Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model

Takashi Ichihara; Richard T. George; Joao A.C. Lima; Yoshihiro Ikeda; Albert C. Lardo

doi:10.1109/NSSMIC.2010.5874200

Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model

Takashi Ichihara, Richard T. George, Joao A.C. Lima, Yoshihiro Ikeda, Albert C. Lardo

School of Medicine

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

4 Scopus citations

Abstract

The purpose of this study was to describe the upslope method-derived myocardial perfusion index using the parameters based on a tracer kinetic model of iodixanol contrast agent and to validate this theoretically derived relationship using an ischemic canine model. The established modified Kety model was used to describe the extravascular diffusion of iodixanol contrast agent, which undergoes no cellular uptake or metabolism. This model consists of two functional compartments, one describing the vascular compartment and the second representing all myocardial capillaries, interstitium, and cells. These compartments are connected by two rate constants, K₁ and k ₂, which represent the first-order transfer constants from the left ventricular (LV) blood to myocardium and from myocardium to the vascular system, respectively. In the early phase after the arrival of contrast agent in the myocardium, the relationship between K₁ and the concentrations of iodixanol contrast agent in the myocardium and arterial blood (LV blood) is described by K₁ {dC_myo(t_peak)/dt}/C _a(t_peak) (Eq. 1), where C_myo(t) is the relative concentration of iodixanol contrast agent in the myocardium at time t, C _a(t) is the relative concentration of iodixanol contrast agent in the LV blood, and t_peak is the time at the peak of C_a(t) and maximum upslope of C_myo(t). Six canine models of left anterior descending (LAD) artery stenosis were prepared and underwent first-pass contrast-enhanced mult-detector row computed tomography (MDCT) perfusion imaging during adenosine infusion (0.14-0.21 mg/kg/min) to study a wide range of flow rates. K₁ was measured using the Patlak plot method and upslope method applied to time-attenuation curve data of the LV blood pool and myocardium. The results were compared against microsphere myocardial blood flow measurements. The Patlak plot-derived K₁ and upslope method-derived K₁ showed a good linear association. Regional K₁ can be measured accurately using the upslope method-derived myocardial perfusion index based on a compartment model.

Original language	English (US)
Title of host publication	IEEE Nuclear Science Symposuim and Medical Imaging Conference, NSS/MIC 2010
Pages	2330-2333
Number of pages	4
DOIs	https://doi.org/10.1109/NSSMIC.2010.5874200
State	Published - 2010
Event	2010 IEEE Nuclear Science Symposium, Medical Imaging Conference, NSS/MIC 2010 and 17th International Workshop on Room-Temperature Semiconductor X-ray and Gamma-ray Detectors, RTSD 2010 - Knoxville, TN, United States Duration: Oct 30 2010 → Nov 6 2010

Publication series

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

Other

Other	2010 IEEE Nuclear Science Symposium, Medical Imaging Conference, NSS/MIC 2010 and 17th International Workshop on Room-Temperature Semiconductor X-ray and Gamma-ray Detectors, RTSD 2010
Country/Territory	United States
City	Knoxville, TN
Period	10/30/10 → 11/6/10

ASJC Scopus subject areas

Radiation
Nuclear and High Energy Physics
Radiology Nuclear Medicine and imaging

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10.1109/NSSMIC.2010.5874200

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Ichihara, T., George, R. T., Lima, J. A. C., Ikeda, Y., & Lardo, A. C. (2010). Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model. In IEEE Nuclear Science Symposuim and Medical Imaging Conference, NSS/MIC 2010 (pp. 2330-2333). Article 5874200 (IEEE Nuclear Science Symposium Conference Record). https://doi.org/10.1109/NSSMIC.2010.5874200

Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model. / Ichihara, Takashi; George, Richard T.; Lima, Joao A.C. et al.
IEEE Nuclear Science Symposuim and Medical Imaging Conference, NSS/MIC 2010. 2010. p. 2330-2333 5874200 (IEEE Nuclear Science Symposium Conference Record).

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

Ichihara, T, George, RT, Lima, JAC, Ikeda, Y & Lardo, AC 2010, Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model. in IEEE Nuclear Science Symposuim and Medical Imaging Conference, NSS/MIC 2010., 5874200, IEEE Nuclear Science Symposium Conference Record, pp. 2330-2333, 2010 IEEE Nuclear Science Symposium, Medical Imaging Conference, NSS/MIC 2010 and 17th International Workshop on Room-Temperature Semiconductor X-ray and Gamma-ray Detectors, RTSD 2010, Knoxville, TN, United States, 10/30/10. https://doi.org/10.1109/NSSMIC.2010.5874200

Ichihara T, George RT, Lima JAC, Ikeda Y, Lardo AC. Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model. In IEEE Nuclear Science Symposuim and Medical Imaging Conference, NSS/MIC 2010. 2010. p. 2330-2333. 5874200. (IEEE Nuclear Science Symposium Conference Record). doi: 10.1109/NSSMIC.2010.5874200

