SU671194A1 - Method of preparing iodine-123 - Google Patents

Description

(5.4) METHOD OF OBTAINING IODA-123

This invention relates to the field of applied radiochemistry, in particular to the manufacture of radioactive drugs for medicine. The known method of obtaining iodine-1 by irradiating a 78 MeV deuteron beam of a target from sodium iodide powder, which is formed when xenon is irradiated with a halo current, is removed from the target, absorbed at a low temperature in a coal trap, desorb xenon-123 by heating the trap and condense it in a cooled ampoule, where xenon-123 decomposes to form iodine-123, which is then removed by flushing with water or organic solution 1. The closest to the described method to the technical essence and the achieved result is the method of obtaining iodine-123 beam irradiation with C, -particles with energy of 42 MeV from a target rich in tellurium-1 tellurium. The gels formed during irradiation with xenon are extracted from the target, the gas stream is passed through a system of cooled traps, the trap with xenon-123 is held for 6 hours to convert xenon to iodine-123 and iodine is washed off with an aqueous or organic solution 2. The radiochemical purity of the product obtained is 99, 6%. The disadvantage of this method is that it is necessary to use unique cyclotrons for obtaining iodine-123, which are hardly available for practical use. The aim of the invention is to simplify the technology for the recovery of iodine-123. This goal is achieved by using for irradiation a target from a natural or xenon-124 enriched xenon beam bremsstrahlung of an electron accelerator with an energy of 20-25 MeV. At the same time, xenon-123 is obtained by the reaction of (, D) Xe, and after holding for 6 hours to convert Xe to remove the remaining xenon, the 123-iodine formed is washed off with an aqueous or organic solution. The technological yield of iodine-123 is 95%, the radionuclide purity is 98.8%. The technological yield of 3-123 in this method remains unchanged when using xenon from natural or Xe-enriched target for irradiation, however, the activity of iodine-123 per unit of weight (or volume) of xenon differs depending on. from the degree of enrichment of xenon xenon -124. In particular, when xenon containing 3-4.5% xenon-124 is irradiated, the yield of iodine-123 per unit weight of the target increases by 30-45 times, ceteris paribus.

Example. The sealed quartz ampoule / containing natural xenon is irradiated with a 20 MeV bremsstrahlung beam in an electron accelerator. After irradiation, the gt pool is kept bh, then opened and iodine-123 is washed off with a weak alkali solution. The technological yield of iodine-123 is 95%, the admixture of iodine-12 is 0.2%, the content of other radioactive impurities does not exceed 10%.

EXAMPLE 2. A sealed quartz ampoule containing Xe-enriched xenon is irradiated with a 25 MeV electron beam accelerator beam. The ampoule is displaced into a vacuum unit; the setup is pumped out to 10 mm Hg. Art. and open the ampoule. Xenon124 is frozen in a trap cooled with liquid nitrogen. The ampoule is disconnected from the vacuum unit and after the conversion of xenon-123 to iodine-123, the latter is washed off the walls with a weak solution of an organic solvent. Technological yield 5 iodine-123 95%, admixture of iodine-125 2%, the remaining impurities are not more. Xenon-124 can be reused.

Claims (1)

Invention Formula The method of obtaining iodine-123 by irradiating a mi containing a substance capable of nuclear transformations with the formation of xenon-123,: after ci4 4, the release of the isotope of iodine-123, characterized in that, in order to simplify the technology of iodine-123 emission, the beam irradiation of electron radiation the accelerator is subjected to a target of natural or xenon enriched in xenn-124. Sources of information taken into account in the examination l.3nt-Z.Arre.Radiation etna asot. 25, 1974, 535-543. 2. 3nt I Appt. Kadliatiovi 24, 1973, 173-177. (Prototype).