cells are the support cells of the nervous system.

Functions:
Neuroglia cells in CNS: astrocytes

Astrocytes

àblood-brain barrier
Neuroglial cells in CNS: microglial

Microglia
Neuroglial cells in the CNS: ependymal cells

Ependymal cells

By Martin Hasselblatt MD (Own work) [GFDL (http://www.gnu.org/copyleft/fdl.html), CC-BY-SA-3.0 (http://creativecommons.org/licenses/by-sa/3.0/) or CC BY-
SA 2.5-2.0-1.0 (https://creativecommons.org/licenses/by-sa/2.5-2.0-1.0)], via Wikimedia Commons
Neuroglial cells in the CNS: oligodendrocytes

Oligodendrocytes
Neuroglial cells in the PNS: Schwann cells

Schwann Cells
Neuroglial cells in the PNS: satellite cells

Satellite cells
The picture can't be displayed.
Neuroglia Location Function
Type
Forms blood brain barrier. Regulates composition of ECF in
Astrocyte CNS
CNS. Guides neuronal development in embryo.

Phagocyte that protects CNS from pathogens (immune
Microglia CNS
functions). Engulfs bacteria/pathogens, debris, dead cells.

Epithelial cells that line ventricles of brain and central canal.
Ependymal cell CNS
Regulates CSF production.

Oligodendrocyte CNS Form myelin sheath in CNS.

Schwann cell PNS Form myelin sheath in PNS.

Protects and cushions neuron bodies of PNS. Helps maintain
Satellite cell PNS
proper extracellular environment.
The picture can't be displayed.
 Myelin

Formed by neuroglial cells
Oligodendrocytes (CNS)
Schwann Cells (PNS)

Made of lipids and proteins

Provides electrical insulation

nodes of Ranvier

àMyelinated neurons transmit signals much faster than unmyelinated.
Gray vs White Matter
Myelin in the CNS vs. in the PNS
Formation of Myelin
Multiple Sclerosis

Immune system attacks the myelin
sheath and cells that produce it
Axonal Injury & Regeneration – in PNS
Axonal Injury & Regeneration
Central Nervous System

Injuries to spinal cord are often crushing
rather than cutting.
The picture can't be displayed.
Basics of cell membrane review
Transport across the cell membrane
Substrates can cross a cell
membrane in a few ways:

Active methods

Passive methods
Na+-K+ Pump (Na+-K+ ATPase)

Na+-K+ pump manages the balance of sodium and potassium inside and outside of the cell
Pumps Na+ out of cell
Pump K+ into cell
Form of active transport (requires ATP)

NaNa
+ +
Extracellular fluid
Extracellular fluid 33 Na 2K+ +
Na+ expelled
+
gradient
gradient expelled 2K
Na+/K
Na + ATPase
+/K + ATPase

P
P
Cytosol 3 3Na
Na
+ +
Cytosol
ATP 2 K2+ K+
K+ K
+
ATP
gradient PP imported
imported
gradient ADP
11 22 ADP 33 44
Na+-K+ Pump (Na+-K+ ATPase)

Helps to establish and maintain an
electrochemical gradient across
the cell membrane

Electrical gradient

Chemical/concentration gradient
Ion channels: leak channels - passive

Ion channels (or leak channels) allow for
movement of small, charged particles
across the cell membrane.

Integral membrane proteins

Selective
Cell membrane potential (VM)

0 mV
–70 mV +70 mV

0 mV
–70 mV +70 mV

Extracellular Reference Recording
fluid electrode microelectrode

Extracellular Reference Recording
fluid electrode microelectrode

Cytosol
Cytosol

(b) Measurement of the resting membrane potential of a neuron
(b) Measurement of the resting membrane potential of a neuron
Membrane potential (VM)

Separation of electrical charges
across the membrane

The picture can't be displayed.

