The Biological Approach PDF

Summary

This document provides a detailed overview of the biological approach in psychology, focusing on the organization of the nervous system, including the central nervous system (CNS), peripheral nervous system (PNS), somatic nervous system, and autonomic nervous system (ANS). It explains the different parts of a neuron and describes the processes of electrical and chemical communication within and between neurons, including action potentials and neurotransmitters. It also covers various neurotransmitters, like glutamate and GABA.

Full Transcript

The Biological
Approach
Organizati
on of the
Nervous
System
Central
Nervous
System
Central Nervous System:
the part of the nervous
system that comprises the
brain and spinal cord
Peripheral Nervous
System: the part of the
nervous system that
comprises all the nerve
cells in the body outside
the central nervous
system.
Peripheral
Nervous
System
Somatic Nervous System:
nerve cells of the
peripheral nervous
system that serve the
skeletal muscles. Somatic
nerves transmit from the
central nervous system
(CNS) to the skeletal
muscles and sensory
information from the
skeletal muscles back to
the CNS
Autonomic Nervous
System

Autonomic Nervous System: all of
the nerves of the peripheral
nervous system that serve
involuntary systems of the body
such as internal organs and glands.
You don’t have to think about
digestion to digest or control your
heart manually.
The ANS is further divided into 2
subdivisions
Sympathetic
Parasympathetic
Sympathetic
Nervous System

The branch of the ANS that
activates bodily systems in times
of emergency
Fight or Flight  In the even of
an emergency, the
sympathetic nervous system
will divert blood away from the
digestive system and urinary
track towards the heart,
muscles and lungs.
The body releases a hormone
called adrenaline.
Parasympathetic
Nervous System

Parasympathetic nervous system:
the branch of the ANS that usually
relaxes or returns the body to a
less active, restful state.
Rest and Digest  Blood flow is
diverted towards the digestive
system and away from skeletal
muscles, heart rate slows, and
breathing relaxes.
All of the systems aroused by
the sympathetic nervous
system are relaxed by the
parasympathetic nervous
system
Origins of Neuron
Doctrine

Humoral Theory: a theory that
states that the human body is
comprised of 4 humors: blood,
phlegm, yellow vile, and black
vile.
Camilo Golgi: used a tissue
staining technique to identify
and illustrate neurons under a
microscope, still he believed that
the nervous system was
continuous and uninterrupted
Neuron Doctrine

Santiago Ramon y Cajal: known as the
father of modern neuroscience.
He used the Golgi staining method
and discovered that the nervous
system was not a continuous but
composed of individual cells
separated by small gaps.

Neuron doctrine: the universally
accepted concept that the
nervous system is made of
individual cells, neurons, and
supported by glial cells.
Electrical and
Chemical

A key aspect of the nervous
system is that communication
between neurons is both
chemical and electrical.
Anatomy of the neuron
The Action Potential
( Electrical)
Neurotransmitters
(Chemical)
Glial Cells
Central nervous system cells that
provide structural support, promote
efficient communication between
neurons, and serve as scavengers,
removing cellular debris
Blood Brain Barrier: glial cells help
form a barrier that insulates the
CNS and regulates the movement
of molecules in and out of the CNS.
Think of them as the support
staff helping the neuron serve
its function effectively and
efficiently.
Half of all cells in your brain
are glia
 The
Neuron
The Neuron
Neurons: the cells that process and
transmit information in the nervous
system
1. The basic building block of the
nervous system, all major
brain structures are composed
of neurons
2. Information within the neuron
travels in the form of an
electrical signal
3. Information between neurons
travels in chemical form via
chemicals known as
neurotransmitters.
The Soma

Soma: the cell body of the
neuron
Contains the nucleus and
all other organelles
Dendrites: fingerlike
projections from a neuron’s
soma that receive incoming
messages from the other
neurons
The axon hillock separates
the soma from the axon, it is
also the origin of the action
potential.
The Axon

