White matter disease - Imaging findings and differential diagnosis

Orlando Ortiz, MD, MBA, FACR, Amanjit S. Baadh, MD, Winthrop-University Hospital, Mineola, NY, and Elizabeth Lustrin, MD, NRAD Medical Associates, Lake Success, NY

Summary:   Cross-sectional imaging is transforming the radiologic and clinical assessment of the small bowel and care of patients with small-bowel diseases. Computed tomography (CT) and magnetic resonance imaging (MRI) techniques, such as enterography and enteroclysis, permit excellent visualization of the small-bowel wall and lumen, helping radiologists detect inflammation, tumors, and even vascular lesions. Imaging protocols, however, should be selected based on clinical suspicion and adapted to individual patients. The authors explore the many ways cross-sectional imaging is transforming the assessment of small-bowel diseases.

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 Dr. Ortiz is the Chairman of the Department of Radiology and Dr. Baadh is a Resident, in the Department of Radiology, Winthrop-University Hospital, Mineola, NY; and Dr. Lustrin is a Diagnostic Radiologist at NRAD Medical Associates, Lake Success, NY.

White matter (WM) consists of myelinated axons that arise from either the neuronal cell bodies in the cerebral cortex or the nuclei of deep gray matter structures. In the brain, most of these axons are located centrally, whereas in the spinal cord, they are positioned peripherally.Any WM injury regardless of mechanism is associated with inflammation and/or edema. The damaged axons lose their myelin and subsequent gliosis results in volume loss. The term “white matter disease” is an imaging reference to magnetic resonance imaging (MRI) or computed tomography (CT) findings. These imaging findings reflect a variety of pathologic processes that can be acute, subacute, or chronic in nature and have concomitantly affected the WM of the brain and/or spinal cord.

Significance of white matter disease

The appearance of white matter disease (WMD) on imaging studies is often nonspecific. However, the imaging appearance of WMDon cross-sectional imaging may aid in classification and diagnosis. Furthermore, the presence of WMD on an imaging study may initiate additional imaging and clinical investigation so that a working diagnosis can be established and appropriate medical treatment initiated.The clinical presentation in patients with WMD, in turn, is quite variable. Patients can be affected at any age from childhood to adulthood.Patients can present with significant acute neurologic deficits, gradual neurologic deterioration, or no symptoms at all. Disease entities may result in monophasic illness or may manifest in progressive or relapsing fashion. Nevertheless, it is some sort of neurologic symptom or sign that prompts imaging of the central nervous system with subsequent identification of a WM abnormality within the brain and/or spinal cord.These abnormalities are most elegantly depicted on MRI studies of these structures. Occasionally, however, in situations where the patient’s medical condition precludes MRI, WM lesions may indeed be seen, though with less sensitivity, on CT studies of the brain (Figure 1). OnCT, multiple sclerosis (MS) lesions present as small foci of decreased attenuation, which may demonstrate enhancement following contrast administration.

Classification of white matter disease

The differential diagnosis of WMD is extensive (Table 1). WMD traditionally has been divided into demyelinating and dysmyelinating processes. In the former category, normally formed myelinated axons are adversely affected with resultant destruction and loss of myelin. Dysmyelinating processes reflect the sequelae of enzymatic deficiencies that lead to abnormally myelinated axons and subsequent breakdown of the abnormal myelin. An example of a few entities in this latter category include adrenoleukodystrophy, metachromatic leukodystrophy, Canavan’s disease, Alexander’s disease, Krabbe’s disease, and sudanophilic leukodystrophy. In general, many of these metabolic disorders are most frequently encountered in children and young adults. This article will focus on demyelinating conditions that manifest as WMD on neuroimaging studies of the craniospinal axis, as these entities overall are more common and likely to be encountered in both inpatient and outpatient radiology practice settings. An emphasis will be placed on clinical and imaging findings that distinguish these entities, especially as they compare to multiple sclerosis.