All cells have resting membrane
potentials

A-
Resting membrane potential
Extracellular fluid Plasma membrane Cytosol
Extracellular fluid Plasma membrane Cytosol

Extracellular
Extracellular
fluid
fluid

Chloride ion
Chloride ion

Sodium ion
Sodium ion
Na+/K+ ATPase
K+ leak channel Na+ leak channel Na+/K+ ATPase
K+ leak channel Na+ leak channel
3 Na+
3 Na+

Resting
Resting
membrane
membrane
potential
potential

Cytosol
Cytosol
ATP 2 K+
ATP 2 K+
Phosphate ion
Phosphate ion ADP
ADP
Protein
Protein

Potassium ion
Potassium ion
Membrane potential (VM)

Membrane potential depends on:
Concentration gradients of K+ and Na+
High [Na+]
Relative permeability of K+ and Na+
Low [K+] Extracellular

At rest, the cell membrane is:
More permeable to K+
Less permeable to Na+

Low [Na+] Intracellular
High [K+]
Summary

Central vs. peripheral nervous system
Nerve cells (neurons) – structure and classifications
Where nerve impulses are initiated
Direction of nerve impulse conduction

Glial cells (CNS and PNS) and their functions
Myelin in the CNS vs. PNS

Neurophysiology: fundamental concepts
Interaction of passive and active factors that establish resting membrane potential
Neuronal Signaling and
Communication

Textbook Chapter: 6

Paige Jackson, MPT, MKIN, CSCS
Learning Objectives

1. Define and explain the mechanisms underlying action potentials
and their propagation
2. Describe the events at a chemical synapse
3. Explain the concepts of synaptic integration (spatial and
temporal summation)
4. Describe the action of some neurotransmitters and their
receptor action, and whether they cause EPSPs or IPSPs
5. Define and explain the mechanisms underlying graded
potentials
Membrane Potential – definitions review
Resting membrane potential: the electrical potential difference across the cell
membrane of an unstimulated cell (i.e. a cell at “rest”)
Polarization:
Depolarization:
Repolarization:
Hyperpolarization:
Overshoot:

Permeability: the ability of a substance or barrier to allow for molecules to pass
through it

Equilibrium potential: the membrane potential when the concentration and electrical
potential of an ion are equal and opposite in magnitude

Current: when charged particles flow in a new direction
Definitions cont’d…
Membrane potential can change …

depolarization

repolarization
hyperpolarization
Action Potentials

An action potential is a rapid
depolarization of the membrane potential,
followed quickly by repolarization and re-
establishment of the resting membrane
potential.
Action potential has 3 phases:

Rising Falling After-hyperpolarization
Action potential: all-or-none phenomenon

-70 mV
some stimulus
Action potential: all-or-none phenomenon

-70 mV
some stimulus
Action potential: Rising Phase

+30 mV peaks at +30 mV

Na+
PEN
ted
cha age-ga
ls O
nne
t
vol
-55 mV critical threshold
-70 mV
Action potential: Falling Phase

meanwhile …
Voltage-gated K+ channels also
triggered OPEN at -55 mV (but
+30 mV more slowly)

voltage-g
channels
ated K+
OPEN
-70 mV
Action potential: After Hyperpolarization

voltage-gated K+ channels also
+30 mV slow to close

all closed K+
Voltage-gated
channels still
-70 mV closing …
Na+ channels: Resting State

Extracellular fluid Plasma membrane Cytosol

At resting membrane
potential, the Na+
channel activation gate
is closed.

mV

Time
Na+ channels: Activation

A depolarizing stimulus arrives at the
channel – Na+ activation gate opens.

Na+

mV

Time

K+
Na+ channels: Inactivation

mV

Time Inactivation gate closes
Na+ and Na+ entry stops. K+
channel meanwhile has
opened.

K+
Na+ channels: Resetting

Na+

K+

During repolarization, the activation and
mV
inactivation gates of the voltage-gated
Na+ channel reset to their original
positions
Time
Refractory Period

larger than normal stimulus is
second action potential required to trigger another action
cannot be triggered potential
absolute relative
refractory period refractory period

action potentials will action potentials CAN fire
NOT fire
Refractory Period

Membrane potential (mV)
Stimulus strength

Absolute Relative refractory period
refractory period
Action potentials do not lose strength with distance
Conduction of action potentials
 direction of propagation

X
why doesn’t the action potential propagate backward?
refractory period prevents firing of another AP
Factors influencing speed of action potentials

Two main influences on conduction speed:

1. Axon diameter

2. Myelin (Insulation)
Factors influencing conduction speed of action potentials

axon diameter
­ diameter à ¯ resistance
Myelin: Saltatory Conduction
myelinated sections - current flows quickly
with minimal leak
nodes of Ranvier - depolarization opens Na+
channels and AP is replenished

to node
‘leaping’ from node

high concentration of Na+
fewer ion channels
and K+ channels
Factors influencing the speed of conduction

diameter myelinated?
fastest

A fibers 5-20 μm yes

B fibers 2-3 μm yes

C fibers 0.5-1.5 μm no slowest
Graded Potentials

Graded potential is a small, local change
in membrane potential.

