biological bases of behavior
DESCRIPTION
Biological Bases of Behavior. Unit III. Neural processing and the endocrine system. Neurons: The Origin of Behavior. Neurons : cells in the nervous system that communicate with one another to perform information-processing tasks Components of neurons: - PowerPoint PPT PresentationTRANSCRIPT
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U N I T I I I
BIOLOGICAL BASES OF BEHAVIOR
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NEURAL PROCESSING AND THE ENDOCRINE SYSTEM
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NEURONS: THE ORIGIN OF BEHAVIOR
• Neurons: cells in the nervous system that communicate with one another to perform information-processing tasks
• Components of neurons:• Cell body – coordinates information-processing
tasks and keeps the cell alive• Dendrites – receive information from other
neurons• Axon – transmits information to the other
neurons, muscles and glands
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• Glial cells – support cells found in the nervous system• Some digest parts of dead neurons• Some provide physical and nutritional support for neurons
• Myelin sheaths – an insulating layer of fatty material around the axons of some neurons• Formed by some glial cells
• Synapse: junction or region between the axon of one neuron and the dendrites or cell body of another
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THE SYNAPSE
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TYPES OF NEURONS
• Sensory neurons – receive information from the external world and convey it to the brain via the spinal cord
• Motor neurons – carry signals from the spinal cord to the muscles to produce movement
• Interneurons – connect sensory neurons, motor neurons and other interneurons• Most common
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COMMUNICATING INFORMATION WITHIN A NEURON
•Communication happens in two stages:1. Conduction of an electric signal over
relatively long distances within neurons
2. Transmission of electric signals between neurons over the synapse
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COMMUNICATION -CONT-
• Neuron’s cell membrane is porous and allows ions (small electrically charged molecules ) to flow in and out of the cell
• When at rest, channels that allow small, positively charged potassium ions (K+) to pass are open• Channels that allow the flow of other molecules are normally closed
• There are more potassium ions inside the neuron, so some K+ ions flow out leaving the neuron with fewer positively charged molecules on the inside relative to the outside
• Resting potential – difference in electric charge between the inside and outside of a neuron’s cell membrane
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COMMUNICATION -CONT-
• Action potential – electric signal that is conducted along the length of a neuron’s axon to the synapse• Occurs only when an electric shock reaches a certain
level, or threshold• When an electric charge is raised to the threshold value,
the K+ channels briefly shut down and other channels that allow the flow of sodium (Na+), another positively charged ion, are opened
• When an electric current passes down the length of a myelinated axon, the charge “jumps” from node to node instead of travelling down the entire axon
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• Refractory period – time following an action potential during which a new action potential can’t be initiated• After action potential reaches it’s maximum,
K+ flows out until the axon returns to resting potential• Eventually an active chemical “pump” in the
cell membrane moves Na+ back outside the axon and K+ inside
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ACTION POTENTIAL
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THE ACTION POTENTIAL
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SYNAPTIC TRANSMISSION BETWEEN NEURONS
• Terminal buttons – knoblike structures that branch out from most axons• When the action potential reaches the terminal button, it
stimulates the release of neurotransmitters – chemicals that transmit information across the synapse to a receiving neuron’s dendrites
• Neurotransmitters float across the synapse and bind to sites on the dendrites of the receiving neuron called receptors – parts of the cell membrane that receive the neurotransmitter and initiate a new electric signal
• Activation of receptors on the receiving neuron can cause a new electric potential to be initiated, called synaptic transmission
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• Neurotransmitters left in the synapse are cleared up through one of three processes:• Reuptake – neurotransmitters are reabsorbed
by the terminal buttons of the presynaptic neuron’s axon• Enzyme deactivation – specific enzymes break
down and destroy specific neurotransmitters• Autoreceptors – detect how much of a
neurotransmitter has been released into a synapse and signal the neuron to stop releasing the neurotransmitter when too much is present
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SYNAPTIC TRANSMISSION
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TYPES OF NEUROTRANSMITTERS
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HOW DRUGS MIMIC NEUROTRANSMITTERS
• Agonists – drugs that increase the action of a neurotransmitter• Prozac blocks
reuptake of serotonin
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• Antagonists – drugs that block the function of a neurotransmitter
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THE ORGANIZATION OF THE NERVOUS SYSTEM
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• Nervous system – interactive network of neurons that conveys electrochemical information throughout the body
• Made up of two divisions:• Central nervous system (CNS) – brain and the
spinal cord• Peripheral nervous system (PNS) – connects
the CNS to the body’s organs and muscles• Also composed of two parts:
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• Somatic nervous system – set of nerves that conveys information into and out of the CNS• Autonomic nervous system (ANS) – set of
nerves that carries involuntary and automatic commands that control blood vessels, body organs and glands• Sympathetic nervous system – set of nerves that
prepares the body for action in threatening situations• Parasympathetic nervous system – helps the body
return to a normal resting state
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THE HUMAN NERVOUS SYSTEM
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SYMPATHETIC AND PARASYMPATHETIC SYSTEMS
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COMPONENTS OF THE CNS: THE SPINAL CORD
• Some behaviors do not require input from the brain to the spinal cord• Spinal reflexes –
simple pathways in the nervous system that quickly generate muscle contractions