Multiple sclerosis

Multiple sclerosis (MS) is an inflammatory demyelinating disease, in which there is autoimmune mediated injury to myelin sheaths surrounding axons in the brain and spinal cord.1 Recent studies have proposed chronic cerebrospinal venous insufficiency as a potential etiologic factor. These studies have used color Doppler ultrasound to demonstrate obstructive anomalies of extracranial veins, such as the internal jugular and azygous along with venographic evidence of significant stenoses in venous structures adjacent to the central nervous system.2 Additional studies from other centers are forthcoming to further assess this venous insufficiency model. MS is included as part of the working diagnosis in a large and diverse set of neurologic presentations, particularly in young adults in their 2nd through 4th decades of life. Twenty percent of patients are > 40-years-old and 10% of patients are < 20-years-old. An age of onset > 55-years-old is rare and in this situation the possibility of an alternative diagnosis should be considered.3 The estimated prevalence of MS is between 2 and 150 cases per 100,000 people, depending on racial/ethnic background and geography.4 MS is defined as an idiopathic inflammatory demyelinating disease of the central nervous system characterized by the presence of focal plaques of demyelination with reactive scarring in the cerebral and spinal cord WM (Figure 2).5 Cerebrospinal fluid abnormalities, such as the presence of oligoclonal bands, are not always present and are not necessarily specific to the diagnosis. The clinical presentation and course in patients with MS is variable. To better characterize a clinical course that includes clinical exacerbations or relapses, periods of quiescence, and/or neurologic progression, a consensus statement groups the disease course into 4 major categories:

  1. Relapsing/remitting MS,
  2. Progressive relapsing MS,
  3. Secondary progressive MS, and
  4. Primary progressive MS.6

This classification is significant in that, in the United States, medical treatments are presently approved by the Food and Drug Administration only for relapsing/remitting MS.

MRI with conventional and advanced imaging techniques is the gold standard for diagnosing and monitoring patients with suspected or clinically proven MS. MRI is used to identify other WMD processes that may clinically mimic MS. MRI findings are also used to provide prognostic information. MRI is used not only to monitor a patient’s response to medical therapy but also to assess for any complications that might be caused by a treatment. All major clinical research trials that are attempting to assess possible treatments for MS utilize MRI as a fundamental part of the research design to report, quantify, and monitor treatment outcomes.

MS lesions are often located in a perivenular distribution.7 They tend to have a predilection for areas of high perivenular density, such as the periventricular and subcortical WM, the optic nerves and chiasm, the cerebral and cerebellar peduncles, and the lateral columns of the spinal cord.5 MRI is sensitive for detecting WM lesions in the brain and spinal cord (Figure 3). Proton-density, T2-weighted and fluid-attenuated inversion recovery (FLAIR) sequences are ideal for detecting and characterizing MS plaques.8 On MRI, the typical MS lesion presents as an ovoid or flame-shaped, hyperintense lesion on the aforementioned sequences. Periventricular WM lesions often have a perpendicular orientation relative to the margins of the lateral ventricles (Figure 4). The lesions are of variable size and often > 3 mm in diameter. These lesions can manifest a dynamic imaging appearance with respect to signal intensity and morphology over time, regardless of treatment status (Figure 5).9 The MRI signal changes reflect the presence of inflammatory cells and foci of demyelination as well as foci of remyelination.5 Lesions may also show a thin,less-T2-hyperintense rim along their periphery (Figure 6). Rarely, as seen in patients with Balo’s concentric sclerosis, prominent alternating bands of hyperintensity and hypointensity may be observed in larger lesions. Small lesions do not have mass effect, whereas large lesions can exert focal mass effect, such as in young patients with Schilder’s type MS (Figure 7).10,11 On T1-weighted images, MS lesions are either hypointense or isointense to WM. WM lesions that show significant hypointensity are referred to as T1 “black holes;” their neuropathologic substrate consists of foci of demyelination and axonal loss (Figure 3).12

MS lesions can and do occur within gray matter structures, such as the cerebral cortex, reflecting cortical demyelination, but these are not readily identified with conventional imaging techniques. Contrast-enhanced MRI is useful in the evaluation of patients with MS. Supposedly“active” MS lesions that are newly formed and have a prominent inflammatory and demyelinating component may undergo sufficient blood-brain barrier disruption as to show enhancement with gadolinium contrast agents (Figures 8-11). This contrast enhancement, however, like the underlying lesion, is dynamic in that it is transient. Re-activated MS lesions may also show contrast enhancement. The absence of contrast enhancement should not mistakenly be equated with lesion quiescence or absence of disease activity. In this case, the extent of inflammation, demyelination, and underlying tissue injury might be below a threshold that can be detected with current imaging approaches.13 Contrast enhancement occurs less frequently in the progressive forms of MS. A radiologically isolated syndrome has been described in patients who present with incidental imaging findings that are suggestive of possible MS. This condition is referred to as “pre-MS” because up to 33% of these patients convert to a clinically isolated syndrome, or so called first attack, within 5 years. These patients may have abnormal visual evoked responses, spinal cord involvement, and contrast-enhancing cerebral white matter plaques.14 The McDonald diagnostic criteria for MS were recently revised in 2010 to allow for a more prompt diagnosis of MS in patients who have experienced a clinically isolated syndrome.15 For example, a clinical presentation of 2 or more episodes of an inflammatory neurologic insult or attack, combined with MRI evidence of 2 or more brain lesions, would suffice to make a clinical diagnosis of MS based on the modified McDonald criteria. In instances of either one prior attack or one brain lesion detected by MRI, then additional data, such as evidence of dissemination of lesions in space or time within the brain and/or spinal cord, are required to confirm a diagnosis of MS.15

