Gamma Therapy Application: An innovative method of treatment with radiation applicators
In the modern medical world, new and effective methods of treating various diseases are constantly being sought. One of these methods is gamma application therapy, which is based on the use of radioactive applicators applied to the patient’s skin or mucous membranes. This innovative approach offers new opportunities in the treatment of tumor diseases and other pathologies.
Gamma application therapy is based on the use of ionizing radiation, which has the ability to penetrate tissue and have a therapeutic effect on the patient’s cells. Radioactive applicators containing gamma radiation sources are applied to the surface of the skin or mucous membranes in the desired area. This allows you to achieve a high local concentration of radiation in the affected area, while minimizing the impact on surrounding tissue.
The advantages of gamma application therapy are obvious. Firstly, this method allows you to accurately dose the radiation and direct it to a specific area of the body, which contributes to the most effective effect on the tumor or other affected area. Secondly, gamma radiation has a high penetrating ability, which makes it possible to achieve a deep therapeutic effect even on hard-to-reach tumors.
Gamma application therapy is widely used in oncology. It can be used as a stand-alone treatment or in combination with other methods such as chemotherapy or surgery. It is important to note that gamma application therapy is a minimally invasive procedure, which helps reduce the patient’s recovery time after treatment.
However, like any medical method, gamma application therapy has its limitations and potential side effects. Patients undergoing this procedure must be carefully selected and monitored under constant medical supervision. In some cases, skin reactions may occur at the site where the applicators are applied, as well as common side effects associated with radiotherapy.
In conclusion, gamma application therapy is an innovative treatment method that opens up new prospects in the fight against tumor diseases and other pathologies. Its advantages include precise radiation dosage, localized exposure and high penetrating power of gamma radiation. However, potential limitations and side effects of this method must be considered. Gamma patch therapy requires further research and clinical trials to determine its full effectiveness and safety. In the future, it may become a valuable addition to existing treatments and help improve outcomes in the treatment of various diseases.
Gamma therapy (GT) in oncology is a method of radiation therapy based on the use of radiation sources and the therapeutic use of penetrating radiation to treat malignant tumors or reduce their size. The GT uses: Cs-137 isotope (γ-radiation), Co-60 (γ-, β-radiation) and Ge-67 (β-radiation). GT by dose factors: radiosensitivity of normal tissues up to 0.4–0.5 Gy −1; radiosensitivity of tumors from 0.6 to 2.5 × 10−4 Gy−1, 0.01–0.1 Gy. Dosimetric methods: mainly radiometry of the surfaces of hollow metal blocks; in practice, an approximate logarithmic dosimeter is used.