Radiopharmacology

Radiopharmacology is radiochemistry applied to medicine and thus the pharmacology of radiopharmaceuticals (medicinal radiocompounds, that is, pharmaceutical drugs that are radioactive). Radiopharmaceuticals are used in the field of nuclear medicine as radioactive tracers in medical imaging and in therapy for many diseases (for example, brachytherapy). Many radiopharmaceuticals use technetium-99m (Tc-99m) which has many useful properties as a gamma-emitting tracer nuclide. In the book Technetium a total of 31 different radiopharmaceuticals based on Tc-99m are listed for imaging and functional studies of the brain, myocardium, thyroid, lungs, liver, gallbladder, kidneys, skeleton, blood and tumors. The term radioisotope, which in its general sense refers to any radioactive isotope (radionuclide), has historically been used to refer to all radiopharmaceuticals, and this usage remains common. Technically, however, many radiopharmaceuticals incorporate a radioactive tracer atom into a larger pharmaceutically-active molecule, which is localized in the body, after which the radionuclide tracer atom allows it to be easily detected with a gamma camera or similar gamma imaging device. An example is fludeoxyglucose in which fluorine-18 is incorporated into deoxyglucose. Some radioisotopes (for example gallium-67, gallium-68, and radioiodine) are used directly as soluble ionic salts, without further modification. This use relies on the chemical and biological properties of the radioisotope itself, to localize it within the body. See nuclear medicine. Production of a radiopharmaceutical involves two processes: The production of the radionuclide on which the pharmaceutical is based. The preparation and packaging of the complete radiopharmaceutical. Radionuclides used in radiopharmaceuticals are mostly radioactive isotopes of elements with atomic numbers less than that of bismuth, that is, they are radioactive isotopes of elements that also have one or more stable isotopes.

A concept for the extraction of the most refractory elements at CERN-ISOLDE as carbonyl complex ions

Development of a processing route for carbon allotrope-based TiC porous nanocomposites

The influence of bottom boundary layer hydrodynamics on sediment focusing in a contaminated bay

A concept for the extraction of the most refractory elements at CERN-ISOLDE as carbonyl complex ions

Development of a processing route for carbon allotrope-based TiC porous nanocomposites

The influence of bottom boundary layer hydrodynamics on sediment focusing in a contaminated bay