Particle therapy

Carbon ion therapy (C-ion RT) uses particles more massive than protons or neutrons. Carbon ion radiotherapy has increasingly garnered scientific attention as technological delivery options have improved and clinical studies have demonstrated its treatment advantages for many cancers such as prostate, head and neck, lung, and liver cancers, bone and soft tissue sarcomas, locally recurrent rectal cancer, and pancreatic cancer, including locally advanced disease. It also has clear advantages to treat otherwise intractable hypoxic and radio-resistant cancers while opening the door for substantially hypo-fractionated treatment of normal and radio-sensitive disease.

By mid 2017, more than 15,000 patients have been treated worldwide in over 8 operational centers. Japan has been a conspicuous leader in this field. There are five heavy-ion radiotherapy facilities in operation and plans exist to construct several more facilities in the near future. In Germany this type of treatment is available at the Heidelberg Ion-Beam Therapy Center (HIT) and at the Marburg Ion-Beam Therapy Center (MIT). In Italy the National Centre of Oncological Hadrontherapy (CNAO) provides this treatment. Austria will open a CIRT center in 2017, with centers in South Korea, Taiwan, and China soon to open. No CIRT facility now operates in the United States but several are in various states of development.^[13]

Biological advantages of heavy-ion radiotherapy

From a radiation biology standpoint, there is considerable rationale to support use of heavy-ion beams in treating cancer patients. All proton and other heavy ion beam therapies exhibit a defined Bragg peak in the body so they deliver their maximum lethal dosage at or near the tumor. This minimizes harmful radiation to the surrounding normal tissues. However, carbon-ions are heavier than protons and so provide a higher relative biological effectiveness (RBE), which increases with depth to reach the maximum at the end of the beam's range. Thus the RBE of a carbon ion beam increases as the ions advance deeper into the tumor-lying region.^[14] CIRT provides the highest linear energy transfer (LET) of any currently available form of clinical radiation.^[15] This high energy delivery to the tumor results in many double-strand DNA breaks which are very difficult for the tumor to repair. Conventional radiation produces principally single strand DNA breaks which can allow many of the tumor cells to survive. The higher outright cell mortality produced by CIRT may also provide a clearer antigen signature to stimulate the patient's immune system.^[16][17]

Particle therapy of moving targets

The precision of particle therapy of tumors situated in thorax and abdominal region is strongly affected by the target motion. The mitigation of its negative influence requires advanced techniques of tumor position monitoring (e.g., fluoroscopic imaging of implanted radio-opaque fiducial markers or electromagnetic detection of inserted transponders) and irradiation (gating, rescanning, gated rescanning and tumor tracking).^[18]

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