Phantom validation of quantitative Y-90 PET/CT-based dosimetry in liver radioembolization
Background PET/CT has recently been shown to be a viable alternative to traditional post-infusion imaging methods providing good quality images of 90 Y-laden microspheres after selective internal radiation therapy (SIRT). In the present paper, first we assessed the quantitative accuracy of 90 Y-PET...
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Veröffentlicht in: | EJNMMI research 2017-11, Vol.7 (1), p.94-15, Article 94 |
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Sprache: | eng |
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Zusammenfassung: | Background
PET/CT has recently been shown to be a viable alternative to traditional post-infusion imaging methods providing good quality images of
90
Y-laden microspheres after selective internal radiation therapy (SIRT). In the present paper, first we assessed the quantitative accuracy of
90
Y-PET using an anthropomorphic phantom provided with lungs, liver, spine, and a cylindrical homemade lesion located into the hepatic compartment. Then, we explored the accuracy of different computational approaches on dose calculation, including (I) direct Monte Carlo radiation transport using Raydose, (II) Kernel convolution using Philips Stratos, (III) local deposition algorithm, (IV) Monte Carlo technique (MCNP) considering a uniform activity distribution, and (V) MIRD (Medical Internal Radiation Dose) analytical approach. Finally, calculated absorbed doses were compared with those obtained performing measurements with LiF:Mg,Cu,P TLD chips in a liquid environment.
Results
Our results indicate that despite
90
Y-PET being likely to provide high-resolution images, the
90
Y low branch ratio, along with other image-degrading factors, may produce non-uniform activity maps, even in the presence of uniform activity. A systematic underestimation of the recovered activity, both for the tumor insert and for the liver background, was found. This is particularly true if no partial volume correction is applied through recovery coefficients. All dose algorithms performed well, the worst case scenario providing an agreement between absorbed dose evaluations within 20%. Average absorbed doses determined with the local deposition method are in excellent agreement with those obtained using the MIRD and the kernel-convolution dose calculation approach.
Finally, absorbed dose assessed with MC codes are in good agreement with those obtained using TLD in liquid solution, thus confirming the soundness of both calculation approaches. This is especially true for Raydose, which provided an absorbed dose value within 3% of the measured dose, well within the stated uncertainties.
Conclusions
Patient-specific dosimetry is possible even in a scenario with low true coincidences and high random fraction, as in
90
Y–PET imaging, granted that accurate absolute PET calibration is performed and acquisition times are sufficiently long. Despite Monte Carlo calculations seeming to outperform all dose estimation algorithms, our data provide a strong argument for encouraging the use of the local depositio |
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ISSN: | 2191-219X 2191-219X |
DOI: | 10.1186/s13550-017-0341-9 |