Explanation: Myelin, a substance rich in lipids, serves as an electrical insulator for neuronal axons, significantly enhancing the velocity of action potential propagation.

Explanation: Myelin-like sheaths with comparable structural characteristics have been identified in various invertebrate taxa, such as annelids and crustaceans, indicating that myelination is not exclusive to vertebrates.

Explanation: The white matter of the CNS appears white primarily due to the high concentration of myelinated axons, which are rich in lipids.

Explanation: The initial description of myelin in the 18th century marked the beginning of understanding its existence. However, its detailed structure, composition, and complex functions were elucidated over subsequent centuries with advancements in microscopy and neuroscience.

Explanation: Myelin in the PNS is crucial for both motor and sensory functions. Its role in insulating axons and facilitating rapid signal conduction is vital for the efficient transmission of both motor commands and sensory information.

Explanation: Myelination ensures rapid and precise neural signaling, which is fundamental for coordinated motor control and efficient communication between the central nervous system and muscles.

Explanation: Myelin's primary role is to insulate axons, thereby significantly increasing the speed of electrical signal transmission through saltatory conduction.

Explanation: The white matter of the CNS is primarily composed of myelinated axons, which appear white due to their high lipid content.

Explanation: Myelination significantly increases conduction speed, which is essential for agile and efficient communication across the long distances in larger animals.

Explanation: Myelination is the biological process by which glial cells form myelin sheaths around neuronal axons, serving to insulate and speed up nerve impulse transmission.

Explanation: Oligodendrocytes produce myelin in the central nervous system (CNS), while Schwann cells are responsible for myelination in the peripheral nervous system (PNS).

Explanation: Myelinating cells, including Schwann cells, provide essential metabolic and homeostatic support to axons, in addition to insulation.

Explanation: Myelinating cells provide metabolic support to axons, supplying essential energy substrates that help maintain axonal function, particularly after electrical activity.

Explanation: Axons larger than approximately 1 to 2 micrometers in diameter are typically myelinated; smaller axons generally remain unmyelinated.

Explanation: Not all axons are myelinated; many axons, particularly smaller ones, remain unmyelinated in both the CNS and PNS.

Explanation: Oligodendrocytes in the CNS are capable of extending multiple processes to myelinate segments of several different axons, unlike Schwann cells in the PNS which typically myelinate only one axon segment.

Explanation: The 'axon-myelin unit' concept emphasizes the dynamic and supportive relationship between axons and their myelinating cells, which provide insulation, metabolic support, and influence axonal structure and response to injury.

Explanation: In the CNS, astrocytes are more commonly associated with unmyelinated axons, often ensheathing them, while oligodendrocytes are responsible for myelination.

Explanation: Oligodendrocytes are the specialized glial cells in the CNS that form the myelin sheath around axons.

Explanation: Axon diameter is a primary determinant for myelination; larger diameter axons (typically >1-2 µm) are generally myelinated.

Explanation: The 'axon-myelin unit' concept highlights the integrated nature of axons and their myelinating cells, emphasizing mutual support, structural influence, and shared responses to physiological changes.

Explanation: Oligodendrocytes in the CNS can myelinate segments of multiple axons, whereas Schwann cells in the PNS typically myelinate only a single segment of one axon.

Explanation: Myelin forms segmented sheaths along the axon, separated by unmyelinated gaps known as nodes of Ranvier, which are critical for saltatory conduction.

Explanation: Saltatory conduction is the mechanism by which action potentials propagate rapidly along myelinated axons by 'jumping' between the nodes of Ranvier.

Explanation: Myelination significantly increases the speed of nerve impulse conduction through saltatory conduction, making it much faster than in unmyelinated fibers.

Explanation: In myelinated axons, voltage-gated sodium channels are highly concentrated at the nodes of Ranvier, the unmyelinated gaps, which is essential for saltatory conduction.

Explanation: The nodes of Ranvier are unmyelinated gaps between segments of myelin, and they are crucial for saltatory conduction, not continuous propagation.

Explanation: Myelin acts as an electrical insulator by decreasing the capacitance and increasing the resistance across the axonal membrane. This reduction in capacitance allows the membrane potential to change more rapidly, contributing to faster signal conduction.

Explanation: Saltatory conduction is the efficient mode of action potential propagation in myelinated axons, characterized by the impulse 'jumping' from one node of Ranvier to the next.

Explanation: Nodes of Ranvier are the periodic, unmyelinated interruptions in the myelin sheath along an axon, crucial for the concentration of ion channels and saltatory conduction.

Explanation: Myelin's insulating properties decrease the axonal membrane's capacitance and increase its resistance, facilitating faster and more efficient electrical signal propagation.

Explanation: Voltage-gated sodium channels are concentrated at the nodes of Ranvier, enabling the rapid influx of sodium ions necessary for the action potential to regenerate and 'jump' along the axon.

Explanation: Myelin was first described as white matter fibers in 1717 by Vesalius. Rudolf Virchow later named it 'myelin' in 1854.

Explanation: Myelin consists of about 40% water, and its dry mass is composed primarily of lipids (60-75%) and proteins (15-25%).

Explanation: Myelin basic protein (MBP) is crucial for compact myelin formation in the Central Nervous System (CNS). While MBP is present in the PNS, it is not the primary protein responsible for compacting myelin there.

