Communication Within a Neuron PDF

Summary

These lecture notes cover the communication within a neuron, including neuron structure, resting membrane potential, action potential, propagation of action potential, a withdrawal reflex, the role of inhibition, and the use of squid axons in studying electrical potentials. The material is suitable for undergraduate biology and psychology students.

Full Transcript

PSYC 2210 Biological Psychology

COMMUNICATION
WITHIN A NEURON

Prof. Dr. Hakan Çetinkaya
Yaşar University – Department of Psychology
 COMMUNICATION WITHIN A NEURON

Neuron Structure:

Neurons have a distinctive structure
consisting of a cell body (soma),
dendrites, and an axon.

Dendrites receive signals from other
neurons or sensory receptors.

The axon carries signals away from the
cell body.
 COMMUNICATION WITHIN A NEURON

Resting Membrane Potential:

Neurons have a resting membrane
potential, an electrical charge across the
cell membrane when the neuron is not
actively transmitting signals.

This resting potential is primarily
maintained by the selective
permeability of the cell membrane to
ions like potassium (K+) and sodium
(Na+).
 COMMUNICATION WITHIN A NEURON

Action Potential:

The basic unit of communication within
a neuron is the action potential, an
electrical impulse that travels along the
axon.

When a neuron receives a strong
enough stimulus, it depolarizes, causing
voltage-gated sodium channels to open,
allowing sodium ions to enter the cell,
leading to a rapid change in membrane
potential.
 COMMUNICATION WITHIN A NEURON

Propagation of Action Potential:

The action potential travels down the
axon in a process called saltatory
conduction, jumping from one node of
Ranvier to the next, which significantly
speeds up the transmission of the
signal.
 COMMUNICATION WITHIN A NEURON

A Withdrawal Reflex
The figure shows a simple example of a useful function of the nervous system.
The painful stimulus causes the hand to pull away from the hot iron.

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 COMMUNICATION WITHIN A NEURON

The Role of Inhibition
Inhibitory signals arising from the brain can prevent the withdrawal reflex from causing
the person to drop the casserole.
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 COMMUNICATION WITHIN A NEURON

Squid or "Kalamar" is not only a delicious culinary delight but also holds scientific significance.

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 COMMUNICATION WITHIN A NEURON

Measuring Electrical Potential of
Axons
▪ The giant axon of a squid is about 0.5mm
in diameter (hundreds of times larger
than the largest mammalian axon).
▪ This axon controls an emergency
response (sudden contraction in danger).

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 COMMUNICATION WITHIN A NEURON

Terms
▪ Resting potential The resting potential refers to
the electrical potential difference across the
membrane of a neuron when it is not actively
transmitting signals.

▪ In a resting giant axon membrane, such as the
giant axon of a squid, the resting potential is
typically around -70 millivolts (mV). This negative
potential is primarily due to the uneven
distribution of ions across the neuronal
membrane.

▪ The key ions involved in establishing the resting
potential are sodium (Na+), potassium (K+), and
chloride (Cl-) ions.

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 COMMUNICATION WITHIN A NEURON

Measuring Electrical Potential of Axons:
Membrane Potential
▪ Microelectrode: a very fine electrode, generally used
to record activity of individual neurons.
▪ Since glass will not conduct electricity, the glass
microelectrode is filled with a liquid (a solution of
potassium chloride) that conducts electricity.
▪ Inside of axon is negatively charged with respect to
outside. The difference is 70mV, so the inside of the
membrane is -70mV.
▪ This electrical charge is called the membrane
potential.
▪ This electrical charge across the membrane is called Measuring Electrical Charge
resting potential. The figure shows (a) a voltmeter detecting the charge
across a membrane of an axon and (b) a light bulb
detecting the charge across the terminals of a11battery.
 COMMUNICATION WITHIN A NEURON

Studying the Axon
The figure shows the means by
which an axon can be stimulated
while its membrane potential is
being recorded.

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 COMMUNICATION WITHIN A NEURON

Terms
▪ Depolarization Reduction (toward zero) of the
membrane potential of a cell from its normal
resting potential.

▪ Hyperpolarization An increase in the membrane
potential of a cell, relative to the normal resting
potential.

▪ Action Potential The brief electrical impulse that
provides the basis for conduction of information
along an axon.

▪ Threshold of excitation The value of the
membrane potential that must be reached to
produce an action potential.

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 COMMUNICATION WITHIN A NEURON

The Action Potential
▪ They increased the strength of depolarizing
stimulus.
▪ Each stimulus briefly depolarizes the membrane
potential a little more.
▪ At 4, the membrane potential suddeenly
reverses itself. Thus, inside becomes positive
and the outside becomes negative.
▪ It quickly turns to normal, but after it
hyperpolarized for a short time.
▪ The whole process takes about 2 msec.
▪ This phenomenon, a very rapid reversal of the
membrane potential is called the action
potential.
▪ The voltage level that triggers an action
potential is called the treshold of excitation.
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 COMMUNICATION WITHIN A NEURON

Terms
▪ Diffusion: Movement of molecules from regions of high concentration to regions of low concentration.
▪ Electrolyte: An aqueous solution of a material that ionizes—namely, a soluble acid, base, or salt.
▪ Ion: A charged molecule. Cations are positively charged, and anions are negatively charged.
▪ Electrostatic pressure: The attractive force between atomic particles charged with opposite signs or the
repulsive force between atomic particles charged with the same sign.
▪ Intracellular fluid: The fluid contained within cells.
▪ Extracellular fluid: Body fluids located outside of cells. in the intracellular fluid.

