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White matter

White matter is a type of neural tissue found in the deeper regions of the and the outer regions of the , consisting of bundles of myelinated axons that connect various gray matter areas, enabling efficient communication across the ; its pale appearance derives from the fatty sheath insulating these nerve fibers. Comprising approximately 50% of the 's volume, white matter is organized into distinct tracts categorized as association fibers (connecting regions within the same hemisphere, such as the arcuate fasciculus for language processing), commissural fibers (linking the two hemispheres, notably via the ), and projection fibers (extending between cortical and subcortical structures, like the for motor control). The sheath, produced by , dramatically increases the speed of electrical impulse conduction—up to 50 times faster than in unmyelinated axons—supporting rapid information transfer essential for cognitive functions including attention, memory, and executive processing. Disruptions to white matter, as seen in conditions like or , can impair neural connectivity, leading to cognitive decline, motor deficits, and other neurological symptoms, underscoring its critical role in brain health and . Evolutionarily, white matter has expanded disproportionately compared to gray matter in humans, facilitating complex neural networks that underpin advanced .

Anatomy and Composition

Macroscopic Features

White matter exhibits a distinctive pale, whitish appearance in the , primarily due to the lipid-rich sheaths that insulate the axons, which scatter light and create this color upon gross inspection. In contrast, adjacent gray matter appears darker because of its high concentration of neuronal cell bodies and unmyelinated structures that absorb more light. This visual distinction has been noted since the , when anatomist first described the "white substance" separate from gray matter in his 1543 work De Humani Corporis Fabrica, marking a foundational observation in . Upon gross dissection of the , white matter is observable as organized bundles or tracts of myelinated fibers, visible to the naked eye and forming prominent structures such as the , which connects the cerebral hemispheres. These tracts present a firm, cohesive due to the dense packing of axons, distinguishing them from the more diffuse gray matter. The density and volume of white matter show regional variations and scale across mammalian species, with evolutionary expansion favoring greater white matter proportions in larger brains to support extended connectivity; in adult humans, white matter constitutes approximately 50% of total brain volume. This proportion underscores white matter's role in facilitating efficient neural communication in complex brains.

Microscopic Components

White matter is primarily composed of bundled myelinated axons, responsible for production, supportive , and a scarcity of neuronal cell bodies or somata. form multilayered sheaths around multiple axons, while contribute to structural integrity, nutrient supply, and maintenance of the extracellular environment. Neuronal somata are largely absent, distinguishing white matter from gray matter, which is rich in cell bodies. The axonal components consist mainly of myelinated fibers with diameters ranging from 0.2 to 20 micrometers, enabling efficient long-range ; unmyelinated fibers are present but constitute a minor proportion. These myelinated axons are organized in parallel bundles, surrounded by sheaths that provide electrical insulation. The in white matter exhibits low water content—approximately 71% by volume—compared to gray matter's 83%, reflecting the dense packing of lipid-rich . This includes glycosaminoglycans, such as hyaluronan and proteoglycans, which support cellular interactions, along with sparse fibers primarily in perivascular and regions. In human white matter, volumetric composition estimates indicate that axons occupy about 33% of the volume, myelin sheaths account for approximately 25-35%, with the remaining portion comprising glia (5-10%), blood vessels (<5%), and extracellular space (15-20%). These proportions vary by region but underscore the dominance of axonal and myelin elements in conferring white matter's structural and functional properties.

Myelination Process

Myelination in the begins prenatally in humans, with precursor cells (OPCs) emerging around 10-12 weeks of and initial formation starting approximately 20 weeks into pregnancy, as evidenced by the appearance of myelin basic protein (MBP)-positive by 28 weeks. This process initiates in the and optic nerves, progressing rostrally to the cerebral hemispheres and caudally to the during the third . Postnatally, myelination accelerates rapidly in the first two years of life, particularly in association and projection fibers, and continues at a slower rate through childhood and , reaching a peak around age 20-30 years, after which minor refinements persist into adulthood. This extended timeline allows for adaptive myelination in response to experience and neural activity, with the and among the last regions to fully myelinate. The mechanism of myelination involves mature , which extend multiple cytoplasmic processes to selectively ensheath greater than 0.2 micrometers in diameter, wrapping them in a spiral fashion to form a multilayered lipid-rich sheath. This wrapping begins at the inner tongue of the membrane, which advances laterally along the , driven by dynamics and phospholipid signaling such as PI(3,4,5)P3 accumulation, resulting in compaction of the extracellular leaflets to create a tight, insulating barrier. Gaps in the sheath, known as nodes of Ranvier, are left at regular intervals to facilitate , with one capable of myelinating up to 50 axonal segments simultaneously. The process is highly regulated by axonal signals, including neuregulin-1 and neuronal activity, which influence sheath thickness and internode length to optimize conduction velocity. At the molecular level, the myelin sheath's structure relies on key proteins such as MBP and proteolipid protein (PLP), which together comprise about 80% of the protein content (and ~15-25% of the dry weight) and are essential for membrane compaction and stability. MBP, a positively charged intracellular protein, neutralizes the negative charges of phospholipids to promote adhesion between myelin lamellae, while PLP, a hydrophobic tetraspan protein embedded in the membrane, maintains sheath integrity and inhibits immune recognition. These proteins are synthesized locally in the oligodendrocyte processes through the transport of mRNA transcripts along microtubules, a process facilitated by RNA-binding proteins like hnRNP A2 and regulated by transcription factors such as Sox10, ensuring precise assembly at the site of myelination. Disruptions in this synthesis, such as mutations in the MBP or PLP genes, lead to hypomyelination or dysmyelination syndromes. Remyelination, the repair process following demyelination, exhibits limited efficiency in the adult but shares mechanistic similarities with initial myelination, primarily involving the recruitment and of OPCs into remyelinating . These OPCs migrate to sites, proliferate in response to signaling molecules like PDGF and FGF, and extend processes to form new, albeit thinner and shorter, sheaths around demyelinated axons, often achieving partial restoration over months. Factors such as aging, , and inhibitory components impair this potential, resulting in incomplete repair and vulnerability to axonal degeneration.

Location and Organization

Distribution in the Brain

White matter is primarily located in subcortical regions of the brain, where it surrounds clusters of gray matter nuclei and forms compact bundles that facilitate inter-regional communication. In the cerebral hemispheres, it occupies the deeper layers beneath the cortical gray matter, creating structures such as the , which separates the and from the , and the , a radiating array of fibers that fans out from the toward the . These distributions ensure efficient projection of signals between cortical areas and subcortical structures like the and . In terms of volume, white matter constitutes approximately 60% of the cerebral hemispheres in adults, reflecting its role in extensive , while in newborns, white matter constitutes a smaller proportion of cerebral volume due to incomplete myelination at birth. This proportion increases progressively throughout as axons myelinate, supporting enhanced neural . Evolutionarily, white matter has undergone significant expansion in , with humans exhibiting a disproportionate increase relative to gray matter to accommodate complex cognitive networks and long-range connections. This growth is particularly pronounced in prefrontal regions, enabling advanced and unique to Homo sapiens. Key specific locations include periventricular regions adjacent to the , where white matter tracts converge and are vulnerable to developmental insults, and brainstem areas containing descending pathways such as the . These originate from the in the and descend through the , cerebral peduncles, and medullary pyramids to influence spinal motor neurons.