The application of advanced MRI techniques in evaluating MS is still under investigation. These techniques include magnetization transfer(MT), diffusion weighted and diffusion tensor imaging (DWI and DTI), susceptibility-weighted imaging, functional MRI (fMRI), and MR spectroscopy (MRS) (Figure 3). For example, some studies have shown the MT changes precede the subsequent development of enhancing MS lesions in what are initially areas of normal-appearing white matter.5 Cerebral atrophy is a significant imaging finding that occurs over time inpatients with MS. Patients with MS show an average annual cerebral volume loss of 0.6% to 0.8% per year compared to healthy controls (0.3%per year) as shown on volumetric MR studies.13 Initial reports have shown increased levels of iron accumulation within the deep gray matter nuclei, such as the basal ganglia, of patients with MS compared to normal control subjects (Figure 12).16

The other key structures that can be affected by demyelination include the optic nerves and spinal cord. Indeed, optic neuritis can be the initial presentation as a clinically isolated syndrome in patients who subsequently are diagnosed with MS (Figure 13). Patients present with monocular visual loss and focal areas of T2 signal change and optic nerve enlargement. Focal enhancement of the lesion after contrast agentadministration is best demonstrated with fat-suppressed, T1-weighted imaging and, when combined with the clinical presentation, often distinguishes optic neuritis from optic nerve-sheath neoplasms. Spinal cord involvement in MS often occurs with brain involvement, but it can occur as an isolated finding.17 The MS spinal cord lesion is located within the periphery of the spinal cord and occupies less than half of the cross-sectional area of the spinal cord (Figure 14). The lesions are focal and usually do not extend for more than 1 or 2 vertebral body segments. MS spinal cord lesions are isointense to hypointense on T1-weighted images, hyperintense on T2, and show varying amounts and types of enhancement after contrast administration. Spinal cord atrophy may also be observed, especially in patients with chronic disease.

Autoimmune/idiopathic

Acute disseminated encephalomyelitis (ADEM)

Acute disseminated encephalomyelitis (ADEM) is an autoimmune disorder that affects the white matter in the brain and spinal cord.18 This is often a monophasic WMD process that occurs within a few weeks of a prior viral or bacterial infection or vaccination. ADEM has an estimated incidence of 0.8/100,000 population per year. Cerebrospinal fluid analysis shows increased albumin and proteins with absent oligoclonal bands. Oligoclonal bands are rarely present in the cerebrospinal fluid and when observed, are transient. Gray matter structures,such as the basal ganglia or cortex, may also be affected.19 Children are most frequently affected, but ADEM may also be observed in adults.MRI shows either multiple small or large flocculent T2 or FLAIR hyperintense lesions within the subcortical WM (Figure 15). These lesions may show patchy or partial peripheral enhancement. Unlike MS, gray matter involvement is commonly seen with ADEM. ADEM, however, tends to spare the corpus callosum and does not show the perivenular distribution seen with MS. Spinal cord involvement in ADEM is often patchy, but it can be quite extensive. ADEM is a self-limited process in the majority of cases and follow-up imaging will show lesion stability or resolution in those patients who go on to recover. ADEM, however, may cause permanent neurologic deficits. Current treatments for ADEM include anti-inflammatory or immunosuppressive medications. ADEM should be suspected in a child that develops neurologic symptoms and WMD shortly after an infection or vaccination.

