Subependymal giant cell astrocytoma

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Subependymal giant cell astrocytomas (~~SGCA's~~SGCAs) are benign tumours (~~WHO~~(WHO grade I), seen almost exclusively in young patients with tuberous sclerosis ~~(TS)~~. They can be either asymptomatic or symptomatic due obstructive hydrocephalus, surgery treatment is often curative.

On imaging, they classically appear as an intraventricular mass near the foramen of Monro, larger than 1 cm, showing calcifications, heterogenous MRI signal, and marked contrast enhancement.

Epidemiology

Subependymal giant cell tumours are a well ~~known~~-known manifestation of TStuberous sclerosis, affecting 5-15% of patients with the condition⁸. They are principally diagnosed in patients under 20 years of age, ~~but are~~only occasionally found in older ~~people~~individuals.

Clinical presentation

Subependymal giant cell tumours are often asymptomatic. When symptoms occur, they are usually a result of obstructive hydrocephalus because of mass effect around the ventricular system~~. Common sites~~ at the level of ~~obstruction include~~ the interventricular foramen (of Monro)~~, the~~ ~~cerebral aqueduct (of Sylvius)~~ ~~and the~~ ~~third~~ or ~~fourth ventricles~~.

Pathology

Subependymal giant cell astrocytomas are considered WHO grade I lesions in the current (2016) WHO classification of CNS tumours⁸.

Macroscopic appearance

These tumours ~~are~~are multilobulated well-circumscribed tumours arising from the wall of the lateral ventricles near the foramen of Monro. They frequently contain cysts and calcification ⁸.

Microscopic appearance

Subependymal giant cell astrocytomas are believed to arise from a subependymal nodule present in the ventricular wall in a patient with TStuberous sclerosis, although this has yet to be categorically established ^4,8.

Histologically, subependymal nodules and subependymal giant cell tumours are essentially indistinguishable, and the distinction lies in the potential of a ~~subependymal giant cell tumour~~SEGA for growth and mass effect ⁵. The cells that appear astrocytic, usually resemble gemistocytes; large polygonal cells with prominent eosinophilic cytoplasm. A smaller number of ganglionic appearing giant pyramidal-like cells ⁸.

The ependymal lining over ~~SGCA~~SGCAs remains intact making CSF seeding highly unlikely ⁷.

Current evidence suggests that ~~SGCAs~~they are of a mixed neuronal and glial lineage, although they continue to be classified as astrocytomas ⁵. ~~They are considered WHO grade I lesions (see~~ ~~WHO classification~~

Immunophenotype

Immunohistochemical examination of ~~CNS~~these tumours). demonstrates the following reactivity ⁸:

S100: positive
GFAP: variable
synaptophysin: variable
CD34: negative
additional variable and focal reactivity: class III beta-tubulin, NeuN, SOX2

Radiographic features

The foramen of Monro is the classic location, and the tumour arises when a subependymal nodule transforms into SGCA over a period of time.

CT

typically appears as an intraventricular mass near the foramen of Monro
they are usually larger than 1 cm
lesions are iso- or slightly hypoattenuating to grey matter
calcification is common and haemorrhage is possible
accompanying hydrocephalus may be present
often shows marked contrast enhancement (~~subependymal~~(subependymal nodule s also enhance)

MRI

T1: heterogenous and hypo- to isointense to grey matter
T2: heterogenous and hyperintense to grey matter; calcified components can be hypointense
T1 C+ (Gd): can show marked enhancement

Treatment and prognosis

Young children who have tuberous sclerosis may be offered screening because of the increased risk of developing subependymal giant cell astrocytomas.

The main treatment is surgery, which is indicated if the tumour is symptomatic, or growth is demonstrated on MRI. Surgery is often curative. Oral Rapamycin™ (sirolimus) has also been trialled ³.

Differential diagnosis

In the clinical context of known TStuberous sclerosis, the appearance is virtually pathognomonic, and the main differential is between a subependymal nodule and SGCA. Serial imaging is most helpful here, as growth implies SCGA.

