Introduction to Psychology - Ch. 3 Biological Psychology PDF

Summary

This document is a chapter on biological psychology from an introductory psychology textbook. It covers topics such as genetics and behavior, chromosomes and genes, and the role of the nervous system in human behavior. The content provides a general overview suitable for introductory psychology courses.

Full Transcript

Introduction to Psychology

Ch. 3 Biological Psychology
 Modules
3.1: Genetic and Evolutionary Perspectives on
Behaviour
3.2: How the Nervous System Works: Cells and
Neurotransmitters
3.3: Structure and Organization of the Nervous System
3.4: Windows to the Brain: Measuring and Observing
Brain Activity
 3.1 Learning Objectives
Know the key terminology related to genes, inheritance,
and evolutionary psychology.
Understand how twin and adoption studies reveal
relationships between genes and behaviour.
Apply your knowledge of genes and behaviour to
hypothesize why a trait might be adaptive.
Analyze claims that scientists have located a specific
gene that controls a single trait or behaviour.
Analyze explanations for cognitive gender differences
that are rooted in genetics.
 Historically two opposing view points:
– Nativists
Emphasized genes, inborn characteristics
Nature
– Empiricists
Focused on learning and experience
Nurture
Human behaviour is influenced by both genetics
and environment
– Not nature or nurture
– Genes influence the experiences one has
– Experience also affect our genes (which ones are
presently turned on and off) - Epigenetics
 Evolutionary Psychology
– A field of psychology emphasizing evolutionary
mechanisms that may help to explain human
commonalities in cognition, development, emotion,
social practices, and other areas of behaviour
Behavioural Genetics
– An interdisciplinary field of study concerned with
the genetic bases of individual differences in
behaviour and personality

Chromosomes
Chromosome
& Genes
– Molecule of DNA (deoxyribonucleic acid)
is a molecule formed in a double-helix shape that contains four
amino acids: (A)denine, (C)ytosine, (G)uanine, and (T)hymine.
– Lined with all the genes a person inherits
– Rod shaped
– Found in nucleus of cell
Genes
– Located in DNA (fixed location)
– Contain genetic blueprint
– are the basic units of heredity; they are responsible for guiding
the process of creating the proteins that make up our physical
structures and regulate development and physiological
processes throughout the lifespan.
– Genes contain bases, carry codes for protein manufacture
Heredity encoded in combinations of bases adenine, thymine,
guanine, and cytosine
 Chromosomes & Genes

Every cell has 46 chromosomes
(23 pairs)
– Exception: egg and sperm
Contain 23 chromosomes
Combine to form new cell with
46 chromosomes
Receive one of each gene pair
from each parent
 Chromosomes & Genes
Genotype
– Specific genetic makeup of an organism
– Present from conception
– Never changes
Phenotype
– Observable characteristic, including
physical structures and behaviours,
produced by the genetic makeup
– One’s phenotype represents the
physical and behavioural manifestations
of the genotype through interactions
with the environment.
E.g., how tall you ‘can’ grow versus
how tall you ‘actually’ grow
 Genes
So why aren’t genotype and phenotype
always identical?
Characteristic displayed if:
– Dominant gene from either parent
– Two recessive genes (one from each parent)
– Polygenic transmission (multiple gene pairs
influence a single phenotypic trait)
 The Genetics of Difference
Will now examine how differences among people
may be influenced by genes
 The Genetics of Difference
The meaning of heritability
– A statistical estimate of the proportion of the total variance in
some trait that is attributable to genetic differences among
individuals within a group
– is a statistic, expressed as a number between zero and one that
represents the degree to which genetic differences between
individuals contribute to individual differences in a behaviour
or trait found in a population.
– Expressed as proportion (.60 or 60/100)
– Maximum value is 1.0
Some variables such as height are highly heritable, other
variables such as musical ability are moderately
heritable
 Behavioural Genetics
is the study of how genes
and environment influence
behaviour.
Study of genetic
relatedness
– With parents = 50%
– Siblings = 50%
– Grandparents = 25%
Facts About Heritability
1. An estimate of heritability applies
only to a particular group living in a
particular environment
Heritability of a particular trait may be
high in one group and low in another
2. Heritability estimates do not apply to
individuals, only to variations within
a group
Can only examine the degree to which
differences among people in general are
explained by their genetic differences
3. Even highly heritable traits can be
modified by the environment
E.g. height
 Computing Heritability
Studying adopted children allows researchers to
compare correlations between the traits of adopted
children and those of their biological and adoptive
relatives
Results are used to compute heritability estimate
 Adoption Studies
Compare an individual who was adopted
earlier in life to both adopted and biological
parents on a particular characteristic
– If more similar to biological parents – suggests
genetic influence
– If more similar to adopted parents –
environmental factors may be more important
 Computing Heritability

If identical twins are
more alike than
fraternal twins, then the
increased similarity
must be due to genetic
influences
But fraternal twins may
receive different
treatment than identical
Monozygotic Dizygotic
twins twins
twins
 Computing Heritability

