Yttrium-90 () is a radioactive isotope of yttrium. Yttrium-90 has found a wide range of uses in radiation therapy to treat some forms of cancer.
Decay
undergoes [[β− decay|beta decay]] to zirconium-90 with a half-life of 64.05 hours and a decay energy of 2.28 MeV with an average beta energy of 0.9336 MeV.[Single-photon transition between spin-0 states is never possible. See Selection rule#Angular momentum.] and the normal decay of that state is internal conversion; the alternative of [[pair production]] has been the subject of study for potential use, despite its rarity.
Production
Yttrium-90 is produced by the nuclear decay of strontium-90 which has a half-life of nearly 29 years and is a
fission product of
uranium used in nuclear reactors. As the strontium-90 decays, chemical high-purity separation is used to isolate the yttrium-90 before precipitation.
Yttrium-90 is also directly produced by neutron activation of natural yttrium (
89Y) targets in a nuclear research reactor.
Medical application
90Y plays a significant role in the treatment of hepatocellular carcinoma (HCC),
leukemia, and
lymphoma, although it has the potential to treat a range of tumors.
Trans-arterial radioembolization is a procedure performed by interventional radiologists, in which
90Y
microspheres are injected into the arteries supplying the tumor.
The microspheres come in two forms: resin, in which
90Y is bound to the surface, and glass, in which
90Y is directly incorporated into the microsphere during production.
Once injected, the microspheres become lodged in blood vessels surrounding the tumor and the resulting radiation damages the nearby tissue.
The distribution of the microspheres is dependent on several factors, including catheter tip positioning, distance to branching vessels, rate of injection, properties of particles, like size and density, and variability in tumor perfusion.
Radioembolization with
90Y significantly prolongs time-to-progression (TTP) of HCC,
has a tolerable adverse event profile, and improves patient quality of life more than do similar therapies.
Y has also found uses in tumor diagnosis by imaging the Bremsstrahlung radiation released by the microspheres.
Positron emission tomography after radioembolization is also possible.
Post-treatment imaging
Following treatment with
90Y, imaging is performed to evaluate
90Y delivery and absorption to evaluate coverage of target regions and involvement of normal tissue. This is typically performed using Bremsstrahlung imaging with single-photon emission computed tomography CT (SPECT/CT), or using
90Y position imaging with
PET-CT.
Bremsstrahlung imaging after 90Y therapy
As
90Y undergoes beta decay, broad spectrum
Bremsstrahlung is emitted and is detectable with standard gamma cameras or SPECT.
These modalities provide information about radioactive uptake of
90Y, however, there is poor spatial information.
Consequently, it is challenging to delineate anatomy and thereby evaluate tumor and normal tissue uptake. This led to the development of SPECT/CT, which combines the functional information of SPECT with the spatial information of CT to allow for more accurate
90Y localization.
Positron imaging after 90Y therapy
PET/CT and PET/MRI have superior spatial resolution compared to SPECT/CT because PET detects positron pairs produced from the decay of emitted positrons, negating the requirement for a physical collimator.
This allows for better assessment of microsphere distribution and dose absorption. However, both PET/CT and PET/MRI are less widely available and more costly.
See also
-
Radionuclide therapy
-
Selective internal radiation therapy
External links
