“Unsealed source radiotherapy”的意思、由来-开放百科全书

As such, this is a type of targeted therapy which uses the physical, chemical and biological properties of the radiopharmaceutical to target areas of the body for radiation treatment.^[3] The related diagnostic modality of nuclear medicine employs the same principles but uses different types or quantities of radiopharmaceuticals in order to image or analyse functional systems within the patient.

RNT contrasts with sealed-source therapy (brachytherapy) where the radionuclide remains in a capsule or metal wire during treatment and needs to be physically placed precisely at the treatment position.^[4]

Clinical use

Iodine-131

Most of the iodine not taken up by thyroid tissue is excreted through the kidneys into the urine. After radioiodine treatment the urine will be radioactive or 'hot', and the patients themselves will also emit gamma radiation. Depending on the amount of radioactivity administered, it can take several days for the radioactivity to reduce to the point where the patient does not pose a radiation hazard to bystanders. Patients are often treated as inpatients and there are international guidelines, as well as legislation in many countries, which govern the point at which they may return home.^[7]

MIBG

Bone metastasis

Phosphorus-32

Yttrium-90

⁹⁰Y colloid

An yttrium-90 (⁹⁰Y) colloidal suspension is used for radiosynovectomy in the knee joint.^[16]

⁹⁰Y spheres

Experimental antibody based methods

At the Institute for Transuranium Elements (ITU) work is being done on alpha-immunotherapy, this is an experimental method where antibodies bearing alpha isotopes are used. Bismuth-213 is one of the isotopes which has been used. This is made by the alpha decay of Ac-225. The generation of one short-lived isotope from longer lived isotope is a useful method of providing a portable supply of a short-lived isotope. This is similar to the generation of technetium-99m by a technetium generator. The actinium-225 is made by the irradiation of radium-226 with a cyclotron.^[18]

References

1. ^{{cite journal|last1=Buscombe|first1=J.|last2=Navalkissoor|first2=S.|title=Molecular radiotherapy|journal=Clinical Medicine|date=1 August 2012|volume=12|issue=4|pages=381–386|doi=10.7861/clinmedicine.12-4-381|pmid=22930888|pmc=4952132|doi-access=free}}
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6. ^{{cite book|last1=IAEA|title=Manual on therapeutic uses of iodine-131|date=1996|publisher=International Atomic Energy Agency|location=Vienna|page=7|url=http://www.iaea.org/inis/collection/NCLCollectionStore/_Public/28/027/28027984.pdf}}
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9. ^{{cite journal|last1=Den|first1=RB|last2=Doyle|first2=LA|last3=Knudsen|first3=KE|title=Practical guide to the use of radium 223 dichloride.|journal=The Canadian Journal of Urology|date=April 2014|volume=21|issue=2 Supp 1|pages=70–6|pmid=24775727}}
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