Kidney modelling for FDG excretion with PET

Huiting Qiao; Jing Bai; Yingmao Chen; Jiahe Tian

doi:10.1155/2007/63234

Kidney modelling for FDG excretion with PET

Huiting Qiao^*
, Jing Bai
, Yingmao Chen
, Jiahe Tian

^*Corresponding author for this work

Tsinghua University
General Hospital of People's Liberation Army

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

The purpose of this study was to detect the physiological process of FDG's filtration from blood to urine and to establish a mathematical model to describe the process. Dynamic positron emission tomography scan for FDG was performed on seven normal volunteers. The filtration process in kidney can be seen in the sequential images of each study. Variational distribution of FDG in kidney can be detected in dynamic data. According to the structure and function, kidney is divided into parenchyma and pelvis. A unidirectional three-compartment model is proposed to describe the renal function in FDG excretion. The time-activity curves that were picked up from the parenchyma, pelvis, and abdominal aorta were used to estimate the parameter of the model. The output of the model has fitted well with the original curve from dynamic data.

Original language	English
Article number	63234
Journal	International Journal of Biomedical Imaging
Volume	2007
DOIs	https://doi.org/10.1155/2007/63234
State	Published - 2007
Externally published	Yes

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10.1155/2007/63234

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title = "Kidney modelling for FDG excretion with PET",

abstract = "The purpose of this study was to detect the physiological process of FDG's filtration from blood to urine and to establish a mathematical model to describe the process. Dynamic positron emission tomography scan for FDG was performed on seven normal volunteers. The filtration process in kidney can be seen in the sequential images of each study. Variational distribution of FDG in kidney can be detected in dynamic data. According to the structure and function, kidney is divided into parenchyma and pelvis. A unidirectional three-compartment model is proposed to describe the renal function in FDG excretion. The time-activity curves that were picked up from the parenchyma, pelvis, and abdominal aorta were used to estimate the parameter of the model. The output of the model has fitted well with the original curve from dynamic data.",

author = "Huiting Qiao and Jing Bai and Yingmao Chen and Jiahe Tian",

year = "2007",

doi = "10.1155/2007/63234",

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AU - Qiao, Huiting

AU - Bai, Jing

AU - Chen, Yingmao

AU - Tian, Jiahe

PY - 2007

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N2 - The purpose of this study was to detect the physiological process of FDG's filtration from blood to urine and to establish a mathematical model to describe the process. Dynamic positron emission tomography scan for FDG was performed on seven normal volunteers. The filtration process in kidney can be seen in the sequential images of each study. Variational distribution of FDG in kidney can be detected in dynamic data. According to the structure and function, kidney is divided into parenchyma and pelvis. A unidirectional three-compartment model is proposed to describe the renal function in FDG excretion. The time-activity curves that were picked up from the parenchyma, pelvis, and abdominal aorta were used to estimate the parameter of the model. The output of the model has fitted well with the original curve from dynamic data.

AB - The purpose of this study was to detect the physiological process of FDG's filtration from blood to urine and to establish a mathematical model to describe the process. Dynamic positron emission tomography scan for FDG was performed on seven normal volunteers. The filtration process in kidney can be seen in the sequential images of each study. Variational distribution of FDG in kidney can be detected in dynamic data. According to the structure and function, kidney is divided into parenchyma and pelvis. A unidirectional three-compartment model is proposed to describe the renal function in FDG excretion. The time-activity curves that were picked up from the parenchyma, pelvis, and abdominal aorta were used to estimate the parameter of the model. The output of the model has fitted well with the original curve from dynamic data.

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DO - 10.1155/2007/63234

M3 - 文章

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SN - 1687-4188

VL - 2007

JO - International Journal of Biomedical Imaging

JF - International Journal of Biomedical Imaging

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ER -

Kidney modelling for FDG excretion with PET

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