Osmotic demyelination syndrome

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Osmotic demyelination syndrome refers to acute demyelination ~~seen~~ seen in the setting of osmotic changes, typically with the rapid correction of hyponatraemia. It is the ~~more recent~~preferred term replacing central pontine myelinolysis, recognising that extrapontine structures can also be affected, previously known as extrapontine myelinolysis.

Epidemiology

The initial description of central pontine myelinolysis by Adams et al. in 1959 ² ~~was~~ was entirely in a population of chronic alcoholics, and certainly, this scenario is common. Since then it has been increasingly recognised in other patient groups, but usually in the setting of rapidly corrected electrolyte disturbance ¹:

chronic alcoholics
chronically debilitated patients
transplant recipients
pregnancy and hyperemesis

Clinical presentation

Clinically osmotic demyelination syndrome presents in a biphasic pattern. ~~The~~ The first phase is usually attributable not to the demyelination but rather to the inciting electrolyte abnormality, with patients being acutely encephalopathic. Following rapid reversal of this abnormality, the patient transiently improves before progressing onto the classic osmotic demyelination syndrome features 2-3 days later. When pontine involvement is prominent, clinical features consist of:

spastic quadriparesis
pseudobulbar palsy
changes in levels of consciousness
coma
death

Pathology

Although the exact mechanism is still uncertain, it is known that oligodendroglial cells are most susceptible to osmotic stresses, leading to their demise. It is not surprising that the distribution of osmotic myelinolysis, therefore, parallels the distribution of these cells.

Histologically, osmotic demyelination syndrome is characterised by intramyelinic splitting, vacuolation, and myelin sheath rupture ³. After many days, macrophages can be identified.

Radiographic features

CT

CT may demonstrate low attenuation crossing the midline in the lower pons. However, CT assessment of the skull base can be difficult due to beam hardening artifact and, if available, MRI is preferred.

MRI

The earliest change is seen on DWI with restriction in the lower pons. This is seen within 24 hours of the onset of quadriplegia ³. This same region demonstrates eventual high T2 signal and later a low T1 signal. The T1 and T2 changes may take up to two weeks to develop. This region has a classic trident-shaped appearance. The overall appearance on T2/FLAIR axial MRI has also been likened to the face of a pig, referred to as piglet sign. ~~Occasionally~~ Occasionally gadolinium enhancement is also demonstrated, just as in the acute phase of multiple sclerosis (MS ) ~~plaque~~ plaque. The peripheral fibres (ventrolateral longitudinal fibres, corticospinal tracts), as well as the periventricular and subpial regions, are typically spared.

Similar appearances are seen in other parts of the brain: ~~basal~~ basal ganglia, ~~midbrain~~ midbrain, and subcortical white matter.

Signal characteristics of the affected region include:

T1: mildly or moderately hypointense
T2/FLAIR: hyperintense, sparing the periphery and corticospinal tracts
PD: hyperintense
DWI: hyperintense
ADC: signal low or signal loss
T1 C+ (Gd): ~~usually~~ usually there is no enhancement, but some authors reported that it may occur ^5,6

Nuclear medicine

PET

Affected regions may demonstrate initial high uptake followed by subsequent low uptake with 18-FDG.

Treatment and prognosis

To prevent osmotic demyelination, serum sodium correction should be gradual. One ~~recent~~ article states that serum sodium level correction should be 4 mEq/L to 6 mEq/L within 1 to 2 hours, with no more than 10 mEq/L~~, is an upper limit~~ correction within the initial 24 hours ⁷.

Some patients show complete recovery however six-month survival rate is only 5-10%.