Investigators have also studied identical
twins who were separated early in life and
reared apart
Any similarities in traits between them
should be primarily genetic and should
permit a direct estimate of heritability
 Behavioural Genomics: The Molecular
Approach
Twin and adoption studies provide estimates of
heritability, but they do not tell us how traits are
inherited.
To determine the “how”, researchers use
behavioural genomics.
– is the study of DNA and the ways in which specific
genes are related to behaviour.
The Human Genome Project identified between
20 000 and 25 000 genes and all the sequences of
the A, C, G, and T amino acids making up the
genes.
 The Genetic Code
Human Genome Project (1990)
– Genetic structure of each of the 23 chromosome
pairs has been mapped
– More than 75 genes that contribute to hereditary
diseases have been identified
However, possession of that gene does not
guarantee the disorder.
– For example, a single gene has been identified as a
risk factor for Alzheimer’s disease, but not
everyone who inherits this gene develops the
disease.
 Genome
Genome
The full set of genes in each cell of an organism (with
the exception of sperm and egg cells)
The Link Between Genes and Behaviour
Even when researchers locate a gene on a chromosome,
they do not automatically know its role in physical or
psychological functioning
Most human traits are influenced by more than one gene
pair
– Examples include height and eye colour
Combinations of genes work together to influence
behaviour.
Similarly, a single gene is not limited to affecting only
one trait.
inheritance of a gene does not guarantee that
characteristic or disease.
– Environmental factors can also play a role.
 The Link Between Genes and Behaviour
Behaviour is a result of an interaction between genetics and
environment
Intelligence
– Is it genetics or environment?
If it is completely controlled by genes
– Individuals with same genes should have same IQ scores
– Identical twins - correlation =.86
– Parent-child - correlation =.36
– More shared genes the more similar individuals are in IQ
However, greater similarity between twins / siblings raised
together than raised apart
– Environment also influences IQ
More important question
– How do genes and environment interact to influence
intelligence?
 Reaction Range
Help us understand interaction between genetics and
environment
Are there genetically determined ‘boundaries’ on the
expression of a trait?
Reaction range
– Range of possibilities - upper and lower limits - that the genetic
code allows
– Individual inherits a range for potential expression of a trait
– Environmental effects determine where person falls within
these limits
 The Genetics of Similarity
Evolution
Natural selection
Evolutionary biologists and psychologists
Innate human characteristics
 Evolution & Behaviour
What is evolution?
– Change over time (generations) in the frequency
with which genes, & the characteristics they
produce, occur within an interbreeding population
Why do gene frequencies in a given
population change?
– Mutations
– Natural selection
 Evolution & Behaviour
Mutations and recombination
– Mutations
Random events and accidents in gene reproduction
during cell division
– Recombinations
Small components of genetic material can cross over
from one member of a chromosome pair to another
during the formation of eggs and sperm
– Create genetic variations, making evolution possible
– Can be passed to offspring
 Natural Selection
The evolutionary process
in which individuals with
genetically influenced
traits that are adaptive in a
particular environment
tend to:
– survive; and
– reproduce in greater
numbers
As a result, their traits become more common in the
population
Must be variation in a species’ characteristic in order for
natural selection to occur
Nature determines which genes survive and reproduce
 Adaptations
Products of natural selection
Allows organisms to meet recurring
environmental challenges to their survival,
increasing the organisms’ reproductive
ability
 Types of Adaptations
Broad
– Learn language, reason logically, etc.
Domain-specific
– Solve particular problem
Mate selection
Choosing safe food
Avoiding certain environmental hazards
Etc.
 Evolution
Natural selection cannot explain all of the
behavioural and physical traits that reflect a gene’s
success
E.g. why do some males birds have really bright
colour while females do not
– This characteristic would increase probability of being
observed by a predator and decrease likelihood for
survival
Other causes of evolution must also occur
– Sexual selection
A gene’s fate is decided by members of either the other sex or
the same sex, with which one is competing
 Sexual selection
Intersexual selection:
– a member of one sex chooses a mate from the
other sex on the basis of certain characteristics
– E.g. females choosing males based on physical
characteristics
Intrasexual selection:
– members of the same sex compete for a partner
of the other sex
Two males have to compete for attention of females
– E.g. males with brighter colouring better at attracting
females, females don’t need bright colour because aren’t
competing
 Innate Human Characteristics
Because of the process of evolution that humans
have undergone many characteristics are
– present at birth in all humans
– or develop quickly as a child matures
Examples
– Infant reflexes, e.g. sucking reflex
– Interest in novelty
– Desire to explore and manipulate objects
– Impulse to play and fool around
Wanting to explore and play can be adaptive
– Basic cognitive skills
E.g. concepts of greater than, less than, identify faces, interpret
gestures and expression, etc.
Thought to have helped our ancestors survive and reproduce
 Human Nature
More common aspects of human behaviour:
– Innate ability to acquire language
– Infants prewired to perceive certain stimuli, e.g.
more responsive to human faces
– Need to belong to a group
– Some basic emotions seem universal
 Evolution and Sexual Strategies
Due to different kinds of survival and mating
problems, the sexes have evolved differently in the
areas of aggressiveness, physical dominance, and
sexual strategies
– Males compete with other males for access to females
– Females conceive and carry only a limited number of
pregnancies so they choose fewer, more dominant
males with good resources and high status
 Evolutionary Psychologists and the
Question of Gender
Focus on commonalities of human mating and dating
around the world
 Mate Preference
What are people looking for in mates?
Across cultures similarities exist in mate preference
 What do men & women want in
an ideal mate?
For both men & women:
– Mutual attraction, dependability, emotional
stability
– Kindness, intelligence, understanding
 Attraction and Symmetry
Facial symmetry is one factor involved in whether men and
women perceive someone as attractive.
– Humans are genetically programmed to have
symmetrical features
Research has shown that individuals will identify the most
symmetrical faces as attractive even when the differences
are so slight they cannot explain why they chose the
symmetrical face over the asymmetrical.
Physical characteristics often play a role is whether we
approach people, want to date them, etc.
– However, symmetry is likely to be less important than
other qualities in the long term.
 Spatial Memory
Evolutionary psychologists believe that the brain has a set of
cognitive adaptations for solving problems related to survival and
reproductive fitness.
They also believe that male and female problem solving differs
because they faced different survival issues.
One sex difference reported involves solving the mental
rotation task.
Males tend to be quicker and more accurate in solving these
problems.
It should be noted that females outperform males on
different types of spatial tasks, specifically, tests involving
memory for the spatial location of objects (see Figure
3.7). This may be due to females’ evolutionary role as a
gatherer rather than as a hunter.
A biological and evolutionary perspective might hypothesize that
over the course of human evolution the male brain became
specialized for mental rotation tasks.
Spatial Memory
 3.2 Learning Objectives
Know the key terminology associated with nerve
cells, hormones, and their functioning.
Understand how nerve cells communicate.
Understand the ways that drugs and other
substances affect the brain.
Understand the roles that hormones play in our
behaviour.
Apply your knowledge of neurotransmitters to
form hypotheses about drug actions.
Analyze the claim that we are born with all the
nerve cells we will ever have.
 Communication in the nervous
system
The structure of the neuron
Neurons in the news
How neurons communicate
Chemical Messengers
 Neurons
Building blocks of the nervous system
which are linked together in circuits
Vary greatly in shape and size
 Types of Neurons

