bio psych

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dem

Cards (78)

Nervous system 
A specialised network of cells making up our internal communication system. It helps to collect, process and respond to information in our environment and co-ordinate the working of organs and cells
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Central nervous system (CNS) 
Division of the human nervous system that is responsible for complex commands and decisions. It integrates incoming information and co-ordinates activity across the whole body. It is made up of the brain and spinal cord
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Brain 
An organ made up of a mass of nerve tissues. It is our centre of conscious awareness and allows us to have higher mental processes
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Spinal cord 
Extension of the brain which passes messages to and from the brain. It connects nerves to the peripheral nervous system
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Peripheral nervous system (PNS) 
Division of the human nervous system that sends messages to and from the CNS. It links the outside world with the CNS and controls muscles and glands
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Somatic nervous system 
A voluntary part of the peripheral nervous system, controlling muscle movement and receives information from sensory receptors on the body. Works with the CNS to direct muscles to act
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Autonomic nervous system 
Involuntary part of the PNS that transmits information to and from internal organs and helps control vital functions
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Sympathetic nervous system 
The fight and flight response which prepares the body to respond to threat
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Parasympathetic nervous system 
The rest and digest response which restores the body back to its usual state of relaxation
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Parasympathetic vs Sympathetic 
Parasympathetic: constrict pupils, increase saliva production, decrease heart rate, dilate blood vessels, constrict bronchi, increase stomach and intestine motility, contract bladder
Sympathetic: dilate pupils, decrease saliva production, increase heart rate, constrict blood vessels, dilate bronchi, reduce stomach and intestine motility, relax bladder
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Endocrine system 
An information system in the body that instructs glands to release hormones into the bloodstream. Slower but more powerful than the nervous system, with longer lasting effects
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Gland 
Organ in the body that produces hormones
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Hormone 
Chemical substances that circulate in the bloodstream and only affect target organs
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Fight or flight response
Stress perceived in the hypothalamus
2. Activates the pituitary gland to trigger activity in the autonomous nervous system
3. Stress hormone adrenaline is released from the adrenal gland
4. The ANS switches to the sympathetic state
5. Adrenaline causes physiological changes in the body which produces arousal needed for fight or flight
6. When threat passes, the parasympathetic branch of the ANS returns the body to its resting state
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Neuron 
Building blocks of the nervous system. Nerve cells which process and transmit messages chemically and electrically. Transmits impulses from a receptor to the spinal cord or brain
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Types of neurons 
Sensory neuron: long dendrites, short axons, allows sensory and motor neurons to communicate
Relay neuron: short dendrites, short axons, sends impulses between CNS and PNS
Motor neuron: short dendrites, long axons, sends impulses from CNS to muscle, organ or gland
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Synaptic transmission 
Electrical impulse (action potential) travels down the presynaptic neuron towards the synapse
2. This triggers the release of neurotransmitters from the vesicles and into the synapse
3. The neurotransmitters diffuse across the synapses and bind with receptor sites on the postsynaptic neuron
4. The chemical signal is converted back to an electrical signal to continue the process again in the postsynaptic neuron
5. Unused neurotransmitters are taken back up to the presynaptic neuron via reuptake valves and they go back to the vesicles to be reused on the next transmission
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Excitation 
A neurotransmitter that increases the positive charge of the presynaptic neuron, increasing the likelihood that it will fire (e.g. adrenaline)
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Inhibition 
A neurotransmitter that increases the negative charge of the presynaptic neuron, decreasing the likelihood that it will fire (e.g. serotonin)
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Summation 
The process which determines whether a neuron will fire: 1) Sum up the excitatory and inhibitory influences, 2) If overall effect is inhibitory - less likely to fire, 3) If overall effect is excitatory - more likely to fire. Action potential will only be triggered if the sum meets the threshold.
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Localisation of function 
The idea that certain functions have certain locations within the brain
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Localised brain functions 
Motor cortex: Controls voluntary movements, in the back of the frontal lobe
Somatosensory cortex: Receives information from touch receptors, in the parietal lobe
Visual cortex: Processes visual information, in the occipital lobe
Auditory cortex: Processes sound, in the temporal lobe
Broca's area: Main centre of speech production, in the frontal lobe
Wernicke's area: Concerned with speech comprehension, in the temporal lobe
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The motor cortex in the left controls movement in the right hand side of the body, and the motor cortex in the right controls movement in the left hand side of the body
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The right hemisphere's visual cortex processes visual information received by the left eye and vice versa
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Neurons on one side of the auditory cortex detect high frequency sounds, but neurons on the other side detect low frequency sounds
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Broca's aphasia 
A language disorder caused by damage in a specific area of the brain that controls language expression and comprehension. Patients struggled with language production, couldn't speak full sentences and took a long time to get words out.
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Wernicke's aphasia 
Language was easily formed but the sentences were not comprehensive, with impaired meaning and poor comprehension. Suggests that damage to Wernicke's area causes damage to language interpretation.
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Hemispheric lateralisation 
The idea that the two halves of the brain are functionally different and that each hemisphere has functional specialisation
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Contralateral 
Where each hemisphere controls the opposite side of the body
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Problems of causation in Sperry's research - all patients had epilepsy and there was no control group, so it cannot be certain that non-epileptic people have the same level of lateralisation in their brains
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Fink et al. used PET scans and found that areas in the right hemisphere were more active during visual processing tasks
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Brain plasticity 
The brain's ability to alter its structure and function in reaction to the environment and through experience
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How brain plasticity occurs 
Impulses travel along neurons and travel to the next neuron via a synapse
2. Neural pathways are created as new information is passed from one neuron to another
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Objects placed in the left hand 
Processed in the right hemisphere
Couldn't be spoken about
Participant could find a similar object
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Objects placed in the right hand
Processed in the left hemisphere
Could be spoken about
Could also find a similar object
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Left hand drawings 
Clearer and better, showing superiority of right hemisphere for visual motor tasks
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Problems of causation - all patients had epilepsy and there was no control group so it cannot be certain that non-epileptic people have the same level of lateralisation in their brains
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Fink et al used PET scans and found that areas in the right hemisphere were more active during visual processing tasks
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Neural pathways 
1. Impulses travel along neurons and to the next neuron via a synapse
2. New information is passed from one neuron to another
3. Pathways used more become stronger
4. Pathways not used regularly weaken
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Pruning 
Connections lost due to lack of use
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