HP1000 Biopsychology (W2).pdf

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The brain
Parts of the Brain: Anatomy, Structure & Functions

Structure of the brain

Hindbrain

Location Function

Medulla Top of the spinal Controls Sensory nerves coming from the
column life-sustaining left and right sides of the body
functions cross over (information from the left
(heartbeat, side of the body goes to the right
breathing, side of the brain, vice versa)
swallowing)

Reticular Network of neurons Responsible Allows people to ignore constant,
Formation running through the for attention, unchanging information (eg. white
middle of the alertness, noise) and become alert to changes
medulla and the arousal in information
pons and slightly
 beyond

Pons Above the medulla Influences Relays messages from between the
sleep, cerebellum and cortex (motor
dreaming, nerves carry messages from the
arousal brain to body)

Cerebellum Base of the skull, Controls all Learned reflexes stored here to
behind the pons involuntary, become more automatic
rapid, fine
motor
movement
(balance) +
muscle
coordination

Forebrain
- Limbic system, cortex, basal ganglia

Cingulate cortex In the cortex, right Important role in emotional and cognitive
above the corpus processing
callosum in the frontal
and parietal lobes

Limbic system: involved in emotions, motivation, memory, learning

Location Function

Thalamus Center of the brain Relay station. Processes sensory
information (hearing, sight, touch, taste)
that passes through it (except smell) before
sending it to the cortex

Hypothalamus Below and in front of Controls hunger, thirst, sexual behaviour,
 the thalamus; above the sleepwalking and waking, and emotions
pituitary gland
Also controls the pituitary gland

Hippocampus Temporal lobe Responsible for the formation of long-term
declarative memories

Amygdala Near the hippocampus Involved in fear response and memory of
fear so that people can respond to danger
quickly

Cortex: outermost part of the brain
Divided into two cerebral hemispheres connected by the corpus callosum

Cortical areas and Location Function
lobes

Occipital lobe Back and base of Processes visual information from the eyes
each hemisphere in the primary visual cortex

Visual cortex Occipital, temporal Identify and make sense of visual
and parietal lobes information from the eyes

Parietal lobes Top and back of the
cortex

Somatosensory At the front of the Processes Cells at the top of
cortex parietal lobes on information from the the brain receive
either side of the skin receptors for information from the
brain touch, temperature bottom of the body
and body position and vice versa

Temporal lobe Just behind the
temples

Primary auditory In the temporal lobe Language understanding
cortex
 Auditory association Analyses data about sound, allowing us to
area recognise pitch/ melody

Frontal lobe Front of the brain Higher mental functions of the brain:
planning, personality, memory storage,
complex decision making, language

Connected to the limbic system; helps in
controlling emotions

Motor cortex Frontal lobe Controls the movements of the body’s
voluntary muscles

Association areas of the cortex
- Made up of neurons in the cortex devoted to making connections between sensory
information coming into the brain and stored memories, images and knowledge
Association area Location Function

Broca’s area Left frontal lobe Associated with the production of speech,
speaking smoothly and fluently

Damage to Broca’s area: Broca’s aphasia
- Words will be halting and pronounced incorrectly

Wernicke’s area Left temporal lobe Involved in understanding/interpreting the
meaning of words

Damage to Wernicke’s area: Wernicke’s aphasia
- Speech is fluent but nonsensical (wrong words used)

Midbrain
- sensory and motor functions

Brain hemispheres

Contralateral pathways
 Right side of the brain controls left side of the body, and left side of the brain controls the
right side of the body

Corpus callosum: Connects the left and right hemispheres of the brain
- Split-brain patients (in which the corpus callosum has been severed to treat
epilepsy)

Hemispheric laterisation
- Depends on the task; tendency of each part of the brain to exert control over different
functions

- Left hemisphere specialises in tasks that involve sequence and analysis
- Right hemisphere processes information in a broader sense (perception,
visualisation, recognition of patterns etc.)
Methods to study the brain
Lesioning studies Brain stimulation

- Study individuals with damage in - Send mild electrical currents through
their brains the brain that causes neurons to
- For animals, researchers may react as if they have received a
deliberately damage specific areas message
of the brain - Does not change the brain neurons

Eg.
1. Deep brain stimulation (DBS) -
invasive
2. Transcranial magnetic Stimulation
(TMS) - non-invasive
3. Transcranial electrical current
stimulation (tECS) - non-invasive