Neurons can differ in form and
function.
For example, motor neurons carry
messages away from the brain and
spinal cord and toward muscles that
control their flexion and extension.
 Glial Cells
Support, nourish, insulate, protect neurons
Surround neurons and hold them in place
Manufacture nutrient chemicals neurons need
Absorb toxins and waste materials that can damage neurons
Guide neurons to targeted brain location during prenatal
brain development
Help determine which neural connection get strengthened
and those that become weakened
Help form the blood-brain barrier which prevents a wide
range of substances, including toxins, from entering the brain
Synchronize activity of billions of neurons (comprise NS)
Start immune responses in the brain
 Myelin Sheath
Fatty insulation layer derived from glial
cells
– CNS – myelin derived from oligodendrocytes
– insulates axon from electrical activity
– acts to increase rate of transmission of signals
Up to 150 m/s
– nodes of Ranvier
gaps that exist in myelin sheath along axon
myelin is absent or very thin
– signals jump from one gap to next in
myelinated neurons
– Some neurons are unmyelinated
0.5 to 10 m/s
 Myelin Sheath
Multiple sclerosis
– neurological disorder characterized by
demyelination of axons
– immune system attacks myelin sheath
– Loss of sensation
– Vision problems
– Jerky, uncoordinated movements and
eventually paralysis
 Structure of a Neuron
Dendrites
– receive information from other neurons and
transmit towards the cell body
Cell body (soma)
– keeps the neuron alive and determines
whether it will fire
– Contains genetic information determining
cell function
Axon
– extending fibre that conducts impulses away
from the cell body and transmits to other
neurons, glands or muscles
– Branches at end to form a number of axon
terminals
 Nerves
A collection of fibres from individual neurons
– Typically the axons
– Sometimes dendrites
43 pairs of peripheral nerves
– Most enter through spine
– 12 pairs directly connect to brain
Cranial nerves
 Past assumptions:
1. Damaged or injured neurons in CNS could
not grow back (regenerate)
Evidence against this assumption
– Animal studies
» Regrowing of severed axons in spinal cord when
treated with certain nervous system chemicals
2. No new neurons in CNS were produced
after birth in mammals
Research with mice
– New neurons were created from immature cells from
mouse brains
» Referred to as neurogenesis
 Neurogenesis
– The production of new
neurons from immature
stem cells
Stem cells
– Immature cells that renew
themselves and have the
potential to develop into
mature cells
– These cells exist in the
human brain and other
organs
 Stem-Cell Research
Embryonic stem cells appear most promising in
developing treatments for cancers, organ and brain
diseases (e.g., Alzheimer’s)
Currently have ethical debate over their use
– Stems cells gotten from aborted fetuses or from embryos
consisting of a few cells
New techniques try to extract them without harming
the embryo
McGill team has had some success in transforming
adult cells into brain tissue
Have reprogrammed adult cells (e.g. skin cells) into
stem cells (induced pluripotent stem cells) – 2007
– 2012 Noble Prize winners for medicine
– http://news.ca.msn.com/world/nobel-awarded-for-stem-cell-
early-cloning-work
How Neurons Communicate: An
Electrochemical Process
Neurons:
– Generate electricity
– Release chemicals
Cell membrane of neurons acts as selective
filter allowing some substances to enter
and leave the neuron and preventing other
substances from doing so
How Neurons Communicate: An
Electrochemical Process
Neurons
– have a resting potential of -70 millivolts
– creating a state of polarization
– surrounded by a salty liquid environment which
has a high concentration of sodium ions (Na+)
– inside has some positively charged potassium
ions (K+) and many other negatively charged ions
– inside of cell more negative than outside of cell
– combination creates the resting potential
 Action Potential
Electrical part of electrochemical process is
the Action Potential
Sudden reversal in the membrane’s voltage
Depolarization = Shift in voltage from
minus to plus
Resting = minus 70 mV (inside cell)
Shift to plus 40 mV (inside cell)
 Action Potential
Dendrites - stimulated by axons of other
neurons and cause a small shift in the cell
membrane’s electrical potential
Graded potential – a change in electrical
potential of a neuron that is proportional to
the intensity of the incoming stimulation,
but not sufficient to produce an action
potential
If graded potential (partial depolarization) reaches
-55 mV (action potential threshold), neuron fires
and an action potential occurs
Action potential threshold – intensity of
stimulation needed to produce an action potential
 Action Potential
Unlike graded potentials, which vary in
proportion to the intensity of the
stimulation, action potentials occur
with maximum intensity or they do not
occur at all – this is referred to as the
all-or-none law
 Action Potential
The membrane potential is changed by graded
potentials acting on ion channels which are small