Explanation: Galactocerebroside, a type of glycolipid, is indeed a primary lipid component found in myelin.

Explanation: Cholesterol is vital for the structural integrity and proper formation of the myelin sheath; its deficiency severely impedes myelination.

Explanation: Myelin-associated glycoprotein (MAG) is located on the inner membrane of the myelin sheath and plays a role in the interaction between the myelin and the axon, contributing to its stability and potentially guiding its formation.

Explanation: Myelin is composed of approximately 40% water; the remaining dry mass is predominantly lipids and proteins.

Explanation: Proteolipid protein (PLP) is the most abundant protein in CNS myelin and is critical for compacting and stabilizing the myelin sheath.

Explanation: Galactocerebroside, a glycolipid, is a principal lipid constituent of myelin, contributing significantly to its structure and function.

Explanation: Myelin-associated glycoprotein (MAG) is involved in the adhesion between the myelin sheath and the axon, contributing to the structural integrity of the axon-myelin unit.

Explanation: Myelin basic protein (MBP) is a critical protein in CNS myelin, essential for the compaction and stability of the myelin sheath.

Explanation: Cholesterol is a vital lipid component for the structural integrity and proper development of the myelin sheath.

Explanation: The increased conduction speed provided by myelination is essential for efficient and agile communication across the long distances found in larger organisms.

Explanation: Myelination in humans begins earlier, during the third trimester of gestation (around 26 weeks), and continues throughout development.

Explanation: The significant myelination occurring during infancy is strongly correlated with the development of advanced cognitive and motor skills, such as language acquisition and coordinated movement.

Explanation: Myelination continues into adulthood, and myelin plasticity allows for ongoing changes in myelin sheaths, contributing to learning and adaptation throughout life.

Explanation: Myelin plays a role in adult learning and memory by optimizing neural pathway efficiency. Myelin plasticity allows for ongoing changes that contribute to cognitive processes throughout life.

Explanation: Myelin plays a significant role in cognitive functions, including learning and memory, by optimizing neural pathway efficiency. Disruptions in myelination can impair these processes.

Explanation: Myelin plasticity, the ability of myelin sheaths to change in adulthood, suggests that myelination dynamics are not static but can be influenced by experience, contributing to learning, memory consolidation, and cognitive adaptation.

Explanation: Myelination commences in humans during the third trimester of gestation, approximately at 26 weeks of development.

Explanation: Myelin's plasticity allows for modifications in neural pathway efficiency, which is integral to learning new information and forming memories throughout life.

Explanation: Demyelination impairs or blocks nerve signal conduction, leading to functional deficits, rather than improving it.

Explanation: The condition described is dysmyelination, which involves defective myelin formation from birth. Demyelination refers to the loss or damage of pre-existing myelin sheaths.

Explanation: Symptoms of demyelination are diverse and can affect motor control, sensory perception, vision, cognition, and other neurological functions, depending on the affected areas.

Explanation: The immune system plays a significant role in many forms of demyelination, particularly in autoimmune diseases where it attacks myelin components.

Explanation: Dysmyelination refers to the defective formation or structure of myelin sheaths, often due to genetic causes, whereas demyelination refers to the loss or damage of already formed myelin.

Explanation: Leukodystrophies are genetic disorders affecting myelin, characterized by defective myelin structure and function (dysmyelination), not overproduction.

Explanation: The 'shiverer mouse' is a genetic model characterized by severe dysmyelination, meaning it has defective myelin sheaths. It is used in research to study the mechanisms of myelin formation and the consequences of its absence or dysfunction.

Explanation: Heat sensitivity, or Uhthoff's phenomenon, is a symptom observed in some demyelinating diseases where neurological symptoms worsen with increased body temperature, rather than improve.

Explanation: Demyelination disrupts the insulating properties of the myelin sheath, leading to a significant impairment or complete failure of nerve signal conduction.

Explanation: Visual disturbances, such as blurred or double vision, are common symptoms in demyelinating diseases due to damage to the optic nerve's myelin sheath.

Explanation: Dysmyelination refers to the abnormal formation or structure of myelin, typically resulting from genetic defects affecting myelin synthesis or maintenance.

Explanation: Multiple Sclerosis (MS) is a prominent example of a demyelinating disease, where the immune system attacks and damages the myelin sheath in the CNS.

Explanation: In autoimmune conditions, the immune system can mistakenly target myelin components, triggering inflammation and damaging the myelin sheath.

Explanation: In the peripheral nervous system, the myelin sheath, specifically the neurilemma, provides a scaffold that aids in the regrowth of severed nerve fibers.

Explanation: Untreated pernicious anemia can result in subacute combined degeneration of the spinal cord, causing myelin deterioration and neurological symptoms affecting balance and cognition.

Explanation: Investigating remyelination involves strategies such as transplanting oligodendrocyte precursor cells, aiming to restore myelin sheaths in demyelinated areas.

Explanation: The neurilemma, formed by Schwann cells in the PNS, is crucial for nerve regeneration. It provides a guiding scaffold for regenerating axons to reconnect with their targets after injury.

Explanation: Myelin repair, known as remyelination, is a natural process that can occur after damage to the myelin sheath, often involving oligodendrocyte precursor cells.

Explanation: The neurilemma, formed by Schwann cells in the PNS, is crucial for nerve regeneration. It provides a guiding scaffold for regenerating axons to reconnect with their targets after injury.