BIOL 1800 Nervous System Lecture 2024 PDF

Summary

This document is a lecture on nervous tissue and the nervous system, part 1 for BIOL 1800 in 2024. It details the four types of body tissues (epithelial, connective, muscular, nervous) and covers learning outcomes, functions, organs, and reflex arcs.

Full Transcript

CC - The nervous tissue, part 1

Lecture 8:
Nervous Tissue & the Nervous System
BIOL 1800
Dr Marie Conway
The 4 types of body tissues
Cells are the building blocks in the body
A tissue is a group of cells that carry out a specific function – cells are organised into
4 tissue types:
1. Epithelial Covers exposed surfaces, lines internal passageways, forms glands
Fills internal spaces, provides structural support for other tissues, transports
2. Connective
materials within the body, stores energy reserves
Specialised for contraction, includes the skeletal muscles, muscle of the heart,
3. Muscular
muscular walls of hollow organs
Carries information from one part of the body to another in the form of
4. Nervous
electrical impulses

1 and 2 are classified by morphology, 3 and 4 by function
These tissues make up the organs and systems of the body
Learning Outcomes for NS
At the end of this week’s lectures you will be able to:
List the parts of the Nervous system:
CNS (brain and spinal cord)
PNS (cranial and spinal nerves, sensory receptors)
Explain the terms sensory, motor and integration as they apply to the
nervous system
Outline the structure of a nerve cell (neuron) and the function of each part
of the neuron
Explain the role of the glial cells
Explain how neurons convey information in a reflex
Nervous System Organs
Organs of the Nervous System
Brain and spinal cord
Sensory receptors of sense organs (eyes, ears, etc.)
Nerves connect nervous system with other systems (nerve is a bundle of axons).
Spinal nerves and Cranial nerves

Basic functions of nervous system
Sensory function – senses certain changes (stimuli) both within (internal
environment) and outside (external environment) the body
Integrative function – analyses sensory information, stores some aspects, and makes
decisions regarding appropriate behaviour
Motor function – may respond to stimuli by initiating muscular contractions or
glandular secretions
The Nervous System
Anatomical Divisions of the Nervous System
Central nervous system (CNS)
Brain and spinal cord
Divided into grey and white matter
Supported by glia, CT and blood vessels

Peripheral nervous system (PNS)
Cranial and spinal nerves
Nerves can have both sensory and motor axons
Nerves are supported by glia, CT and blood
Includes somatic nervous system (SNS) and
autonomic nervous system (ANS)
The Central Nervous System (CNS)
Consists of the spinal cord and brain

Contains neural tissue (neurons and glia),
connective tissues, and blood vessels

Is protected by bone and meninges (CT)
Functions of the CNS
Are to process and coordinate:
sensory data: from inside and outside body
motor commands: control activities of peripheral organs (via muscles,
glands)
higher functions of brain: intelligence, memory, learning, emotion
CNS – information processed at conscious and subconscious levels
CNS – integrates physiology and psychology
 E.g. in Thermoregulation
CNS work example

Blood temperature is the stimulus
The hypothalamus can respond to the change in temperature (outside
the set range)
The hypothalamus in response turns on:
Heat loosing or
Heat gaining mechanisms
Peripheral Nervous System
All neural tissue outside the CNS
Delivers sensory information to CNS; delivers motor commands from the CNS
Bundles of axons (nerve fibres carry this information)

Consists of 12 pair of cranial nerves and 31 pair of spinal nerves.
The cranial nerves carry impulses between the brain, head and neck with only 1 exception (vagus nerve)
The spinal nerves carry impulses between the spinal cord, the chest, abdomen and extremities

Afferent division
Brings information to the CNS
Efferent division
Carries motor commands to muscles and glands
Somatic nervous system provides voluntary control
Autonomic nervous system provides involuntary control
Peripheral nervous system
Somatic nervous system Autonomic nervous system
Control skeletal muscle ANS automatically regulates
contractions smooth muscle, cardiac muscle,
Voluntary contraction – under glandular secretions, and adipose
conscious control e.g. control over tissue at subconscious level
arm to raise full glass of water to Parasympathetic and sympathetic
your lips division  antagonistic effects
Involuntary contractions – E.g. parasympathetic activity slows
controlled at subconscious level e.g. the heart rate; - relax, digest, rest
if you accidentally placing your Sympathetic activity accelerates the
heart rate
hand on hot stove you move it ② fight or flight reaction
away immediately
Automatic response is called a reflex
 95% -brain + spinal cord

Nervous tissue neurons- do not devide, the longest cell.
limited ability to repair

Neurons – basic functional unit of the nervous system
Specialised for intercellular communication