Other general considerations include:

-<p><strong>Subependymal giant cell astrocytomas (</strong><strong>SGCA's)</strong> are benign tumours (<a href="/articles/cns-tumours-classification-and-grading-who">WHO grade I</a>), seen almost exclusively in young patients with <a href="/articles/tuberous-sclerosis">tuberous sclerosis (TS)</a>. They can be either asymptomatic or symptomatic due obstructive hydrocephalus, surgery treatment is often curative. </p><p>On imaging they classically appear as an intraventricular mass near the foramen of Monro, larger than 1 cm, showing calcifications, heterogenous MRI signal, and marked contrast enhancement. </p><h4>Epidemiology</h4><p>Subependymal giant cell tumours are a well known manifestation of TS, affecting 5-15% of patients with the condition. They are principally diagnosed in patients under 20 years of age, but are occasionally found in older people. </p><h4>Clinical presentation</h4><p>Subependymal giant cell tumours are often asymptomatic. When symptoms occur, they are usually a result of <a href="/articles/obstructive-hydrocephalus">obstructive hydrocephalus</a> because of mass effect around the <a href="/articles/ventricular-system">ventricular system</a>. Common sites of obstruction include the<a href="/articles/interventricular-foramen-of-monro-1"> interventricular foramen (of Monro)</a>, the <a href="/articles/cerebral-aqueduct-of-sylvius">cerebral aqueduct (of Sylvius)</a> and the <a href="/articles/third-ventricle">third</a> or <a href="/articles/fourth-ventricle">fourth ventricles</a>.</p><h4>Pathology</h4><p>Subependymal giant cell tumours are believed to arise from a subependymal nodule present in the ventricular wall in a patient with TS <sup>4</sup>. Histologically, subependymal nodules and subependymal giant cell tumours are indistinguishable, and the distinction lies in the potential of a subependymal giant cell tumour for growth and mass effect <sup>5</sup>.</p><p>The ependymal lining over SGCA remains intact making CSF seeding highly unlikely <sup>7</sup>.</p><p>Current evidence suggests that SGCAs are of a mixed neuronal and glial lineage, although they continue to be classified as astrocytomas <sup>5</sup>. They are considered WHO grade I lesions (see <a href="/articles/cns-tumours-classification-and-grading-who">WHO classification of CNS tumours</a>). </p><h4>Radiographic features</h4><p>The <a href="/articles/foramen-of-monro">foramen of Monro</a> is the classic location, and the tumour arises when a <a href="/articles/subependymal-nodules">subependymal nodule</a> transforms into SGCA over a period of time.</p><h5>CT</h5><ul>
~~-<li>typically appears as an intraventricular mass near the <a href="/articles/interventricular-foramen-of-monro-1">foramen of Monro</a>~~
~~-</li>~~
+<p><strong>Subependymal giant cell astrocytomas (</strong><strong>SGCAs)</strong> are benign tumours (WHO grade I), seen almost exclusively in young patients with <a href="/articles/tuberous-sclerosis">tuberous sclerosis</a>. They can be either asymptomatic or symptomatic due obstructive hydrocephalus, surgery treatment is often curative. </p><p>On imaging, they classically appear as an intraventricular mass near the <a title="Foramen of Monro" href="/articles/interventricular-foramen-of-monro-1">foramen of Monro</a>, larger than 1 cm, showing calcifications, heterogenous MRI signal, and marked contrast enhancement. </p><h4>Epidemiology</h4><p>Subependymal giant cell tumours are a well-known manifestation of tuberous sclerosis, affecting 5-15% of patients with the condition <sup>8</sup>. They are principally diagnosed in patients under 20 years of age, only occasionally found in older individuals. </p><h4>Clinical presentation</h4><p>Subependymal giant cell tumours are often asymptomatic. When symptoms occur, they are usually a result of <a href="/articles/obstructive-hydrocephalus">obstructive hydrocephalus</a> because of mass effect around the ventricular system at the level of the<a href="/articles/interventricular-foramen-of-monro-1"> interventricular foramen (of Monro)</a>.