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CNS Tumors – clinical and radiological aspects

Publication at First Faculty of Medicine, Faculty of Physical Education and Sport, Central Library of Charles University |
2022

Abstract

Tumors of the central nervous system (CNS) include primary tumors - itraaxial, growing from brain and spinal cord cells (neuroepithelial tumors) or extraaxial, growing from surrounding structures (brain and spinal cord, nerve sheaths, vascular structures, lymphatic tissue, germ cells, malformations, pituitary glands). Much more often they are located in the intracranial space a solitary or multiple metastatic spread of malignancy originating from another organ (eg lung, breast, malignant melanoma, Grawitzs tumor).

The occurrence of metastases of solid tumors is then in the intraaxial or extraaxial region, leptomeningeal or dural. Even morphologically benign tumors with their occurrence in a closed CNS compartment can have malignant behaviour and cause severe slowly developing to acute neurological symptoms, including intracranial hypertension.

Primary tumors of the central nervous system present 1-2% of all cancers, with a higher incidence in adults after the age of 60, with a slight predominance in men, with higher mortality in men than in women. About 5% of CNS tumors are hereditary (e.g., Li-Fraumeni syndrome, neurofibromatosis type I, II).

The causes of most brain and spinal cord tumors are unclear, the effect of radiation has been definitely demonstrated, there is an increased risk in transplant patients and AIDS (Acquired Immune Deficiency Syndrome) patients, and the potentiating effects of some chemicals and viruses on the development of CNS neoplasms are uncertain. The effectiveness of treatment of brain and spinal cord tumors is influenced by the existence of the so-called hematoencephalic barrier, which protects the brain from the penetration of toxic substances, but at the same time prevents the penetration of most cytostatics to the tumor target.

Another obstacle may be the localization of the tumor in areas difficult to access for histological verification (brain stem, optical chiasma) due to the high risk of complications even after stereotactic biopsy. In some cases, in an effort not to cause an irreversible neurological deficit by inconsiderate tissue collection, the sample of histological material can then become inconclusive to tumor cells, i.e., tumor cells are not captured.

Last but not least, the radiosensitivity of some brain structures is also limiting, which makes it impossible to apply a higher dose of ionizing radiation to a tumor affecting sensitive tissues or located near of these sensitive tissues. The rapid development of immunohistochemical (IHC) and molecular genetic analysis methods has significantly refined diagnostics and thus theoretically facilitates the choice of the optimal treatment procedure for the individual patient.

While advances in modern conformal photon and particle (currently the most frequently proton) radiotherapy, stereotactic radiosurgery has enabled accurately targeted irradiation of the CNS tumor site and at the same time spare the high-risk brain structures, thereby significantly reduce the risk of acute and late neurotoxicity, pharmacotherapy options are still limited. Just molecular-genetic knowledge already provides us with predictive and prognostic information.

They should increasingly stratify patients for targeted therapy.