Distribution in the Spinal Cord

In the spinal cord, white matter forms a continuous sheath surrounding the central gray matter, which is organized in an H-shaped configuration in cross-section due to the ventral and horns projecting laterally. This arrangement divides the white matter into three main columns: the anterior (ventral) funiculus, located between the anterior fissure and the anterolateral sulcus; the posterior () funiculus, situated between the posterior sulcus and the posterolateral sulcus; and the lateral funiculus, positioned between the and ventral roots. These columns contain bundled axons that facilitate ascending sensory pathways and descending motor pathways, with the white matter appearing pale due to sheaths. The proportion of white matter relative to gray matter varies along the spinal cord's length, with a higher ratio of white to gray matter in rostral segments compared to caudal ones, reflecting the increasing number of long ascending and descending tracts in upper regions. In the enlargement (approximately to T1), the spinal cord cross-section is widest, reaching up to 13.3 mm in transverse diameter, to accommodate innervation of the upper limbs, while thoracic segments are narrower at about 8.3 mm, and segments measure around 9.4 mm. This segmental variation results from the embedding of the H-shaped gray matter centrally, which expands in enlargements for motor and but occupies a smaller relative area in regions due to extensive white matter tracts. White matter in the serves as the primary conduit linking the to peripheral structures, housing tracts such as the in the anterior and lateral columns for transmitting and sensations, and the dorsal columns (fasciculus gracilis and cuneatus) for and fine touch. These pathways ensure bidirectional communication, with ascending fibers carrying sensory input to supraspinal centers and descending fibers relaying motor commands from the .

Major White Matter Tracts

White matter tracts in the are classified into three primary categories based on their connectivity: commissural tracts, which interconnect homologous regions of the two cerebral hemispheres; association tracts, which link different cortical areas within the same hemisphere; and projection tracts, which connect cortical regions to subcortical structures, including the . These tracts facilitate interhemispheric integration, intrahemispheric communication, and sensorimotor relay, respectively, forming the structural backbone of neural information transfer. Commissural tracts primarily include the and the . The is the largest commissural bundle, comprising approximately 200 million myelinated axons that enable interhemispheric communication between corresponding cortical areas, such as prefrontal and sensorimotor regions. The , a smaller transversely oriented tract, connects the temporal lobes, including olfactory and limbic structures, supporting functions like bilateral sensory integration and emotional processing. Association tracts are subdivided into long and short types, with the former spanning distant cortical regions and the latter connecting adjacent gyri. Key long association tracts include the arcuate fasciculus, which links Broca's and Wernicke's areas in the frontal and temporal lobes, playing a crucial role in language processing, repetition, and semantic integration. The uncinate fasciculus provides direct connections between the and anterior temporal regions, facilitating memory encoding, , and emotional regulation. Short association tracts, known as U-fibers or arcuate fibers, form superficial loops beneath the cortex to interconnect neighboring gyri within the same lobe, contributing to local cortical processing and integration. Projection tracts convey signals between the and lower brain or spinal structures, ensuring coordinated motor and sensory functions. The originates from the and descends through the to innervate spinal motor neurons, primarily controlling voluntary skilled movements of the limbs and trunk. The , extending from the to the primary , relays visual information from the to occipital areas, enabling perception of the contralateral . Across the , these long and short tracts collectively form an extensive network, with the total length of myelinated axons estimated at 150,000 to 180,000 kilometers in young adults, underscoring the immense scale of white matter connectivity.

Physiological Functions

Signal Conduction Mechanisms

White matter facilitates rapid electrical signal transmission through , where action potentials propagate by jumping between nodes of Ranvier along myelinated axons. This mechanism contrasts with continuous conduction in unmyelinated axons, enabling conduction velocities of 100–150 m/s in myelinated fibers compared to 0.5–10 m/s in unmyelinated ones. The nodes of Ranvier, short unmyelinated segments rich in voltage-gated sodium channels, allow to occur only at these points, while the insulating sheath between nodes prevents signal dissipation. The biophysical basis of this enhanced conduction lies in the properties of the myelin sheath, which acts as an electrical by increasing membrane (R_m) and reducing . These changes are analyzed through , which models the as a cylindrical where the length constant λ—representing the distance over which a voltage decays to 1/e of its value—is given by λ = √(R_m / R_i), with R_i as the axial . Myelin's multilayered structure effectively boosts R_m, extending λ and allowing local currents to spread farther between nodes without significant loss, thus supporting efficient regeneration. Saltatory conduction also improves energy efficiency by requiring lower ion flux per action potential, as sodium entry and subsequent ATP-dependent pumping by Na⁺/K⁺-ATPase occur primarily at nodes rather than along the entire axon length. This reduces the metabolic cost of signaling, with myelinated axons consuming approximately 70 times less energy per action potential than unmyelinated axons of equivalent signaling capacity. The overall system, including supporting that produce , conserves ATP by minimizing axonal ion imbalances and leveraging glial metabolic support. Conduction velocity in myelinated s is directly proportional to (v ∝ d), as larger reduce internal resistance and allow thicker layers, optimizing current flow. In contrast, some models for unmyelinated s suggest v ≈ √d due to differing resistive properties. This relationship, first theoretically established by Rushton, underscores how white matter tract scaling influences neural timing.

Role in Neural Networks

White matter serves as the primary structural substrate for the brain's , forming the wiring that links distributed neural regions into functional networks essential for and . By facilitating long-range connections between cortical and subcortical areas, white matter tracts enable the of information across the , supporting complex processes such as , , and . For instance, the superior longitudinal fasciculus contributes to the connectivity of the , which is active during and self-referential thinking. White matter exhibits , allowing its microstructure to adapt based on and learning, which enhances efficiency over time. In individuals with extensive musical training, such as professional musicians who began in childhood, there is increased —a measure of white matter integrity—in the , reflecting stronger interhemispheric connectivity that supports bimanual coordination and auditory-motor integration. These changes demonstrate how repeated use can strengthen tract organization, optimizing information flow within neural circuits. Through its role in inter-regional communication, white matter enables across networks, where conduction delays between distant areas influence the temporal dynamics of cognitive functions. For example, interhemispheric transfer via the typically occurs with delays of 10-20 milliseconds, allowing synchronized activity between hemispheres for tasks requiring bilateral integration, such as language processing or spatial reasoning. This timing is critical for maintaining coherence in distributed networks, preventing disruptions in overall function. Evolutionarily, the disproportionate expansion of white matter relative to gray matter in humans has underpinned the development of advanced , including abstract thinking and . This growth in tract volume and myelination density has enabled more efficient long-range signaling, supporting the emergence of large-scale networks that distinguish architecture from that of other . Such adaptations have been pivotal in facilitating the neural required for higher-order functions.

