Module 2- BIOPSYCH (FINAL).pdf

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NEURONS AND
SYNAPSES
By: Elida Dominique L. Morona
THE NERVOUS
SYSTEM: AN
OVERVIEW
 Central Nervous system
Brain and Spinal Cord
recieves sensory
signals, stores
memories, and carries
thoughts
DIVISIONS OF THE
NERVOUS SYSTEM Peripheral Nervous
system

Nerves, neurons, and
sensory organs outside
of the CNS
send signals to CNS.
stimulates effectors
PERIPHERAL
NERVOUS
Somatic Autonomic
interacts with external Regulates the body’s
SYSTEM (PNS) enviornments internal enviornment.

Affarent nerves - Affarent nerves -
sensory signals from sensory signals from
the senses to the CNS the senses to the CNS

Efferent Nerves - Efferent Nerves -
Motor signals from the Motor signals from the
CNS to the skeletal CNS to the skeletal
muscles. muscles.
AUTONOMIC
NERVOUS Sympathetic
SYSTEM (PNS) Fight or Flight response
also known as “Adrenergic nervous system”
Secretion of Epinephrine through the stimulation of
sweat glands
aroused body to expend energy

Parasympathetic
Rest and Digest
also known as “Cholinergic nervous system”
no effect on sweat glands.
calms body to conserve and maintain energy
 WHICH OF THE
FOLLOWING IS TRUE?
1. the brain and the cranium complete the CNS
2.The brain and the spinal cord comprise the PNS

A. 1 ONLY C. BOTH

B. 2 ONLY D. NONE
 QUESTION 2
You are being chased by a dog, and were able to
escape. you were able to reach your home
immediately...as you reach your house, what is the
response of your body?

A. Sympathetic B. Parasympathetic
CELLS OF THE
NERVOUS
SYSTEM
Neurons and Glia (Neuroglia)
NEURON
“Nerve Cell”
Basic Building block of
the nervous system
Cells that are
specialized for the
reception, conduction
03 - SOCIAL MEDIA
and transmission of
electrochemical
signals
03 - SOCIAL MEDIA
Presynaptic Terminal
end bulb or
bouton
CLASSES OF NEURONS
NEURON CELL
MEMBRANE
lipid bilayer
some membrane
protein serve as a
channel protein
03 - SOCIAL and
MEDIA
some are signal
protein
NEUROTRANSMITTER
NEUROTRANSMITTER
A chemical released from a neuron
following an action potential.
travels across the synapse to
excite or inhibit the target neuron.
Different types of neurons use
different neurotransmitters
03 - SOCIAL MEDIA and
therefore have different effects on
their targets.
 Excitatory
CLASSIFICATION
OF
NEUROTRANSMITTER
They increase the likelihood that the
neuron will fire an action potential.

Inhibitory
They decrease the likelihood that the
neuron will fire an action potential.
TYPES OF NEUROTRANSMITTER
TYPES OF NEUROTRANSMITTER
TYPES OF NEUROTRANSMITTER
 TO BE
CONTINUED...
ACTION VS RESTING POTENTIAL I GLIAL CELLS !
NERVE CELLS SYNAPSES
GLIAL CELLS
FORGOTTEN CELLS
NEURONS
VS
Neurons Glial
Generate and
GLIAL Modulate neuron
propagate electrical
function and signaling.
and chemical signals
Has no dendrites and
Has dendrites and
axons
axons
smaller than neurons
bigger than Glial cells

ARE THERE MORE GLIAL
CELLS THAN NEURONS?
TYPES OF GLIAL
CELLS
astrocytes, oligodendrocytes, microglia
ASTROCYTE
Largest Glial cell
means “star cell”
provide physical support to
neurons and clean up debris within
the brain by producing and
releasing chemicals.
involve in providing nourishment to
neurons
regulate synaptic release of
neurotransmitter and reuptake and
inactivation of neurotransmitter
(e.g., GABA and Glutamate)
OLIGODENDROCYTES
provide support to axons and
produce myelin sheath (80% lipids
and 20% protein) in CNS
Bare axon - Node of Ranvier

SCHWANN CELLS
perform as similar function as
oligodendrocytes in the PNS
1 =1 ratio as oppose to 1 = many of
oligodendrocytes
Only one who can guide axonal
regenration (regrowth)
MICROGLIA
smallest of the glial cells
respond to injury or disease
by by multiplying, engulfing
cellular debris, or even an
entire cell (scavenger cell)
responsible for the
inflammatory reaction
NERVE IMPULSE
membrane potential and resting potential,
MEMBRANE POTENTIAL
Difference in electrical charge between the inside and the outside of
a cell