protein structures in cell membrane
Each ion channels allows specific ions to enter or
leave the neuron
When the action potential threshold is reached ion
channels are opened and Na+ ions flow into
neuron
– making membrane voltage more positive
(depolarization)
When there is complete depolarization +40 mV this
constitutes the action potential
 Action Potential
Na+ ion channels stay open for short period of time
K+ channels are opened and K+ leaves the neuron in
order to return the neuron to resting state, -70 mV inside
the cell
The action potential appears to flow along the
membrane, however, there is not a single action
potential, a new one is generated at each section of the
cell membrane
– In myelinated axons, action potential hops from one Node of
Ranvier to the next
After the action potential
– K+ ions pumped back into the neuron and
– Na+ pumped back to the outside of the cell
– to restore the original balance of ions so that another action
potential can occur
 Action Potential
After the action potential there occurs a
refractory period
– A time period where the membrane is not
excitable and another action potential cannot be
discharged
– This limits the rate at which action potentials
can occur within a cell
Action potentials are identical to one
another
– Thus information about the strength of the
stimulus can be communicated by increasing
the rate of firing or by increasing the number of
neurons that are firing
Resting Potential to Action Potential
Communication Between Neurons
Synaptic Transmission
Synapse
– Comprised of
Axon terminal,
The synaptic cleft,
Membrane of dendrite or cell body
Neurons do NOT make physical contact
Communicate via chemicals called
neurotransmitters
Synaptic cleft
– Gap between axon terminal & dendrite
 Communication Between Neurons
Chemical part of electrochemical process
Neurotransmitters
– Chemicals produced by neurons
– Synthesized inside neuron
– Stored in synaptic vesicles
– Released by presynaptic neuron
Bind to receptor sites in postsynaptic neuron
– Specific neurotransmitters bind only to specific sites!
– Cause a chemical reaction to occur that will either excite or
inhibit the postsynaptic neuron
Numerous types of neurotransmitters have been
identified, each with its own unique shape.
– However, neurons tend to only send and receive a limited
number of neurotransmitters.
Synaptic Transmission
 Effect of Neurotransmitters
Excitatory neurotransmitter
– Depolarizes neuron’s membrane
– Stimulates inflow of sodium ions
– Increases likelihood of action potential
Inhibitory neurotransmitter
– Hyperpolarizes neuron’s membrane
– Stimulates ion channels to allow K+ to flow out
– Decreases likelihood of action potential
– Allows fine-tuning of responses
Prevents uncoordinated discharges (e.g., seizures)
Deactivation of Neurotransmitters
Neurotransmitters activate or inhibit neuron
until deactivated
Two major ways:
– Breakdown
Other chemicals in the synapse break down
neurotransmitters into their chemical components
– Reuptake
Neurotransmitters are taken back into presynaptic
axon terminal
 How neurons communicate
The message that reaches a final destination
depends on:
– Rate at which individual neurons are firing
– How many are firing
– What types of neurons are firing
– Where the neurons are located
– Degree of synchrony among different neurons
Transmission of messages doesn’t depend on how
strongly individual neurons are firing
– Firing of neuron is all-or-none
 Chemical Messengers
Neurotransmitters
Endorphins
Hormones (Endocrine System)
 Neurotransmitter (NT)
Chemical substance released by a transmitting
neuron at the synapse and capable of affecting the
activity of a receiving neuron
Abnormal levels can have negative effects
– However abnormal levels do not necessarily
cause the disorder
 Major Neurotransmitters
Serotonin
– Influences neurons involved in appetite, sleep, sensory
perception, temperature regulation, pain suppression,
aggression, and mood
– Undersupply associated with
Depression
Sleeping disorders
Eating disorders
Dopamine
– Voluntary movement, attention, emotion, reward
– Undersupply
Parkinson’s
Depression
– Oversupply
schizophrenia
 Major Neurotransmitters
Acetylcholine (ACh)
– Muscle action, memory, attention, cognitive functioning
– Junction between neurons and skeletal muscles
Voluntary movement
– Undersupply
Related to memory loss in Alzheimer’s
Norepinephrine
– Increased heart rate, slowing of intestinal activity during
stress, learning, memory, dreaming, emotion, waking,
attention
– Regulating stress response
– Undersupply
depression
 Major Neurotransmitters
Gamma amino butyric acid (GABA)
– Major inhibitory NT, important in controlling all
behaviour
– Abnormal levels implicated in:
Sleeping disorders
Eating disorders
Convulsive disorders, e.g. epilepsy
– Destruction of GABA-producing neurons in
Huntington’s
Tremors
Loss of motor control
Glutamate
– Major excitatory NT
– Ability to form new memories
– Abnormal functioning – trigger of epileptic seizure
 Types of Neurotransmitters
Table 3.1 Major Neurotransmitters and Their Functions