Decremental signal strength
Graded potentials vary in size

the size (amplitude/duration) of a
graded/synaptic potential is
related to the size of the stimulus
Where do graded potentials occur?
motor end plates
dendrites of interneurons
dendrites of motorneurons

sensory receptors sensory transduction
– dendritic ends of sensory neurons (receptor membrane) To CNS
– receptor cells
Receptor Afferent
Stimulus
membrane neuron

To CNS

Receptor Vesicle containing
cell neurotransmitter
Cell-to-cell Communication: the Synapse

Synapse is the junction between neurons (or between neuron and another cell)

neurons can connect with:

electrical synapses (gap junctions)
chemical synapses
Synapses

A synapse has three parts:
1. pre-synaptic neuron
2. synaptic cleft
3. post-synaptic cell

Convergence:

Divergence:
Chemical vs. Electrical Synapses

Chemical synapses

Electrical synapses
Chemical Synapse events
1. Action potential arrives at synaptic
bulb

2. Voltage-gated Ca2+ channels open

3. Ca2+ enters synaptic bulb and
triggers exocytosis of
neurotransmitters from synaptic
vesicles into the synaptic cleft

4. Neurotransmitters diffuse across the
cleft and attach to receptors on
postsynaptic membrane

5. Ion channels on postsynaptic
membrane open (neurotransmitters
removed from cleft)

6. Postsynaptic potential generated
Postsynaptic Activation

Ionotropic receptors a

Metabotropic receptors
Synaptic activation is one-way

Neurotransmitter
is released and
diffuses into the
cleft

Neurotransmitter
Neurotransmitter binds removed from
to postsynaptic receptors synaptic cleft
à post-synaptic potential (PSP
Neurotransmitter Removal

Neurotransmitters are removed from the synaptic
cleft in a variety of ways:
1.

2.

3.

4.
Excitatory Post Synaptic Potentials (EPSP) Inhibitory Post Synaptic Potentials (IPSP)
Excitatory and inhibitory synapses

EPSPs
Depolarizing/excitatory activity

IPSPs
Hyperpolarizing/inhibitory activity
Synaptic Integration

Spatial summation of post-synaptic
potentials is one way threshold is
achieved.
Synaptic Integration

Temporal summation also
contributes to reaching
threshold potential.
Integration of Graded Potentials/Synaptic Integration
Integration of Graded Potentials:

https://www.youtube.com/watch?v=ZnC8v9Dl_O4
Drug and Disease Modification of Synaptic Transmission
Some Neurotransmitters

Acetylcholine (ACh)
Neurons that release ACh are called cholinergic neurons

Catecholamines
Group of neurotransmitters that contain specific molecular structure
Dopamine:
Norepinephrine:
Epinephrine:
Serotonin
Excitatory pathways
Inhibitory pathways

Glutamate

Gamma-aminobutyric acid (GABA):
Resetting the Na+/K+ balance after an AP

The Na+-K+ ATPase channels continuously work to maintain ‘proper’ or
resting levels of sodium and potassium on either side of the cell membrane
After an AP passes through, there is more Na+ inside at the cell membrane
and more K+ outside at the cell membrane than there was prior to the AP
passing
These active transport pumps move Na+ and K+ against the concentration
gradient and back to their initial resting state locations (i.e. Na+ outside and
K+ inside) Na +
Extracellular fluid
gradient 3 Na+ expelled 2K+
Na+/K+ ATPase

P
3 Na+
Cytosol
K+ ATP 2 K+
gradient ADP P imported
1 2 3 4
Resetting the Na+/K+ balance after an AP
Sodium enters the protein, ATP binds at a specific binding site on the protein that
hydrolyzes it with ATPase into its components of ADP + Pi + Energy
The energy causes the protein to change shape and ‘open the gate’ on the
extracellular side of the membrane, thus releasing the Na+ back out
Potassium then enters the protein channel and triggers it to rest back to it’s
original position, thereby opening the gate on the inside of the cell, where the
potassium can return to the intracellular fluid
Initial concentration gradient is re-established and ready for next AP