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 COMMUNICATION WITHIN A NEURON

What Causes the Action Potential
▪ Why there is membrane potential
This electrical charge is the result of a balance between two opposing forces:
1. The force of diffusion
2. The force of electrostatic Pressure

1. The force of diffusion: Movement of molecules from regions of high concentration to regions of low
concentration. Molecules are constantly in motion and their rate of movement is proportional to the
temperature. Only at absolute zero [0 K (kelvin) = -273.15 C] do molecules cease their random movement.

2. The force of Electrostatic Pressure: When some substances are dissolved in water, they split into two parts,
each with an opposing electrical charge (ions). This aqueous solution of a material that ionizes are called
electrolyte. The ions are two types: Cations (with a positive charge) and anions (with a negative charge).
Therefore, what the electrostatic pressure is the attractive force between atomic particles charged with
opposite signs, or the repulsive force between atomic particles charged with the same sign.

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 COMMUNICATION WITHIN A NEURON

Ions in the Extracellular and Intracellular Fluid

▪ The fluid within cells (intracellular fluid) and the fluid surrounding them (extracellular fluid) contain different
ions.

▪ Thus, the forces of diffusion and electrostatic pressure contributed by these ions give rise to the membrane
potential.

There are several important ions:

1. Organic anions (negatively charged proteins) (A-), found only in the intracellular fluid.

2. Chloride ions (Cl-), found in the intracellular and extracellular fluids, but predominantly in the extracellular
fluid.

3. Sodium ions (Na+), found in the intracellular and extracellular fluids, but predominantly in the extracellular
fluid.

4. Potassium ions (K+), found in the intracellular and extracellular fluids, but predominantly in the intracellular 17
fluid.
 COMMUNICATION WITHIN A NEURON
The relative concentration of some important ions inside and outside the neuron and the forces acting on them.

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 Action Potential
A sodium-potassium transporter, situated in the cell membrane.

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 Action Potential
Ion channels: When ion channels are open, ions can pass through them, entering or leaving the cell.

▪ The forces of both diffusion and
electrostatic pressure tend to push Na+
into the cell. However, the membrane is
not very permeable to this ion, and
sodium-potassium transporters
continuously pump out Na+, keeping the
intracellular level of Na+ low.
▪ What if the membrane suddenly becomes
permeable to Na+?
▪ This sudden influx of positively charged
ions would drastically change the
membrane potential.
▪ Then, Na+ ions rush into the cell (by
FD&EP), and K+ ions rush out of the cell
(by FD&NoEP).
▪ Action potential: The brief electrical
impulse that provides the basis for
conduction of information along an axon.
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 Action Potential
Ion channels: When ion channels are open, ions can pass through them, entering or leaving the cell.

▪ The membrane consists of a double layer
of lipid molecules in which are floating
many different kinds of protein
molecules.

▪ One class of protein molecules provides a
way for ions to enter or leave the cells.

▪ These molecules constitute ion channels.

▪ Each open sodium channel can admit 100
million ions per second.

▪ There are at least 75 different types of
ion channels.

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Action Potential

The Movements of Ions

1. Na+ rushes in (propelled by the forces of diffusion and electrostatic
pressure. Because these channels are voltage-dependent ion
channels, they are opened by changes in the membrane potential.
Inflow of positively charged sodium ions produces a rapid change in
teh membrane potential, from -70 to +40 mV.
2. The membrane contains voltage-dependent potassium channels,
but these channels are less sensitive than voltage-dependent
sodium channels. That is, they require a greater level of
depolarization before they begin to open. Thus, they begin to open
later than the sodium channels.
3. At the peak (in 1 msec), sodium channels cannot open again until
the membrane once more reaches the resting potential. At this
time, then, no more Na+ can enter the cell.

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Action Potential

The Movements of Ions

4. The voltage-dependent potassium channels in the membrane are
open, letting K+ ions move freely through the membrane. At this
time, inside of the axon is now positively charged, so K+is driven out
of the cell by diffusion and electrostatic pressure. This outflow of
cations causes the membrane potential to return toward its normal
value. As it does so, the potassium channels begin to close again.
5. Potassium channels close, and no more potassium leaves the cell.
6. The accumulation of of K+ ions outside the membrane causes a
temporary hyperpolarization. These extra ions soon diffuse away,
and membrane potential returns to -70mV. Eventually sodium-
potassium transporters remove the Na+ that leaked in and retrieve
the K+ that leaked out.

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