Action potential - -When a neuron sends a signal down it's
axon to communicate with another neuron (-65 mV
Threshold) -”All or nothing law/response”

Resting potential - amount of power that is available to a cell
to maintain its homeostatic state (-70 millivolts (mV) as the
resting potential) hence, polarized
SODIUM POTASSIUM PUMP
IONIC BASIS OF THE RESTING
Potential
positively and negatively charged ions and ions can pass through ion
channels
electro static pressure and concentration gradient
GENERATION AND
Conduction of
Postsynaptic
Potentials
GENERATION AND Conduction of
Postsynaptic Potentials
Excitatory postsynaptic potential (EPSPs)- Sodium channels open
- Depolarization

Inhibitory postsynaptic potential (IPSPs) - Chloride/ Potassium
channels open
- Hyperpolarization
STAGES OF ACTION
POTENTIAL
ACTION POTENTIAL
Threshold of excitation is usually about -65 mV
Action potential (AP) as a massive but momentary
reversal of the membrane potential from about-70 to
about +50 MV
All or none response/law
Two types of summation: spatial and temporal.
CONDUCTION OF ACTION
POTENTIALS
Voltage-activated ion channels open or close in
response to changes in the level of the membrane
potential
STAGES OF ACTION
POTENTIALS
Depolarization
“upswing”
Positively charged sodium ions rush into a nerve cell
Sodium channels open
the membrane of the stimulated cell reverses its
polarity so that the outside of the membrane is
negative relative to the inside
STAGES OF ACTION
POTENTIALS
Repolarization
“Downswing” – once reached threshold
Sodium ion channels close and potassium ion
channels open
restore the localized negative membrane potential of
the cell, bringing it back to its normal voltage.
STAGES OF ACTION
POTENTIALS
Refractory Phase
The neuron cannot reach action potential during this
“rest period.”
The sodium-potassium pump returns sodium ions to
the outside and potassium ions to the inside.
Absolute vs relative refractory period.
Depends on two things: The sodium channels are
closed, and potassium is flowing out of the cell at a
faster than-usual rate.
AXONAL CONDUCTION OF
ACTION POTENTIALS
Nondecremental
Slower conduction than postsynaptic potentials
Antidromic conduction vs Orthodromic conduction
CONDUCTION IN MYELINATED
AXONS
Ions can pass through the axonal membrane only at
the nodes of Ranvier
Rapid and decremental
Saltatory conduction - “to leap”
SYNAPTIC TRANSMISSION
Chemical Transmissions of Signals Among Neurons
STRUCTURE OF SYNAPSES
Axodendritic synapse
- Axon to dendrite
Axosomatic synapse
- Axon to Soma
Axoaxonic synapse
- Axon to axon
------------------------
Directed vs non
directed synapse
 HOW DO
NEUROTRANSMITTERS
TRAVEL?
SYNTHESIS, PACKAGING, AND
TRANSPORT OF NEUROTRANSMITTER
MOLECULES
several types of neurotransmitters
large neurotransmitters are all neuropeptides (small
chains of amino acids that are synthesized and
released by neurons.)
Co-existence in many neurons
SYNTHESIS, PACKAGING, AND
TRANSPORT OF NEUROTRANSMITTER
MOLECULES
Storage of Transmitters - The presynaptic terminal
stores high concentrations of neurotransmitter
molecules in vesicles.
RELEASE OF NEUROTRANSMITTER
MOLECULES
Exocytosis

bursts of release of
neurotransmitter from
the presynaptic
neuron.
ACTIVATION OF RECEPTORS BY
NEUROTRANSMITTER MOLECULES
neurotransmitters bind to receptors in the
postsynaptic membrane (Ligand)
ionotropic receptors - ligand-gated ion
channels (Glutamate and GABA)
metabotropic receptors - require G proteins
and second messengers to indirectly modulate
ionic activity in neurons
Ionotropic synapse VS Metabotropic synapse
REUPTAKE, ENZYMATIC
DEGRADATION, AND RECYCLING
message terminating system
enzymatic degradation
in the process of reuptake, excess
neurotransmitters are returned to the
presynaptic neuron.
THANK YOU