Subacute sclerosing panencephalitis (SSPE)

Subacute sclerosing panencephalitis (SSPE) is a rare, measles-mediated encephalitis associated with progressive neurologic deterioration and death. This disease has a subacute course and is often seen in children with prior measles infection. SSPE is rare in adults. Cerebrospinal fluid analysis will show elevated antibody titers against measles and elevated gamma globulin. The MR imaging appearance is one of asymmetric, T2-hyperintense, nonenhancing lesions within the periventricular and subcortical WM of the cerebral hemispheres (Figure 16).Corpus callosum and deep gray matter involvement may be observed. Cerebral swelling may be seen. Cerebral volume loss with reduced gray matter volume may be observed in the frontal and temporal cortex.20 MRS may show normal to increased choline and myoinositol and decreased n-acetyl aspartase.21

Neuromyelitis optica

Neuromyelitis optica, or Devic’s disease, is a unique idiopathic WM inflammatory process in which there is an auto-antibody response against astrocytic aquaporin 4. A highly specific serum marker, NMO-IgG, is identified in 60% of patients. Both optic nerve and spinal cord involvement are observed in patients with Devic’s disease (Figure 17). The spinal cord lesions have a prominent longitudinal extent and may also involve the central-cord gray matter. T2-weighted images show expansile hyperintense signal within at least 3 vertebral segments of the spinal cord and increased T2 signal within the affected optic nerve. Both optic nerve and spinal cord lesions tend to enhance in the acute phase of the illness. The cerebral WM is spared or may show the presence of nonspecific WM lesions, a key differentiating feature from multiple sclerosis. The clinical presentation is monophasic and rapidly disabling, with a subsequent relapsing disease process that is associated with a poor prognosis. Rituximabtherapy, a treatment employing a monoclonal antibody against CD20 B lymphocytes, has been shown to potentially decrease the frequency of relapses as well as the associated disability.22 Acute transverse myelitis (ATM) is an idiopathic inflammatory disorder that affects the spinal cord in adolescents and young adults.23 Patients may have experienced a prior infectious event prior to presenting with ATM. Furthermore, MS is eventually diagnosed in a small percentage of patients with ATM. Patients typically present with motor deficits, autonomic dysfunction, and a sensory disturbances. MR imaging shows involvement of > 2/3 of the cross-sectional area of the spinal cord that extends for a least 3 or more vertebral segments. An extensive T2-hyperintense lesion, which may be associated with a cord expansion that shows peripheral contrast enhancement, is the most common imaging finding (Figure 18). Advanced imaging techniques with DTI show decreased fractional anisotropy values in both the affected spinal cord segment and in the adjacent distal normal-appearing spinal cord in patients with ATM.24 With respect to spinal-cord imaging findings, there is overlap between ATM and NMO, and MS isolated to the spinal cord.

Infection

Lyme neuroborreliosis

Lyme neuroborreliosis is a multisystem infectious disease that affects the cerebral WM, cranial nerves, the cauda equina, eye,joints, heart, and skin. The causative agent is a spirochete, Borrelia burgdorferi in the United States and Borrelia garinnii and afzelii in Europe that is transmitted by a tick bite. There is usually a seasonal pattern to exposure to these tick bites during the spring and summer in endemic areas. An erythema migrans rash with a target-like appearance, arthritis, and carditis are common clinical presentations. MRI abnormalities in patients with Lyme disease are rare.25 When present, MRI shows small nonspecific, T2-hyperintense periventricular WM lesions that variably enhance (Figure 19). Unlike MS, cranial nerve, cauda equine, or meningeal enhancement may be observed in Lyme disease.25,26 Early diagnosis is important as prompt treatment may reduce or prevent disease progression.

Progressive multifocal leukoencephalopathy (PML)

Progressive multifocal leukoencephalopathy (PML) is a demyelinating process that results from infection with the John Cunningham (JC) virus of the myelin-producing oligodendrocytes in patients that are immunosuppressed. Immunocompromised patients that are affected include patients with acquired immunodeficiency syndrome, organ transplant patients on immunosuppression therapy, patients receiving chemotherapy, steroid therapy, or treatment for multiple sclerosis. Patients with PML present with progressive neurologic deterioration. The MRI findings include one or more variable sized confluent, yet asymmetric, WM T2-signal abnormalities that involve the subcortical WM, including the U-fibers, and extend to the periventricular WM (Figure 20). Corpus callosum involvement may be observed. PML usually shows no contrast enhancement (Figure 21). When large confluent areas of WM involvement are seen, the absence of mass effect is notable. In patients who are infected with the human immunodeficiency virus (HIV), the clinical and imaging appearance of PML may simulate that of HIV encephalitis. In HIV encephalopathy, the white matter T2-signal abnormality may show a less discrete or a fuzzy appearance with a diffuse periventricular predisposition and relative sparing of the subcortical U fibers. Cerebral atrophy is common in both PMLand HIV encephalitis. Advanced imaging techniques, such as MT, show a decreased MT relaxation in PML compared to HIV encephalitis.As with PML, mass effect and contrast enhancement are often lacking. Contrast enhancement in HIV-positive patients receiving antiretroviral therapy may be due to the immune reconstitution inflammatory syndrome, which is attributed to an aberrant immune response and is associated with worsening of a pre-existing disease.27