Neuroimaging techniques
Brain structure Brain function

1. Computed Tomography (CT) 1. Positron emission tomography
Creates a digital structural image of the (PET)
brain using a series of x-rays Measures brain activity/ function by seeing
Relatively lower resolution, but can still aid which cells are using up the low-level
in detecting larger brain tumours etc. radioactive glucose that is injected in the
person’s brain
2. Magnetic Resonance Imaging (MRI)
Uses brief but powerful pulses of magnetic 2. Electroencephalography (EEG)
energy and radiofrequency energy to create Records electrical activity of cortical
highly detailed pictures of structures of the neurons (neurons in the cortex) using
brain electrodes placed on the scalp

3. Functional Magnetic Resonance 3. Magnetoencephalography (MEG)
Imaging (fMRI) Detects small magnetic fields generated by
Uses brief but powerful pulses of magnetic the electrical activity of neurons
energy and radiofrequency energy to
measure changes in blood oxygen levels in 4. Functional near-infrared
the brain, creating a ‘movie’ of changes in spectroscopy (fNIRS)
the activity of the brain Uses near-infrared light to measure
changes in blood-oxygen levels in the brain,
and hence brain activity
Nervous system

Neurons
- Specialised cell that receives and sends message within the nervous system
Dendrites Soma Axons Axon terminals

Receives messages Contains the Carries messages to Communicate with
from other cells nucleus + keeps the other cells. Ends of other cells
cell alive and axons branches to
functioning form axon terminals

Neurotransmission
- Sending of messages to other cells
Axon terminals contain synaptic vesicles which contain neurotransmitters
Axon potential travels down the axon of the presynaptic neuron to the synaptic
vesicles
Synaptic vesicles release their neurotransmitters into the synaptic gap
Molecules float across the synapse and fit themselves into the receptor sites of the
postsynaptic neuron
○ Receptor sites allow only particular molecules of a certain shape to fit into it

To clear the synapse for the next stimulation, reuptake occurs
Neurotransmitters end up back in the presynaptic neuron, the repackages into the
synaptic vesicles
Except ACh

Neurotransmitters
(found at the synapses)
Excitatory Inhibitory

Increases activity of postsynaptic neuron Decreases activity of postsynaptic neuron
Drugs may be
Antagonists Agonists

Block (receptor sites) which blocks/reduces Mimic/enhance the effects of a
a cell’s response to the action of other neurotransmitter on the receptor sites fo the
chemicals, neurotransmitters next cell

Increasing/decreasing activity of the cell

Central nervous system
- Made up of the brain and spinal cord

Spinal cord
- Long bundle of neurons connecting the brain and peripheral nervous system

Spinal cord reflex
Afferent (sensory) neurons Interneurons Efferent (motor) neurons

Neurons that carry Neurons in the centre of the Neurons that carry
information from the senses spinal cord that receives messages from the central
to the central nervous information from the afferent nervous system to the body
system neurons and sends
commands to the muscles
through the efferent neurons

Eg. touching a flame
An afferent neuron will send the pain message up to the spinal column, where it enters into
the central area of the spinal cord. The interneuron in that central area will then receive the
message and send out a response along an efferent neuron, causing your finger to pull back
Changes to synaptic connections
Neuroplasticity Neurogenesis Pruning

The ability to constantly Formation of new neurons Process of trimming unused
change both the structure (and hence synapses) brain connections, making
and function of many cells in neurons available for future
development
the brain in response to
trauma or experience

As people learn new things,
dendrites grow and/or
strengthen and new
synapses form in some
areas of the brain

Peripheral nervous system
- Made up of all the nerves and neurons not contained in the brain and spinal cord
- Allows the brain and spinal cord communicate with the sensory systems, enabling
them to control the muscles and glands of the body (senses, voluntary muscles)

Somatic nervous system
Sensory pathway Motor pathway

Nerves carry messages (containing afferent Nerves carry messages (containing efferent
neurons) from the senses to the central neurons) from central nervous system to
nervous system the voluntary muscles of the body

Autonomic nervous system
Sympathetic division Parasympathetic division

‘Fight-or-flight’ system. Gets the body ready ‘Rest-and-digest’ system. Returns the body
to deal with stress (heart pumps faster, to normal functioning after a stressful
pupils dilate etc.) situation ends, where the activity of the
sympathetic division will be replaced by the
activation of the parasympathetic division
 Typically active; responsible for most
day-to-day bodily functioning (eg. regular
heartbeat, normal breathing)

Endocrine system
Endocrine glands secrete chemicals (hormones) directly into the bloodstream, carrying them
to their target organs
- Influences body functions, behaviours, emotions, and development

Pituitary gland
Master gland: controls/ influences all other endocrine glands
Located just below the brain and is connected to the hypothalamus