Intracerebral metastases pathophysiology: Difference between revisions
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*The ability of cancer cells to sever their link to the primary tumor site and commence the metastatic process, once specific functions have been acquired by an appropriate subset of cancer cells. The multistep cascade can be grouped into two stages: migration (intravasation, dissemination, and extravasation) and colonization.<ref name="RahmathullaToms2012">{{cite journal|last1=Rahmathulla|first1=Gazanfar|last2=Toms|first2=Steven A.|last3=Weil|first3=Robert J.|title=The Molecular Biology of Brain Metastasis|journal=Journal of Oncology|volume=2012|year=2012|pages=1–16|issn=1687-8450|doi=10.1155/2012/723541}}</ref> | *The ability of cancer cells to sever their link to the primary tumor site and commence the metastatic process, once specific functions have been acquired by an appropriate subset of cancer cells. The multistep cascade can be grouped into two stages: migration (intravasation, dissemination, and extravasation) and colonization.<ref name="RahmathullaToms2012">{{cite journal|last1=Rahmathulla|first1=Gazanfar|last2=Toms|first2=Steven A.|last3=Weil|first3=Robert J.|title=The Molecular Biology of Brain Metastasis|journal=Journal of Oncology|volume=2012|year=2012|pages=1–16|issn=1687-8450|doi=10.1155/2012/723541}}</ref> | ||
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Revision as of 15:18, 11 November 2015
Intracerebral metastases Microchapters |
Differentiating Intracerebral Metastases from other Diseases |
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Diagnosis |
Treatment |
Case Studies |
Intracerebral metastases pathophysiology On the Web |
American Roentgen Ray Society Images of Intracerebral metastases pathophysiology |
Risk calculators and risk factors for Intracerebral metastases pathophysiology |
Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]Associate Editor(s)-in-Chief: Sujit Routray, M.D. [2]
Overview
Pathophysiology
Pathogenesis
- The ability of cancer cells to sever their link to the primary tumor site and commence the metastatic process, once specific functions have been acquired by an appropriate subset of cancer cells. The multistep cascade can be grouped into two stages: migration (intravasation, dissemination, and extravasation) and colonization.[1]
Migration | Colonization |
---|---|
|
|
Gallery
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(a) Formation of metastatic tumor cell lines at primary sites like breast, lung, and skin (melanoma) seen as the red nodes. Metastasis from these primary sites then spreads to the brain via the circulatory system (red arrows) and also to adjacent sites like the liver, bone, lung, and lymph nodes (black arrows). The inset shows the primary site of melanoma cells proliferating and migrating towards the vasculature, subsequently disseminating to secondary organ sites.[1]
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(b) The metastatic tumor cells detach from the primary site and penetrate the adjacent parenchyma to reach the blood vessels. On reaching the vessels, the cells invade and enter the circulation (intravasation) and then disseminate within the vascular system (left half of figure). These cells eventually adhere to secondary sites “soil” to then extravasate out of the blood vessels and for colonies of metastatic cells (right half of figure).[1]
Genetics
Genes involved in the pathogenesis of intracerebral metastases are tabulated below:[1]
Gene | Cancer site (primary) | Role and implications | Chromosome location |
---|---|---|---|
RHoC | Melanoma |
|
1p21-p13 |
LOX |
Breast |
|
5q23.1-q23.2 |
VEGF |
Lung |
|
6p21.1 |
CSF1 |
Breast |
|
1p13.3 |
ID1 |
Breast |
|
20q11.21 |
TWIST1 |
Breast |
|
7p21.1 |
MET | Renal cell cancer |
|
7q31.2 |
MMP-9 |
Colorectal |
|
20q13.12 |
NEDD9 | Melanoma |
|
6p24.2 |
LEF1 | Lung |
|
4q25 |
HOXB9 |
Lung |
|
17q21.32 |
BMP4 |
Lung |
|
14q22.2 |
STAT3 | Melanoma |
|
17q21.2 |
Gross Pathology
- Typically metastases are sharply demarcated from the surrounding parenchyme and usually there is a zone of peritumoral edema out of proportion with the tumor size.