Vascular

Central nervous system vasculitis

Central nervous system vasculitis may present with subcortical WM ischemic lesions in children and adults (Figure 22).28 The additional involvement of deep gray matter structures such as the basal ganglia or cortical gray matter may help to distinguish vasculitis from otherWMD processes. Furthermore, acute lesions will show restricted diffusion on DWI sequences. Central nervous system vasculitis may require catheter angiography to show areas of vascular contour irregularities or biopsy to confirm the diagnosis. Vasculitis may also be associated with other systemic vasculitides such as systemic lupus erythematosis and polyarteritis nodosa (Figure 23).

CADASIL

Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is a progressive, hereditary, small vessel angiopathy that affects young adults. The autosomal dominant NOTCH3 gene is located on chromosome 19.29 Patients present with recurrent symptoms due to transient ischemic attacks or subcortical stroke. As with vasculitis, the WMD involvement is that of T2 hyperintensity with restricted diffusion in acute ischemic lesions. Foci of microscopic hemorrhage manifest as areas of hypointensity on gradient echo and susceptibility-weighted images.29 The WMD in CADASIL may be present prior to symptom onset. The anterior temporal lobe WM and corpus callosum may also be affected, a finding that distinguishes CADASIL from subcortical arteriosclerotic encephalopathy (Figure 24). The latter condition is associated with hypertension. Unlike other vasculitides, gray matter involvement is rare and catheter angiography does not show vascular contour abnormalities. Perfusion imaging will show decreased cerebral blood flow and volume in the areas of signal abnormality. In elderly patients with extensive chronic ischemic WMD and lacunes, it may be difficult to distinguish from inflammatory conditions that affect the WM. Clinical parameters, such as patient age and a history of hypertension, help to identify these patients. Additionally, the absence of corpus callosum involvement, perivenular inflammatory change and contrast enhancement, and the presence of deep gray matter lacunar infarcts are more consistent with a diagnosis of chronic white matter ischemic change in the elderly.

Susac’s syndrome

Susac’s syndrome is another microangiopathy that can present with WMD in adults in their 3rd to 5th decades of life.30 In this condition, T2 hyperintense WM lesions are characteristically present within the body of the corpus callosum in addition to the subcortical WM, brainstem,and deep gray matter structures. Patients with Susac’s syndrome present with a clinical triad of encephalopathy, bilateral hearing loss and retinal artery branch occlusions. Other vascular etiologies that may also involve the cerebral WM include hypoxic encephalopathy and posterior reversible encephalopathy syndrome (PRES). The clinical presentations in these patients and the imaging findings, which may involve the gray matter structures in hypoxic encephalopathy and the parieto-occipital lobes in PRES, readily distinguishing these entities from more typicalWMD pathologic conditions (Figures 25, 26). Hemorrhagic foci ranging from petechial hemorrhages to sulcal hemorrhages to hematoma maybe seen in up to 15% of patients with PRES, particularly those who have received bone marrow transplants or are on undergoing systemic anticoagulation.31

Acquired conditions

Radiation necrosis

Radiation therapy may be associated with WMD, as oligodendrocytes are very sensitive to radiation. WM injury may be seen at any point in time following radiation treatment to the brain for primary or metastatic tumors.32 The extent of WM damage may vary from edema to necrosis. Radiation necrosis may be focal or diffuse (Figure 27). The subcortical U fibers are spared while the periventricular WM is diffusely affected. In diffuse necrotizing leukoencephalopathy extensive areas of WM injury are present (Figure 28). This may also be seen in patients receiving chemotherapy. Increased T2-signal abnormality is present in areas of WM edema and/or necrosis. T1-hypointense signal is seen in areas of radiation necrosis. Peripheral, irregular or ring like contrast enhancement may be indistinguishable from underlying neoplasm.Advanced imaging techniques such as MRS show decreased NAA and increased lactate and lipid peaks or decreased cerebral blood volume with perfusion imaging. Radiation necrosis is hypometabolic on positron emission tomography. Radiation necrosis should be considered in the differential diagnosis of a new enhancing WM lesion remote to the original treated lesion or if there is interval development of lesion enhancement in what was initially a non-enhancing tumor, or if there is corpus callosum or periventricular WM enhancement that caps the ventricles.