</p><h4>Pathology</h4><p>Subependymal giant cell astrocytomas are considered WHO grade I lesions in the current (2016) <a href="/articles/who-classification-of-cns-tumours-1">WHO classification of CNS tumours</a> <sup>8</sup>. </p><h5>Macroscopic appearance</h5><p>These tumours are multilobulated well-circumscribed tumours arising from the wall of the lateral ventricles near the foramen of Monro. They frequently contain cysts and calcification <sup>8</sup>. </p><h5>Microscopic appearance</h5><p>Subependymal giant cell astrocytomas are believed to arise from a subependymal nodule present in the ventricular wall in a patient with tuberous sclerosis, although this has yet to be categorically established <sup>4,8</sup>.</p><p>Histologically, subependymal nodules and subependymal giant cell tumours are essentially indistinguishable, and the distinction lies in the potential of a SEGA for growth and mass effect <sup>5</sup>. The cells that appear astrocytic, usually resemble gemistocytes; large polygonal cells with prominent eosinophilic cytoplasm. A smaller number of ganglionic appearing giant pyramidal-like cells <sup>8</sup>. </p><p>The ependymal lining over SGCAs remains intact making CSF seeding highly unlikely <sup>7</sup>.</p><p>Current evidence suggests that they are of a mixed neuronal and glial lineage, although they continue to be classified as astrocytomas <sup>5</sup>. </p><h5>Immunophenotype</h5><p>Immunohistochemical examination of these tumours demonstrates the following reactivity <sup>8</sup>: </p><ul>
+<li>
+<a title="S100" href="/articles/s100">S100</a>: positive</li>
+<li>
+<a title="Glial fibrillary acid protein (GFAP)" href="/articles/glial-fibrillary-acid-protein-gfap">GFAP</a>: variable</li>
+<li>
+<a title="Synaptophysin" href="/articles/synaptophysin">synaptophysin</a>: variable</li>
+<li>CD34: negative</li>
+<li>additional variable and focal reactivity: class III beta-tubulin, NeuN, SOX2</li>
+</ul><h4>Radiographic features</h4><p>The <a href="/articles/foramen-of-monro">foramen of Monro</a> is the classic location, and the tumour arises when a <a href="/articles/subependymal-nodules">subependymal nodule</a> transforms into SGCA over a period of time.</p><h5>CT</h5><ul>
+<li>typically appears as an intraventricular mass near the foramen of Monro</li>
~~-<li>often shows marked contrast enhancement (<a href="/articles/subependymal-nodule">subependymal nodule</a><a href="/articles/subependymal-nodules">s</a> also enhance)</li>~~
+<li>often shows marked contrast enhancement (subependymal nodule<a href="/articles/subependymal-nodules">s</a> also enhance)</li>
-</ul><h4>Treatment and prognosis</h4><p>Young children who have tuberous sclerosis may be offered screening because of the increased risk of developing subependymal giant cell astrocytomas.</p><p>The main treatment is surgery, which is indicated if the tumour is symptomatic, or growth is demonstrated on MRI. Surgery is often curative. Oral Rapamycin™ (sirolimus) has also been trialled <sup>3</sup>.</p><h4>Differential diagnosis</h4><p>In the clinical context of known TS, the appearance is virtually pathognomonic, and the main differential is between a subependymal nodule and SGCA. Serial imaging is most helpful here, as growth implies SCGA.</p><p>Other general considerations include:</p><ul>
+</ul><h4>Treatment and prognosis</h4><p>Young children who have tuberous sclerosis may be offered screening because of the increased risk of developing subependymal giant cell astrocytomas.</p><p>The main treatment is surgery, which is indicated if the tumour is symptomatic, or growth is demonstrated on MRI. Surgery is often curative. Oral Rapamycin™ (sirolimus) has also been trialled <sup>3</sup>.</p><h4>Differential diagnosis</h4><p>In the clinical context of known tuberous sclerosis, the appearance is virtually pathognomonic, and the main differential is between a subependymal nodule and SGCA. Serial imaging is most helpful here, as growth implies SCGA.</p><p>Other general considerations include:</p><ul>

References changed:

8. Louis D, Ohgaki H, Wiestler O et al. The 2007 WHO Classification of Tumours of the Central Nervous System. Acta Neuropathol. 2007;114(2):97-109. <a href="https://doi.org/10.1007/s00401-007-0243-4">doi:10.1007/s00401-007-0243-4</a> - <a href="https://www.ncbi.nlm.nih.gov/pubmed/17618441">Pubmed</a>

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