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title = "Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model",

abstract = "The purpose of this study was to describe the upslope method-derived myocardial perfusion index using the parameters based on a tracer kinetic model of iodixanol contrast agent and to validate this theoretically derived relationship using an ischemic canine model. The established modified Kety model was used to describe the extravascular diffusion of iodixanol contrast agent, which undergoes no cellular uptake or metabolism. This model consists of two functional compartments, one describing the vascular compartment and the second representing all myocardial capillaries, interstitium, and cells. These compartments are connected by two rate constants, K1 and k 2, which represent the first-order transfer constants from the left ventricular (LV) blood to myocardium and from myocardium to the vascular system, respectively. In the early phase after the arrival of contrast agent in the myocardium, the relationship between K1 and the concentrations of iodixanol contrast agent in the myocardium and arterial blood (LV blood) is described by K1 {dCmyo(tpeak)/dt}/C a(tpeak) (Eq. 1), where Cmyo(t) is the relative concentration of iodixanol contrast agent in the myocardium at time t, C a(t) is the relative concentration of iodixanol contrast agent in the LV blood, and tpeak is the time at the peak of Ca(t) and maximum upslope of Cmyo(t). Six canine models of left anterior descending (LAD) artery stenosis were prepared and underwent first-pass contrast-enhanced mult-detector row computed tomography (MDCT) perfusion imaging during adenosine infusion (0.14-0.21 mg/kg/min) to study a wide range of flow rates. K1 was measured using the Patlak plot method and upslope method applied to time-attenuation curve data of the LV blood pool and myocardium. The results were compared against microsphere myocardial blood flow measurements. The Patlak plot-derived K1 and upslope method-derived K1 showed a good linear association. Regional K1 can be measured accurately using the upslope method-derived myocardial perfusion index based on a compartment model.",

author = "Takashi Ichihara and George, {Richard T.} and Lima, {Joao A.C.} and Yoshihiro Ikeda and Lardo, {Albert C.}",

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AU - Lardo, Albert C.

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N2 - The purpose of this study was to describe the upslope method-derived myocardial perfusion index using the parameters based on a tracer kinetic model of iodixanol contrast agent and to validate this theoretically derived relationship using an ischemic canine model. The established modified Kety model was used to describe the extravascular diffusion of iodixanol contrast agent, which undergoes no cellular uptake or metabolism. This model consists of two functional compartments, one describing the vascular compartment and the second representing all myocardial capillaries, interstitium, and cells. These compartments are connected by two rate constants, K1 and k 2, which represent the first-order transfer constants from the left ventricular (LV) blood to myocardium and from myocardium to the vascular system, respectively. In the early phase after the arrival of contrast agent in the myocardium, the relationship between K1 and the concentrations of iodixanol contrast agent in the myocardium and arterial blood (LV blood) is described by K1 {dCmyo(tpeak)/dt}/C a(tpeak) (Eq. 1), where Cmyo(t) is the relative concentration of iodixanol contrast agent in the myocardium at time t, C a(t) is the relative concentration of iodixanol contrast agent in the LV blood, and tpeak is the time at the peak of Ca(t) and maximum upslope of Cmyo(t). Six canine models of left anterior descending (LAD) artery stenosis were prepared and underwent first-pass contrast-enhanced mult-detector row computed tomography (MDCT) perfusion imaging during adenosine infusion (0.14-0.21 mg/kg/min) to study a wide range of flow rates. K1 was measured using the Patlak plot method and upslope method applied to time-attenuation curve data of the LV blood pool and myocardium. The results were compared against microsphere myocardial blood flow measurements. The Patlak plot-derived K1 and upslope method-derived K1 showed a good linear association. Regional K1 can be measured accurately using the upslope method-derived myocardial perfusion index based on a compartment model.

AB - The purpose of this study was to describe the upslope method-derived myocardial perfusion index using the parameters based on a tracer kinetic model of iodixanol contrast agent and to validate this theoretically derived relationship using an ischemic canine model. The established modified Kety model was used to describe the extravascular diffusion of iodixanol contrast agent, which undergoes no cellular uptake or metabolism. This model consists of two functional compartments, one describing the vascular compartment and the second representing all myocardial capillaries, interstitium, and cells. These compartments are connected by two rate constants, K1 and k 2, which represent the first-order transfer constants from the left ventricular (LV) blood to myocardium and from myocardium to the vascular system, respectively. In the early phase after the arrival of contrast agent in the myocardium, the relationship between K1 and the concentrations of iodixanol contrast agent in the myocardium and arterial blood (LV blood) is described by K1 {dCmyo(tpeak)/dt}/C a(tpeak) (Eq. 1), where Cmyo(t) is the relative concentration of iodixanol contrast agent in the myocardium at time t, C a(t) is the relative concentration of iodixanol contrast agent in the LV blood, and tpeak is the time at the peak of Ca(t) and maximum upslope of Cmyo(t). Six canine models of left anterior descending (LAD) artery stenosis were prepared and underwent first-pass contrast-enhanced mult-detector row computed tomography (MDCT) perfusion imaging during adenosine infusion (0.14-0.21 mg/kg/min) to study a wide range of flow rates. K1 was measured using the Patlak plot method and upslope method applied to time-attenuation curve data of the LV blood pool and myocardium. The results were compared against microsphere myocardial blood flow measurements. The Patlak plot-derived K1 and upslope method-derived K1 showed a good linear association. Regional K1 can be measured accurately using the upslope method-derived myocardial perfusion index based on a compartment model.

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Evaluation of equivalence of upslope method-derived myocardial perfusion index and transfer constant based on two-compartment tracer kinetic model

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