Gallium-68 generator explained

A germanium-68/gallium-68 generator is a device used to extract the positron-emitting isotope 68Ga of gallium from a source of decaying germanium-68. The parent isotope 68Ge has a half-life of 271 days and can be easily utilized for in-hospital production of generator produced 68Ga. Its decay product gallium-68 (with a half-life of only 68 minutes, inconvenient for transport) is extracted and used for certain positron emission tomography nuclear medicine diagnostic procedures, where the radioisotope's relatively short half-life and emission of positrons for creation of 3-dimensional PET scans, are useful.

Parent isotope (68Ge) source

The parent isotope germanium-68 is the longest-lived (271 days) of the radioisotopes of germanium. It has been produced by several methods.[1] In the U.S., it is primarily produced in proton accelerators: At Los Alamos National Laboratory, it may be separated out as a product of proton capture, after proton irradiation of Nb-encapsulated gallium metal.[2] At Brookhaven National Laboratories, 40 MeV proton irradiation of a gallium metal target produces germanium-68 by proton capture and double neutron knockout, from gallium-69 (the most common of two stable isotopes of gallium). This reaction is: 69Ga(p,2n)68Ge.

A Russian source produces germanium-68 from accelerator-produced helium ion (alpha) irradiation of zinc-66, again after knockout of two neutrons, in the nuclear reaction 66Zn(α,2n)68Ge.

Mechanism of generator function

When loaded with the parent isotope germanium-68, these generators function similarly to technetium-99m generators, in both cases using a process similar to ion chromatography. The stationary phase is either metal-free or alumina, TiO2 or SnO2, onto which germanium-68 is adsorbed. The use of metal-free columns allows direct labeling of 68Ga without prepurification, hence making production of gallium-68-radiolabeled compounds more convenient. The mobile phase is a solvent able to elute (wash out) gallium-68 (III) (68Ga3+) after it has been produced by electron capture decay from the immobilized (absorbed) germanium-68.

Currently, such 68Ga (III) is easily eluted with a few mL of 0.05 M, 0.1 M or 1.0 M hydrochloric acid from generators using metal-free tin dioxide[3] or titanium dioxide adsorbents, respectively, within 1 to 2 minutes. With generators of tin dioxide and titanium dioxide-based adsorbents, there once remained more than an hour of pharmaceutical preparation to attach the gallium-68 (III) as a tracer to the pharmaceutical molecules DOTATOC or DOTA-TATE, so that the total preparation time for the resulting radiopharmaceutical is typically longer than the 68Ga isotope half-life. This fact required that these radiopharmaceuticals be made on-site in most cases, and the on-site generator is required to minimize the time losses. However, new kits such as "NETSPOT" for more rapidly preparing Ga-68 edotreotide or DOTATATE from Ga-68 (III) ions have increased the flexibility of sourcing of this radiopharmaceutical for Ga-68 endocrine receptor (octreotide) scans. With NETSPOT the preparation of the Ga-68 DOTATATE is immediate once the Ga-68 has been acquired from the generator and mixed with the reagent. [4]

Indications for gallium-68 PET scanning

See main article: Gallium scan. Gallium-67 citrate salt imaging is useful for imaging old or sterile abscesses. Gallium-68 is useful in direct tumor imaging, especially leukocyte-derived malignancies and prostate cancer metastases.

See also

External links

Notes and References

  1. Web site: Note on Ge-68 production methods in 1996. Accessed March 15, 2010 . March 15, 2010 . June 11, 2011 . https://web.archive.org/web/20110611043400/http://www.med.harvard.edu/JPNM/physics/isotopes/Ge/Ge68/prod.html . dead .
  2. Bach. H. T.. Claytor. T. N.. Hunter. J. F.. Olivas. E. R.. Kelsey. C. T.. Connors. M. A.. Nortier. F. M.. Runde. W. H.. Modrell. C.. Lenz. J. W.. John. K. D.. Improving the survivability of Nb-encapsulated Ga targets for the production of Ge-68. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms. 15 March 2013. 299. 32–41. 10.1016/j.nimb.2013.01.035.
  3. Loc'h . C . Mazièré . B . Comar . D . A new generator for ionic gallium-68 . Journal of Nuclear Medicine . 21 . 2 . 171–3 . 1980 . 6965408 . vanc .
  4. Web site: The Clinical Impact of Utilizing NETSPOT - DMS Health. 19 September 2019.