Explain the structure of a typical neuron. How do neurons transmit electrical signals through action potentials?

Explain the Structure of a Typical Neuron. How Do Neurons Transmit Electrical Signals Through Action Potentials?

Structure of a Typical Neuron

A neuron is the fundamental unit of the nervous system, specialized for transmitting signals.

• Cell Body (Soma): Contains the nucleus and organelles; metabolic center of the neuron.
• Dendrites: Branched extensions that receive signals from other neurons and convey them to the cell body.
• Axon: Long projection that transmits electrical signals away from the cell body.
• Axon Terminals: Endings of axons that release neurotransmitters into synaptic clefts.
• Myelin Sheath: Insulating layer around axon (formed by Schwann cells in PNS or oligodendrocytes in CNS) that increases conduction speed.
• Nodes of Ranvier: Gaps in myelin that facilitate saltatory conduction.

Transmission of Electrical Signals

Neurons communicate via electrical impulses known as action potentials.

1. Resting Membrane Potential

Maintained by sodium-potassium pumps, the neuron is polarized at approximately -70 mV.

2. Initiation of Action Potential

When a threshold stimulus depolarizes the membrane, voltage-gated Na⁺ channels open, allowing Na⁺ influx and further depolarization.

3. Propagation

The depolarization travels along the axon. In myelinated axons, the signal jumps from node to node (saltatory conduction), speeding up transmission.

4. Repolarization

Na⁺ channels close and K⁺ channels open, allowing K⁺ to exit, restoring the negative membrane potential.

5. Hyperpolarization and Return to Resting State

Excess K⁺ outflow causes hyperpolarization briefly before the membrane stabilizes via the Na⁺/K⁺ pump.

Neurons thus effectively transmit signals via action potentials, essential for brain activity, reflexes, and muscle movement.