Transcript Slide 1

HUMAN NERVOUS SYSTEM
controls all Human behavior
You are ‘YOU’ because of your
NERVOUS SYSTEM , not
because of your kidney or Heart
or………………
All BEHAVIOR is determined by
the Human Nervous System
GENETICS
NEURAL
NETWORK
ENVIRONMENT
BRAIN
HNS
MALFUNCTION
DISTURBANCE OF BEHAVIOR
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HUMAN NERVOUS
MOTOR SYSTEM
SENSORY SYSTEM
SYSTEM
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NEURAL
NETWORK
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10 11 NEURONS
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PRECISELY
CONNECTED WITH
EACH OTHER
REFLEX ACTION
OR DELAYED
ACTION
SENSORY
CODING
INFORMATION PROCESSING
INFORMATION STORAGE
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Functional Unit of the Brain
1. Resting Membrane Potential is a potential
difference that exists across the membrane of a
all cells.
2. Electrotonic Potential is a voltage signal that is
produced by passive changes in resting
membrane potential of a cell (neuron or muscle).
3. Action Potential is a voltage signal (an
impulse) that is produced by a sudden and a
transient reversal of resting membrane potential
of an excitable active cell (neuron or muscle).
MEMBRANE
OUT
IN
MEMBRANE
MEMBRANE
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- -
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- 70mV
Resting Membrane
Potential
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OUT
IN
Depolarization or
Hypopolarization
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OUT
IN
- 50mV
- 80mV
- - - - - - - -
Hyperpolarization
The magnitude of potential depends on the degree
of separation of the opposite charges
Electrotonic Potentials
(IPSP)
(EPSP) OR Hypopolarization
ACETYLCHOLINE
NICOTINIC RECEPTOR
(CHANNEL)
(Secretory granules)
At some
excitatory
synapses,
closing of K+ or
Cl- channels or
both may cause
ecxitation of the
postsynaptic
cell
At some inhibitory
synapses, K+
channels open and
hyperpolarize the
postsynaptic cell
63%
τ
In cells with longer time constant the signals decay slowly and therefore EPSPs have more
time and better chance of integration – a process called “Temporal summation”.
In cells with shorter time constant the signals rapidly decay and therefore EPSPs have poor
chance of integration.
In cells with longer length constant the signals spread to longer distances with minimal
decay, and therefore EPSPs have better chance of integration – a process called “Spatial
summation”.
In cells with shorter length constant the signals spread to smaller distances, because of
rapid decay and therefore EPSPs have poor chance of integration.
Graded Potential
Local circuits cross the membrane only at the nodes of Ranvier.
 Current density is
greater.
 Depolarisation is
more rapid & threshold
is reached more quickly
 CV is raised
The AP appears to jump from node to node rather than propagate
smoothly along the axon.
This process is Salatatory Conduction (Lat. saltere = to jump).
Local circuits can travel along the cytoplasm for several internodal
lengths and still be strong enough to depolarise a node of Ranvier to
threshold. Thus if one or more nodes are blocked, propagation is still
possible over the inactive region. The axon has a large Safety Factor.