Neurotransmitter Some Major Functions
Glutamate Excites nervous system; memory and
autonomic nervous system reactions
GABA (gamma-amino butyric acid) Inhibits brain activity; lowers arousal, anxiety,
and excitation; facilitates sleep
Acetylcholine Movement; attention
Dopamine Control of movement; reward-seeking
behaviour; cognition and attention
Norepinephrine Memory; attention to new or important stimuli;
regulation of sleep and mood
Serotonin Regulation of sleep, appetite, mood
 Drug Effects on Neurotransmission

Agonists - are drugs that enhance or mimic the effects of a
neurotransmitter’s action.
Antagonists - inhibit neurotransmitter activity by blocking
receptors or preventing synthesis of the neurotransmitter.
 Endorphins
Also known as endogenous opioid peptides
Effects
– Reduce pain
– Promote pleasure
Thought to play role in
– Appetite, sexual activity, blood pressure, mood, memory,
learning
Some functions as neurotransmitters, same as hormones
Others modulate the effects of neurotransmitters
Were discovered because morphine an opiate was
discovered to bind to opiate receptor sites in the brain
Endocrine System
Consists of
numerous glands
throughout body
Conveys
information from
one part of the body
to another in form
of hormones
Interacts with
nervous system &
immune system
 Endocrine System
Hormones – chemical messengers that are secreted
from its glands into the bloodstream
Many cells have receptors that respond to specific
hormones
Hormones
– Promote bodily growth
– Aid in digestion
– Regulate metabolism
– Sexual development and behaviour
– Etc.
 Endocrine System
Some neurotransmitters are also classified
as hormones
– E.g. norepinephrine
 Endocrine System
Examples of hormones:
– Melatonin
Secreted by pineal gland
Regulates biological rhythms
Promotes sleep
– Adrenal hormones
Produced by adrenal glands
Involved in emotion and stress
Mobilizes body’s resources
Also increase in response to
– Heat, pain, cold, burns, physical exercise, etc.
Prolonged exposure can have detrimental effects
E.g.s
– Cortisol – increases blood sugar levels, boosts energy
– Epinephrine (adrenalin)
– norepinephrine
 Endocrine System
Examples of hormones:
Sex hormones
– Regulates development and functioning of
reproductive organs
– 3 main types
Androgens
– E.g. testosterone
– Masculinizing hormones
– Produced mainly in testes, but also in adrenal glands
and ovaries
– Start the physical changes males go through at
puberty
– Hair growth in both sexes
 Endocrine System
Examples of hormones:
Sex hormones
– 3 main types
Estrogens
– Feminizing hormones
– Start physical changes in females at puberty
– Influence course of menstrual cycle
– Produced mainly in ovaries, also in testes and adrenal
glands
Progesterone
– Contributes to growth and maintenance of uterine lining
– Produced mainly in ovaries, also in testes and adrenal
glands
 Endocrine versus Nervous
System
Nervous system Endocrine system
– Transmits – Transmits information
information rapidly slower, because
– Uses nerve impulses depends on rate of
to transmit blood flow
information
– Uses hormones via the
– Communicates with
a smaller number of bloodstream to
cells transmit information
– Communicates with
larger number of cells
 3.3 Learning Objectives
Know the key terminology associated with
the structure and organization of the nervous
system.
Understand how studies of split-brain
patients reveal the workings of the brain.
Apply your knowledge of brain regions to
predict which abilities might be affected
when a specific area is injured or diseased.
 Nervous System
 Composed of neurons
 It gathers and processes information,
produces responses to stimuli, and
coordinates the workings of different cells
 Its processes underlie thoughts, feelings,
and behaviour
Divisions of the Nervous System
 Divisions of Nervous System
1. Central Nervous System (CNS)
– Brain and Spinal Cord
– Receives, processes, interprets, and stores
incoming sensory information
– Sends out messages destined for glands,
internal organs and muscles
2. Peripheral Nervous System
– Connects CNS with muscles, glands, and
sensory receptors
– Subdivided into:
Somatic nervous system
Autonomic nervous system
 The Central Nervous System

