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Copper radionuclides

Somatostatin Analogs Labeled with Copper Radionuclides. 185... [Pg.179]

Blower P J, Lewis J S, Zweit J (1996). Copper radionuclides and radiopharmaceuticals in nuclear medicine. Nucl. Med. Biol. 23 957-980. [Pg.939]

Copper radionuclides are promising candidates for both PET imaging... [Pg.10]

Different samples of aqueous solution containing radionuclides of Co and Eu were prepared at different copper sulphate concentrations and constant polymer concentrations (pAM) of 15 mg/1. The addition of salt to the system was done to reduce both the repulsion forces between the radionuclides and the interaction between the polymeric chains [7]. The polymer efficiency for the prepared samples was determined, results are shown in Fig. 15. It is clear that the polymer efficiency for Eu " is higher than for Co. This can be explained by the difference in the tightly bound structured water associated with different cationic species [14,107]. On this basis, we expect that Co is more hydrated than Eu. This is due to the difference in the ionic size. The hydra-... [Pg.130]

Researchers at BNL claim that this technology may be used to extract metals such as cadmium, arsenic, lead, zinc, copper, magnesium, manganese, aluminum, barium, nickel, and chromium, as well as radionuclides such as uranium, thorium, plutonium, cobalt, cesium, and strontium. They state that the process offers the following advantages ... [Pg.425]

According to the technology developer, geochemical fixation can treat dissolved hexavalent chromium and other metals in groundwater at concentrations ranging from the detection limit to several hundred parts per milhon. The developer asserts that geochemical attenuation can treat most of the common heavy metals, trace elements, and namral radionuclides that occur in groundwater, such as metal-cyanide complexes, arsenic, cadmium, chromium, copper, lead, selenium, uranium, and radium. [Pg.1030]

The radionuclides commercially available and most commonly used for a number of the foregoing applications include anhmony-125 banum-133, 207 bismuth-207 bromine-82 cadmium-109, 115 m calcium-45 carbon-14 cerium-141 cesium-134, 137 chlorine-36 chromium-51 cobalt-57, 58, 60 copper-64 gadolimum-153 germanium-68 gold-195. 198 hydrogen-3 (tritium) indium-111, 114 m iodine-125, 129, 131 iron-55, 59 krypton-85 manganese-54 mercury-203 molvbdenum-99 nickel-63 phosphorus-32. 33 potassium-42 promethium-147 rubidium-86 ruthenium-103 samarium-151 scandium-46 selenium-75 silver-110 m sodium-22, strontium-85 sulfur-35 technetium-99 thallium-204 thulium-171 tin-113, 119 m, 121 m. titamum-44 ytterbium-169, and zinc-65. [Pg.1410]

A discussion of the coincidence technique with some general applications has been published by Wahlgren, Wing and Hines 71>. Many of the early applications of the technique made use of the fact that 64Cu is one of the few radionuclides produced by thermal neutron irradiation for which the 0.511 MeV positron annihilation photopeak is a prominent feature of the spectrum. Copper has been determined in meteorites 72> and copper ores 73,74) ]-,y coincidence counting of 04Cu annihilation radiation. The rapid and selective nature of the determination may have important applications in the on-line sorting of copper ores. [Pg.79]

Sulfate reduction permeable reactive barriers to treat acidity, cadmium, copper, nickel, and zinc two case studies. In Handbook of Groundwater Remediation Using Permeable Reactive Barriers—Applications to Radionuclides, Trace Metals, and Nutrients (eds. D. L. Naftz, S. J. Morrison, J. A. Davis, and C. C. Puller). Academic Press, San Diego, CA, pp. 495-522. [Pg.4742]

The metals (excluding radionuclides) currently identified for regulation under RCRA/SDWA are listed in Table I. The original list of 13 metals was defined in the 1986 revision of the SDWA. These Include two group II metals (barium and beryllium), eight transition metals (cadmium, chromium, copper, lead, mercury, nickel, silver, and thallium), and three near-transltlon metals (selenium, arsenic, and antimony). [Pg.11]

The choice of therapeutic radionuclide will depend upon a combination of theoretical concepts such as half-life, mode and energy of particulate emission, as well as more practical issues such as cost and availability. Copper-67, for example, has an excellent profile of physical decay characteristics (half-life 2.6 d beta emissions 580 keV, gamma emissions 185 keV) but is very... [Pg.258]


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See also in sourсe #XX -- [ Pg.916 ]




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