- Common intracranial sites associated with subependymal giant cell astrocytoma include:[2]
- Cerebrum (80%)
- Cerebellum (15%)
- Brain stem (5% )
Gallery
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This solitary brain metastasis from thyroid papillary carcinoma resulted in neurological symptoms. The thyroid primary was clinically occult. (Courtesy of Dr. Nikola Kostich, Minneapolis, MN.).[3]
Microscopic Pathology
The histopathological appearance of intracerebral metastases may vary with the type of primary tumor. Common findings are listed below:[4][5]
- Tubule formation/glands
- Well-circumscribed and sharply demarcated from surrounding tissue (with the exception of melanoma metastasis)
- Mitoses
- Nuclear atypia
- Nuclear hyperchromasia
- Variation of nuclear size
- Variation of nuclear shape
Gallery
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Very low magnification micrograph demonstrating metastatic adenocarcinoma that from a colorectal primary, i.e. colorectal carcinoma, by immunostains on HPS stain. The cerebellum seen on the image has Bergmann gliosis and Purkinje cell loss.[6]
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High magnification micrograph demonstrating metastatic adenocarcinoma that is from a colorectal primary, i.e. colorectal carcinoma, by immunostains on HPS stain. The cerebellum has Bergmann gliosis and Purkinje cell loss.[6]
-
High magnification micrograph of a brain metastasis on HPS stain demonstrating normal brain tissue on the left and tumor cells on the right. The sharp demarcation between tumor and normal is typical of brain metastases.[6]
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Adenocarcinoma infiltrating the brain in a case of lung cancer on H&E stain.[6]
Immunohistochemistry
- The immunohistochemistry profile of intracerebral metastases may vary with the type of the primary tumor.[7]
- Intracerebral metastases are demonstrated by positivity to tumor markers such as:[7]
- General brain metastases: Pankeratin +ve, GFAP -ve
- Lung adenocarcinoma and small cell lung carcinoma: TTF-1 +ve, CK7 +ve, CK20 -ve
- Breast carcinoma: CK7 +ve, ER +ve, PR +ve, BRST2 +ve/-ve
- Colorectal carcinoma: CK20 +ve, CDX2 +ve, TTF-1 -ve, CK7 -ve
- Clear cell renal cell carcinoma: PAX8 +ve, vimentin +ve, CD10 +ve, CK7 -ve, CK20 -ve
- Melanoma: S-100 +ve, HMB-45 +ve, melan-A +ve.
Gallery
-
Immunohistochemistry profile of intracerebral metastases from an adenocarcinoma of lung (primary) demonstrating positivity to CK7, CK20, and TTF1.[8]
References
- ↑ 1.0 1.1 1.2 1.3 Rahmathulla, Gazanfar; Toms, Steven A.; Weil, Robert J. (2012). "The Molecular Biology of Brain Metastasis". Journal of Oncology. 2012: 1–16. doi:10.1155/2012/723541. ISSN 1687-8450.
- ↑ Khuntia, Deepak (2015). "Contemporary Review of the Management of Brain Metastasis with Radiation". Advances in Neuroscience. 2015: 1–13. doi:10.1155/2015/372856. ISSN 2356-6787.
- ↑ Gross image of brain metastases. Libre pathology 2015. http://librepathology.org/wiki/index.php/Brain_metastasis. Accessed on November 10, 2015
- ↑ Microscopic features of brain metastasis. Libre pathology 2015. http://librepathology.org/wiki/index.php/Brain_metastasis. Accessed on November 10, 2015
- ↑ Microscopic appearance of brain metastases. Dr Bruno Di Muzio and Dr Trent Orton et al. Radiopaedia 2015. http://radiopaedia.org/articles/brain-metastases. Accessed on November 10, 2015
- ↑ 6.0 6.1 6.2 6.3 Microscopic images of brain metastasis. Libre pathology 2015. http://librepathology.org/wiki/index.php/Brain_metastasis. Accessed on November 10, 2015
- ↑ 7.0 7.1 IHC features of brain metastasis. Libre pathology 2015. http://librepathology.org/wiki/index.php/Brain_metastasis. Accessed on November 10, 2015
- ↑ IHC image of brain metastasis. Libre pathology 2015. http://librepathology.org/wiki/index.php/Brain_metastasis. Accessed on November 10, 2015