Spinal cord
– A collection of neurons and
supportive tissue running from the
base of the brain down the centre of
the back
– Protected by spinal column
 Central Nervous System: Spinal cord
Spinal Cord
– Most nerves enter / leave
CNS through spinal cord
– Motor neurons exit front of
spinal cord and sensory
neurons enter back of spinal
cord
– Spinal reflexes do not
involve brain
Though there can be connections to
the brain, so can sometimes be
influenced by emotion, etc.

Structure
– Central portion = grey
neuron cell bodies
– Outer portion = white
myelinated axons
 Central Nervous System: Brain
Brain
– 3 pounds
– 2% of body weight
– 20% of oxygen
Metabolic rate
– Remains relatively constant day / night
– Increases slightly when dreaming
Number of structures controlling behaviour
– both voluntary & involuntary
2 Hemispheres (left & right)
 Peripheral Nervous System
Contains all components of nervous systems
outside of brain and spinal cord
 Peripheral Nervous System
Types of nerves:
1. Sensory - Carry input messages from
special receptors in muscles, skin, other
internal and external sense organs to
spinal cord and then passed onto brain
2. Motor - Transmit impulses from brain &
spinal cord to glands, muscles, & organs
 Peripheral Nervous System
Subdivided into:
1. Somatic nervous system (skeletal NS)
– Consists of sensory & motor neurons
– Sends information from sensory organs to CNS
– Sends information from CNS to muscles to control
voluntary movements
2. Autonomic nervous system (2 divisions)
– Controls glands, blood vessel, & smooth muscles in
body organs
– Controls involuntary movements/functions
i. Sympathetic nervous system: arouses body ‘fight or
flight’
ii. Parasympathetic nervous system: slows down body
processes
 The Brain and Its Structures
Table 3.2 Major Brain Regions, Structures, and Their Functions
Regions and Structures Functions
Hindbrain Blank
Brainstem (medulla and pons) Breathing, heart rate, sleep, and wakefulness
Cerebellum Balance, coordination and timing of movements; attention and emotion
Midbrain Blank
Superior colliculus Orienting visual attention
Inferior colliculus Orienting auditory attention
Forebrain Blank
Basal ganglia Movement, reward processing
Amygdala Emotion
Hippocampus Memory
Hypothalamus Temperature regulation, motivation (hunger, thirst, sex)
Thalamus Sensory relay station
Cerebral Cortex Blank
Occipital lobe Visual processing
Parietal lobe Sensory processing, bodily awareness
Temporal lobe Hearing, object recognition, language, emotion
Frontal lobe Thought, planning, language, movement
 The Hindbrain
The hindbrain controls the basic,
life-sustaining processes
The brain stem is located at the
top of the spinal cord.
consists of the medulla and
the pons.
Nerve cells in the medulla
connect with the body to
perform basic functions,
such as breathing and
heart rate.
The pons contributes to
general levels of
wakefulness and play a
role in dreaming.
 The Hindbrain
The reticular formation sends signals to the cortex to
influence attention and alertness and also communicates
with cells in the spinal cord involved with motor control.
The cerebellum is specialized in the coordination and
timing of movements.
is the lobe-like structure at the base of the brain that is
involved in the monitoring of movement, maintaining
balance, attention, and emotional responses.
Involved in remembering simple skills and acquired
reflexes
Plays a part in higher cognitive tasks as well:
analyzing sensory information
solving problems
understanding words
 The Midbrain
Midbrain - resides just above the
hindbrain and primarily functions as a
relay station between the sensory and
motor areas.
The midbrain is involved with the
reflexive ability to identify the
location of sudden movements and
sounds.
The ability to capture your
visual attention is influenced by
the superior colliculus.
The ability to move your
auditory attention is influenced
by another midbrain structure,
the inferior colliculus.
 The Forebrain
Forebrain
the most visibly obvious region of
the whole brain, consists of
multiple interconnected structures
that are critical to such complex
processes as emotion, memory,
thinking, and reasoning.
Major structures include:
basal ganglia,
limbic system,
hypothalamus,
Thalamus
Cerebral cortex
 The Forebrain
Basal Ganglia - are involved in facilitating planned
movements and skill learning, and integrating sensory and
movement information with the brain’s reward system.
The basal ganglia are involved with planned movement,
skill learning, and pleasurable emotions.
the nucleus accumbens is a part of the basal ganglia that
accompanies all sorts of pleasurable experiences, such as
sexual excitement, thrills (from gambling), and satisfying
a food craving.
Addicting drugs, such as cocaine, target dopamine
transmission in the nucleus accumbens.
 The Forebrain
Limbic System
is an integrated network involved in emotion and
memory.
 The Forebrain
Limbic System Structures:
Amygdala
facilitates memory formation for emotional events,
mediates fear responses, and appears to play a role in
recognizing and interpreting emotional stimuli,
including facial expressions.
The amygdala connects with structures in the nervous
system responsible for adaptive fear responses, such as
freezing in position when a threat is detected.
Hippocampus
is critical for learning and memory, particularly the
formation of new memories.
enabling us to form spatial memories for navigating the
environment
Hypothalamus
serves as a sort of thermostat, maintaining body
temperature and it also affects drives (e.g., aggression
and sex) by interacting with the endocrine system.
Regulates autonomic nervous system
 The Forebrain
Thalamus
Relays sensory messages to
the cerebral cortex
– Routes sensory
information to
appropriate place (e.g.,
visual goes to visual
centres; auditory to
auditory centres)
Includes all sensory
messages except those from
sense of smell
 The Cerebral Cortex
Cerebral Cortex
is the convoluted, wrinkled
outer layer of the brain that is
involved in multiple higher
functions, such as thought,
language, and personality
 The Cerebral Cortex