Interaction with Gray Matter

White matter axons, which form the long-range projections of the , originate from neuronal cell bodies in gray matter and travel through white matter tracts before terminating in gray matter regions, where they form synapses on dendrites or somata of target neurons. This anatomical enables the of local processing in gray matter with global connectivity provided by white matter, minimizing conduction delays across the . For instance, global axons penetrate gray matter modules, creating synaptic endpoints that facilitate within cortical columns of approximately 10,000 neurons. At the gray-white matter junctions, play a critical role in bridging the two compartments, extending processes that regulate nutrient flow from blood vessels to neural elements and maintain the integrity of the blood-brain barrier. Protoplasmic in gray matter and fibrous in white matter converge at these borders, providing metabolic support such as glucose and to axons and while ensheathing synaptic terminals and nodes of Ranvier to stabilize ionic environments. This glial ensures efficient energy transfer and across the interface, with endfeet on capillaries expressing aquaporin-4 to control water and solute exchange. The balance between gray and white matter volumes shifts dramatically during , reflecting the maturation of neural . In infancy, gray matter dominates, comprising a larger proportion of total due to rapid neuronal and dendritic ; for example, hemispheric gray matter increases by 149% in the first year of life, compared to 11% for white matter. By childhood and into adulthood, white matter expands more substantially through myelination and axonal elongation, resulting in white matter constituting approximately 50% of in adults while gray matter peaks and then declines relatively. This transition underscores the evolving dependency of gray matter computation on white matter infrastructure. In pathophysiological contexts, lesions at gray-white matter borders, such as those in ischemic , exploit this interface to amplify damage across compartments. White matter's vulnerability to hypoperfusion—due to sparse vascularization and reliance on gray matter-derived collaterals—leads to and axonal injury that propagates secondary neurodegeneration into connected gray matter regions, exacerbating cortical atrophy and functional deficits. For instance, subcortical white matter infarcts account for about 50% of lesion volume and correlate with remote gray matter thinning via disrupted fiber tracts at the borders, worsening outcomes like motor impairment.

Imaging Techniques

Conventional MRI Methods

Conventional (MRI) methods provide essential structural visualization of white matter by exploiting differences in tissue relaxation properties, particularly the influence of on signal intensity. These techniques, including T1-weighted, T2-weighted, and (FLAIR) sequences, have been foundational since the when MRI was first developed for human imaging, with clinical adoption accelerating in the 1980s for detecting white matter abnormalities such as those in (MS). In T1-weighted imaging, white matter appears hyperintense (brighter) relative to gray matter due to the shorter longitudinal relaxation time (T1) of myelinated axons, typically around 800 ms at 1.5 T field strength, which arises from the lipid-rich sheath enhancing magnetization recovery. This contrast allows delineation of major white matter tracts and overall architecture, though it is less sensitive to subtle pathologies like early demyelination. T2-weighted imaging, conversely, highlights water content, rendering white matter hypointense (darker) in healthy states but hyperintense in areas of , inflammation, or demyelination, where increased free water prolongs transverse relaxation time (T2). FLAIR sequences build on T2 weighting by incorporating an inversion recovery pulse with a long inversion time to null the cerebrospinal fluid (CSF) signal, which has a long T1 and T2 similar to pathological tissues. This suppression improves detection of periventricular white matter lesions by reducing CSF-related artifacts and enhancing contrast for hyperintense abnormalities adjacent to ventricles. Together, these methods enable identification of gross white matter lesions and structural integrity, pivotal for diagnosis since the when MRI first demonstrated plaque-like hyperintensities. Conventional MRI typically achieves voxel resolutions of 1-3 mm, sufficient for visualizing large-scale tracts like the but limited for resolving individual axons or fine microstructural details below this scale. While these approaches excel at basic anatomical contrast, they do not quantify directional fiber properties, which are addressed by advanced techniques. Emerging applications as of include () algorithms that enhance MRI images to approximate 7T resolution, improving white matter visualization without higher-field hardware. Additionally, portable low-field MRI systems, developed in recent years, enable accessible detection of white matter hyperintensities in community settings.

Advanced Diffusion Imaging

Advanced diffusion imaging techniques, particularly diffusion tensor imaging (DTI), enable the non-invasive mapping of white matter microstructure by exploiting the of water molecules along axonal fibers. In DTI, water within each imaging is modeled as an , where the principal axes represent the primary, secondary, and tertiary diffusion directions, providing insights into fiber orientation and integrity. This second-order tensor approximation assumes a single dominant fiber orientation per voxel, yielding scalar metrics such as (FA), which quantifies the degree of diffusion directionality on a scale from 0 (isotropic diffusion) to 1 (highly anisotropic, coherent fiber bundles). Higher FA values indicate greater tract coherence, often reflecting myelinated density and alignment in white matter regions. Building on DTI, employs deterministic or probabilistic fiber tracking algorithms to reconstruct three-dimensional white matter pathways by propagating streamlines along principal directions. These methods connect regions of interest, such as the and subcortical structures, to visualize major tracts like the arcuate fasciculus, which links language-related areas in the frontal, temporal, and parietal lobes. has revolutionized the study of connectivity, allowing delineation of bundles that are challenging to resolve with traditional . Despite its utility, DTI faces limitations in voxels containing crossing or kissing fibers, where multiple orientations lead to averaged tensor estimates and reduced accuracy; such complex configurations occur in approximately 60-90% of white matter . To address this, higher-order models like and high angular resolution (HARDI) sample on a spherical basis or with denser angular resolutions, resolving multiple fiber orientations within a single . , for instance, reconstructs the orientation distribution function (ODF) from q-space data, enabling the detection of crossing fibers without assuming Gaussian . HARDI extends this by acquiring data at higher b-values and more directions, improving angular resolution for intricate white matter architectures. More recent multi-compartment models, such as neurite orientation dispersion and (NODDI), introduced in , further refine white matter assessment by estimating neurite index (NDI) and orientation dispersion index (ODI) from multi-shell diffusion data. These metrics provide biophysical insights into dendritic and axonal , offering greater specificity for microstructural changes in disorders like compared to DTI or HARDI alone, and are increasingly used in clinical research as of 2025. Key quantitative metrics from these techniques include mean diffusivity (MD), which measures the average magnitude of and inversely correlates with and cellular barriers in white matter. In healthy adults, in the typically ranges around 0.7, with regional variations such as higher values in the splenium (~0.78) reflecting compact, myelinated fibers. These metrics provide robust proxies for microstructural integrity, aiding in the assessment of white matter organization beyond conventional imaging.