Osmotic demyelination syndrome

Osmotic demyelination syndrome is a metabolic disorder that results from abrupt correction of serum sodium osmolality.33 This rare condition is observed in chronic alcoholic patients, but may also be seen in patients with liver failure, liver transplant patients being treated with cyclosporine, burn victims and patients with prolonged heavy use of diuretics. Rapid correction of hyponatremia in increments > 12 mmol/L/d results in destruction of the myelin sheath. Affected patients present with encephalopathy, spastic quadriplegia and/or pseudobulbar palsy. WMD in this condition is characterized by nonenhancing T2-signal hyperintensity within the central pons (Figure 29). Extrapontine sites of potential involvement within the brain include the basal ganglia, capsular region, hippocampi, lateral geniculate bodies and peripheral cortex. Lesions may be either isointense or hypointense on T1-weighted sequences. Anecdotal reports have shown restricted diffusion on DWI images in areas of acute demyelination. Patients are treated with supportive care with a variable prognosis, but few patients avoid permanent neurologic damage.

Marchiafava-Bignami

Marchiafava-Bignami is another rare toxic metabolic disorder also seen in chronic alcoholics and which primarily results in demyelination of the corpus callosum (Figure 30). A vitamin B complex deficiency is thought to be the cause of progressive laminar necrosis in the corpus callosum.34 WMD may also occur in the anterior and posterior commissures, the periventricular WM and the cerebellar peduncles. There is relative sparing of the subcortical U fibers. Patients present with alteration of mental status, seizures or cognitive deficits. T1-weighted images show foci of decreased signal intensity within the affected WM. These areas are hyperintense on T2-weighted and FLAIR images. The treatment for this disease is limited and includes supportive therapy with vitamin B complex replacement therapy.

Subacute combined degeneration (SCD)

Another condition that is associated with a vitamin B deficiency, in this case B12, is subacute combined degeneration (SCD). Numerous etiologies may result in B12 deficiency including malnutrition, prior surgeries of the gastrointestinal tract such as ileal resection, deficiency of intrinsic factor, malabsorption syndromes, Crohn’s disease, nitrous oxide abuse, and HIV infection. In contradistinction to Marchiafava-Bignami disease,SCD affects the posterior columns of the spinal cord.35 The imaging findings consist of an inverted “V” shaped focus of T2 hyperintensity on axial images within the dorsal aspect of the spinal cord with lateral greater than medial dorsal column involvement (Figure 31). A long continuous band of T2 signal abnormality is seen within the cervical and thoracic portions of the spinal cord on sagittal images. The lesion may be associated with spinal cord enlargement and mild enhancement may be observed. Patients with SCD present with the insidious onset of sensory disturbances, including paresthesias and abnormal proprioception with ataxia. The clinical presentation and the lack of cerebral WMD distinguish this entity fromMS, NMO, ATM and ADEM.

Diffuse axonal injury

Diffuse axonal injury is another condition that may manifest with focal WM lesions on imaging. These lesions reflect the sequelae of shearing injury and are often found within the subcortical WM, the corpus callosum and the brainstem. A clinical history of significant head trauma along with the identification of hemorrhagic foci on gradient-echo or susceptibility-weighted images helps to confirm this diagnosis.

Conclusion

WMD comprises a variety of disorders that demonstrate overlap in MRI findings. MS is a common WMD process that affects young adults.MS is a dynamic disease process with respect to both clinical and imaging features. A better understanding of demyelinating WMD entities with respect to their more common clinical and imaging manifestations can assist in narrowing the differential diagnosis and potentially suggesting the diagnosis in certain clinical scenarios.