Largest brain structure
This upper part of the brain is divided into
two cerebral hemispheres
– connected by the corpus callosum
is a densely concentrated bundle of nerve
cells connecting the two hemispheres.
– Generally
Left hemisphere controls right side of
body
Right hemisphere controls left side of
body
– Two hemispheres involved in different tasks
Referred to as lateralization
In charge of most sensory, motor and
cognitive processes
 Cerebral Cortex
Cell bodies in cortex form a grey tissue
(grey matter)
75% of area lies within fissures (folds) –
great amount of tissue compressed into a
small space
– Provide landmarks for dividing cortex into major
areas
– 4 lobes
Each lobe has a particular set of functions, but are also
connected by nerve cells to each other and other regions of
the midbrain and hindbrain
Lobes of the Cerebral Cortex
 Lobes of the Cerebral Cortex
Occipital lobes
– Contains visual cortex – processing of visual
information
Parietal lobes
– are located behind the frontal lobes, are involved in
our experiences of touch as well as bodily awareness.
– Parts of these lobes involved in attention and a variety
of mental operations
– Contains somatosensory cortex
 Parietal Lobe
Somatosensory Cortex
– Receives specific sense information from
opposite side of body
– Receives sensory information that gives rise to
the sensations of cold, heat, touch, sense of
balance, and sense of body movement
 Motor & Somatosensory Cortex
Amount of cortex
devoted to body part
proportional to
sensitivity of that
part
– Governs opposite
side of body
 Lobes of the Cerebral Cortex
Temporal lobes
– Memory, perception,
emotion
– involved in hearing,
language, and some
higher-level aspects of
vision such as object and
face recognition.
– Contains auditory cortex
Processes sounds
– Left lobe, Wernicke’s area
Involved in language
comprehension
 Frontal lobes
29% of the human cortex
Self-awareness; planning; initiative; responsibility;
emotional experience; creative thinking; social
judgment
allow you to deliberately guide and reflect on your own
thought processes.
Damage – loss in ability to plan and carry out a
sequence of actions, and loss in ability to judge the
order in which a series of events took place
Prefrontal cortex
– Located just behind forehead
– Seat of executive functions
– Goal-setting; judgment; strategic planning; impulse control
– Involved in personality
 Frontal Lobes
Left lobe, Broca’s area
– Language production
– Important for ability to perform
sequence of fine motor
movements required for speech
– Involved in the ability to use
grammar
Motor Cortex
– Controls movement on opposite
side of body
– Controls movement of over 600
muscles involved in voluntary
movement
– Located at rear of frontal lobe
 Hemispheric Specialization
The two hemispheres of the brain may
look the same, but perform different
functions, a phenomenon called
hemispheric specialization.
i) Basically, the right side
specializes in cognitive tasks that
involve visual and spatial skills,
recognition of visual stimuli, and
musical processing.
ii) The left hemisphere is more
specialized for language and math.
 Hemispheric Specialization
Research on split-brain patients shows us:
– Nearly all right-handed and the majority of left-handed
individuals process language mainly in the left hemisphere
– Left side more involved in some symbolic, logical, and
sequential tasks
– Many researchers believe in left-hemisphere dominance
Left hemisphere exerts control of right hemisphere
– Others insist the right-hemisphere is not inferior
It is superior in
– spatial visual problem-solving (e.g. map reading),
– Facial recognition
– Read facial expressions
Involved in comprehending non-verbal sounds
Has some language abilities
Shouldn’t think of the two hemispheres as two minds as
the two halves co-operate on many tasks
 The Corpus Callosum
Millions of myelinated
axons connecting the
brain’s hemispheres
Provides a pathway for
communication between
hemispheres
If surgically severed to
treat epilepsy,
hemispheres cannot
communicate directly
 Split Brain Experiments
Sever corpus callosum
hemispheres no longer
communicate - but optic
nerve remains intact
With optic nerve
– Fibers cross over (optic
chiasm)
Right visual field - processed
in left hemisphere
Left visual field - processed
in right hemisphere
Word presented to right
visual field – could verbally
describe what they saw
Word presented to left visual
field – could not verbally
describe what they saw
 Split-Brain Experiment
Subjects were presented information to one or the
other side of their brain
E.g. presented photographs with two different faces
pasted together
– Presented images quickly – half of image presented to
left visual field and half presented to right visual field
– Person had to:
Say what they had seen
Point with left had to face they had seen
Split-Brain Experiment
 Split-Brain Experiment
Results
– Patients identified verbally the pictures to the right (i.e.,
boy)
Speech centers are typically in the left hemisphere which
receives input from the right visual field
– When asked to point to the face seen, the patients pointed
to the left picture (I.e. man with moustache)
Left hand controlled by right hemisphere which gets input from
the left visual field
– Didn’t notice anything different about the original
photographs they viewed
Split-Brain Experiment
 3.4 Learning Objectives
Know the key terminology associated with
measuring and observing brain activity.
Understand how studies of animals with brain
lesions can inform us about the workings of the
brain.
Apply your knowledge of neuroimaging techniques
to see which ones would be most useful in
answering a specific research question.
Analyze whether neuroimaging can be used to
diagnose brain injuries.
 Studying the Brain
Methods:
1. Neuropsychological Test
2. Destruction & Stimulation
3. Electrical and Magnetic Detection
4. Scanning the brain
 Studying the Brain
Neuropsychological Tests
– Measure verbal & nonverbal behaviours known to be
affected by certain types of brain damage
– Used to evaluate individuals who have had damage to their
brain due to accident or disease