Nervous tissue also includes supporting cells called neuroglia, or glial
cells

Neuroglia have functions including:
Survival and functioning of neurons
Preserving the physical and biochemical structure of nervous tissue
70% of brain tumours are tumours of a glial cell

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Nervous tissue

◦synapses

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Neurons

Four general regions:
A large cell body
Several short, branched
dendrites
Single, long axon
Terminal branches of
the axon called
telodendria
neurons can't be replaced
when damaged
- rapid change in neuro plasma
from body to axon
The cell body
Large, round nucleus – prominent nucleolus
Cytoplasm is the perikaryon - contain organels_-EF1, 3%273:É"ATP needs
Cytoskeleton of the perikaryon contains neurofilaments and
neurotubules
Bundles or neurofilaments, called neurofibrils, extend into the dendrites
and axon, providing internal support for them
Dendrites
Extend and branch out from the cell body
Play key roles in intracellular communication
Highly branched, some studded with projections called dendritic spines
(0.5 to 1µm long)
These participate in synapses
In the CNS, a neuron receives information from other neurons primarily
at the dendritic spines, which may represent 80-90 percent of the
neuron’s total surface area
Axons
O

Long cytoplasmic process capable of propagating an electrical impulse
known as an action potential
Axoplasm – cytoplasm of the axon
contains neurofibrils, neurotubules, small vesicles, lysosomes, mitochondria, and
various enzymes
Axolemma – plasma membrane of the axon
surrounds the axoplasm
in the CNS, the axolemma may be exposed to interstitial fluid or it may be
covered by the cellular processes of neuroglia
Axon hillock – thickened region where the base (or initial segment) of the
axon in a typical neuron joins the cell body
Axons
Axons create and pass electrical signals
(AP) along their length. May be up to 1m
long

The end of the axon is called the synaptic
terminal

Chemicals are released from the synaptic
terminal
vessicles with
chemicals,
Nerves Communicate at a synapse communicate with
posts. cell

Chemical
Junction gap called a synaptic cleft
The synapse
In the nervous system, messages move from one location to another in
the form of action potentials along axons
Transfer of message from one neuron to another takes place at a synapse
 a specialised site where the neuron communicates with another cell
Information passes from presynaptic neuron to postsynaptic neuron
Synapses may also involve other types of postsynaptic cells
e.g., the neuromuscular junction is a synapse in which the postsynaptic cell is a
skeletal muscle fibre
2 types of synapses
Electrical - direct physical contact between cell-rate

Chemical - two cells, one sends, second reaives

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The synapse
Axon terminal of presynaptic cell releases
chemicals called neurotransmitters into the
synaptic cleft
Neurotransmitters are contained in synaptic
vesicles

Synaptic cleft separates presynaptic
membrane from postsynaptic membrane

Each axon terminal contains mitochondria
and vesicles filled with neurotransmitter
molecules Chemical
Junction gap called a synaptic cleft
Telodendria
Axon may branch along its length – producing side branches known as
collaterals
Collaterals enable a single neuron to communicate with several other cells
The main axon trunk and any collaterals end in a series of find extensions
called telodendria, or terminal branches
Telodendria end at axon terminals, or synaptic terminals – role in
communication with another cell
Classification of Neurons by Structure based on dendrites in relation to cell body and axons

Anaxonic neuron Bipolar neuron Unipolar neuron Multipolar neuron

Anaxonic neurons Bipolar neurons have Unipolar neurons Multipolar neurons
have more than two two processes have a single have more than two
processes, and they separated by the cell elongated process, processes; there is a
may all be dendrites; body. with the cell body single axon and
axons are not obvious rare -sane organs-small located off to the side multiple dendrites
- largest 30mn ◦ Longest - from tips of toes to most common
spinal cord
◦ sensory neurons
Classification of neurons by function
Sensory neurons - unipolar neurons
Also known as afferent neurons bodies

Form afferent division of the PNS - celltcolated in pheripheral sensory ganglia
bring nerve signals to the brain and spinal cord sensory receptors → brain
Interneurons - connection in between
bring nerve signals from one nerve cell to another within the brain
and spinal cord  make connections between sensory and motor
neurons
Motor neurons - multi polar neurons
bring nerve signals away from the brain and spinal cord reflex = brain → elector
 The Nerve Cell (or Neuron) Structure

Dendrites receive inputs

Stimulus

Stimulus

Electrical signals travel out A chemical is released at the
along the axon synapse
 Just to know these 5?
Neural activities

make up the activity
of movement signal

1. Resting potential - every cell hase, membrane potential of resting cell, when changed → starts
the response is the signal movement
2. Graded potential - stimulus makes change in R. sp., signal is sent out, iffarge renough
3. Action potential - el- impuls, moves across axon to synapse
4. Synaptic activity - produce grated potential of posts. cell
5. Information processing - response of the posts. cell.
Glia (neuroglia) - hold neurons in place and helps it perforce its function

