Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations

Nicolas A. Karakatsanis; Martin A. Lodge; Hassan Mohy-Ud-Din; A. K. Tahari; Yun Zhou; Richard L. Wahl; Arman Rahmim

doi:10.1109/NSSMIC.2012.6551920

Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations

Nicolas A. Karakatsanis, Martin A. Lodge, Hassan Mohy-Ud-Din, A. K. Tahari, Yun Zhou, Richard L. Wahl, Arman Rahmim

School of Medicine

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

4 Scopus citations

Abstract

Whole body PET/CT, a well established imaging method in nuclear medicine for the clinical evaluation of a wide variety of metastatic cancer malignancies, commonly involves static scanning over multiple beds. Recently, we proposed a clinically feasible transition of whole-body PET/CT imaging to the dynamic domain, by acquiring (i) an initial 6min dynamic scan over the heart, followed by (ii) an optimized sequence of whole-body PET scans, allowing for quantitative whole body parametric imaging. Comparative evaluation of parametric and SUV images indicated enhanced contrast-to-noise ratio (CNR) but also higher noise for the parametric images. The objective of this study is to further improve parametric image CNR to enhance tumor detectability, by limiting noise in the estimates, while enhancing contrast and quantitative accuracy of parametric images. For this purpose, we utilize the weighted correlation coefficient (WR) of the kinetic model (Patlak) fits at each voxel to determine the cluster of voxels, where (i) advanced, as opposed to conventional, statistical parameter estimation, (ii) spatial smoothing or (iii) thresholding is applied. Thus, we facilitate the integration of whole body parametric imaging into the clinic as a competitive alternative to SUV. Through quantitative analysis on selected tumor regions of the resulting images, we show enhanced CNR when ridge regression is applied only to voxels associated with high WR, while ordinary least squares (OLS) and WR driven post-smoothing is performed to the rest. This hybrid regression method yields reduced mean squared error in tumor regions, compared to OLS. In addition, by setting the WR threshold level in the range [0.85 0.9], CNR is further enhanced for tumor regions of high WR. Finally, for the same type of tumors, hybrid regression also achieves higher CNR, compared to SUV, when the last two dynamic frames are omitted, allowing for shorter acquisition times.

Original language	English (US)
Title of host publication	2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012
Pages	4017-4027
Number of pages	11
DOIs	https://doi.org/10.1109/NSSMIC.2012.6551920
State	Published - 2012
Event	2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012 - Anaheim, CA, United States Duration: Oct 29 2012 → Nov 3 2012

Publication series

Name	IEEE Nuclear Science Symposium Conference Record
ISSN (Print)	1095-7863

Other

Other	2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012
Country/Territory	United States
City	Anaheim, CA
Period	10/29/12 → 11/3/12

ASJC Scopus subject areas

Radiation
Nuclear and High Energy Physics
Radiology Nuclear Medicine and imaging

Access to Document

10.1109/NSSMIC.2012.6551920

Cite this

Karakatsanis, N. A., Lodge, M. A., Mohy-Ud-Din, H., Tahari, A. K., Zhou, Y., Wahl, R. L., & Rahmim, A. (2012). Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations. In 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012 (pp. 4017-4027). Article 6551920 (IEEE Nuclear Science Symposium Conference Record). https://doi.org/10.1109/NSSMIC.2012.6551920

Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations. / Karakatsanis, Nicolas A.; Lodge, Martin A.; Mohy-Ud-Din, Hassan et al.
2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012. 2012. p. 4017-4027 6551920 (IEEE Nuclear Science Symposium Conference Record).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Karakatsanis, NA, Lodge, MA, Mohy-Ud-Din, H, Tahari, AK, Zhou, Y, Wahl, RL & Rahmim, A 2012, Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations. in 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012., 6551920, IEEE Nuclear Science Symposium Conference Record, pp. 4017-4027, 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012, Anaheim, CA, United States, 10/29/12. https://doi.org/10.1109/NSSMIC.2012.6551920

Karakatsanis NA, Lodge MA, Mohy-Ud-Din H, Tahari AK, Zhou Y, Wahl RL et al. Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations. In 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record, NSS/MIC 2012. 2012. p. 4017-4027. 6551920. (IEEE Nuclear Science Symposium Conference Record). doi: 10.1109/NSSMIC.2012.6551920