The axon: a long projection
that extends from a neuron’s
soma, it transmits electrical
impulses away from the
soma and towards the
adjacent neuron and
stimulates the release of
neurotransmitters.
Myelin sheath: The fatty
substance wrapped around
some axons, which insulates
the axon, making the nerve
impulse travel more
efficiently.
Made by glial cells called
Schwann cells
The Terminal Button
Terminal button: a little knob at the end of the axon,
contains tiny sacs of neurotransmitters.
The action potential triggers the release of neurotransmitters
into the synapse.
Synapse: the junction between an axon and the
dendrites or soma of an adjacent neuron, where
information is transmitted from one neuron to another.
1. Resting Potential

Resting potential: the difference
between electrical charge between the
inside and outside of the neuron is eat rest.
-70mV
Ions: chemically charged particles that
predominate in bodily fluids; found both
inside and outside of cells
We will be focusing sodium (Na+) and
potassium (K+)
Na+ and K+ channels are found on the
cell membrane; some allow the free
movement of ions while others are
voltage- dependent channels
The sodium potassium pump: an active
pump that moves three Na+ out of the cell
in exchange for 2 K+. (3:2 ratio)
2. Depolarization

Action potential: the impulse of
positive charge that runs down an
axon.
As ions move across the membrane,
a charge builds up at the axon hillock,
making the membrane more positive
All or nothing principle: the idea
that once the threshold has been
crossed, either an action potential
fires or it does not.
Incoming impulses cause
depolarization, but a neuron must
reach the threshold of -55mV for an
AP to propagate.
The Node of Ranvier
Once the threshold is crossed and
the membrane potential is -
55mV, sodium channels will open
and flood the cell, making it more
positive.
Node of Ranvier: gaps in the
myelin sheath across which the
action potential jumps. +40mV
Instead of moving across the
surface of the axon, the action
potential will “jump” from node
to node.
Up to 150 m/s
3. Repolarization
After the AP has peaked, Na+ channels will
close and K+ channels will open., making
the membrane potential more negative.
The neuron returns to resting potential. -
70mV
Refractory period: the span of time,
after an AP, has been generated, when the
neuron is returning to its resting state and
the neuron cannot generate an action
potential.
Neurotransmission

Once the action potential reaches the
terminal button, the electrical signal
ends, and the chemical signal begins.
Neurotransmitter (NTs): chemicals
that transmit information between
neurons
Synaptic vesicles: tiny sacs in the
terminal buttons that contain
neurotransmitters.
The synaptic vesicles release the
NTs into the synaptic gap, binding
with receptors in a lock-and-key
arrangement.
What happens
after?
Reuptake: a way of removing
excess NT from the synapse, in
which excess NTs are returned
to the sending, or pre-synaptic,
neuron for storage in vesicles
for future use.
Enzymatic degradation: a way
of removing excess NTs in
which enzymes specific for
that NT bind with the NT and
destroy it.
Neurotransmitter
s
Glu and GABA

Glutamate (Glu): the major excitatory NT in the brain that
increases the likelihood that a post-synaptic neuron will fire,
important in learning, memory, neural processing, and brain
development.
Too much Glu leads to runaway excitation in brain activity
causing a seizure (Cho and Shaikh, 2023).
Gamma-aminobutyric acid (GABA): a major inhibitory NT in
the brain that tells post-synaptic neurons not to fire, slows the
CNS activity and necessary to regulate and control neural
activity
Too much GABA and the brain activity is suppressed and
leads to loss of consciousness (Clauss, 2010).
Acetylcholine
Acetylcholine (ACh): an NT that
controls muscle movement and
plays a role in mental processes
such as learning, memory,
attention, sleeping, and dreaming.
Receptors are found in muscles at
the neuromuscular junction where
Ach excites and slows down
muscles.
Dopamine
Dopamine (DA): a neurotransmitter
released in response to behaviors
that feel good or are rewarding to
the person or animal, also involved
in voluntary motor control.
Eating a good meal, shopping,
playing video games etc trigger
the release of DA in the brain.
Plays a role in addictive
behavior
Plays a role in schizophrenia
and Parkinson's disease
Serotonin
Serotonin (5HT): a NT with a wide-
ranging side effects, involved in
dreaming and controlling
emotional states, specially anger,
anxiety and depression.
People who suffer from
depression tend to have lower
levels of 5HT
Can be found in both the brain
and the gut
Epinephrine and Norepinephrine
Epinephrine (E): also known as
adrenaline, a NT that arouses
bodily systems (such as increasing
heart rate).
Does not affect mental stage,
Norepinephrine (NE): a NT that
activates the sympathetic
response to stress, increasing
heart rate, rate of respiration, and
blood pressure in support of rapid
action.
Increases arousal and alertness
ADHD
The Brain
The Hindbrain