Differential diagnosis

General imaging differential considerations include:

demyelination including multiple sclerosis (MS)
pontine infarction from basilar perforators can be central, although usually, brainstem infarcts stop at the midline
pontine neoplasms including astrocytomas: brainstem is asymmetrically expanded with mass effect upon adjacent cisterns. local vessels may also be displaced
brainstem metastasis: usually enhances
vigabatrin toxicity: bilateral dorsal pontine longitudinal restricted diffusion

-<p><strong>Osmotic demyelination syndrome </strong>refers to acute <a href="/articles/demyelination">demyelination</a> seen in the setting of osmotic changes, typically with the rapid correction of <a href="/articles/hyponatremia">hyponatraemia</a>. It is the more recent term replacing <a href="/articles/central-pontine-myelinolysis-2">central pontine myelinolysis</a>, recognising that extrapontine structures can also be affected, previously known as <a href="/articles/extrapontine-myelinolysis-epm">extrapontine myelinolysis</a>. </p><h4>Epidemiology</h4><p>The initial description of central pontine myelinolysis by Adams et al. in 1959 <sup>2</sup> was entirely in a population of chronic alcoholics, and certainly, this scenario is common. Since then it has been increasingly recognised in other patient groups, but usually in the setting of rapidly corrected electrolyte disturbance <sup>1</sup>:</p><ul>
+<p><strong>Osmotic demyelination syndrome </strong>refers to acute <a href="/articles/demyelination">demyelination</a> seen in the setting of osmotic changes, typically with the rapid correction of <a href="/articles/hyponatremia">hyponatraemia</a>. It is the preferred term replacing <a href="/articles/central-pontine-myelinolysis-2">central pontine myelinolysis</a>, recognising that extrapontine structures can also be affected, previously known as <a href="/articles/extrapontine-myelinolysis-epm">extrapontine myelinolysis</a>. </p><h4>Epidemiology</h4><p>The initial description of central pontine myelinolysis by Adams et al. in 1959 <sup>2</sup> was entirely in a population of chronic alcoholics, and certainly, this scenario is common. Since then it has been increasingly recognised in other patient groups, but usually in the setting of rapidly corrected electrolyte disturbance <sup>1</sup>:</p><ul>
-</ul><h4>Clinical presentation</h4><p>Clinically osmotic demyelination syndrome presents in a biphasic pattern. The first phase is usually attributable not to the demyelination but rather to the inciting electrolyte abnormality, with patients being acutely encephalopathic. Following rapid reversal of this abnormality, the patient transiently improves before progressing onto the classic osmotic demyelination syndrome features 2-3 days later. When pontine involvement is prominent, clinical features consist of:</p><ul>
+</ul><h4>Clinical presentation</h4><p>Clinically osmotic demyelination syndrome presents in a biphasic pattern. The first phase is usually attributable not to the demyelination but rather to the inciting electrolyte abnormality, with patients being acutely encephalopathic. Following rapid reversal of this abnormality, the patient transiently improves before progressing onto the classic osmotic demyelination syndrome features 2-3 days later. When pontine involvement is prominent, clinical features consist of:</p><ul>
-</ul><h4>Pathology</h4><p>Although the exact mechanism is still uncertain, it is known that oligodendroglial cells are most susceptible to osmotic stresses, leading to their demise. It is not surprising that the distribution of osmotic myelinolysis, therefore, parallels the distribution of these cells.</p><p>Histologically, osmotic demyelination syndrome is characterised by intramyelinic splitting, vacuolation, and myelin sheath rupture <sup>3</sup>. After many days, macrophages can be identified.</p><h4>Radiographic features</h4><h5>CT</h5><p>CT may demonstrate low attenuation crossing the midline in the lower <a href="/articles/pons">pons</a>. However, CT assessment of the skull base can be difficult due to <a href="/articles/beam-hardening">beam hardening artifact</a> and, if available, MRI is preferred.