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COMPONENTS OF THE CNS:THE BRAIN
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THE HINDBRAIN
• Hindbrain – area of the brain that coordinates information coming into and out of the spinal cord• Sometimes called the brain stem – includes:• Medulla – extension of the spinal cord into the skull that
coordinates heart rate, circulation and respiration• Reticular formation – brain structure that regulates sleep,
wakefulness and levels of arousal• Cerebellum – large structure that controls fine motor skills• Thalamus – directs messages to the sensory receiving areas in
the cortex and transmits replies to the cerebellum and medulla• Pons – relays information from the cerebellum to the rest of the
brain
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THE HINDBRAIN
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THE MIDBRAIN
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THE FOREBRAIN
•Highest level of the brain•Controls complex cognitive, emotional, sensory and motor functions•Divided into two main parts:• Cerebral cortex – outermost layer of the
brain• Subcortical structures – areas of the
forebrain housed under the cerebral cortex near the center of the brain
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SUBCORTICAL STRUCTURES
•Limbic system – located below the cerebral hemispheres• Associated with emotions and drives• Amygdala – involved in many emotional
processes, particularly the formation of emotional memories• Hippocampus – plays a role in the storage of
memories
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SUBCORTICAL STRUCTURES -CONT-
• Thalamus – sits on top of the brain stem and serves as a relay station• Like a server in a computer network
• Hypothalamus – regulates body temperature, hunger, thirst and sexual behavior• Basal ganglia – large neuron clusters that
work with the cerebellum and cerebral cortex to control and coordinate voluntary movements
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THE FOREBRAIN
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THE CEREBRAL CORTEX
• Divided into two hemispheres• Each controls the opposite side of the body• Corpus callosum – thick band of nerve fibers that
connects large areas of the cerebral cortex on each side of the brain and supports communication of information across the hemispheres• Hemispheres are subdivided into four areas/lobes• Occipital lobe – processes visual information• Parietal lobe – processes information about touch• Temporal lobe – hearing and language• Frontal lobe – has specialized areas for movement,
abstract thinking, planning, memory and judgment
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• Motor cortex – area at the back of the frontal lobe that controls voluntary movements• Sensory cortex – area at the front of the
parietal lobes that registers and processes body touch and movement sensations• Association areas – areas of the cerebral cortex
that are composed of neurons that help provide sense and meaning to information registered in the cortex• Are usually less specialized and more flexible than
neurons in the primary areas
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THE BRAIN AND LANGUAGE
• Aphasia – impairment of language, usually caused by left hemisphere damage either to Broca’s area or to Wernicke’s area• Broca’s area – controls language and
expression• Usually in the left frontal lobe• Directs muscle movements involved in speech
• Wernicke’s area – controls language reception• Usually in left temporal lobe
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• Plasticity – the brain’s ability to change, especially during childhood, by reorganizing after damage or by building new pathways based on experience
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OUR DIVIDED BRAIN
• Split brain – results from surgery that isolates the brain’s two hemispheres by cutting the fibers connecting them
Left visual field
Right half of each
eye
Right hemispher
e
Right visual field
Left half of each eye
Left hemispher
e
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• Some things to remember about the brain’s hemispheres:• There is no activity to which only one
hemisphere makes a contribution• Logic is not confined to the left hemisphere
and creativity and intuition are not exclusive properties of the right hempishere• It is impossible to educate one hemisphere at a
time• There is no evidence that people are purely
“left-brained” or “right-brained”
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HOW WE STUDY THE BRAIN
• Brain lesioning – abnormal disruption in the tissue of the brain resulting from injury or disease• Is done with laboratory animals to determine
the function of different parts of the brain• Strokes and brain injuries create lesioned
areas in the brain
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• Electrical activity within the brain is measured with an electroencephalogram (EEG)• Multiple electrodes are attached to the outside
of the head• Advantages:• Can detect very rapid changes in electrical activity,
allowing analysis of stages of cognitive activity• Disadvantages:• Provides poor spatial reasoning of the source (cells,
brain region) of electrical activity
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•Neuroimaging techniques• PET (positron mission tomography) scan –
indicates specific changes in neuronal activity by detecting where a radioactive form of glucose goes while the brain performs a given task• Advantage – provides visual image corresponding to
anatomy• Disadvantages:
• Requires exposure to low levels of radioactivity• Not as clear as an MRI• Cannot follow changes faster than 30 seconds
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• CT (computed tomography) scan – series of X-rays taken from different angles and combined by computer into a composite representation of a slice through the body
• MRI (magnetic resonance imaging) – show brain anatomy
• fMRI (functional MRI) – can reveal brain’s functioning and structure
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FMRI SCAN OF A CONCUSSION
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GENETICS, EVOLUTIONARY PSYCHOLOGY AND BEHAVIOR
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BEHAVIOR GENETICS
• Chromosome – strands of DNA wound around each other in a double-helix configuration• DNA – complex molecule containing the genetic
information that makes up the chromosomes• Genes – biochemical units of heredity that make
up the chromosomes
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TWIN AND ADOPTION STUDIES
• Identical twins – develop from a single fertilized egg that splits in two• Also called monozygotic twins• Share 100% of their genes
• Fraternal twins – develop from separate fertilized eggs• Also called dizygotic twins• Share about 50% of their genes• Likelihood increases with use of fertility
treatments and genes