Astrocytoma CT: Difference between revisions

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Revision as of 00:20, 24 August 2015

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]

A Computed Tomography (CT) or Magnetic Resonance Imaging (MRI) scan is necessary to characterize the anatomy of this tumor (size, location, consistency).
CT will usually show distortion of third and lateral ventricles with displacement of anterior and middle cerebral arteries.
A X-ray computed tomography (CT) or Magnetic resonance imaging (MRI) scan is necessary to characterize the extent of these tumors (size, location, consistency). CT will usually show distortion of third and lateral ventricles with displacement of anterior and middle cerebral arteries. Histologic analysis is necessary for grading diagnosis.
In the first stage of diagnosis the doctor will take a history of symptoms and perform a basic neurological exam, including an eye exam and tests of vision, balance, coordination and mental status. The doctor will then require a computerized tomography (CT) scan and magnetic resonance imaging (MRI) of the patient's brain.
During a CT scan, x rays of the patient's brain are taken from many different directions. These are then combined by a computer, producing a cross-sectional image of the brain.
For an MRI, the patient relaxes in a tunnel-like instrument while the brain is subjected to changes of magnetic field. An image is produced based on the behavior of the brain's water molecules in response to the magnetic fields. A special dye may be injected into a vein before these scans to provide contrast and make tumors easier to identify.

Typically low grade infiltrating astrocytomas appear as isodense or hypodense regions of positive mass effect, often without any enhancement (in fact presence of enhancement would suggest high tumours), although particularly gemistocytic astrocytomas can demonstrates wispy enhancement.
Calcification is not seldom (10-20% of cases)1 and may be related to oligodendroglial components (i.e oligoastrocytoma).
Cystic or fluid attenuation components are also encountered, particularly in gemistocytic and protoplasmic varieties.

Typically fibrillary low grade infiltrating astrocytomas appear as isodense or hypodense regions of positive mass effect, usually without any enhancement (in fact presence of enhancement would suggest high grade, e.g. WHO III or IV tumours.
Calcification is not infrequently seen (10-20% of cases)1 but is more common in mixed tumours relating to an oligodendroglial components (i.e. oligoastrocytoma).
Cystic or fluid attenuation components are also encountered although this is far more common in gemistocytic and protoplasmic variants.

Typically protoplasmic low grade infiltrating astrocytomas appear as hypodense regions of positive mass effect, usually without any enhancement (in fact presence of enhancement would suggest high grade tumours). Areas of the tumour appear of fluid attenuation, due to the aforementioned prominent mucinous microcystic component.

CT appearances are intermediate, appearing as regions of low attenuation with positive mass effect. Enhancement is variable.

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

@@ Line 23: / Line 23: @@
 ===Anaplastic astrocytomas<ref name=Radiopaedia 2015 Anaplastic astrocytoma>{{cite web | title = Anaplastic astrocytoma [Dr Bruno Di Muzio and Dr Frank Gaillard]| url = http://radiopaedia.org/articles/anaplastic-astrocytoma }}</ref>===
 * CT appearances are intermediate, appearing as regions of low attenuation with positive mass effect. Enhancement is variable.
+===Subependymal Giant Cell Astrocytoma<ref name=Radiopaedia052015>{{cite web | title = Subependymal giant cell astrocytoma [Dr Bruno Di Muzio and Dr Jeremy Jones]| url = http://radiopaedia.org/articles/subependymal-giant-cell-astrocytoma }}</ref>===
+* The foramen of Monro is the classic location, and the tumour arises when a subependymal nodule transforms into SGCA over a period of time.
+* 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 nodules also enhance)