Na+ Extracellular fluid
These pumps can gradient Na+/K+ ATPase
3 Na+ expelled 2K+

catch up with the [Na]
because the voltage-
gated Na ion channels
have closed so no new
sodium is coming in P
3 Na+
Cytosol
(peak of AP) K+ ATP
P
2 K+
gradient 1 2 ADP 3 4 imported
Summarized steps of AP:
1. Adequate summation of graded potentials at axon hillock causes the membrane
potential to shift from -70mV to the critical threshold of -55mV
2. At -55mV voltage-gated sodium channels open and positively-charged sodium floods
into the cell causing a rapid depolarization of the cell membrane
3. Voltage-gated potassium channels are also triggered open, but they do so more
slowly. They fully open by the time the membrane potential reaches +30mV
4. The escape of positively-charged potassium from inside the cell causes a rapid
repolarization of the cell membrane
1. At the same time, the inactivation gates in the sodium channels have closed, blocking more sodium
from crossing into the cell
5. The potassium channels are slow to close, and the cell membrane is more permeable
to potassium (aka lots of potassium can leave the cell) so the cell membrane is
hyperpolarized momentarily à during this time a stronger signal is required for
another action potential to fire
1. Sodium channels are reset by this time, ready for the next AP
6. Active Na+-K+ ATPase pumps work to reset the initial, resting concentrations of Na+
and K+ on the outside and inside of the cell, respectively.
 Na+ Extracellular fluid 2K+
3 Na+ expelled
gradient Na+/K+ ATPase

P
Cytosol 3 Na+
K+ ATP 2 K+
1 2 ADP 3 P 4 imported
gradien
t
Central Nervous System &
Sub-cortical Areas

Textbook Chapter: 10

Paige Jackson, MPT, MKIN, CSCS
Nerve vs Neuron (review)

Nerve is a group of axons plus
connective tissue wrappings and
blood vessels.

Neurons are the functional
unit/cell of the nervous system.

Pathways/tracts:

àcommissures:
The Central Nervous System
The central nervous system is comprised
of the brain and the spinal cord.

Brain has 3 major divisions:
1. Forebrain
Cerebrum
Diencephalon
2. Midbrain

3. Hindbrain
Pons
Medulla oblongata
Cerebellum
Cerebrum

The cerebrum is the largest part of the
brain.

gyri (or gyrus, sing.):

sulci (sulcus, sing.)

fissures
Cerebrum

The cerebrum is divided into four lobes:

1. Frontal

2. Parietal

3. Occipital

4. Temporal
 central
sulcus
precentral postcentral
gyrus gyrus

[
[
parieto-occipital
sulcus

Lateral cerebral
sulcus
 muscles,
movement
control

sensation

vision
‘executive’
functions

Insula - taste, smell
hearing, memory
acquisition
different brain regions perform different functions
Cerebral Cortex - function

àfunctions of cortex can be mapped

primary motor area primary somatosensory area

Primary areas: mediate the actual function

Secondary areas: apply meaning (also
called association areas) primary
visual area
primary gustatory area primary auditory area
primary olfactory area
Cerebrum

Primary Somatosensory Areas

primary somatosensory area
somatosensory association area

Somatosensory Association Area
Cerebrum

Primary Motor Area
primary motor area
motor association area
(premotor cortex)

Motor Association Area (premotor cortex)
Cerebrum

Primary Auditory Area

primary
visual area

Auditory Association Area
visual association
area
primary auditory area
Primary Visual Area auditory association area

Visual Association Area
Cerebrum

Primary Olfactory Area

Secondary Olfactory Area

Primary Gustatory Area primary gustatory area
primary olfactory area

Secondary Gustatory Area
Cerebrum

Prefrontal Cortex (prefrontal
association area)

prefrontal
association area
 old/young lady

identical visual input but 2 different perceptions
Control of Movement in the Cerebrum

PRIMARY MOTOR AREA
motor execution

PREMOTOR AREA
motor planning
(association area)
Homunculus

Homunculus
https://learnsomatics.ie/how-your-brain-sees-your-body/
Basal Nuclei

Basal nuclei are subcortical structures.

Main functions:
Basal Nuclei – understanding function

Parkinson Disease
Hypokinetic movement disorder

Treatment: L-Dopa
Basal Nuclei – understanding function

Huntington’s Disease
Hyperkinetic movement disorder
Limbic System

The limbic system is a functional system.