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Tables & Figures

  • Figure 1. CT findings in 30-year-old woman with MS. Contrast-enhanced axial CT image of the brain in a patient with MS shows ring enhancing (small arrow) and nodular enhancing (large arrow) lesions within the subcortical and periventricular WM. Nonenhancing low-attenuation foci are seen within the WM. Cerebral atrophy is also present in this patient, who initially presented to the emergency room with alteration in mental status.
    Figure 1.
  • Figure 2. Low-power photomicrograph (Luxol fast blue with a PAS counter stain) from biopsy of patient subsequently proven to have MS shows perivenular foci of demyelination (arrows).
    Figure 2.
  • Figure 3A. A 68-year-old woman with MS. T1-weighted axial MR image (A) shows a small ovoid focus of hypointensity within the WM (arrowhead), a moderate-sized hypointense WM lesion (small arrow) and a very hypointense lesion, or black hole, in the right frontal subcortical WM (large arrow). (B) The T2-weighted axial MR image shows corresponding hyperintensity in these same locations (arrows and arrowheads). (C) A sagittal FLAIR image shows a somewhat perpendicular orientation (arrows) to the periventricular WM lesions. (D) FLAIR axial image with DTI overlay shows paucity of WM tracts in the area of right frontal encephalomalacia (arrow).
    Figure 3A.
  • Figure 3B.
    Figure 3B.
  • Figure 3C.
    Figure 3C.
  • Figure 3D.
    Figure 3D.
  • Figure 4. FLAIR axial image in a patient with MS shows characteristic perpendicular orientation of the periventricular WM lesions (arrows). A lesion is also present within the splenium of the corpus callosum (arrowhead).
    Figure 4.
  • Figure 5A. A 46-year-old male with MS. T2-weighted axial MR images obtained 2 years apart show an ovoid hyperintense lesion (arrow) within the left middle cerebellar peduncle (A) that was not present on the prior study (B). A midline flame-shaped hyperintense pontine lesion (C, arrow) on the prior study had resolved on follow-up (not shown).
    Figure 5A.
  • Figure 5B.
    Figure 5B.
  • Figure 5C.
    Figure 5C.
  • Figure 6. 37-year-old man with upper- and lower-extremity numbness. T2-weighted axial image shows oval-shaped hyperintense right frontal WM lesion (arrow) surrounded by a less hyperintense rim.
    Figure 6.
  • Figure 7A. 15-year-old female with MS. (A) T2-weighted axial MR image shows a large hyperintense lesion within the right parietal lobe that is associated with extensive edema (arrow) and (B) shows peripheral enhancement along with significant mass effect upon the ventricular system (arrow). (C) Three years later, there is relative resolution of the parietal WM lesions, but a new peripherally enhancing right frontal lesion (arrow) is seen.
    Figure 7A.
  • Figure 7B.
    Figure 7B.
  • Figure 7C.
    Figure 7C.
  • Figure 8A. 72-year-old man with MS. (A) Proton-density-weighted axial MR image shows multiple WM hyperintense lesions (arrows). (B).Two of these lesions show nodular enhancement (arrows) on the postcontrast-T1-weighted axial MR image.
    Figure 8A.
  • Figure 8B.
    Figure 8B.
  • Figure 9A. 37-year-old man with upper- and lower-extremity numbness (same patient as in Figure 6). (A) T2-weighted axial MR image shows ovoid-shaped hyperintense parietal lesion (arrow) and (B) shows solid enhancement (arrow) on the contrast-enhanced T1-weighted axial image.
    Figure 9A.
  • Figure 9B.
    Figure 9B.
  • Figure 10A. 25-year-old male with right facial sensory deficit. (A) Pre- and (B) postcontrast-enhanced T1-weighted axial MR images show oval hypointense lesion (arrow) with solid enhancement (arrow). (C).This lesion was hyperintense (arrow) on the T2-weighted axial MR image.
    Figure 10A.
  • Figure 10B.
    Figure 10B.
  • Figure 10C.
    Figure 10C.
  • Figure 11. Contrast-enhanced T1-weighted coronal MR image shows a ring- enhancing MS lesion (arrow) adjacent to the inferior aspect of the left lateral ventricle.
    Figure 11.
  • Figure 12. 40-year-old woman with chronic MS. T2-weighted conventional spin echo image shows marked hypointensity within both basal ganglia (arrows) consistent with iron deposition. There is extensive white matter signal abnormality and cerebral atrophy.
    Figure 12.
  • Figure 13A. 48-year-old woman with acute vision loss involving the left eye. (A) T2-weighted and (B) fat-suppressed contrast-enhanced T1-weighted coronal MR images show focal swelling and T2-signal change and enhancement within the left optic nerve (arrows). The MRI of the brain at the time of the orbit study was unremarkable. (C) Subsequent study of the brain 6 months later showed several WM lesions (arrows) as shown on FLAIR axial image. 
