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Biology

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35-2 The Nervous System

35-2 The Nervous System

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35-2 The Nervous System

What are the functions of the nervous system?

35-2 The Nervous System

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35-2 The Nervous System

The nervous system controls and coordinates functions throughout the body and responds to internal and external stimuli.

35-2 The Nervous System

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Neurons

Neurons

The messages carried by the nervous system are electrical signals called impulses.

The cells that transmit these impulses are called neurons.

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Neurons

Neurons are classified according to the direction in which an impulse travels.

• Sensory neurons carry impulses from the sense organs to the spinal cord and brain.

• Motor neurons carry impulses from the brain and spinal cord to muscles and glands.

• Interneurons connect sensory and motor neurons and carry impulses between them.

35-2 The Nervous System

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Neurons

Structures of a Neuron

Axon terminals

Myelin sheath

Cell body

Nodes Axon

Dendrites

Nucleus

35-2 The Nervous System

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Neurons

The largest part of a typical neuron is the cell body.

It contains the nucleus and much of the cytoplasm.

Cell body

35-2 The Nervous System

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Neurons

Dendrites extend from the cell body and carry impulses from the environment toward the cell body.

Dendrites

35-2 The Nervous System

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Neurons

The axon is the long fiber that carries impulses away from the cell body.

Axon terminals

Axon

35-2 The Nervous System

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Neurons

The axon ends in axon terminals.

Axon terminals

Axon

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Neurons

The axon is sometimes surrounded by an insulating membrane called the myelin sheath.

There are gaps in the myelin sheath, called nodes, where the membrane is exposed.

Impulses jump from one node to the next.

Myelin sheath

Nodes

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The Nerve Impulse

The Nerve Impulse

The Resting Neuron 

When resting, the outside of the neuron has a net positive charge.

The inside of the neuron has a net negative charge.

The cell membrane is electrically charged because there is a difference in electrical charge between its outer and inner surfaces.

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The Nerve Impulse

The sodium-potassium pump in the nerve cell membrane pumps sodium (Na+) ions out of the cell and potassium (K+) ions into the cell by means of active transport.

As a result, the inside of the cell contains more K+

ions and fewer Na+ ions than the outside.

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The Nerve Impulse

Sodium-Potassium Pump

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The Nerve Impulse

More K+ ions leak across the membrane than Na+ ions. This produces a negative charge on the inside and a positive charge on the outside.

The electrical charge across the cell membrane of a neuron at rest is known as the resting potential.

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The Nerve Impulse

How is a nerve impulse transmitted?

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The Nerve Impulse

The Moving Impulse

An impulse begins when a neuron is stimulated by another neuron or by the environment.

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The Nerve Impulse

At the leading edge of the impulse, gates in the sodium channels open allowing positively charged Na+ ions to flow inside the cell membrane.

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The Nerve Impulse

The inside of the membrane temporarily becomes more positive than the outside, reversing the resting potential.

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The Nerve Impulse

This reversal of charges is called a nerve impulse, or an action potential.

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The Nerve Impulse

As the action potential passes, gates in the potassium channels open, allowing K+ ions to flow out restoring the negative potential inside the axon.

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The Nerve Impulse

The impulse continues to move along the axon.

An impulse at any point of the membrane causes an impulse at the next point along the membrane.

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The Nerve Impulse

Threshold 

A stimulus must be of adequate strength to cause a neuron to transmit an impulse.

The minimum level of a stimulus that is required to activate a neuron is called the threshold.

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The Nerve Impulse

A stimulus that is stronger than the threshold produces an impulse.

A stimulus that is weaker than the threshold produces no impulse.

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The Synapse

The Synapse

At the end of the neuron, the impulse reaches an axon terminal. Usually the neuron makes contact with another cell at this site.

The neuron may pass the impulse along to the second cell.

The location at which a neuron can transfer an impulse to another cell is called a synapse.

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The Synapse

A Synapse

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The Synapse

The synaptic cleft separates the axon terminal from the dendrites of the adjacent cell.

Synaptic cleft

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The Synapse

Terminals contain vesicles filled with neurotransmitters.

Neurotransmitters are chemicals used by a neuron to transmit an impulse across a synapse to another cell.

Vesicle

Neurotransmitter

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The Synapse

As an impulse reaches a terminal, vesicles send neurotransmitters into the synaptic cleft.

These diffuse across the cleft and attach to membrane receptors on the next cell.

Receptor

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The Synapse

Sodium ions then rush across the membrane, stimulating the next cell.

If the stimulation exceeds the cell’s threshold, a new impulse begins.

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The Synapse

Moments after binding to receptors, neurotransmitters are released from the cell surface.

The neurotransmitters may then be broken down by enzymes, or taken up and recycled by the axon terminal.

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35-2

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35-2

Neurons that carry impulses from the brain and spinal cord to the muscles are

a. interneurons.

b. sensory neurons.

c. resting neurons.

d. motor neurons.

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35-2

The part of the neuron that carries impulses toward the cell body is the

a. axon.

b. myelin sheath.

c. dendrite.

d. nodes.

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35-2

The minimum level of a stimulus that is required to activate a neuron is called its

a. action potential.

b. resting potential.

c. threshold.

d. synapse.

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35-2

Chemicals that are used by a neuron to transmit impulses are called

a. neurotransmitters.

b. synapses.

c. axons.

d. inhibitors.

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35-2

An action potential begins when

a. sodium ions flow into the neuron.

b. potassium ions flow into the neuron.

c. sodium and potassium ions flow into the neuron.

d. sodium and potassium ions flow out of the neuron.

END OF SECTION