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  • boron neutron capture therapy is an experimental type of radiotherapy.

  • radiotherapy involves killing cells using ionizing radiation mainly through ionization

  • of cell dna or ionization of water in the cell near the dna forming free radicals which

  • then damage the dna. with the dna damaged the cell dies or loses the ability to reproduce

  • . there are three main types of radiotherap y. external beam radiotherapy uses a beam

  • of radiation such as high energy x-rays gamma rays electron beam or proton beam and focus

  • es it directly at the tumour. sealed source radiotherapy involves placing a radioactive

  • source directly into the body in or next to the tumour through surgery. and finally there

  • is the unsealed source radiotherapy which involves injecting or ingesting a soluble

  • radioactive substance designed to concentrate in tumours.

  • bnct is a distinct type of radiotherapy different from the three main types listed. it is a

  • combination of external beam neutron beam and unsealed source radiotherapy boron-10

  • amplifying the advantages while reducing the disadvantages of the two types.

  • bnct involves injecting a tumour seeking compound tagged with the isotope boron-10 for example

  • sodium tetra-borate borax or sodium boroc aptate. after allowing the substance to concentrate

  • at tumours a beam of epithermal neutrons is directed at this area. capturing a neutron

  • will induce fission in boron-10. the products of fission are an alpha particle and a lithium

  • -6 ion. these will ideally kill the tumour cell.

  • going through each of the component carefully first of all is the neutron beam. the epither

  • mal neutron beam is created from a nuclear reactor usually a small research reactor fuel

  • led from uranium and filtered from other radiation and slowed down into epithermal neutrons through

  • lead aluminium teflon and cadmium. 5 x 10 9 neutron/ cm2-sec then as the neutron beam

  • travels through the human tissue it loses its ke through elastic scattering thermal

  • ization the same way a moderator may slow a neutron down in a nuclear reactor. through

  • the loss of energy it becomes a thermal neutron ideal for the boron-10.

  • the neutron beam should ideally not affect the tissue and only be captured by boron-10

  • . this is unfortunately impossible and other than the scattering of the neutrons giving

  • away ke to the tissue there are several un wanted nuclear reactions which are usually

  • more destructive.

  • these are unlikely as the human body is composed of mainly oxygen carbon hydrogen and nitrogen

  • . out of these oxygen and carbon are very unlikely to capture a neutron as their neutron

  • cross sections are very small.

  • the neutron cross section of an isotope represents the probability of the isotope interacting

  • with the neutron. it is in the units barns b and one barn is 10 to the power of -28 meter

  • square. it is basically how large the cross section of the nuclei should be for the number

  • of neutrons interacted to be true. it has nothing to do with the actual size of the

  • nucleus.

  • the term barn came about when a physicist working on radioactivity found that according

  • to the size of the neutron and the number of neutrons that were captured or interact

  • ed by a uranium atom the cross section of the nucleus should be as big as a barn.

  • thus carbon and oxygen have extremely low neutron cross sections at least 5 to 6 orders

  • of magnitude lower than boron and have little to no chances of undergoing a nuclear reaction

  • . nitrogen and hydrogenon also have very small neutron cross sections 2 to 3 orders of magnitude

  • lower than boron and the nuclear reaction should be unlikely but due to the sheer ny

  • mver of nitrogen and hydrogen atoms they do produce some nuclear reactions.

  • one of this is the neutron proton reaction of nitrogen 14 producing an energetic proton

  • in exchange for capturing the neutron. pause another one is a reaction of hydrogen creating

  • deuterium and gamma rays through fusion. therefore it is important that the boron concentration

  • is very high in tumours so the neutron delivered can be held to a minimum to avoid these un

  • necessary background reactions.

  • now let's have a look at the boron. boron -10 is not radioactive it has a very high

  • neutron capture cross section and () when it captures a thermal neutron it changes to

  • boron-11 for a brief time then fissions. the binding energy produced by this reaction goes

  • into the energetic alpha particle the rec oiling lithium-6 ion and the gamma ray which

  • occurs 94% of the time.

  • the linear energy transfer of the alpha and lithium particles make them ideal. let. the

  • linear energy transfer represents the rate of energy transferred to particles per distance

  • . de/dx. therefore high let means lot of energy is given but since more energy is lost at

  • the same time it cannot go very far. the alpha particle and the lithium ion have very high

  • linear energy transfer and their path length how far they () travel before stopping is

  • smaller than the diameter of a tumour cell . this means assuming the boron has been deposit

  • ed in or next to the tumour cell it should only attack the cell and will do little damage

  • to normal cells.

  • overall bnct is a binary therapy involving neutron radiation and boron-10. unlike the

  • external beam therapy it is not limited to the surface nor does the radiation dose have

  • to increase increasing the background dose if the targeted tumour is not at near the

  • surface. unlike sealed source it is non-invasive and the radiation exposure can be controlled

  • . the biological compound injected is initially non-radioactive and safe unlike unsealed radi

  • otherapy.

  • due to these advantages there is one particular type of cancer glioblastoma multiforme gbm

  • that bnct is particularly effective against . gbm was in fact one the main reasons why

  • bnct was developed. as it is a brain tumour it is severely affected by the high background

  • radiation of external beam radiotherapy. sealed source radiotherapy cannot be used as surgery

  • is very risky.

  • however bnct is still in the development phase . there are several issues that must be address

  • ed. one of this is the lack of effective tum our seeking compounds. another issue is the

  • need of a nuclear reactor. this makes it difficult to treat the patients and a compact neutron

  • accelerator must be developed.

  • bnct being a binary therapy is an important factor. binary therapy signifies there are

  • two components that can be adjusted thus many more variables are involved compared to other

  • therapy. this is both an advantage and a weakness . the sheer number of variables means at the

  • beginning of development it takes much more time to develop and find the optimum values

  • . however at the end of the day they will have more flexibility and potential than other

  • forms raditherapy and will prove its worth .

boron neutron capture therapy is an experimental type of radiotherapy.

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B2 中上級

BNCTの基本的な説明 (A basic explanation of BNCT)

  • 28 2
    龔祈 に公開 2021 年 01 月 14 日
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