Functional and Structural Correlations

White matter structure, particularly as measured by from diffusion tensor imaging, exhibits strong correlations with cognitive processing speed, especially in aging populations. Higher FA values in key tracts such as the and superior longitudinal fasciculus are associated with faster reaction times and better performance on tasks like the Symbol Digit Modalities Test, with reported correlations ranging from r = 0.7 to 0.8 in studies of older adults with , a condition linked to accelerated aging effects. In broader aging cohorts, these associations typically fall in the moderate range of r ≈ 0.3–0.5, reflecting how preserved axonal integrity facilitates efficient neural transmission and underlies declines in executive function as FA decreases with age. White matter integrity also plays a critical role in , buffering against neuropathological changes and predicting resilience to cognitive decline. In , degeneration of tracts like the fornix and cingulum often precedes overt symptoms, with reduced FA in these regions correlating with early impairments in and executive function, thereby diminishing before gray matter atrophy becomes prominent. Higher , influenced by factors such as and , moderates the impact of white matter fiber bundle shortening on cognitive performance, attenuating declines in tasks assessing global in healthy older adults. Multimodal approaches integrating diffusion tensor imaging (DTI) with functional MRI (fMRI) enhance understanding of effective connectivity, particularly in cognitive tasks requiring . By combining structural connectivity metrics like with task-evoked BOLD signals, these methods reveal how white matter pathways support directed in frontoparietal s during attention-demanding paradigms, such as flanker tasks, where disruptions in tract predict reduced . This fusion highlights causal influences, for instance, from prefrontal regions to parietal areas, aligning structural constraints with functional dynamics. Longitudinal studies demonstrate that white matter maturation tracks , with FA increases continuing into young adulthood and peaking around the mid-20s to early 40s across major tracts like the and uncinate fasciculus. This temporal alignment corresponds to cognitive maturation, including improvements in reasoning and , as enhanced microstructural integrity supports more efficient neural networks during this period of peak brain plasticity.

Clinical and Research Aspects

Associated Disorders

White matter disorders encompass a range of pathological conditions that disrupt the structural integrity and functional connectivity of myelinated axons in the . Demyelinating diseases, which involve the loss or damage of sheaths, are among the most prominent, leading to impaired signal transmission and neurological deficits. (), the most common such disorder, is characterized by the formation of demyelinating plaques in white matter, resulting from an autoimmune attack on -producing . This process affects approximately 2.9 million people globally as of 2023, predominantly young adults, and manifests with symptoms including motor weakness, sensory disturbances, and . Leukodystrophies represent another key category of demyelinating disorders, primarily genetic in origin and targeting white matter . Adrenoleukodystrophy (ALD), an X-linked peroxisomal disorder caused by mutations in the ABCD1 gene, leads to the accumulation of very long-chain fatty acids, resulting in progressive demyelination of cerebral white matter and . This condition often presents in childhood with behavioral changes, vision loss, and motor decline, underscoring the vulnerability of white matter to metabolic disruptions. Diagnosis of these demyelinating conditions typically relies on (MRI) to visualize white matter lesions, as detailed in conventional MRI methods. Vascular disorders also significantly impact white matter, particularly through small vessel disease (), which causes ischemia and chronic hypoperfusion. White matter hyperintensities (WMH), visible as areas of increased signal intensity on MRI, are hallmark features of SVD and reflect damage to periventricular and deep white matter tracts. These hyperintensities are associated with 25% of ischemic strokes, contributing to vascular and disturbances in affected individuals. Traumatic injuries to white matter often result from mechanical forces disrupting axonal integrity. (DAI), a common consequence of (TBI), arises from rotational shear forces that stretch and tear axons within white matter tracts, leading to widespread and secondary degeneration. DAI is prevalent in moderate to severe TBIs, such as those from accidents, and carries a poor , with mortality rates around 25% in the acute phase and long-term disabilities including , cognitive deficits, and persistent vegetative states in survivors. Genetic factors further contribute to white matter through mutations affecting genes. Pelizaeus-Merzbacher disease (PMD), an X-linked disorder caused by mutations in the PLP1 gene encoding proteolipid protein 1—a major component of —results in severe hypomyelination of central white matter. This leads to , , and developmental delay from infancy, with the degree of hypomyelination correlating to clinical severity due to disrupted function and formation.

Developmental and Aging Changes

White matter myelination begins prenatally in the around the fourth month of (approximately 16 weeks), initially in the dorsal columns, and progresses rostrally (cephalad) from the toward higher brain regions. By the late second trimester (around 29 weeks), myelination advances in the and cerebellar peduncles, extending to the and optic radiations by the third trimester. At birth, much of the cerebral white matter remains immature, setting the stage for extensive postnatal development. During childhood and , white matter volume undergoes rapid expansion, roughly doubling by age 5 as the reaches about 90% of adult size, reflecting accelerated myelination that enhances axonal conduction efficiency. This growth continues through , driven in part by in gray matter regions, which refines neural circuits and supports increased white matter integrity for improved connectivity, alongside experience-dependent learning that promotes targeted myelination in association pathways. Diffusion tensor imaging studies reveal progressive increases in during this period, particularly in frontal and parietal tracts, correlating with cognitive maturation. In aging, white matter integrity peaks between 30 and 50 years, after which it declines, with reductions in content returning to levels seen in childhood by ages 70–80, accompanied by reduced microstructural integrity. This loss is linked to demyelination, which contributes to decreasing () across major tracts, as evidenced by quantitative MRI showing age-related reductions in water fraction and increased radial diffusivity. Such changes reflect cumulative axonal degeneration and impaired function, impacting overall network efficiency. Sex differences influence white matter trajectories, with males typically exhibiting a later peak in myelination compared to females, who reach earlier maxima but experience a steeper age-related decline. These patterns, observed via diffusion tensor imaging and g-ratio mapping in major fiber tracts like the and arcuate fasciculus, suggest females may have advanced early maturation but greater vulnerability to later demyelination, potentially modulated by hormonal and genetic factors. Longitudinal studies confirm these divergences, with males showing sustained in frontal regions into midlife, while females demonstrate more pronounced reductions post-50 years.

Current Research Directions

Current research in white matter builds on the (HCP) through extensions that emphasize mapping individual variability in neural pathways. Recent updates, including the HCP Young Adult 2025 release, incorporate advanced processing pipelines for data from over 1,000 subjects, enabling detailed analysis of white matter microstructure and differences across individuals. These efforts leverage 7T MRI to achieve sub-millimeter resolution in whole-brain diffusion imaging, facilitating precise of major white matter bundles and assessments up to 0.9 for key pathways. Additionally, longitudinal extensions across age groups highlight dynamic changes in white matter organization, supporting personalized models of . Investigations into white matter neuroplasticity focus on remyelination therapies to restore myelin integrity following demyelination. The antihistamine has shown promise in phase II trials for (), with follow-up analyses in 2023 demonstrating evidence of myelin repair in the using myelin water fraction imaging, yielding relative increases of approximately 4.5% during treatment periods. This builds on the original ReBUILD trial, which established clemastine's efficacy in improving visual latency as a marker of remyelination. Ongoing studies explore combination therapies, such as clemastine with metformin, reporting statistically significant enhancements in remyelination biomarkers in relapsing patients as of 2025. Artificial intelligence applications are advancing automated for white matter analysis, enhancing and precision over traditional manual methods. models, including convolutional neural networks like TractSeg, achieve segmentation accuracies exceeding 97% for up to 72 white matter bundles, reducing processing time and variability in data. Recent comparisons show AI-based approaches yield consistent measurements with manual while improving scalability for large datasets, with gains up to 99% in shape prediction tasks. Systematic reviews confirm these tools boost overall accuracy in bundle delineation by integrating data, supporting broader clinical adoption. Despite progress, significant gaps persist in white matter research, particularly in glial-axon signaling and cross-species translations. Current understanding of bidirectional glial-axon interactions, such as and gliotransmission supporting axonal metabolism, remains limited, hindering targeted interventions for disorders like . Translating findings from models to humans is challenged by species-specific glial heterogeneity, with insufficient transcriptomic data to validate therapeutic efficacy across taxa. Furthermore, post-2020 calls emphasize the need for more diverse population studies to capture variability in white matter responses, addressing underrepresentation that limits generalizability of current models.

