Technetium-99m Generator

A technetium-99m generator, or colloquially a technetium cow or moly cow, is a device used to extract the metastable isotope ^99mTc of technetium from a decaying sample of molybdenum-99. ⁹⁹Mo has a half-life of 66 hours and can be easily transported over long distances to hospitals where its decay product technetium-99m (with a half-life of only 6 hours, inconvenient for transport) is extracted and used for a variety of nuclear medicine diagnostic procedures, where its short half-life is very useful.

Parent isotope source

⁹⁹Mo can be obtained by the neutron activation (n,γ reaction) of ⁹⁸Mo in a high- neutron-flux reactor. However, the most frequently used method is through fission of uranium-235 in a nuclear reactor. While most reactors currently engaged in ⁹⁹Mo production use highly enriched uranium-235 targets, proliferation concerns have prompted some producers to transition to low-enriched uranium targets. The target is irradiated with neutrons to form ⁹⁹Mo as a fission product (with 6.1% yield). Molybdenum-99 is then separated from unreacted uranium and other fission products in a hot cell.

Generator invention and history

^99mTc remained a scientific curiosity until the 1950s when Powell Richards realized the potential of technetium-99m as a medical radiotracer and promoted its use among the medical community. While Richards was in charge of the radioisotope production at the Hot Lab Division of the Brookhaven National Laboratory, Walter Tucker and Margaret Greene were working on how to improve the separation process purity of the short-lived eluted daughter product iodine-132 from tellurium-132, its 3.2-days parent, produced in the Brookhaven Graphite Research Reactor. They detected a trace contaminant which proved to be ^99mTc, which was coming from ⁹⁹Mo and was following tellurium in the chemistry of the separation process for other fission products. Based on the similarities between the chemistry of the tellurium-iodine parent-daughter pair, Tucker and Greene developed the first technetium-99m generator in 1958. It was not until 1960 that Richards became the first to suggest the idea of using technetium as a medical tracer.

Generator function and mechanism

Technetium-99m's short half-life of 6 hours makes long-term storage impossible. Transport of ^99mTc from the limited number of production sites to radio pharmacies (for manufacture of specific radiopharmaceuticals) and other end users would be complicated by the need to significantly overproduce to have sufficient remaining activity after long journeys. Instead, the longer-lived parent nuclide ⁹⁹Mo can be supplied to radio pharmacies in a generator, after its extraction from the neutron-irradiated uranium targets and its purification in dedicated processing facilities. Radio pharmacies may be hospital-based or stand-alone facilities, and in many cases will subsequently distribute ^99mTc radiopharmaceuticals to regional nuclear medicine departments. Development in direct production of ^99mTc, without first producing the parent ⁹⁹Mo, precludes the use of generators; however, this is uncommon and relies on suitable production facilities close to radio pharmacies.

Production

Generators provide radiation shielding for transport and to minimize the extraction work done at the medical facility. A typical dose rate at 1 metre from ^99mTc generator is 20–50 μSv/h during transport.

These generators' output declines with time and must be replaced weekly, since the half-life of ⁹⁹Mo is still only 66 hours. Since the half-life of the parent nuclide (⁹⁹Mo) is much longer than that of the daughter nuclide (^99mTc), 50% of equilibrium activity is reached within one daughter half-life, 75% within two daughter half-lives. Hence, removing the daughter nuclide ( elution process) from the generator ("milking" the cow) is reasonably done as often as every 6 hours in a ⁹⁹Mo/^99mTc generator.

Separation

Most commercial ⁹⁹Mo/^99mTc generators use column chromatography, in which ⁹⁹Mo in the form of molybdate, MoO₄^2− is adsorbed onto acid alumina (Al₂O₃). When the ⁹⁹Mo decays it forms pertechnetate TcO₄^−, which, because of its single charge, is less tightly bound to the alumina. Pouring normal saline solution through the column of immobilized ⁹⁹Mo elutes the soluble ^99mTc, resulting in a saline solution containing the ^99mTc as pertechnetate, with sodium as the counterion.

The solution of sodium pertechnetate may then be added in an appropriate concentration to the pharmaceutical kit to be used, or sodium pertechnetate can be used directly without pharmaceutical tagging for specific procedures requiring only the ^99mTcO₄^− as the primary radiopharmaceutical. A large percentage of the ^99mTc generated by a ⁹⁹Mo/^99mTc generator is produced in the first 3 parent half-lives, or approximately one week. Hence, clinical nuclear medicine units purchase at least one such generator per week or order several in a staggered fashion.

Isomeric ratio

When the generator is left unused, ⁹⁹Mo decays to ^99mTc, which in turn decays to ⁹⁹Tc. The half-life of ⁹⁹Tc is far longer than its metastable isomer, so the ratio of ⁹⁹Tc to ^99mTc increases over time. Both isomers are carried out by the elution process and react equally well with the ligand, but the ⁹⁹Tc is an impurity useless to imaging (and cannot be separated).

The generator is washed of ⁹⁹Tc and ^99mTc at the end of the manufacturing process of the generator, but the ratio of ⁹⁹Tc to ^99mTc then builds up again during transport or any other period when the generator is left unused. The first few elutions will have reduced effectiveness because of this high ratio.

References

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Radiopharmaceuticals
Radioactivity
Technetium-99m
Medical physics