    Figure 13A.
  • Figure 13B.
    Figure 13B.
  • Figure 13C.
    Figure 13C.
  • Figure 14A. 42-year-old woman s/p MVA with neck pain and paresthesias. (A) T2-weighted sagittal and (B) axial image show an ovoid-shaped hyperintense intramedullary lesion that involves the posterior columns (arrows).
    Figure 14A.
  • Figure 14B.
    Figure 14B.
  • Figure 15. 12-year-old male with ADEM. T2-weighted axial MR image shows diffuse periventricular WM abnormality (arrows).
    Figure 15.
  • Figure 16. 9-year-old girl with declining academic performance. T2-weighted axial MR image shows focal signal abnormality within the peri-atrial WM (arrows).
    Figure 16.
  • Figure 17A. 28-year-old man with paraplegia. (A) T2-weighted sagittal and (B) contrast-enhanced fat-suppressed T1-weighted sagittal images of the thoracic spine show extensive T2 signal abnormality involving the thoracic spinal cord (arrows) with patchy, confluent enhancement. (C) T2-weighted axial MR image of the orbits shows small hyperintense foci (arrows) within the optic nerves.
    Figure 17A.
  • Figure 17B.
    Figure 17B.
  • Figure 17C.
    Figure 17C.
  • Figure 18A. 43-year-old man with bilateral leg weakness. (A) T2 weighted sagittal MR image shows increased signal intensity within an enlarged spinal cord (arrow). The signal abnormality extends for severe vertebral segments. (B) The contrast-enhanced fat-suppressed T1-weighted axial MR image shows enhancement that involves the majority of the cross-sectional area of the involved spinal cord. (Case is courtesy of Dr. Donald Price, Department of Radiology, Winthrop-University Hospital).
    Figure 18A.
  • Figure 18B.
    Figure 18B.
  • Figure 19. 33-year-old woman status post-tick bite. T2-weighted axial MR image shows multiple small subcortical WM foci of increased signal intensity (arrows).
    Figure 19.
  • Figure 20A. 46-year-old HIV+ man. (A) T2-weighted axial MR image shows extensive signal abnormality in the left occipital lobe (arrow) with involvement of both cortex and WM. (B).There is no significant enhancement on the contrast-enhanced T1-weighted axial MR image (arrow).
    Figure 20A.
  • Figure 20B.
    Figure 20B.
  • Figure 21. 35-year-old man with lethargy. Unenhanced axial CT image shows multiple areas of low density within the subcortical WM (arrows). These lesions showed no contrast enhancement. The patient was subsequently diagnosed with PML.
    Figure 21.
  • Figure 22A. 40-year-old woman with history of systemic lupus erythematosis (SLE) and headaches. (A) T2-weighted axial MR image shows T2 signal abnormality within the left parietal subcortical white matter (arrow). (B) The lesion (arrow) does not enhance after contrast administration.
    Figure 22A.
  • Figure 22B.
    Figure 22B.
  • Figure 23A. 21-year-old man with SLE complained of bilateral lower extremity weakness and lethargy. (A) T2-weighted sagittal image of lumbar spine shows T2-hyperintense signal within the conus medullaris (arrow). (B) FLAIR axial MR image shows focal signal abnormality posterior to the fourth ventricle (arrow). (C) The compressed axial MRA study of the Circle of Willis shows contour irregularity of the distal right vertebral artery (arrow).
    Figure 23A.
  • Figure 23B.
    Figure 23B.
  • Figure 23C.
    Figure 23C.
  • Figure 24A. Patient with CADASIL. (A and B) T2-weighted axial MR images show T2 signal abnormality within the temporal WM (arrows in A) and throughout the frontal and parietal WM (arrows in B). The basal ganglia and thalami also show extensive areas of T2 hyperintensity. (Image is courtesy of Dr. J. Pablo Villablanca, Department of Radiology, UCLA Medical Center.)
    Figure 24A.
  • Figure 24B.
    Figure 24B.
  • Figure 25. 51-year-old executive status post-cardiac arrest with marked decline in cognitive skills. FLAIR axial image shows patchy foci of increased signal intensity within the periventricular and subcortical WM (arrows).
    Figure 25.
  • Figure 26. Posterior reversible encephalopathy syndrome. FLAIR axial image shows increased signal within the occipital and posterior temporal cortex and adjacent subcortical WM (arrows). There was no contrast enhancement in these areas of signal abnormality.
    Figure 26.
  • Figure 27. 77-year-old man with prior cranial radiation treatment for lymphoma. T2-weighted axial MR image shows diffuse WM signal abnormality.
    Figure 27.
  • Figure 28. 40-year-old man status post intrathecal methotrexate therapy for acute lymphocytic leukemia. Proton-density MR image shows frontal and parietal WM signal abnormalities (arrows).
    Figure 28.