An axon with this insulation is called a myelinated
axon and is much faster than an unmyelinated axon

Many axons have an insulating coat around them
This is formed by a glial cell
This speeds the electrical conduction
Glia are important in maintenance and repair
Neuroglia – nervous tissue that support neurons
Neuroglia:
Separate and protect 2 types 4 types

neurons
Provide supportive
framework for nervous
tissue
Act as phagocytes
Help regulate the regulate ions,-- blood suply

composition of interstitial
fluid
Neuroglia
CNS
4 types of neuroglia
Ependymal cell
Microglial cell
Oligodendrocyte - around 24 axons

Astrocyte

PNS
2 types of neuroglia
Satellite cells
- regulate interstatial fuid
- same function as astrocytes?

Schwann cells - myeline the axon
- around just 1 axon
Formation of
myelin sheath
in the PNS of Ranvier

A myelinating Schwann cell
myelinates only one axon
(Figure 12-6a), (whereas an
oligodendrocyte in the CNS
may myelinate several axons)
Non-myelinating Schwann
cells can enclose segments
of several unmyelinated
axons
A series of Schwann cells is
required to enclose an axon
along its entire length (
Figure 12-6b).
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Formation of myelin sheath in the PNS
Stages in the formation of a myelin sheath by a myelinating Schwann cell
around the axon of a peripheral neuron
Neural responses to injuries
- it might not repair
- bigger regeneration on PNS

- eqtently degenerated

- it works as before → synapse
Neural reflexes
Reflexes – quick, automatic responses triggered by specific stimuli;
Regarded as fast, predictable, protective, automatic (subconscious) response to a
stimulus - if the stimuli is the same, it will propably do the same response

preserve homeostasis by making rapid adjustments in the function of organs or
organ systems

Spinal reflexes – controlled in the spinal cord, they function without any
input from the brain

E.g., a reflex controlled in the spinal cord makes you drop a frying pan
you didn’t realise was sizzling hot
Before the information reaches your brain and you become aware of the
pain, you’ve already released the pan before you even realise, you've already done it
Neural Reflexes

- grasp, crawl - plantar reflex

- from constant practise -driving...
- sneezing, blushing, saliva production

- knee or biceps
reflex

plantar reflex, patellar reflex
Neural Reflexes
Involves a circuit called a reflex arc
This reflex arc includes:
Sensory Receptor structure - object → pin....

Sensory nerve cell - sends signal to interneuron

Interneuron(s) (in most cases)
Motor nerve cell - sends signal to effector

Effector- movement
Spinal Cord Reflex Control Spinal cord transverse section

formation of
the action
potential
The monosynaptic reflex - delay between stimuli and the response
Reflex Pathways CNS – brain and spinal cord

Involve the central nervous system (brain and spinal cord)
AND
The peripheral nerves (cranial nerves, spinal nerves and sensory receptors)

The sensory information is processed in the Central Nervous System (CNS)

The CNS then directs the motor response → PNS
Flow of information

- se red light

Example
- driving a car

- food go on the break
Grey matter
The CNS (brain and spinal cord) is divided into grey and white matter

Grey matter of the brain and spinal cord is where nerve cell bodies are
concentrated.
Also the site of incoming signals (and therefore synapses)
Grey because of cell body structures - cells which synthesise protein

Decisions are made in the grey parts of the brain and spinal cord
Spinal cord -31 segmens → 31 spinal nerve
 Brain frontal section Grey matter is
darker

Grey matter is on the
centre of the spinal
cord

Grey matter is mostly
on the outside of
brain tissue
White matter of the brain and spinal cord
White matter of the brain and spinal cord White matter colour is due to the
is where bundles of axons are found glial cell membrane structure

Glial cell
White areas of the brain are the
connections between one part of the brain
and another
White because of fatty tissue (myelin)
in the glial cells that surround the axon
Grey and White Matter
Grey matter
where information from one neuron is passed onto another neuron
 this involves processing

White matter
where information is brought from one part of the CNS to another
 this involves pathways called tracts
Recap:
Anatomical Divisions of the Nervous System
Central nervous system (CNS)
Brain and spinal cord
Divided into grey and white matter
Supported by glia, CT and blood vessels

Peripheral nervous system (PNS)
Cranial and spinal nerves
Nerves can have both sensory and motor axons
Nerves are supported by glia, CT and blood
Nervous tissue

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