References

  1. [1]
    White matter of the brain: MedlinePlus Medical Encyclopedia
    Feb 11, 2025 · White matter is in deeper brain tissues, containing nerve fibers (axons) with myelin, which gives it color and protects nerve fibers.
  2. [2]
    White matter and cognition: making the connection - PubMed Central
    In general, white matter can be seen as providing for the transfer of information within distributed neural networks, while gray matter subserves information ...Missing: definition | Show results with:definition
  3. [3]
    A taxonomy of the brain's white matter: twenty-one major tracts for ...
    Here, we characterized the connections, morphology, traversal, and functions of the major white matter tracts in the brain.
  4. [4]
    Change in the Brain's White Matter - NIH
    Nov 5, 2010 · The white color derives from the electrical insulation (myelin) that coats axons (see the figure). It is formed by nonneuronal cells, ...
  5. [5]
    Neuroanatomy, Gray Matter - StatPearls - NCBI Bookshelf
    The grey matter has a large number of neurons present, which allows it to process information and release new information through axon signaling found in the ...
  6. [6]
    The history of myelin - PMC - PubMed Central
    The renaissance physician Andreas Vesalius (1514–1564†), considered the father of modern anatomy, was the first to describe white matter and gray matter in the ...
  7. [7]
    [PDF] White Matter Anatomy
    White matter includes projection fibers connecting cortex to brainstem, deep nuclei, cerebellum, and spinal cord, and tracts like corticospinal, corticobulbar, ...Missing: definition | Show results with:definition
  8. [8]
    White Matter - an overview | ScienceDirect Topics
    Its glistening white color is due to the abundant presence of lipids in the myelin sheaths. The latter are formed by tightly wrapped membranous structures ...<|separator|>
  9. [9]
    White matter and cognition: making the connection
    White matter comprises half of the brain, has expanded more than gray matter in evolution, and forms an indispensable component of distributed neural networks ...
  10. [10]
    Functional regeneration of the brain: white matter matters - PMC
    In the human brain, white matter makes up about 50% of the brain volume and consumes 43.8% of the brain's total energy budget for resting potential maintenance.
  11. [11]
    White matter volume and white/gray matter ratio in mammalian ...
    It has been suggested that the volume of the white matter scales universally as a function of the volume of the gray matter across mammalian species, as would ...
  12. [12]
    White Matter Structure: A Microscopist's View - ScienceDirect.com
    The white matter of the central nervous system contains axons, their myelin sheaths, and glial cells. Of the glial populations, oligodendrocytes, ...
  13. [13]
    The axon-glia unit in white matter stroke: mechanisms of damage ...
    The white matter is comprised primarily of axons and glial cells, and is devoid of neuronal cell bodies or their dendrites. Bundles of axons are topographically ...
  14. [14]
    Distribution of axon diameters in cortical white matter: an electron ...
    Aug 21, 2014 · Axon diameters in human brains ranged from 0.16 to 9 μm, with most below 1 μm, and a small population of thicker fibers.2.1 Human Brains · 3.1 Human Brains · 4 Discussion
  15. [15]
    Myelination at a glance | Journal of Cell Science
    Jul 15, 2014 · In humans, around 40% of the brain contains white matter comprising densely packed fibres, of which myelin is a main component (50–60% dry ...
  16. [16]
    In vivo measurement of T2 distributions and water contents in ...
    Dec 12, 2005 · The water contents of white and gray matter were 0.71 (0.01) and 0.83 (0.03) g/ml, respectively. All white-matter structures had significantly ...
  17. [17]
    Tissue-specific extracellular matrix accelerates the formation of ...
    Mar 11, 2019 · The brain's extracellular matrix (ECM) is a macromolecular network composed of glycosaminoglycans, proteoglycans, glycoproteins, ...
  18. [18]
    Modeling white matter microstructure - PMC - PubMed Central
    The term fiber refers to the axon plus its myelin sheath. About 33%2 of the white matter volume is composed of axons (Nilsson et al., 2013; Perge et al., 2009).
  19. [19]
    The Initial Myelination in the Central Nervous System - PMC
    Mar 27, 2023 · This review focuses on the current understanding of how CNS myelination is initiated and also the regulatory mechanisms underlying the process.
  20. [20]
    Dynamics and Mechanisms of CNS Myelination - PMC
    CNS myelination involves oligodendrocytes ensheathing axons with a multilamellar sheath, facilitating electrical conduction and bidirectional communication. ...
  21. [21]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC6715306/
  22. [22]
    Biology of Oligodendrocyte and Myelin in the Mammalian Central ...
    This review deals with the recent progress related to the origin and differentiation of the oligodendrocytes, their relationships to other neural cells, and ...
  23. [23]
    https://journals.physiology.org/doi/full/10.1152/physrev.2001.81.2.871
  24. [24]
    https://doi.org/10.1016/j.cell.2013.11.044
  25. [25]
    https://doi.org/10.1523/JNEUROSCI.4314-13.2014
  26. [26]
    Promoting remyelination in central nervous system diseases
    In this review, we present a rather comprehensive account of the mechanisms underlying myelin formation, injury, and repair, with a particular emphasis on the ...
  27. [27]
    https://doi.org/10.1073/pnas.1210293110
  28. [28]
    https://doi.org/10.1093/brain/awu375
  29. [29]
    Neuroanatomy, Internal Capsule - StatPearls - NCBI Bookshelf
    The internal capsule (IC) is a subcortical white matter structure situated in the inferomedial portion of each cerebral hemisphere.Introduction · Structure and Function · Embryology · Surgical Considerations
  30. [30]
    White Matter Disease: Symptoms, Causes, and Treatment - WebMD
    Jan 9, 2025 · Your brain is about 40% grey matter and 60% white matter. Grey ... Cerebral White Matter."O. UC Davis Health System: "White Matter ...
  31. [31]
    A Structural MRI Study of Human Brain Development from Birth to 2 ...
    The percentage of white matter actually decreased in the first and second year. Thus, the ratio of hemispheric gray matter to white matter changes significantly ...
  32. [32]
    Differential Prefrontal White Matter Development in Chimpanzees ...
    Aug 23, 2011 · Prefrontal white matter volume is disproportionately larger in humans than in other primates ... expansion during human development and evolution.
  33. [33]
    Scaling Principles of White Matter Connectivity in the Human and ...
    Nov 24, 2021 · Higher proportions of white matter have been proposed to help maintain connectivity in the expanded cortex of larger brains, which requires ...
  34. [34]
    Frontal and periventricular brain white matter lesions and cortical ...
