Quantitation in PET using isotopes emitting prompt single gammas: application to yttrium-86

Several yttrium-90 labelled somatostatin analogues are now available for cancer radiotherapy. After injection, a large amount of the compound is excreted via the urinary tract, while a variable part is trapped in the tumour(s), allowing the curative effect. Unfortunately, the compound may also be tr...

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Bibliographic Details
Published in:European journal of nuclear medicine and molecular imaging 2003-03, Vol.30 (3), p.354-361
Main Authors: WALRAND, Stéphan, JAMAR, Francois, MATHIEU, Isabelle, CAMPS, Joëlle, LONNEUX, Max, SIBOMANA, Mérence, LABAR, Daniel, MICHEL, Christian, PAUWELS, Stanislas
Format: Article
Language:English
Subjects:
Algorithms
Biological and medical sciences
Gamma Rays
Humans
Investigative techniques, diagnostic techniques (general aspects)
Maximum Allowable Concentration
Medical sciences
Miscellaneous. Technology
Models, Biological
Neoplasms - diagnostic imaging
Neoplasms - metabolism
Neoplasms - radiotherapy
Organ Specificity
Quality Control
Radionuclide investigations
Radiopharmaceuticals - pharmacokinetics
Radiopharmaceuticals - urine
Radiotherapy Dosage
Receptors, Somatostatin - metabolism
Tissue Distribution
Tomography, Emission-Computed - methods
Tomography, Emission-Computed - standards
Whole-Body Counting - instrumentation
Whole-Body Counting - methods
Yttrium Radioisotopes - pharmacokinetics
Yttrium Radioisotopes - therapeutic use
Yttrium Radioisotopes - urine
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Summary:Several yttrium-90 labelled somatostatin analogues are now available for cancer radiotherapy. After injection, a large amount of the compound is excreted via the urinary tract, while a variable part is trapped in the tumour(s), allowing the curative effect. Unfortunately, the compound may also be trapped in critical tissues such as kidney or bone marrow. As a consequence, a method for assessment of individual biodistribution and pharmacokinetics is required to predict the maximum dose that can be safely injected into patients. However, (90)Y, a pure beta(-)particle emitter, cannot be used for quantitative imaging. Yttrium-86 is a positron emitter that allows imaging of tissue uptake using a PET camera. In addition to the positron, (86)Y also emits a multitude of prompt single gamma-rays, leading to significant overestimation of uptake when using classical reconstruction methods. We propose a patient-dependent correction method based on sinogram tail fitting using an (86)Y point spread function library. When applied to abdominal phantom acquisition data, the proposed correction method significantly improved the accuracy of the quantification: the initial overestimation of background activity by 117% was reduced to 9%, while the initial error in respect of kidney uptake by 84% was reduced to 5%. In patient studies, the mean discrepancy between PET total body activity and the activity expected from urinary collections was reduced from 92% to 7%, showing the benefit of the proposed correction method.
ISSN:1619-7070
1619-7089
DOI:10.1007/s00259-002-1068-y