Editing Neutron (section)

== Medical therapies ==
{{Main|Fast neutron therapy|Neutron capture therapy of cancer}}
Because neutron radiation is both penetrating and ionizing, it can be exploited for medical treatments. However, neutron radiation can have the unfortunate side-effect of leaving the affected area radioactive. [[Neutron tomography]] is therefore not a viable medical application.

Fast neutron therapy uses high-energy neutrons typically greater than 20 MeV to treat cancer. [[Radiation therapy]] of cancers is based upon the biological response of cells to ionizing radiation. If radiation is delivered in small sessions to damage cancerous areas, normal tissue will have time to repair itself, while tumor cells often cannot.<ref>{{Cite book |last=Hall |first=Eric J. |url=https://www.worldcat.org/oclc/43854159 |title=Radiobiology for the radiologist |date=2000 |publisher=Lippincott Williams & Wilkins |isbn=0-7817-2649-2 |edition=5th |location=Philadelphia |oclc=43854159 |access-date=2023-03-11 |archive-date=2024-05-12 |archive-url=https://web.archive.org/web/20240512232112/https://search.worldcat.org/title/43854159 |url-status=live }}</ref> Neutron radiation can deliver energy to a cancerous region at a rate an order of magnitude larger than [[gamma radiation]].<ref>Johns HE and Cunningham JR (1978). ''The Physics of Radiology''. Charles C Thomas 3rd edition</ref>

Beams of low-energy neutrons are used in [[neutron capture therapy of cancer|boron neutron capture therapy]] to treat cancer. In boron neutron capture therapy, the patient is given a drug that contains boron and that preferentially accumulates in the tumor to be targeted. The tumor is then bombarded with very low-energy neutrons (although often higher than thermal energy) which are captured by the [[boron-10]] isotope in the boron, which produces an excited state of boron-11 that then decays to produce [[lithium-7]] and an [[alpha particle]] that have sufficient energy to kill the malignant cell, but insufficient range to damage nearby cells. For such a therapy to be applied to the treatment of cancer, a neutron source having an intensity of the order of a thousand million (10<sup>9</sup>) neutrons per second per cm<sup>2</sup> is preferred. Such fluxes require a research nuclear reactor.