@inproceedings{361426e611594dcb99fd8cf996153338,

title = "Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations",

abstract = "Whole body PET/CT, a well established imaging method in nuclear medicine for the clinical evaluation of a wide variety of metastatic cancer malignancies, commonly involves static scanning over multiple beds. Recently, we proposed a clinically feasible transition of whole-body PET/CT imaging to the dynamic domain, by acquiring (i) an initial 6min dynamic scan over the heart, followed by (ii) an optimized sequence of whole-body PET scans, allowing for quantitative whole body parametric imaging. Comparative evaluation of parametric and SUV images indicated enhanced contrast-to-noise ratio (CNR) but also higher noise for the parametric images. The objective of this study is to further improve parametric image CNR to enhance tumor detectability, by limiting noise in the estimates, while enhancing contrast and quantitative accuracy of parametric images. For this purpose, we utilize the weighted correlation coefficient (WR) of the kinetic model (Patlak) fits at each voxel to determine the cluster of voxels, where (i) advanced, as opposed to conventional, statistical parameter estimation, (ii) spatial smoothing or (iii) thresholding is applied. Thus, we facilitate the integration of whole body parametric imaging into the clinic as a competitive alternative to SUV. Through quantitative analysis on selected tumor regions of the resulting images, we show enhanced CNR when ridge regression is applied only to voxels associated with high WR, while ordinary least squares (OLS) and WR driven post-smoothing is performed to the rest. This hybrid regression method yields reduced mean squared error in tumor regions, compared to OLS. In addition, by setting the WR threshold level in the range [0.85 0.9], CNR is further enhanced for tumor regions of high WR. Finally, for the same type of tumors, hybrid regression also achieves higher CNR, compared to SUV, when the last two dynamic frames are omitted, allowing for shorter acquisition times.",

author = "Karakatsanis, {Nicolas A.} and Lodge, {Martin A.} and Hassan Mohy-Ud-Din and Tahari, {A. K.} and Yun Zhou and Wahl, {Richard L.} and Arman Rahmim",

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AU - Karakatsanis, Nicolas A.

AU - Lodge, Martin A.

AU - Mohy-Ud-Din, Hassan

AU - Tahari, A. K.

AU - Zhou, Yun

AU - Wahl, Richard L.

AU - Rahmim, Arman

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N2 - Whole body PET/CT, a well established imaging method in nuclear medicine for the clinical evaluation of a wide variety of metastatic cancer malignancies, commonly involves static scanning over multiple beds. Recently, we proposed a clinically feasible transition of whole-body PET/CT imaging to the dynamic domain, by acquiring (i) an initial 6min dynamic scan over the heart, followed by (ii) an optimized sequence of whole-body PET scans, allowing for quantitative whole body parametric imaging. Comparative evaluation of parametric and SUV images indicated enhanced contrast-to-noise ratio (CNR) but also higher noise for the parametric images. The objective of this study is to further improve parametric image CNR to enhance tumor detectability, by limiting noise in the estimates, while enhancing contrast and quantitative accuracy of parametric images. For this purpose, we utilize the weighted correlation coefficient (WR) of the kinetic model (Patlak) fits at each voxel to determine the cluster of voxels, where (i) advanced, as opposed to conventional, statistical parameter estimation, (ii) spatial smoothing or (iii) thresholding is applied. Thus, we facilitate the integration of whole body parametric imaging into the clinic as a competitive alternative to SUV. Through quantitative analysis on selected tumor regions of the resulting images, we show enhanced CNR when ridge regression is applied only to voxels associated with high WR, while ordinary least squares (OLS) and WR driven post-smoothing is performed to the rest. This hybrid regression method yields reduced mean squared error in tumor regions, compared to OLS. In addition, by setting the WR threshold level in the range [0.85 0.9], CNR is further enhanced for tumor regions of high WR. Finally, for the same type of tumors, hybrid regression also achieves higher CNR, compared to SUV, when the last two dynamic frames are omitted, allowing for shorter acquisition times.

AB - Whole body PET/CT, a well established imaging method in nuclear medicine for the clinical evaluation of a wide variety of metastatic cancer malignancies, commonly involves static scanning over multiple beds. Recently, we proposed a clinically feasible transition of whole-body PET/CT imaging to the dynamic domain, by acquiring (i) an initial 6min dynamic scan over the heart, followed by (ii) an optimized sequence of whole-body PET scans, allowing for quantitative whole body parametric imaging. Comparative evaluation of parametric and SUV images indicated enhanced contrast-to-noise ratio (CNR) but also higher noise for the parametric images. The objective of this study is to further improve parametric image CNR to enhance tumor detectability, by limiting noise in the estimates, while enhancing contrast and quantitative accuracy of parametric images. For this purpose, we utilize the weighted correlation coefficient (WR) of the kinetic model (Patlak) fits at each voxel to determine the cluster of voxels, where (i) advanced, as opposed to conventional, statistical parameter estimation, (ii) spatial smoothing or (iii) thresholding is applied. Thus, we facilitate the integration of whole body parametric imaging into the clinic as a competitive alternative to SUV. Through quantitative analysis on selected tumor regions of the resulting images, we show enhanced CNR when ridge regression is applied only to voxels associated with high WR, while ordinary least squares (OLS) and WR driven post-smoothing is performed to the rest. This hybrid regression method yields reduced mean squared error in tumor regions, compared to OLS. In addition, by setting the WR threshold level in the range [0.85 0.9], CNR is further enhanced for tumor regions of high WR. Finally, for the same type of tumors, hybrid regression also achieves higher CNR, compared to SUV, when the last two dynamic frames are omitted, allowing for shorter acquisition times.

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ER -

Enhanced whole-body PET parametric imaging using hybrid regression and thresholding driven by kinetic correlations

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