The hind brain is the oldest brain region and is
connected to the spinal cord
Medulla- a hindbrain structure that extends
directly from the spinal cord; regulates
breathing , heart rate and blood pressure
Reflexes: Inborn and involuntary behaviors-
such as coughing, swallowing, sneezing, or
vomiting- that are illicited by very specific
stimuli.
Pons: a hindbrain structure that serves as a
bridge between lower brain regions and higher
midbrain and forebrain activities
Also responsible for automatic functions
such as facial expressions and the sleep-
wake cycle.
Cerebellum

Cerebellum, also known as the
little brain, located in the hind
brain, is involved in body
movement, balance,
coordination, fine tuning motor
skills, and cognitive activities
such as learning and language.
Motor skills such as holding a
pencil, riding a bicycle, even
reading are fine tuned by the
cerebellum
The cerebellum plays a role in
dyslexia, a disorder
characterized by difficulty
reading despite having normal
vision and intelligence.
 The
Midbrain
The different areas of the midbrain control
eye muscles, process auditory and visual
information (flash bang), initiates
voluntary movement of the body.
Reticular formation: a network of
nerve fibers that runs up through both the
hindbrain and the midbrain, is crucial for
waking up and falling asleep (arousal).
Lesion studies: cats who had reticular
formation stimulated immediately
woke up.
Cats with lesioned reticular formation
went into a coma and never woke.
The Forebrain
The forebrain is located centrally, above
the midbrain and includes the cerebrum
as well as other systems.
Controls cognitive, sensory and
motor function, and regulate
homeostasis.
Responsible for eating, sleeping and
display emotions.
Structures in the forebrain are
bilateral
Thalamus: a forebrain structure that
receives information from the senses
and relays it to the cerebral cortex for
processing
Relays information from the sensory
organs to their corresponding cortex
 The Limbic
System
A connection group of forebrain
structures (hypothalamus, amygdala,
hippocampus, and cingulate gyrus) that
share important functions in emotion,
memory, motivation, and regulate
autonomic and endocrine function.
Hypothalamus: a limbic system
structure, the master regulator of
almost all drivers and motives we have,
such as hunger, thirst, temperature, and
sexual behaviors, also controls the
pituitary gland
Lesioning one section would cause
overeating and obesity while
lesioning another section would
cause undereating and starvation.
Limbic System
Hippocampus: a limbic structure
that wraps itself around the
thalamus (like a seahorse); plays a
vital role in learning and memory.
Remember HM?
Sensory information deemed
important by the hippocampus
will be converted into a long-
term memory.
The hippocampus is a plastic
structure that changes with
experience; British taxi drivers
in London.
 Limbic System
Amygdala: A small almond shaped structure
located directly in front of the hippocampus; has
connections with many important brain regions
and is important for processing important
information, specially that related to fear.
Has connections with both the cerebral
cortex, hippocampus and the thalamus.
The amygdala's main purpose is to estimate
emotional significance.
Studies in cats have show that stimulation of
the amygdala caused the cats to curve their
backs in an angry-defensive manner.
Lesion studies in monkeys cause them to
become less fearful of snakes.
Recognition of emotions, especially fear, in
other peoples faces involves the amygdala.
Limbic System
Cingulate Gyrus: a beltlike structure in
the middle of the brain, plays an
important role in attention and cognitive
control.
When you are trying to solve a
puzzle or focus on problem, the
cingulate cortex activates.
Basal Ganglia: A collection of structures
surrounding the thalamus, involved in
voluntary motor control.
Parkinson’s and Huntington’s
disease; diseases that involve jerky
uncontrollable movements.
Reward system and addiction
The Changing Brain
True or False? Only long-term
learning increases the number and
structure of neurons in your brain.
True: Whenever we learn and retain
information long term, neurons in
our brains actually grow and change.
The same does not happen with