Comprised of:
Nuclei in different parts of the brain and the tracts
that connect them
Hippocampus
Amygdala
Thalamus
Hypothalamus

Main Functions:
Thalamus (part of diencephalon)

Thalamus is a cluster of nuclei that sends
and receives information to/from the cortex

Flow of info:

Diencephalon
Hypothalamus (part of diencephalon)

Hypothalamus is the master command
centre for neural and endocrine
coordination.

Connects to the pituitary gland
Brainstem

Brainstem consists of four parts:
1. Medulla oblongata
2. Pons
Midbrain
3. Midbrain
4. Reticular formation*

General functions of brainstem:
Brainstem: Medulla (oblongata)

Medulla

Control centres found in the medulla:
Cardiovascular centres

Respiratory rhythmicity centres

Reflex centre
Brainstem: the pons

Pons
Brainstem: midbrain

Midbrain
Brainstem: Reticular Formation

Reticular formation is a network of cells
extending through the brainstem.
Reticular Activating System

Reticular activating system is an aspect
of the reticular formation.

When we are awake:

When we are asleep:

Damage leads to prolonged coma.
Cerebellum

Cerebellum

Key Functions:
Balance control Movement Coordination
Damage to cerebellum

Ataxia:
Dysmetria

Dysdiadochokinesia
Spinal Cord

Spinal cord extends from the brain and
relays signals between the brain and the PNS.

31 pairs of nerves, from each segment

Divided into five sections:
Cervical (8 segments)
Thoracic (12 segments)
Lumbar (5 segments)
Sacral (5 segments)
Coccygeal (1 segment)
Spinal Cord

Conus medullaris =

Filum terminale =

Cauda equina =

http://www.nlm.nih.gov/medlineplus/ency/imagepages/19504.htm
Spinal Cord

Contains white matter and gray matter

Spinal nerves
Posterior ramus
Anterior ramus
POSTERIOR

ANTERIOR
Sensory (ascending) tracts

Motor (descending) tracts
Dermatomes & Myotomes

Dermatomes =

Myotomes =
Spinal Cord Injuries

C1

Cervical
segment

C7
T1

Thoracic
segment

T8
T9
Lumbar
segment
T11
T12
Sacral
segment
L2
 Protecting the Central
Nervous System

Textbook Chapter: 6

Paige Jackson, MPT, MKIN, CSCS

© Pia McDonell of McDonell Media
Protecting the Central Nervous System

3 main ways CNS is protected:
1. Meninges
2. Cerebrospinal Fluid
3. Blood Brain Barrier

other ways…
Meninges

Meninges

Three Layers:
1. Dura mater
2. Arachnoid Mater
3. Pia Mater

àsubarachnoid space
Meninges

Dura mater

Arachnoid mater

Pia mater
Meninges at the spinal cord
Meningeal Extensions
falx cerebri

tentorium
cerebelli

Falx cerebri

Falx cerebelli

Tentorium cerebelli
falx cerebelli
Meningitis

Meningitis
Head Bleeds

Head Bleeds
Epidural hematoma

Subdural hematoma

Subarachnoid hemorrhage
Cerebrospinal Fluid (CSF)

Cerebrospinal fluid (CSF)
àchoroid plexus

Functions:
CSF Flow Superior sagittal sinus
(CSF drainage)

LATERAL VENTRICLES

interventricular foramina
of Monro

cerebral aqueduct
THIRD VENTRICLE
SUBARACHNOID SPACE
(surrounding brain)

lateral aperture (to subarachnoid
FOURTH VENTRICLE space)

CENTRAL CANAL
median aperture (to central canal)

SUBARACHNOID SPACE
(surrounding spinal cord)

(c) Frontal section of brain and spinal cord
CSF Drainage

Superior
sagittal sinus
Frontal plane

Skin

Parietal bone of
Periosteal layer cranium

CRANIAL MENINGES
Meningeal layer
Arachnoid villi Dura mater
Subarachnoid
space Arachnoid mater

Arachnoid villus Pia mater

Cerebral cortex
Falx cerebri

(a) Anterior view of frontal section through skull showing the cranial meninges
Spinal taps / Lumbar punctures
 http://www.nlm.nih.gov/medlineplus/ency/presentations/100123_2.htm

Hydrocephalus
Hydrocephalus is a condition where CSF
accumulates.

