Measurements of glucose phosphorylation with FDG and PET are not reduced by dephosphorylation of FDG-6-phosphate.

H Kuwabara; A Gjedde

Measurements of glucose phosphorylation with FDG and PET are not reduced by dephosphorylation of FDG-6-phosphate.

H Kuwabara, A Gjedde

22 Citations (Scopus)

Abstract

To improve the measurements of glucose metabolism in the human brain, we imposed biologic constraints on the deoxyglucose model with and without dephosphorylation of FDG-6-phosphate (the k4*- and k3*-models). The constraints included constant transport and phosphorylation ratios (tau and phi) and a common partition volume (K1/k2) for tracer [18F]FDG and glucose. In the presence of significant dephosphorylation, the k3*-model yielded time-dependent estimates of the phosphorylation coefficient (k3*), while the K4*-model yielded time-independent estimates. However, the two models yielded practically identical measurements of regional cerebral glucose metabolism in PET studies of six normal volunteers when the phosphorylation affinity ratio (the k3*/k3 ratio of FDG and glucose) and tracer circulation time were 0.30 and 20 min for the k3*-model and 0.33 and 45 min for the k4*-model.

Original language	English
Journal	Journal of Nuclear Medicine
Volume	32
Issue number	4
Pages (from-to)	692-8
Number of pages	6
ISSN	0161-5505
Publication status	Published - 1991
Externally published	Yes

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title = "Measurements of glucose phosphorylation with FDG and PET are not reduced by dephosphorylation of FDG-6-phosphate.",

abstract = "To improve the measurements of glucose metabolism in the human brain, we imposed biologic constraints on the deoxyglucose model with and without dephosphorylation of FDG-6-phosphate (the k4*- and k3*-models). The constraints included constant transport and phosphorylation ratios (tau and phi) and a common partition volume (K1/k2) for tracer [18F]FDG and glucose. In the presence of significant dephosphorylation, the k3*-model yielded time-dependent estimates of the phosphorylation coefficient (k3*), while the K4*-model yielded time-independent estimates. However, the two models yielded practically identical measurements of regional cerebral glucose metabolism in PET studies of six normal volunteers when the phosphorylation affinity ratio (the k3*/k3 ratio of FDG and glucose) and tracer circulation time were 0.30 and 20 min for the k3*-model and 0.33 and 45 min for the k4*-model.",

author = "H Kuwabara and A Gjedde",

year = "1991",

language = "English",

volume = "32",

pages = "692--8",

journal = "The Journal of Nuclear Medicine",

issn = "0161-5505",

publisher = "Society of Nuclear Medicine",

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TY - JOUR

T1 - Measurements of glucose phosphorylation with FDG and PET are not reduced by dephosphorylation of FDG-6-phosphate.

AU - Kuwabara, H

AU - Gjedde, A

PY - 1991

Y1 - 1991

N2 - To improve the measurements of glucose metabolism in the human brain, we imposed biologic constraints on the deoxyglucose model with and without dephosphorylation of FDG-6-phosphate (the k4*- and k3*-models). The constraints included constant transport and phosphorylation ratios (tau and phi) and a common partition volume (K1/k2) for tracer [18F]FDG and glucose. In the presence of significant dephosphorylation, the k3*-model yielded time-dependent estimates of the phosphorylation coefficient (k3*), while the K4*-model yielded time-independent estimates. However, the two models yielded practically identical measurements of regional cerebral glucose metabolism in PET studies of six normal volunteers when the phosphorylation affinity ratio (the k3*/k3 ratio of FDG and glucose) and tracer circulation time were 0.30 and 20 min for the k3*-model and 0.33 and 45 min for the k4*-model.

AB - To improve the measurements of glucose metabolism in the human brain, we imposed biologic constraints on the deoxyglucose model with and without dephosphorylation of FDG-6-phosphate (the k4*- and k3*-models). The constraints included constant transport and phosphorylation ratios (tau and phi) and a common partition volume (K1/k2) for tracer [18F]FDG and glucose. In the presence of significant dephosphorylation, the k3*-model yielded time-dependent estimates of the phosphorylation coefficient (k3*), while the K4*-model yielded time-independent estimates. However, the two models yielded practically identical measurements of regional cerebral glucose metabolism in PET studies of six normal volunteers when the phosphorylation affinity ratio (the k3*/k3 ratio of FDG and glucose) and tracer circulation time were 0.30 and 20 min for the k3*-model and 0.33 and 45 min for the k4*-model.

M3 - Journal article

C2 - 2013809

SN - 0161-5505

VL - 32

SP - 692

EP - 698

JO - The Journal of Nuclear Medicine

JF - The Journal of Nuclear Medicine

IS - 4

ER -

Measurements of glucose phosphorylation with FDG and PET are not reduced by dephosphorylation of FDG-6-phosphate.

Abstract

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