Destruction & Stimulation
– Damage specific areas of the brain through use of chemical,
cold, heat, or electricity and observe the effects of creating
this damage (lesion method)
– Surgically remove certain areas of the brain and examine
effects
– Stimulate areas with electricity / chemicals and observe the
effects on behaviour
 Studying the Brain
Transcranial magnetic stimulation (TMS)
can impair brain activity only temporarily
and can be safely applied to humans.
– is a procedure in which an
electromagnetic pulse is delivered to a
targeted region of the brain.
– This pulse interacts with the flow of ions
around the neurons of the affected area.
The result is a temporary disruption of
brain activity.
TMS can also be used to stimulate, rather than temporarily
impair, a brain region.
Has been used to stimulate under-active areas of the brain
associated with depression.
Has been used to stimulating nerve cells that were impaired by
stroke related damage.
 Structural Neuroimaging
is a type of brain scanning that produces images of
the different structures of the brain.
– Computerized tomography (CT scans)
– Magnetic Resonance Imaging (MRI)
– Diffusion tensor imaging
is a form of structural neuroimaging allowing researchers or
medical personnel to measure white-matter pathways in the
brain.
 Scanning the Brain

CT scans
– Computerized axial
tomography
– Use X-rays to take pictures
of narrow slices of brain
– Brain image then re-
constructed
– Locating areas of damage
within the brain can help
us learn about the
relationship between brain
damages and
psychological functioning
 Scanning the Brain
MRI
– Magnetic resonance imaging
Magnetic fields and radio
frequencies used to produce
vibrations in nuclei of water
atoms
Vibrations picked up by special
receivers
Can study brain structure
Takes pictures several minutes a
part
 Functional Neuroimaging
A type of brain scanning that scanning that provides
information about which areas of the brain are
active when a person performs a certain task
– Electroencephalogram (EEG)
– Magnetoencephalography (MEG)
Measures the tiny magnetic fields created by the electrical
activity of nerve cells in the brain - few ms after it occurs
– Positron Emission Tomography (PET)
– Functional magnetic resonance imaging (fMRI)
 Electrical Detection
EEG - electroencephalography
Records electrical activity of
thousands of neurons through
electrodes
Some EEG patterns correspond to
wakefulness & sleep
Use EEG to examine changes in
brain activity when a particular
event occurs, such as the
presentation of a stimulus
– Show how long it takes the brain to process
stimuli
– Can’t show structures, anatomy, or
functional regions of the brain
 Electrical Detection
Needle electrodes
– Can be inserted into an exposed brain or
through holes in skull
– Allows for gathering of more precise
information
– Can stimulate the brain or record activity
 Scanning the Brain
PET scans
– Positron emission tomography
A method for analyzing
biochemical activity in the
brain, using injections of a
glucose-like substance
containing a radioactive
element
Areas of the brain that are
activated during a task will
have higher glucose
concentrations and will show
up on the scan
 Scanning the Brain
PET Scan
 Functional MRI

measures brain activity by
detecting the influx of
oxygen-rich blood into
neural areas that were just
active.
detects increased blood
flow to active areas, and
displays structure and
function
– can capture images in as
little as 30 ms
 Studying the Brain - evaluation
Brain-scan images can sometimes convey oversimplified
and misleading impressions
– E.g. Manipulating color scales in PET scan can emphasize a
small contrast between two brains or minimize large contrast
– Although researchers have shown that the activity that we
see in fMRI images is actually linked to the firing of
neurons, we still need to be cautious when interpreting fMRI
data.
One reason is that it is correlational in nature.
just because a brain area is active while we perform a task
does not mean that it is necessary for that task
– Brain scans don’t indicate what is happening in the brain
(mentally or physically)
Indicate where things are occurring - not how or why