https://njpediatricneurosurgery.com/services-specialties/hydrocephalus-center/
Blood Brain Barrier

Functions:
Blood Brain Barrier

tight junctions

endothelium
(blood vessel wall)

astrocyte

It is the features of the microvasculature in the brain
that creates the BBB à is it ‘leaky’ anywhere? http://commons.wikimedia.org/wiki/File:Astrocyte_endothel_interaction_01.png
 Peripheral Nervous System
Sensory Physiology (General)
& Spinal Reflexes

Chapter 7.1,7.2,7.5
Peripheral Nervous System

The peripheral nervous
system is the nervous tissue
outside of the brain and the
spinal cord.

https://step1.medbullets.com/neurology/113074/muscles-innervated-by-cranial-nerves
Peripheral Nervous System

It can be divided into:

Afferent pathways
Somatic sensory
Visceral sensory
Special sensory

Efferent pathways
Somatic motor
Autonomic motor
Sensory Receptors

Sensory receptors detect
information from our internal and
external environments.
Sensory Receptors

Categorized by:
Source of stimulus
Exteroceptors –
Proprioceptors –
Enteroceptors –

Mode of detection
Chemoreceptors
Thermoreceptors
Photoreceptors
Mechanoreceptors
Nociceptors
General vs Special Sensory Receptors

General senses:

Special Senses:
Sensory Transduction: receptor potentials

Sensory transduction is the
translation of a stimulus into a
potential (electrical signal).
Sensory Transduction

Magnitude of receptor potential
determines the frequency of action
potentials, but not the amplitude.

Frequency =

Factors that affect magnitude of
receptor potential:
Sensory Receptors

Receptors display adaptation.

Fast adapting receptors aka phasic
receptors

Slow adapting receptors aka tonic
receptors
The Sensory Unit

Central nervous system
Skin
sensory unit

receptive field

Flow of information
Sensory Coding

Sensory coding

https://www.childoftheredwoods.com/articles/blindfold-activity
Sensory Coding: type

Type/modality
Sensory Coding: location

Overlapping receptive fields Lateral inhibition Convergence

Action potentials
in postsynaptic cell

Postsynaptic
cell

Axons of
afferent neurons

A B C
Action potentials
in afferent neuron
Sensory Coding: intensity

The intensity of sensory information
is determined by frequency and
population

Frequency coding

Population coding
General Senses: touch

Mechanoreceptors in the skin
allow for the sensation of touch
and pressure.
General senses: touch
Touch & Pressure Receptors (6):
1. Meissner’s corpuscles

2. Merkel cells

3. Pacinian corpuscles

4. Ruffini corpuscles
General senses: touch

5. Free nerve endings

6. Root hair plexuses
General Senses: pain

Stimulation of nociceptors activated
by real or potential tissue damage

Myelinated type A fibres

Unmyelinated type C fibres
Referred pain?
General senses: temperature

Thermoreceptors respond to
heat or cold.
General senses: proprioception

Proprioception is our awareness
or perception of our body’s position
and movement.
General senses: proprioception

Muscle spindle stretch receptors
are located in skeletal muscles.
General Senses: proprioception

Golgi tendon organs are located in
tendons of muscles.
Muscle and tendon receptors:
Spinal reflexes

Spinal reflexes are automatic motor
responses to a sensory stimulus.
Stretch Reflex

Stimulus:
Receptor:

Effects:
GTO Reflex: tension-monitoring system

Stimulus:

Receptor:

Effect:
Muscle Cramps

Are muscle cramps due to reduced
GTO inhibition?

Calf cramp while swimming
Muscle cramps

Passive stretching to treat cramps?
Flexor (withdrawal) and crossed extensor reflex
To brain

Stimulus:
Afferent nerve
fiber from
Receptor: nociceptor

Effects:
Ipsilateral
extensor
muscle Contralateral
relaxes flexor muscle
relaxes

Ipsilateral Contralateral
flexor muscle extensor muscle
contracts contracts

Begin
Nociceptor
 Peripheral Nervous System:
Autonomic Nervous System

Chapter 6.18

https://www.christopherreeve.org/todays-care/living-with-paralysis/health/secondary-conditions/autonomic-dysreflexia/
Autonomic Nervous System

The autonomic nervous system is
part of the PNS.

