5 Must Know Facts For Your Next Test

1. Myelination begins during fetal development and continues into young adulthood, affecting learning and cognitive function.
2. Myelin sheaths are composed mainly of lipids, which provide insulation to axons and prevent ion leakage during action potentials.
3. Diseases such as multiple sclerosis result from damage to myelin, leading to slowed or disrupted nerve signal transmission.
4. The presence of myelin increases the speed of action potentials significantly, with conduction velocities reaching up to 120 meters per second in large, myelinated fibers.
5. The nodes of Ranvier are small gaps in the myelin sheath that play a key role in facilitating saltatory conduction, making nerve signal transmission more efficient.

Review Questions

• How does myelination enhance membrane excitability and action potential propagation in neurons?
  • Myelination enhances membrane excitability by insulating axons, allowing for faster propagation of action potentials. The myelin sheath reduces capacitance and increases resistance across the axonal membrane, enabling ions to flow more freely during depolarization. This insulation facilitates rapid jumps of electrical signals between nodes of Ranvier, leading to a swift transmission of nerve impulses along myelinated fibers.
• What are the cellular mechanisms involved in the formation and maintenance of myelin sheaths in the nervous system?
  • The formation and maintenance of myelin sheaths involve specialized glial cells: Schwann cells in the peripheral nervous system and oligodendrocytes in the central nervous system. These cells wrap around axons multiple times, creating layers of membrane that contribute to the myelin structure. Additionally, signaling molecules play a role in promoting the differentiation and survival of these glial cells, ensuring proper myelination occurs throughout development and repair processes.
• Evaluate the impact of demyelinating diseases on membrane excitability and action potentials, providing examples.
  • Demyelinating diseases, such as multiple sclerosis, have a profound impact on membrane excitability and action potentials by disrupting the integrity of myelin sheaths. In these conditions, demyelination leads to slower conduction velocities and increased chances of signal failure, as ion channels become more exposed at nodes of Ranvier. This not only impairs communication between neurons but can also result in severe neurological deficits, including muscle weakness and coordination issues, demonstrating the critical role of myelination in maintaining normal neural function.

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