    Recent in vivo imaging studies provide supportive evidence that periventricular white matter lesions are associated with cortical cholinergic deafferentation ...
  35. [35]
    Neuroanatomy, Pyramidal Tract Lesions - StatPearls - NCBI Bookshelf
    It originates in multiple areas of the brain, mainly in the primary motor cortex (Brodmann area 4) and in premotor areas (Brodmann area 6). However, it can ...Missing: white matter periventricular origin
  36. [36]
    Neuroanatomy, Spinal Cord Morphology - StatPearls - NCBI Bookshelf
    White matter surrounds the gray matter and is formed by tracts that transmit information up and down the spinal cord; this divides into 3 funiculi. The ...
  37. [37]
    The Internal Anatomy of the Spinal Cord - Neuroscience - NCBI - NIH
    The white matter of the spinal cord is subdivided into dorsal (or posterior), lateral, and ventral (or anterior) columns, each of which contains axon tracts ...
  38. [38]
    Anatomy of the Spinal Cord (Section 2, Chapter 3) Neuroscience ...
    A transverse section of the adult spinal cord shows white matter in the periphery, gray matter inside, and a tiny central canal filled with CSF at its center.
  39. [39]
    White Matter Structure and Function - Oxford Academic
    White matter is constituted of axons invested with myelin, millions of which combine to form the many tracts that travel within and between the hemispheres as ...
  40. [40]
    On Describing Human White Matter Anatomy
    We use our method to encode anatomical knowledge in human white matter describing 10 association and 8 projection tracts per hemisphere and 7 commissural tracts ...
  41. [41]
    Neuroanatomy, Corpus Callosum - StatPearls - NCBI Bookshelf
    The corpus callosum is a brain region of white matter connecting hemispheres, composed of 200 million nerve fibers, and integrates information between ...
  42. [42]
    Anterior commissure | Radiology Reference Article - Radiopaedia.org
    Jul 12, 2024 · The anterior commissure (AC) is a transversely oriented commissural white matter tract that connects the two cerebral hemispheres along the midline.
  43. [43]
    Functional Contributions of the Arcuate Fasciculus to Language ...
    Jun 25, 2021 · Current evidence strongly suggests that the arcuate fasciculus (AF) is critical for language, from spontaneous speech and word retrieval to repetition and ...
  44. [44]
    Dissecting the uncinate fasciculus: disorders, controversies and a ...
    The uncinate fasciculus is a long-range association fibre connecting the frontal and temporal lobes. In older anatomy texts, the uncinate fasciculus is ...
  45. [45]
    Subcortical U-fibers | Radiology Reference Article - Radiopaedia.org
    May 9, 2023 · Subcortical U-fibers, also known as short association fibers, connect adjacent brain gyri within the cortex or subcortical white matter. They ...
  46. [46]
    Corticospinal Tract Lesion - StatPearls - NCBI Bookshelf - NIH
    The corticospinal tract controls primary motor activity for the somatic motor system and is a major pathway for voluntary movements. The lateral corticospinal ...
  47. [47]
    Optic radiation | Radiology Reference Article | Radiopaedia.org
    May 11, 2017 · The optic radiation, also known as geniculocalcarine tract, is part of the visual pathway, forming the connection between the lateral geniculate nucleus of the ...
  48. [48]
    Aging and the human neocortex - PubMed
    The total myelinated fiber length varied from 150,000 to 180,000 km in young individuals and showed a large reduction as a function of age. The total number ...Missing: axon | Show results with:axon
  49. [49]
    Increased Conduction Velocity as a Result of Myelination - NCBI - NIH
    For example, whereas unmyelinated axon conduction velocities range from about 0.5 to 10 m/s, myelinated axons can conduct at velocities up to 150 m/s.
  50. [50]
    Saltatory Conduction along Myelinated Axons Involves a Periaxonal ...
    Dec 26, 2019 · The propagation of electrical impulses along axons is highly accelerated by the myelin sheath and produces saltating or “jumping” action ...
  51. [51]
    Neuroglial Cells - Neuroscience - NCBI Bookshelf
    ### Summary on Cable Theory, Length Constant, and Myelin Effects
  52. [52]
    The metabolic efficiency of myelinated vs unmyelinated axons - PMC
    Jul 23, 2011 · The metabolic cost of action potential (AP) in myelinated nerve fibers has not been directly estimated, unlike the cost of unmyelinated axons.
  53. [53]
    The Myelin Sheath - Basic Neurochemistry - NCBI Bookshelf
    Conduction velocity in myelinated fibers is proportional to the diameter, while in unmyelinated fibers it is proportional to the square root of the diameter.<|control11|><|separator|>
  54. [54]
    Constrained Source-Based Morphometry Identifies Structural ... - NIH
    WM regions underlying the DMN mainly included the cingulum, corpus callosum, corona radiata, superior longitudinal fasciculus, inferior fronto-occipital ...
  55. [55]
    Early Musical Training and White-Matter Plasticity in the Corpus ...
    Jan 16, 2013 · We found that early-trained musicians had greater connectivity in the posterior midbody/isthmus of the corpus callosum and that fractional ...
  56. [56]
    Dynamic causal modeling of neural responses to an orofacial ...
    The inter-regional axonal conduction delay is typically in the order of 10–20 ms (Friston et al., 2003). ... corpus callosum. Brain Res. 1990;536:97–104. doi: ...
  57. [57]
    Segregation of the Brain into Gray and White Matter - PubMed Central
    Gray matter contains neuron somata, synapses, and local wiring, such as dendrites and mostly nonmyelinated axons. White matter contains global, and in large ...
  58. [58]
    Astrocytes as master modulators of neural networks: Synaptic ...
    May 23, 2023 · Astrocytes modulate neural activity in both gray matter and white matter regions of the brain by adopting morphologies and functions suited ...
  59. [59]
    Histology, Astrocytes - StatPearls - NCBI Bookshelf - NIH
    They perform metabolic, structural, homeostatic, and neuroprotective tasks such as clearing excess neurotransmitters, stabilizing and regulating the blood-brain ...
  60. [60]
    A Structural MRI Study of Human Brain Development from Birth to 2 ...
    Nov 19, 2008 · In contrast, white matter growth was much slower. Cerebellum volume also increased substantially in the first year of life.
  61. [61]
    Age-related Volumetric Changes of Brain Gray and White Matter in ...
    In contrast, the volume of WM is lower in both infants and children compared with adults. Examining the lobar values, it appears that by childhood WM has nearly ...
  62. [62]
    White Matter Injury in Ischemic Stroke - PMC - PubMed Central - NIH
    It is well known that ischemic stroke can cause gray matter injury. However, stroke also elicits profound white matter injury, a risk factor for higher stroke ...
  63. [63]
    MRI: Imaging Living Tissue - NSF Impacts