short-term learning that is soon
forgotten.
 Cerebrum
Cerebrum: Each of the large halves
of the brain, covered with
convolutions, or folds.
Cerebral Cortex: The thin outer
layer of the cerebrum, in which
much of human thought, planning,
perception, and consciousness takes
place
Gyrus and Sulcus: hills and
valleys, respectively
About.5cm thick
Grey Matter: composed of
neuron soma.
White Matter: composed of
The Cerebral
Cortex
The cerebral cortex is
separated into two
hemispheres linked by a
bundle of nerves
Left hemisphere
Right hemisphere
The cortex is further
divided into 4 lobes:
Frontal lobe
Parietal lobe
Occipital lobe
Temporal lobe
Frontal Lobe
The frontal lobes make up one third
of the cerebral cortex and play an
important role in planning, abstract
thinking, problem solving, impulse
control, creativity and social awareness.
Integration of information
Prefrontal Cortex: the cortex that make
humans ‘human’
The last brain region to fully
develop in adulthood
Lobotomy: medical procedure
performed in the 20th century that
involved the ablation of the frontal lobes
Phineas Gage
Motor
Cortex
Motor cortex:
responsible for the
voluntary control of
skeletal muscles.
Parietal
Lobe
The parietal lobes
are responsible for
spatial awareness.
Contain the
somatosensory
cortex
Hemispheric neglect
Hemispheric Neglect
Somatosensor
y Cortex
Somatosensory cortex: a strip of the
parietal lobe involved in the processing
and perception of sensory information
from the body, especially temperature,
touch, pressure and pain.
The homunculus: a small
disproportionate human, that represents
sensation and motor movement of
different body parts, their size depends
on sensitivity.
The hands, palms and lips are
enlarged because they are highly
sensitive
The chest and legs are represented
much smaller.
Occipital
Lobe
Visual cortex: process visual
information from the retinas
through the optic nerve.
Located in the rear of the
cerebrum
Vision vs perception: the visual
cortex is where we ‘see’ and
‘imagine’
Cortical Blindness: a disorder
characterized by the inability to see
despite having intact eyes and
cortical nerve. Due to trauma of the
visual cortex/
Temporal
Lobe
The temporal lobes, located below the
frontal and parietal lobes, have various
functions and house the primary
auditory cortex
The primary auditory cortex is
responsible for processing auditory
information from the ears.
Have connections with the
hippocampus and frontal lobes.
Aphasia
Aphasia: a deficit in the ability to speak or
comprehend language
Broca’s Area: are in the left frontal lobe responsible
for the ability to produce speech.
Broca had an elderly patient who suffered from
an aphasia, when the patient died, he
performed an autopsy and discovered damage
to the left frontal lobe.
He found the same in 8 other patients and
concluded this area was responsible for the
production of speech.
Wernicke’s Area: the area deep in the left temporal
lobe responsible for the ability to speak in
meaningful sentences and to comprehend the
meaning of speech.
Cerebral
Hemispheres
The left and right hemisphere
may look similar, but they
differ in shape, size and
functions.
Some functions performed in
the right hemisphere are not
found in the left hemisphere.
For example, the right
hemisphere is responsible for
the production of speech while
the left hemisphere lacks this
function
This means that the left
hemisphere is “mute”
Corpus Collosum and the Insula
Corpus Collosum: nerve fibers that connects
The hemispheres operate independently but share information
through the corpus collosum
Insula: a small structure inside the cerebrum that plays
an important role in the perception of bodily sensations,
emotional states, empathy and addictive behavior.
Split Brain
 Neurogenesis
Neuroplasticity: the brains ability to adopt
new functions, reorganize itself or make new
neural connections throughout life, as a
function of experience
People who are blind can hear better while
people who are deaf tend to see better
The brain is made for efficiency and does
not allow any brain area to be underused or
go to waste
Neurogenesis: the development of new
neurons
Arborization: the growth and formation of new
dendrites.
Synaptogenesis: formation of entirely new
synapses with other neurons.
Dr. Ramachandran and Phantom Limb
Syndrome.