PSIO 201 Human Anatomy & Physiology I Lecture 4.1 - DRAFT PDF

Summary

These are lecture notes for PSIO 201 Human Anatomy & Physiology I covering the introduction to the nervous system. They have learning objectives, an overview of the nervous system, and discussions on nervous tissue, neuroglia.

Full Transcript

PSIO 201 – Human Anatomy & Physiology I

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 Where We’re Going
Nervous System Intro
Organization
Neuroglia
Neurons

The Brain
Meninges
Cerebrospinal fluid
Blood-brain barrier https://www.art.com/products/p22109264058-sa-i7587847/robert-mcneil-hippocampal-neuron-fluorescent-micrograph.htm

Ch. 12, 14
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 Lecture 4.1 Learning Objectives
1.Describe the general functions of the nervous system.
2.List and describe the divisions of the nervous system and describe how the
different divisions interact with each other.
3.Describe the role of neurons and neuroglia in the nervous system and their
interdependence in terms of function.
4.Describe the difference between nucleus/ganglion and tract/nerve in the context
of the nervous system.
5.Describe the organization of the cerebrum in terms of gyri, sulci, hemispheres,
lobes, and gray and white matter.
6.Describe the function of the meninges, their arrangement around the brain, and
the spaces formed between the layers of the meninges.
7.Describe the composition, functions, and location of cerebrospinal fluid.
8.Describe the blood-brain barrier (BBB) and its components.
 The Nervous
1 1 i 11 System

Major function: coordinate activity to maintain homeostasis

brain Ynal
cord

i bones joints
guts

Fig. 12.1, 12.2 5
 The Nervous System

Fig. 12.1, 12.2 6
 Nervous Tissue
issue
Dense tissue made of two special cell types:
Neurons
Respond to stimuli canfunction
Transmit electrical signals w neurogliacells
Neuroglia
Support cells
Critical and necessary for normal function

7
 Neuroglia
Support staff of the nervous system
regulatory physically

10X as many neuroglia as neurons

Provide physical & regulatory support

Communicate with neurons
onhowtocarryoutfunction

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 Oligodendrocytes
forms myelin sheath
multiple
hf nglff
from
Cytoplasmic extensions wrap around axons → myelin
sheath
Insulates axon
Greatly increases speed of electrical signals
Key part of white matter
critical

Fig. 12.6, Table 12.1 http://tesarlab.case.edu/sites/default/files/styles/me 9
dium/public/news/image/Oligos.png?itok=nceYyikQ
 Ependymal Cells
Lines cavities of brain (ventricles) and central canal of spinal cord
Separates fluid cavities filled with cerebrospinal fluid (CSF) fromotherdensetissue
Branched extensions monitor & adjust composition of CSF

Fig. 12.6, Table 12.1 10
 Microglia
doesn'tleavebrain spinalcord

Smallest neuroglial cells
exceptionally numerous

CNS security force
Immune cells keepseverythingouttobesafe
Act like macrophages
Destroy debris, waste, pathogens
via phagocytosis
betheydoittoowell

Fig. 12.6, Table 12.1
red http://faculty.sites.uci.edu/kimgreen/files/2012/03/Lesion-mouse-NeuN-Iba-cool-DG.jpg

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 Astrocytes
helpsregulateoverall process
Largest and most numerous
Cytoplasmic extensions
Functions
Regulate interstitium
Blood-brain barrier formation
on Yingnervous
Structural framework
Repair damaged tissue
Neuron development

Fig. 12.6, Table 12.1 12
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 CNS Neuroglia 4 big types

Fig. 12.6, Table 12.1 13
PNS Neuroglia outside of brain spinal cord

Peripheral nervous system
Satellite cells similarto astrocytes
Support neurosomas in ganglia (clusters of nerve cell bodies in the PNS)
structuralsupport