    partially funded by NSF — developed the MRI imaging technique, culminating in the first full- ...
  64. [64]
    MRIs: The Diagnostic Tool that Changed MS
    First used in the late 1970s, and quickly gaining widespread use through the 1980s, the MRI was a game-changer in both the diagnosis and treatment of MS.
  65. [65]
    Evolution of diagnostic principles in multiple sclerosis and ...
    Jul 29, 2025 · The advent of MRI and the McDonald criteria​​ The advent of MRI in the 1980s revolutionized multiple sclerosis diagnosis. MRI allowed for the ...
  66. [66]
    T1 values (1.5 T) | Radiology Reference Article - Radiopaedia.org
    Jun 4, 2018 · T1 values are a few hundred milliseconds (ms) for most tissues examined. The following are approximate T1 values (ms) of several tissues for B 0 = 1.5 T.
  67. [67]
    B0-field dependence of MRI T1 relaxation in human brain
    In human brain, T1 is primarily affected (i.e. decreased) by the presence of iron and myelin; the latter has been exploited to generate strong gray-white matter ...
  68. [68]
    What are White Matter Hyperintensities Made of?
    Jun 23, 2015 · White matter hyperintensities (WMH) of presumed vascular origin, also referred to as leukoaraiosis, are a very common finding on brain magnetic resonance ...
  69. [69]
    Fluid attenuated inversion recovery | Radiology Reference Article
    Feb 16, 2013 · FLAIR is a special inversion recovery sequence with a long inversion time. This removes signal from the cerebrospinal fluid in the resulting images.<|separator|>
  70. [70]
    Fluid-Attenuated Inversion Recovery Magnetic Resonance Imaging ...
    FLAIR has been superior to T2-weighted images (T2WIs) for detecting MS brain lesions, including those in or adjacent to the cerebral cortical gray matter. In ...
  71. [71]
    Fluid-Attenuated Inversion Recovery (FLAIR) for Assessment of ...
    FLAIR and its variations are MRI sequences that produce both a strongly T2-weighted image and suppressed CSF signal. To accomplish these twin goals, a ...
  72. [72]
    Magnetic Resonance Imaging in Multiple Sclerosis
    Jan 8, 2020 · Like many diseases, MS was well known long before the introduction of MRI in the early 1980s. Although MS is fundamentally a clinical diagnosis ...<|control11|><|separator|>
  73. [73]
    DTI-based upper limit of voxel free water fraction - ScienceDirect
    However, at the current practical voxel resolution of 1–3 mm in each ... This step creates maps with probabilities of gray matter, white matter and CSF.2. Theory · 2.1. Two-Compartment Model · 4. Results
  74. [74]
    Diffusion Tensor Imaging of Cerebral White Matter: A Pictorial ...
    Mar 1, 2004 · We review the normal anatomy of the white matter (WM) tracts as they appear on directional diffusion tensor imaging (DTI) color maps.
  75. [75]
    MR diffusion tensor spectroscopy and imaging - PubMed
    This paper describes a new NMR imaging modality--MR diffusion tensor imaging. It consists of estimating an effective diffusion tensor, Deff, within a voxel.
  76. [76]
    Diffusion Tensor Imaging - StatPearls - NCBI Bookshelf
    Nov 12, 2023 · Diffusion tensor imaging is an advanced magnetic resonance imaging modality that uses the Brownian motion of water molecules to provide data for images.
  77. [77]
    Potential Pitfalls of Using Fractional Anisotropy, Axial Diffusivity, and ...
    Jan 13, 2022 · Fractional anisotropy (FA), axial diffusivity (AD), and radial diffusivity (RD) are commonly used as MRI biomarkers of white matter microstructure.
  78. [78]
    Q‐ball imaging - Tuch - 2004 - Magnetic Resonance in Medicine
    Nov 23, 2004 · DTI has a significant limitation, however, in that the technique can only resolve a single fiber direction within each voxel (7, 8). This ...
  79. [79]
    Q-ball imaging - PubMed - NIH
    For example, DTI cannot resolve fibers crossing, bending, or twisting within an individual voxel. Intravoxel fiber crossing can be resolved using q-space ...Missing: limitations | Show results with:limitations
  80. [80]
    High Angular Resolution Diffusion Imaging - Radiology Key
    Nov 20, 2016 · The severe limitations of using the diffusion tensor model for fiber tractography have consistently been reported in the neurosurgical ...Using Hardi To Resolve... · Spherical Deconvolution · Using Hardi To Characterize...
  81. [81]
    Mean Diffusivity - an overview | ScienceDirect Topics
    Mean diffusivity is defined as a measure of the overall diffusion of water molecules within a tissue, indicating how freely they can move; it varies with ...
  82. [82]
    Measuring Corpus Callosum FA: Mid-Sagittal vs. Axial Imaging
    The mean FA values with axial DTI were 0.74 ± 0.04, 0.67 ± 0.03, 0.70 ± 0.05, 0.69 ± 0.06 and 0.78 ± 0.03, respectively. The FA values of all the regions except ...
  83. [83]
    White matter fractional anisotropy is related to processing speed in ...
    Decreases in FA have been observed in association with aging [6], especially in the frontal lobe [7]. Moreover, FA decrease has been related with changes in ...
  84. [84]
    Age Differences in Speed of Processing are Partially Mediated ... - NIH
    The objective of the present study was to investigate in healthy adults, the mediating effects of age differences in white matter integrity on the relationship ...
  85. [85]
    Age-related decline in white matter tract integrity and cognitive performance: A DTI tractography and structural equation modeling study - PMC
    Summary of each segment:
  86. [86]
    Cognitive reserve, cortical plasticity and resistance to Alzheimer's ...
    Mar 1, 2012 · Another early diffusion tensor imaging study identified reduced white matter integrity in the splenium of the corpus callosum, superior ...Structural Changes · White Matter And Cognitive... · Cellular Mechanisms In The...
  87. [87]
    Cognitive reserve moderates the relationship between ... - NIH
    This study examined CR as a potential moderator of cognitive performance and brain integrity as defined by FBL.
  88. [88]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC2945445/
  89. [89]
    Predicting effective connectivity from resting‐state networks in ...
    Jan 10, 2013 · The task-fMRI session included an attention and a memory task, which followed the resting-state scan. In this study, we will focus on the ...Fmri Paradigms · Task Fmri · Fmri Data Analysis<|separator|>
  90. [90]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC7083104/
  91. [91]
    Longitudinal Development of Human Brain Wiring Continues from ...
    Jul 27, 2011 · DTI has shown increasing fractional anisotropy (FA), a parameter linked to axon packing and myelination (Beaulieu, 2002), and decreasing mean ...
  92. [92]
    Targeting Immune Imbalance in Multiple Sclerosis - ScienceDirect.com
    Oct 16, 2025 · Affecting more than 2.8 million individuals worldwide, MS remains a leading cause of non-traumatic neurological disability in young adults.
  93. [93]
    Multiple sclerosis: 2023 update - PMC - PubMed Central