</p><h5>MRI</h5><p>The earliest change is seen on DWI with restriction in the lower pons. This is seen within 24 hours of the onset of quadriplegia <sup>3</sup>. This same region demonstrates eventual high T2 signal and later a low T1 signal. The T1 and T2 changes may take up to two weeks to develop. This region has a classic <a href="/articles/trident-sign-osmotic-demyelination">trident-shaped appearance</a>. The overall appearance on T2/FLAIR axial MRI has also been likened to the face of a pig, referred to as <a href="/articles/piglet-sign-osmotic-demyelination">piglet sign</a>. Occasionally gadolinium enhancement is also demonstrated, just as in the acute phase of <a href="/articles/multiple-sclerosis-ms">multiple sclerosis (MS</a><a href="/articles/multiple-sclerosis">)</a><a href="/articles/multiple-sclerosis-ms"> plaque</a>. The peripheral fibres (ventrolateral longitudinal fibres, <a href="/articles/corticospinal-tract">corticospinal tracts</a>), as well as the periventricular and subpial regions, are typically spared.</p><p>Similar appearances are seen in other parts of the brain: basal ganglia, midbrain, and subcortical white matter. </p><p>Signal characteristics of the affected region include:</p><ul>
+</ul><h4>Pathology</h4><p>Although the exact mechanism is still uncertain, it is known that oligodendroglial cells are most susceptible to osmotic stresses, leading to their demise. It is not surprising that the distribution of osmotic myelinolysis, therefore, parallels the distribution of these cells.</p><p>Histologically, osmotic demyelination syndrome is characterised by intramyelinic splitting, vacuolation, and myelin sheath rupture <sup>3</sup>. After many days, macrophages can be identified.</p><h4>Radiographic features</h4><h5>CT</h5><p>CT may demonstrate low attenuation crossing the midline in the lower <a href="/articles/pons">pons</a>. However, CT assessment of the skull base can be difficult due to <a href="/articles/beam-hardening">beam hardening artifact</a> and, if available, MRI is preferred.</p><h5>MRI</h5><p>The earliest change is seen on DWI with restriction in the lower pons. This is seen within 24 hours of the onset of quadriplegia <sup>3</sup>. This same region demonstrates eventual high T2 signal and later a low T1 signal. The T1 and T2 changes may take up to two weeks to develop. This region has a classic <a href="/articles/trident-sign-osmotic-demyelination">trident-shaped appearance</a>. The overall appearance on T2/FLAIR axial MRI has also been likened to the face of a pig, referred to as <a href="/articles/piglet-sign-osmotic-demyelination">piglet sign</a>. Occasionally gadolinium enhancement is also demonstrated, just as in the acute phase of <a href="/articles/multiple-sclerosis-ms">multiple sclerosis (MS</a><a href="/articles/multiple-sclerosis">)</a><a href="/articles/multiple-sclerosis-ms"> plaque</a>. The peripheral fibres (ventrolateral longitudinal fibres, <a href="/articles/corticospinal-tract">corticospinal tracts</a>), as well as the periventricular and subpial regions, are typically spared.</p><p>Similar appearances are seen in other parts of the brain: basal ganglia, midbrain, and subcortical white matter. </p><p>Signal characteristics of the affected region include:</p><ul>
~~-<li><p><strong>T1 C+ (Gd):</strong> usually there is no enhancement, but some authors reported that it may occur <sup>5,6</sup></p></li>~~
-</ul><h5>Nuclear medicine</h5><h6>PET</h6><p>Affected regions may demonstrate initial high uptake followed by subsequent low uptake with 18-FDG.</p><h4>Treatment and prognosis</h4><p>One recent article states that sodium level correction should be 4 mEq/L to 6 mEq/L within 1 to 2 hours, no more than 10 mEq/L, is an upper limit within the initial 24 hours <sup>7</sup>.</p><p>Some patients show complete recovery however six-month survival rate is only 5-10%.</p><h4>Differential diagnosis</h4><p>General imaging differential considerations include:</p><ul>
+<li><p><strong>T1 C+ (Gd):</strong> usually there is no enhancement, but some authors reported that it may occur <sup>5,6</sup></p></li>
+</ul><h5>Nuclear medicine</h5><h6>PET</h6><p>Affected regions may demonstrate initial high uptake followed by subsequent low uptake with 18-FDG.</p><h4>Treatment and prognosis</h4><p>To prevent osmotic demyelination, serum sodium correction should be gradual. One article states that serum sodium level correction should be 4 mEq/L to 6 mEq/L within 1 to 2 hours, with no more than 10 mEq/L correction within the initial 24 hours <sup>7</sup>.</p><p>Some patients show complete recovery however six-month survival rate is only 5-10%.</p><h4>Differential diagnosis</h4><p>General imaging differential considerations include:</p><ul>

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