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 PNS Neuroglia
Peripheral nervous system
Satellite cells
Support neurosomas in ganglia (clusters of nerve cell
bodies in the PNS)
Schwann cells (neurilemmocytes)
Cover all PNS neurons
Can form myelin sheath
Secrete neurotrophic factors to direct growth and
connections

wrapseach axon

Fig. 12.9 15
 Myelin
milk
drinkingwhole
Primarilymadeof lipids solittlekidsneedtobe
Protects & insulates nerve fibers (axons)
Increases transmission speed
one Oligodendrocytes (CNS) & Schwann cells (PNS)
Doesthisbymaintainingmembrane potential
severelywrapsaround neuron
Minimizes ion leakage by minimizing Axon
contact with ECF
cellmembrane
Increases thickness by as much as 100X
nearlyimpossibletogetthrough thick membrane

Fig. 12.8 16
 Neurons
Functional unit of the nervous system

Special functional characteristics:
Excitability – respond to stimuli
Conductivity – respond to stimuli via electrical signals
Secretion – electrical signal → secretion of signaling
molecules

Other notable features:
Extreme longevity (your lifetime, >100 years)
Amitotic – Most lose the ability to divide most divide
High metabolic rate re it
Require continuous supply of glucose & O2
https://analyticalscience.wiley.com/do/10.1002/was.00020482/full/rapidflim-1-2-
2022image2lr.jpg
exeTyYantdepend
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 Generic Neuron Structure
Dendrites
Thin, branched extensions
extendingoffof neurosomes
Contain most types of organelles (no nucleus)

Point of connection with other neurons

cell
body
Receive signal, pass along toneuron
neurosoma onwhattodo

Fig. 12.4 20
 Generic Neuron Structure
Neurosoma (AKA soma, cell body)
Contains nucleus, mitochondria, lysosomes, golgi,
rough ER, ribosomes
singlenucleus insinglecell
1/10 or less of cell volume
Notthatbig
Extensive cytoskeleton into axon & dendrites

Fig. 12.4 21
 Generic Neuron Structure
Axon (AKA nerve fiber)
Axon hillock – origin point of axon
Vary in length (1 micrometer – 1 meter)
Transmits signal from cell bodyput
to axon terminal
Extensive cytoskeleton

Fig. 12.4 22
 Generic Neuron Structure
Terminal arborization
Multiple branches that end in axon terminals
Each axon terminal forms a synapse with the target cell
Lots of synaptic vesicles filled with signaling molecules
Can instead use varicosities (autonomic neurons)
Extensive cytoskeleton but no ER or ribosomes

can'tmakemanythingsin proteinproduction
HRNA
the periphery so'ma

Fig. 12.4 23
 Generic Neuron Structure
Actual proportions
Example: somatic motor neuron
Neurosoma = tennis ball
Dendrites = bushy mass that would fill most of the
classroom
Axon = 1 mile long and narrower than a garden hose

Fig. 12.4 26
 Neuron Classification - Function
Sensory (afferent) neurons
Detect & transmit info about stimuli
From sensory receptors towards the CNS
Info approaches the CNS
Stimulus examples: temperature, light, smell, body
position, pressure, etc.

Typical structure: bipolar or unipolar neurons

Fig. 12.3 28
 Neuron Classification - Function
Interneurons
Most numerous type of neuron (90%)
Completely within CNS
Interconnect sensory & motor pathways
Receive info from sensory neurons
Integrate (process, store, & retrieve) information
Dictate motor response by stimulating motor neurons
Typical structure: multipolar neurons

Fig. 12.3 29
 Neuron Classification - Function
Motor (efferent) neurons
Carry info away from CNS
Info exits the CNS
Reach to effectors/target tissues (mostly muscle
and glandular tissues)
Enlarged axon terminals or varicosities to generate
specific responses
Typical structure: multipolar neurons

Fig. 12.3 30
Neuron Classification
Connection between neuron structure & function
Motor (efferent) & interneurons Sensory (afferent) neurons

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 Variation in Neuron Structure
Touch receptor
Pyramidal &
Purkinje cells in CNS

Bipolar neuron in retina
& olfactory neuron

Amacrine cell in retina

Fig. 12.5 32
 The Central Nervous System

Fig. 13.1, 14.1 34
 Nervous System Organization
Nucleus = a cluster of neuronal cell bodies in the
CNS (plural = nuclei)
Ganglion = a cluster of neuronal cell bodies in the
PNS (plural = ganglia)

