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An activity quantification method based on registration of CT and whole-body scintillation camera images, with application to 131I.

Sjögreen Gleisner, Katarina LU ; Ljungberg, Michael LU and Strand, Sven-Erik LU (2002) In Journal of Nuclear Medicine 43(7). p.972-982
Abstract
This article presents a new method for conjugate view activity quantification for 131I-labeled monoclonal antibody distribution. METHODS: The method is based on the combined use of images from 3 modalities: whole-body (WB) scintillation camera scanning, WB transmission scanning using 57Co, and CT. All images are coaligned using a recently developed program for the registration of WB images. Corrections for attenuation, scatter, and septal penetration are performed in image space. Compensation for scatter and septal penetration is performed by deconvolution, using point-response functions determined from Monte Carlo simulations. Attenuation correction is performed by applying a patient-specific 364-keV narrow-beam attenuation map obtained... (More)
This article presents a new method for conjugate view activity quantification for 131I-labeled monoclonal antibody distribution. METHODS: The method is based on the combined use of images from 3 modalities: whole-body (WB) scintillation camera scanning, WB transmission scanning using 57Co, and CT. All images are coaligned using a recently developed program for the registration of WB images. Corrections for attenuation, scatter, and septal penetration are performed in image space. Compensation for scatter and septal penetration is performed by deconvolution, using point-response functions determined from Monte Carlo simulations. Attenuation correction is performed by applying a patient-specific 364-keV narrow-beam attenuation map obtained by combining information from the CT and the transmission scan. A relationship is presented for the conversion of the CT numbers to mass density. The attenuation- and scatter-compensated image is converted from counts to activity using a sensitivity value that was determined for 364-keV photons in air. This activity projection image is then analyzed for the activity of volumes of interest (VOI) using 2-dimensional regions of interest (ROIs) that are determined from the CT study. The CT is first resliced into coronal slices, and a maximum-extension ROI is outlined that encloses the VOI. Compensation for background activity and overlapping organs is performed on the basis of total patient thickness in the projection line, and on precalculated organ- background thickness fractions. RESULTS: Method evaluation was performed using data from both experimental measurements and Monte Carlo simulations. The use of an attenuation map derived directly from the CT study was also evaluated. For organ activity quantification, an accuracy of > or =10% was obtained. For small-diameter tumors, deviations were larger because of lack of correction for the background-dependent partial-volume effect. CONCLUSION: Registration of CT and WB scintillation camera images was successfully applied to improve activity quantification by the conjugate view method. (Less)
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Contribution to journal
publication status
published
subject
keywords
Monte Carlo Method, Radiometry, Tomography, Non-U.S. Gov't, Support, Cobalt Radioisotopes : diagnostic use, Iodine Radioisotopes : diagnostic use, X-Ray Computed, Image Processing, Computer-Assisted, Monoclonal : diagnostic use, Human, Antibodies
in
Journal of Nuclear Medicine
volume
43
issue
7
pages
972 - 982
publisher
Society of Nuclear Medicine
external identifiers
  • wos:000176853400028
  • scopus:0036301356
ISSN
0161-5505
language
English
LU publication?
yes
id
0cf6af4b-474a-4f7f-928e-74344699bdfb (old id 109126)
alternative location
http://jnm.snmjournals.org/cgi/content/full/43/7/972
http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&list_uids=12097471&dopt=Abstract
date added to LUP
2016-04-01 16:28:31
date last changed
2022-03-30 08:08:58
@article{0cf6af4b-474a-4f7f-928e-74344699bdfb,
  abstract     = {{This article presents a new method for conjugate view activity quantification for 131I-labeled monoclonal antibody distribution. METHODS: The method is based on the combined use of images from 3 modalities: whole-body (WB) scintillation camera scanning, WB transmission scanning using 57Co, and CT. All images are coaligned using a recently developed program for the registration of WB images. Corrections for attenuation, scatter, and septal penetration are performed in image space. Compensation for scatter and septal penetration is performed by deconvolution, using point-response functions determined from Monte Carlo simulations. Attenuation correction is performed by applying a patient-specific 364-keV narrow-beam attenuation map obtained by combining information from the CT and the transmission scan. A relationship is presented for the conversion of the CT numbers to mass density. The attenuation- and scatter-compensated image is converted from counts to activity using a sensitivity value that was determined for 364-keV photons in air. This activity projection image is then analyzed for the activity of volumes of interest (VOI) using 2-dimensional regions of interest (ROIs) that are determined from the CT study. The CT is first resliced into coronal slices, and a maximum-extension ROI is outlined that encloses the VOI. Compensation for background activity and overlapping organs is performed on the basis of total patient thickness in the projection line, and on precalculated organ- background thickness fractions. RESULTS: Method evaluation was performed using data from both experimental measurements and Monte Carlo simulations. The use of an attenuation map derived directly from the CT study was also evaluated. For organ activity quantification, an accuracy of > or =10% was obtained. For small-diameter tumors, deviations were larger because of lack of correction for the background-dependent partial-volume effect. CONCLUSION: Registration of CT and WB scintillation camera images was successfully applied to improve activity quantification by the conjugate view method.}},
  author       = {{Sjögreen Gleisner, Katarina and Ljungberg, Michael and Strand, Sven-Erik}},
  issn         = {{0161-5505}},
  keywords     = {{Monte Carlo Method; Radiometry; Tomography; Non-U.S. Gov't; Support; Cobalt Radioisotopes : diagnostic use; Iodine Radioisotopes : diagnostic use; X-Ray Computed; Image Processing; Computer-Assisted; Monoclonal : diagnostic use; Human; Antibodies}},
  language     = {{eng}},
  number       = {{7}},
  pages        = {{972--982}},
  publisher    = {{Society of Nuclear Medicine}},
  series       = {{Journal of Nuclear Medicine}},
  title        = {{An activity quantification method based on registration of CT and whole-body scintillation camera images, with application to 131I.}},
  url          = {{http://jnm.snmjournals.org/cgi/content/full/43/7/972}},
  volume       = {{43}},
  year         = {{2002}},
}