Download Biological Bases Powerpoint – Neurons

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts

Embodied cognitive science wikipedia , lookup

Endocannabinoid system wikipedia , lookup

Subventricular zone wikipedia , lookup

Premovement neuronal activity wikipedia , lookup

Action potential wikipedia , lookup

Caridoid escape reaction wikipedia , lookup

Central pattern generator wikipedia , lookup

Artificial neural network wikipedia , lookup

Neural oscillation wikipedia , lookup

Convolutional neural network wikipedia , lookup

Multielectrode array wikipedia , lookup

Neuromuscular junction wikipedia , lookup

Recurrent neural network wikipedia , lookup

Mirror neuron wikipedia , lookup

Holonomic brain theory wikipedia , lookup

Electrophysiology wikipedia , lookup

Metastability in the brain wikipedia , lookup

Types of artificial neural networks wikipedia , lookup

Synaptogenesis wikipedia , lookup

Neural engineering wikipedia , lookup

Nonsynaptic plasticity wikipedia , lookup

Neural coding wikipedia , lookup

End-plate potential wikipedia , lookup

Axon wikipedia , lookup

Optogenetics wikipedia , lookup

Single-unit recording wikipedia , lookup

Feature detection (nervous system) wikipedia , lookup

Clinical neurochemistry wikipedia , lookup

Neuroanatomy wikipedia , lookup

Chemical synapse wikipedia , lookup

Development of the nervous system wikipedia , lookup

Molecular neuroscience wikipedia , lookup

Channelrhodopsin wikipedia , lookup

Synaptic gating wikipedia , lookup

Stimulus (physiology) wikipedia , lookup

Biological neuron model wikipedia , lookup

Neuropsychopharmacology wikipedia , lookup

Neurotransmitter wikipedia , lookup

Nervous system network models wikipedia , lookup

Transcript
Introductory Psychology:
Biological Bases of Behavior
AP PSYCHOLOGY: UNIT II
Topic: Neurons and
Neurotransmitters
Everything that is biological, is
simultaneously psychological…
The Biological Bases:
Cells of the Nervous System
PART ONE
Imagine that you are watching an
action-packed movie. As the tension
mounts, your palms sweat and your
heart beats faster. You begin
shoveling popcorn into your mouth,
carelessly spilling some into your
lap. If someone were to ask you what
you were doing in that moment, how
would you respond?
Biological Bases: Cells
 The Nervous System
 An extensive network of specialized cells that carries
information to and from all parts of the body; body’s
information system
Brain to the body, face and internal organs
 Senses to the brain


Two Major Types of Cells in the Nervous System
Neurons (the basic building blocks)
 Glia (a neuron’s support system)

Biological Bases: Cells
 Neurons
 Individual cells; basic
building block of the
nervous system
 Neurons perform three
primary tasks: receive,
integrate and transmit
information
Biological Bases: Cells
 Afferent Neurons (Sensory Neurons)
 Carry information from the body’s tissues & sensory
organs to the brain & spinal cord (INWARD; access)
 Efferent Neurons (Motor Neurons)
 Carry information from the brain & spinal cord to the
body’s tissues & sensory organs (OUTWARD; exit)
 Interneurons
 CNS neurons that communicate internally and
intervene between sensory inputs and motor outputs
(make reflexes happen)
Dendrites
Terminal
Buttons
Node of
Ranvier
Soma
Nucleus
Axon (inside)
Myelin Sheath (covering)
Schwann
Cell
Biological Bases: Cells
 Basic Parts of a Neuron
 Soma (“body” in Greek)


Dendrites (“tree” in Greek)


Cell body; contains nucleus & chemical “machinery”
common to most cells
Branchlike structures that receive information from
other neurons
Axon (“axle” in Greek)

Tube-like structure that carries the neural message away
from the soma and to other cells (neurons)
Biological Bases: Cells
 Basic Parts of a Neuron
 Myelin Sheath


Terminal Branches/Buttons


Fatty substance produced by certain glial cells; encases
axon; helps insulate, protect & speed the neural impulse
Small knobs that secrete chemicals called
neurotransmitters (chemical messengers)
Synapse (“junction” in Greek)

Junction where information is transmitted from one
neuron to another
Biological Bases: Cells
The importance
of myelin is
evident in M.S.
In M.S. the
myelin sheath
degenerates
causing neural
communication
to slow down
Eventually leads
to the loss of
muscle control
Real Life Application: Neurons
Myelin Sheath & Multiple Sclerosis
Biological Bases: Cells
 Glia Cells (“glue” in Greek)
 Provide support for neurons
 Deliver nutrients, produce
myelin, flush waste & dead
neurons and influence
information processing
 Influence the generation of new
neurons during prenatal development
 Outnumber neurons 10 to 1; account for 50% of the
brain’s total volume
Biological Bases:
The Neural Impulse
PART TWO
Biological Bases: Neural Impulse
 Alan Hodgkin &
Andrew Huxley (1952)



Studied giant squid
Unraveled the mystery
of the neural impulse
WHY SQUID?
Semi-Permeable
Fluid
Allows ions to travel
both in and out of
the neuron
Inside the
Neuron
Ions are mostly
negative
Outside the
Neuron
Ions are mostly
positive
Biological Bases: Neural Impulse
 Resting Potential
 A neuron’s state when it is NOT firing a neural
impulse; a neuron at rest
 An inactive neuron has a stable, negative charge (-70
millivolts)