Divided into three components:
1.
2.
3.
Somatic Nervous System vs Autonomic Nervous System
Somatic vs Autonomic Nervous System

Somatic (SNS) - motor

Autonomic – motor
Sympathetic Division: fight or flight

The sympathetic division of the
ANS readies our bodies to react to
stress or a threat.
Response:

Stimuli
Parasympathetic Division: rest & digest

The parasympathetic division of
the ANS facilitates rest and
recovery.

Response

Stimuli
Dual Innervation Sympathetic Response Parasympathetic
Response
Pupils Dilation Constriction

Digestion Inhibited Activated

Metabolism Catabolism Anabolism

Cardiovascular (HR & BP) Increased Decreased

Muscle Tone Increased Decreased

Respiration Increased Decreased

Temp & Sweating Increased Decreased

Urinary Function Decreased Increased

Alertness Increased Decreased
Sympathetic Nervous System

Preganglionic neurons

superior cervical ganglion
sympathetic trunk
middle cervical ganglion
inferior cervical ganglion

sympathetic chain
cervical ganglia

T1-L2
Sympathetic chain/trunk
Sympathetic Cervical Ganglia

Superior cervical ganglion

Middle cervical ganglion

Inferior cervical ganglion

àproject to structures in the
head and neck, as well as the
heart & lungs
Parasympathetic: Craniosacral division
ciliary
ganglion

Preganglionic neurons pterygopalatine
ganglion
submandibular
CN X ganglion

otic ganglion
Ganglia are located near or on the
wall of the target organs.

4 pairs in the head
3 pairs in the sacrum
Parasympathetic ganglia

The 4 pairs in the head are closely
connected to certain cranial nerves.

Ciliary ganglion

Pterygopalatine ganglion

Submandibular ganglion

Otic ganglion
Parasympathetic: CN X – vagus nerve

Vagus nerve (CN X) makes up
75% of parasympathetic NS.
Autonomic vs Somatic Nervous System: activation

Somatic NS acts on
skeletal muscle cells
with acetylcholine.

Parasympathetic
neurons release
acetylcholine.
Autonomic vs. Somatic Nervous System: activation
Preganglionic neurons release
acetylcholine in the sympathetic
nervous system.

Postganglionic neurons in
sympathetic NS release
norepinephrine.
Autonomic vs Somatic NS: Activation

Sympathetic neurons
also synapse with the
adrenal medulla.
Endocrine response in sympathetic system

Epinephrine released from the
adrenal medulla causes:
Neuroplasticity: a quick look
 Frontal plane through

recall: homunculus postcentral gyrus

Hip
Trunk
Nec d
Hea ulder
Shorm
A
Fore t
Elbo rm

k
W and
Leg

ris
H
Li

a
Foot

w
Ri ttle Toes
M ng
i
In ddle Genitals
de
Th x
um
Eye b
No
se
Fac
e
Upp
er li
p
Lips
Low
er li
p
Teeth
, gum
s, and
jaw
n g ue
To
ryn
x inal
Pha abdom
a
Intr

(a) Frontal section of primary somatosensory area
in right cerebral hemisphere
plasticity following injury

L face
R face L hand
R upper arm
L upper arm

(R arm amputated
below elbow)

Ramachandran, Plasticity and functional recovery in neurology. Clin Med 2005
Ramachandran & Rogers-Ramachandran. Phantom limbs and neural plasticity. Arch Neurol 2000
plasticity with training
Einstein’s brain

the ‘knob’ or ‘Omega sign’ –
𝛀 indicative of motor cortical
representation of the hand

Falk et al. Brain 2013
Corey Rich Productions/Novus Select
https://www.si.com/edge/2017/05/16/the-push-book-rock-climber-tommy-caldwell-finger
free study tip: exercise promotes learning
Break:

or: exercise break OR

non-exercise break OR

no break

mind-wandering (MW) “Which of the following responses best characterizes your
questionnaire: mental state just before this screen appeared?”
(1) on task
(2) intentionally mind wandering
(3) unintentionally mind wandering
free study tip: exercise promotes learning
“Which of the following responses best characterizes your
mental state just before this screen appeared?”
(1) on task
(2) intentionally mind wandering
(3) unintentionally mind wandering Test score 48-hrs later compared to
immediately after
Midterm info:
Friday Nov 8
12pm
45 minutes
MC/Short written

Same general rules as before (re: no hats, bags front, no smart
devices, etc.)

Bring pencil and student ID