    Mar 9, 2023 · Multiple sclerosis (MS) is the most frequent inflammatory and demyelinating disease of the Central Nervous System (CNS).Missing: global | Show results with:global
  94. [94]
    Leukodystrophy | National Institute of Neurological Disorders and ...
    Apr 1, 2025 · Leukodystrophy refers to genetic diseases that predominantly affect the white matter of the central nervous system (CNS).
  95. [95]
    ALD - Adrenoleukodystrophy - Alex - The Leukodystrophy Charity
    Adrenoleukodystrophy is a rare genetic disorder caused by mutations in the ABCD1 gene, resulting in the build-up of very long chain fatty acids (VLCFA).Newly Diagnosed? · How Is Ald Inherited? · Current Ald Research
  96. [96]
    Small-vessel disease in the brain - ScienceDirect.com
    CSVD is responsible for approximately 25 % of ischemic strokes and 45 % of vascular dementia [4], [8]. The prevalence of white matter disease increases with age ...
  97. [97]
    CNS small vessel disease: A clinical review - PMC - PubMed Central
    CNS small vessel disease (CSVD) causes 25% of strokes and contributes to 45% of dementia cases. Prevalence increases with age, affecting about 5% of people aged ...
  98. [98]
    Diffuse Axonal Injury - StatPearls - NCBI Bookshelf - NIH
    Jul 7, 2025 · In general, DAI is a form of TBI that is usually severe.[11] Therefore, the implementation of an advanced trauma life support protocol is a ...Introduction · Evaluation · Treatment / Management · Differential Diagnosis
  99. [99]
    Outcome of diffuse axonal injury in moderate and severe traumatic ...
    Aug 3, 2021 · At 3 months, mortality rate was 25.6% and satisfactory outcome observed in 48.1% of patients. The highest mortality was observed in the Grade ...
  100. [100]
    PLP1-Related Disorders - GeneReviews® - NCBI Bookshelf - NIH
    Jun 12, 2025 · PLP1-related disorders of central nervous system myelin formation include a range of phenotypes from Pelizaeus-Merzbacher disease (PMD) to spastic paraplegia 2 ...Diagnosis · Clinical Characteristics · Differential Diagnosis · Genetic Counseling
  101. [101]
    Pelizaeus-Merzbacher disease - Genetics - MedlinePlus
    Feb 1, 2018 · All of these PLP1 gene mutations lead to hypomyelination, nerve fiber damage, and impairment of nervous system function, resulting in the ...
  102. [102]
    Normal myelination | Radiology Reference Article | Radiopaedia.org
    Jun 9, 2025 · The first myelination is seen as early as the 16 th week of gestation, in the column of Burdach, but only really takes off from the 24 th week.
  103. [103]
    MR imaging. Part I. Gray-white matter differentiation and myelination
    Myelination progresses cephalad from the brain stem at 29 weeks to reach the centrum semiovale by 42 weeks. Delayed myelination, defined as the absence of ...Missing: prenatal timeline
  104. [104]
    Assessment of normal myelination in infants and young children ...
    Feb 28, 2023 · White matter myelination is an essential process of CNS maturation. It is believed that this process begins in the fifth fetal month and ...
  105. [105]
    The Development of Brain White Matter Microstructure - PMC
    Processes including myelination and synaptogenesis occur rapidly across the first 2–3 years of life, and ongoing brain remodeling continues into young adulthood ...Missing: timeline | Show results with:timeline
  106. [106]
    Neuroimaging Studies of Normal Brain Development and Their ...
    Alternatively and perhaps more plausibly, changes in gray matter volumes with age may be caused by extensive synaptic pruning, consistent with the decreases in ...
  107. [107]
    White Matter Development During Childhood and Adolescence
    This study demonstrates that during childhood and adolescence, white matter anisotropy changes in brain regions that are important for attention, motor skills, ...
  108. [108]
    Lifespan maturation and degeneration of human brain white matter
    Sep 17, 2014 · It has been suggested that in brain tissue, R1 is principally sensitive to the volume fraction of tissue (macromolecules and lipid membranes) ...
  109. [109]
    Aging of Cerebral White Matter - PMC - PubMed Central - NIH
    Thus, age-related changes in WM may contribute to the functional decline observed in the elderly. In addition, aged WM becomes more susceptible to neurological ...
  110. [110]
    Cerebral White Matter Myelination and Relations to Age, Gender ...
    White matter makes up about fifty percent of the human brain. Maturation of white matter accompanies biological development and undergoes the most dramatic ...
  111. [111]
    HCP-Young Adult 2025 Release - Human Connectome Project
    Aug 11, 2025 · Addition of Reclean (improvements to spatial ICA) and Temporal ICA pipelines and processed output for all 3T and 7T fMRI data. Due to these ...Missing: extensions 2024 MRI white matter variability<|separator|>
  112. [112]
    High resolution whole brain diffusion imaging at 7 T for the Human ...
    We present recent developments and optimizations in 7 T image acquisitions for the HCP that allow us to efficiently obtain high-quality, high-resolution whole ...Missing: extensions 2024
  113. [113]
    Tractometry of the Human Connectome Project: resources and insights
    Jun 11, 2024 · Tractometry analysis of dMRI data focuses on the physical properties of major white matter pathways. It uses computational tractography and ...
  114. [114]
    MWF of the corpus callosum is a robust measure of remyelination
    May 8, 2023 · We analyzed myelin water fraction imaging from ReBUILD, a double-blind, randomized placebo-controlled (delayed treatment) remyelination trial, ...Missing: fractional | Show results with:fractional
  115. [115]
    Clemastine fumarate as a remyelinating therapy for multiple ...
    Dec 2, 2017 · This is the first randomised controlled trial to document efficacy of a remyelinating drug for the treatment of chronic demyelinating injury in multiple ...Missing: fractional anisotropy improvement percentage
  116. [116]
    Trial results suggest drug combo could boost myelin repair in ...
    Sep 26, 2025 · Early results from the CCMR2 trial were announced today. They suggest a combination of two existing drugs may be able to boost myelin repair ...
  117. [117]
    Artificial intelligence in corticospinal tract segmentation using ... - NIH
    Jan 31, 2025 · TractSeg is a tractography tool based on a pretrained convolutional neural network model that automatically segments up to 72 predefined white ...Missing: papers | Show results with:papers
  118. [118]
    A systematic review of automated methods to perform white matter ...
    These methods are fast and utilize deep learning or machine learning techniques like convolutional neural networks (CNNs) to improve segmentation accuracy.
  119. [119]
    Diversity, Functional Complexity, and Translational Potential of Glial ...
    Sep 18, 2025 · This review synthesizes the most recent advances in glial biology, highlighting novel molecular mechanisms, cutting-edge imaging methodologies, ...