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Tract = a bundle of axons in the CNS
Nerve = a bundle of axons in the PNS

35
Nervous System Organization
Gray vs. white matter
Gray matter – neurosomas, dendrites, &
synapses
White matter – bundles of axons

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 The Brain
1350 cc & 3 lbs. of processing power

Contains 20 billion neurons

Key for complex responses

Use 100% of your brain

Fig. 14.1 37
 Cranial Meninges
Connective tissue coverings that surround the brain
Functions:
Protect underlying neural tissues
Anchor the brain in the cranial cavity
Three layers:
Dura mater
Subdural space
Arachnoid mater
Subarachnoid space
Pia mater

Fig. 14.5 38
 Dura Mater
Most superficial layer
Periosteal layer = periosteum of skull (does not continue into spinal cord)
Meningeal layer folds into parts of cranial cavity → separation of regions
Falx cerebri – between R & L cerebral hemispheres
Falx cerebelli – between R & L cerebrellar hemispheres
Tentorium cerebelli – between cerebellum & cerebrum
Dural sinuses form when space between layers gets larger for blood collection

Fig. 14.5 39
 Dura Mater
Most superficial layer
Periosteal layer = periosteum of skull (does not continue into spinal cord)
Meningeal layer folds into parts of cranial cavity → separation of regions
Falx cerebri – between R & L cerebral hemispheres
Falx cerebelli – between R & L cerebrellar hemispheres
Tentorium cerebelli – between cerebellum & cerebrum
Dural sinuses form when space between layers gets larger for blood collection

Fig. 14.5 40
 Arachnoid & Pia Mater
Arachnoid mater
Contains spaces for blood vessels
Subarachnoid space is filled with
cerebrospinal fluid (CSF)

Pia mater
Thin protective layer of tissue
Directly covers nerves and neuroglia

Fig. 14.5 41
 Cerebrospinal Fluid (CSF)
100-160 mL of clear, colorless fluid in ventricles & canals of CNS
Composition:
Filtrate from blood plasma
Contains glucose, oxygen, Na+, Cl-, Mg2+, and other ions
Functions:
Cushioning and shock absorption
Chemical protection
Exchange nutrients and wastes

Fig. 14.6 42
 Ventricles of the Brain
Fluid-filled chambers within the brain
Location of CSF formation
Numbered according to CSF flow
From the 4th ventricle, CSF empties into the central canal of the spinal
cord (or into subarachnoid space)

Fig. 14.6 43
 Don't need to know for exam
CSF Formation & Pathway of Flow
Secreted by choroid plexus in lateral
ventricles (1 & 2)
Ependymal cells also secrete CSF
Flows into 3rd ventricle
Choroid plexus adds more CSF
Flows down cerebral aqueduct to fourth
ventricle
Choroid plexus adds more CSF
Flows out of lateral apertures to fill
subarachnoid space
Also secretes some CSF
Reabsorbed through arachnoid villi into
venous sinuses

Fig. 14.7 44
 Blood Brain Barrier (BBB)
Capillaries of the blood brain barrier are
the least permeable capillaries in the
body

Maintains a stable environment for the
brain

Protects the brain from:
Foreign substances in the blood
Hormones and neurotransmitters that are
traveling through the blood to the rest of
the body
Fig. 12.6 45
 Blood Brain Barrier (BBB)
O2, CO2, and small lipid-soluble molecules
can cross the BBB
Large lipid-soluble molecules (fatty acids)
move slowly
Negatively charged molecules cannot cross

Glucose, amino acids, and other nutrients
must be transported across the BBB

Fig. 12.6 48
 Blood Brain Barrier (BBB)
Capillaries of the blood brain barrier are
the least permeable capillaries in the
body
Endothelial cells form and maintain tight
junctions between one another

Astrocytes extend foot processes around
capillary endothelial cells to form another
barrier layer

https://doi.org/10.1186/s12987-018-0117-2
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 Astrocytes
Largest and most numerous
Cytoplasmic extensions
Functions
Regulate interstitium
Blood-brain barrier
Structural framework
Repair damaged tissue
Neuron development

Fig. 12.6, Table 12.1 46
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