In this state the neuron is capable of generating an action
potential; ready to fire
Biological Bases: Neural Impulse
 Action Potential
 A very brief shift in a
neuron’s electrical
charge that travels
along the axon; begins
at the soma

Neural messages travel
anywhere from 2 mph to 270 mph
Depolarization
occurs when
positive ions
enter the
neuron
making it
more prone to
fire an action
potential
Hyperpolarization
occurs when
negative ions
enter the neuron
making it less
prone to fire an
action potential
Biological Bases: Neural Impulse
 Absolute Refractory Period
 After an action potential, the minimum length of time
during which another action potential cannot begin
The “recharging phase” (1-2 milliseconds)
 The nerve WILL NOT respond to a second stimulus
during this period

Biological Bases: Neural Impulse
 Threshold
 The level of stimulation
required to trigger a
neural impulse
 All-or-None Principle
 If a neuron fires it will
ALWAYS fire at the same
intensity (100%); the
intensity of the stimulus
DOES NOT matter
Biological Bases:
The Synapse
PART THREE
Biological Bases: The Synapse
 Synapse
 A junction between the
axon tip of the sending
neuron and the dendrites
of the receiving neuron
The action potential
CANNOT jump the gap
 How do action potentials
travel from one neuron to
another?

Biological Bases: Neural Impulse
 Like a neuron, a toilet has an
action potential. When you
flush, an “impulse” is sent
down the sewer pipe
 Like a neuron, a toilet has a
refractory period. There is a
short delay after flushing
when the toilet cannot be flushed again
because the tank is being refilled
Biological Bases: Neural Impulse
 Like a neuron, a toilet has a resting
potential. The toilet is “charged” when there
is water in the tank and is capable of being
flushed again
 Like a neuron, a toilet operates on the all-ornone principle – it always flushes with the
same intensity, no matter how much force
you apply to the handle
Biological Bases:
Neurotransmitters
PART FOUR
Biological Bases: Neurotransmitters
 Neurotransmitters
 A chemical messenger
that travels across the
synapse from one neuron
to the next; transmits
information

Influences whether the
second neuron will generate
an action potential or not
Biological Bases: Neurotransmitters
 Excitatory Effect
 A neurotransmitter effect
that makes it MORE likely
the receiving neuron will
generate an action potential
The second neuron is more
likely to fire
 GREEN LIGHT

Biological Bases: Neurotransmitters
 Inhibitory Effect
 A neurotransmitter effect
that makes it LESS likely
the receiving neuron will
generate an action potential
The second neuron is less
likely to fire
 RED LIGHT

Biological Bases: Neurotransmitters
Neurotransmitters bind to the receptors of the receiving neurons
in a lock & key mechanism
Biological Bases: Neurotransmitters
 Agonists
 Chemical substances that
mimic or enhance the effects
of a neurotransmitter on the
receptor sites of the next cell
 Increases or decreases the
activity of that cell, depending
on the effect of the original
neurotransmitter (excitatory or inhibitory)
Example
 Morphine, a man-made chemical substance, is an
endorphin agonist

Biological Bases: Neurotransmitters
 Antagonists
 Chemical substances that
block or reduce a cell’s
response to the action of
other chemicals or
neurotransmitters
Example
 Curare is an acetylcholine
antagonist

Biological Bases: Neurotransmitters
 Reuptake
 Neurotransmitters in
the synapse are reabsorbed
into the sending neurons
through the process of
reuptake

This process applies the
brakes on neurotransmitter
action
Biological Bases: Neurotransmitters
 Acetylcholine (ACh)
 Characteristics
Located at neuromuscular junctions
 Involved in muscle action, learning,
attention, memory and arousal


Dysregulation


Alzheimer’s Disease
Psychopharmacology
Curare (antagonist)
 Botulism (antagonist)
 Spider venom (agonist)

Is there a connection
between Botox &
Acetylcholine??
Biological Bases: Neurotransmitters
 Dopamine (monoamine)
 Characteristics


Involved in mood,
movement, learning,
attention, motivation &
emotion
Dysregulation
Parkinson’s Disease
 Schizophrenia


Psychopharmacology

Cocaine
(agonist)
OVERSUPPLY or
UNDERSUPPLY?
voluntary
Biological Bases: Neurotransmitters
 Norepinephrine (monoamine)
 Characteristics


Involved in mood, alertness and arousal
Dysregulation
Depressive disorders
 Attention Hyperactivity Disorder (ADHD)


Psychopharmacology

Adderall (agonist)
Biological Bases: Neurotransmitters
 Serotonin (monoamine)
 Characteristics
Involved in sleep, wakefulness, mood, appetite & arousal
 Appears to set an “emotional tone”
 Aggression?


Dysregulation
Depression
 Obsessive-Compulsive Disorder
 Eating Disorders


Psychopharmacology

Antidepressants (agonists)
Biological Bases: Neurotransmitters
 GABA (amino acid)
 Characteristics
The most common inhibitory neurotransmitter
 Involved in sleep and the inhibition of movement; aids in
the regulation of anxiety


Dysregulation
Anxiety disorders
 Seizure disorders
 Insomnia


Psychopharmacology

Alcohol (agonist)
Biological Bases: Neurotransmitters
 Glutamate (amino acid)
 Characteristics
The most common excitatory neurotransmitter
 Involved in learning, memory formation and the
development of the nervous system


Dysregulation
Schizophrenia
 Migraines

Biological Bases: Neurotransmitters
 Endorphins
 Characteristics
Inhibitory neural regulators/neural peptides; controls
the release of other neurotransmitters
 Involved in pain relief and response to stress
