Creatine kinase rate constant in the human heart at 7T with 1D-ISIS/2D CSI localization

Creatine Kinase (CK) reaction plays an important role in energy metabolism and estimate of its reaction rate constant in heart provides important insight into cardiac energetics. Fast saturation transfer method ([Formula: see text] nominal) to measure CK reaction rate constant (kf) was previously de...

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Veröffentlicht in:	PloS one 2020, Vol.15 (3), p.e0229933
Hauptverfasser:	Bashir, Adil, Zhang, Jianyi, Denney, Thomas S
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Sprache:	eng
Schlagworte:	Adenosine triphosphate Adenosine Triphosphate - metabolism Adult Bandwidths Biology and Life Sciences Chemical equilibrium Computer engineering Computer simulation Creatine Creatine - metabolism Creatine kinase Creatine Kinase - isolation & purification Creatine Kinase - metabolism Energy Energy metabolism Energy Metabolism - physiology Female Heart - diagnostic imaging Heart - physiology Heart failure Heart rate Humans In vivo methods and tests Kinases Kinetics Livestock Localization Magnetic Resonance Imaging - methods Magnetic Resonance Spectroscopy Male Mathematical models Medicine and Health Sciences Metabolism Metabolites Muscle, Skeletal - enzymology Muscle, Skeletal - metabolism Muscles Myocardium Myocardium - enzymology Myocardium - pathology Numerical simulations Organs Parameter estimation Phosphorus Isotopes - chemistry Physical Sciences Research and Analysis Methods Saturation Skeletal muscle Spatial discrimination Spectroscopy Spectrum analysis Swine
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description	Creatine Kinase (CK) reaction plays an important role in energy metabolism and estimate of its reaction rate constant in heart provides important insight into cardiac energetics. Fast saturation transfer method ([Formula: see text] nominal) to measure CK reaction rate constant (kf) was previously demonstrated in open chest swine hearts. The goal of this work is to further develop this method for measuring the kf in human myocardium at 7T. [Formula: see text] approach is combined with 1D-ISIS/2D-CSI for in vivo spatial localization and myocardial CK forward rate constant was then measured in 7 volunteers at 7T. [Formula: see text] method uses two partially relaxed saturation transfer (ST) spectra and correction factor to determine CK rate constant. Correction factor is determined by numerical simulation of Bloch McConnell equations using known spin and experimental parameters. Optimal parameters and error estimate in calculation of CK reaction rate constant were determined by simulations. The technique was validated in calf muscles by direct comparison with saturation transfer measurements. [Formula: see text] pulse sequence was incorporated with 1D-image selected in vivo spectroscopy, combined with 2D-chemical shift spectroscopic imaging (1D-ISIS/2D-CSI) for studies in heart. The myocardial CK reaction rate constant was then measured in 7 volunteers. Skeletal muscle kf determined by conventional approach and [Formula: see text] approach were the same 0.31 ± 0.02 s-1 and 0.30 ± 0.04 s-1 demonstrating the validity of the technique. Results are reported as mean ± SD. Myocardial CK reaction rate constant was 0.29 ± 0.05 s-1, consistent with previously reported studies. [Formula: see text] method enables acquisition of 31P saturation transfer MRS under partially relaxed conditions and enables 2D-CSI of kf in myocardium. This work enables applications for in vivo CSI imaging of energetics in heart and other organs in clinically relevant acquisition time.
doi_str_mv	10.1371/journal.pone.0229933
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Fast saturation transfer method ([Formula: see text] nominal) to measure CK reaction rate constant (kf) was previously demonstrated in open chest swine hearts. The goal of this work is to further develop this method for measuring the kf in human myocardium at 7T. [Formula: see text] approach is combined with 1D-ISIS/2D-CSI for in vivo spatial localization and myocardial CK forward rate constant was then measured in 7 volunteers at 7T. [Formula: see text] method uses two partially relaxed saturation transfer (ST) spectra and correction factor to determine CK rate constant. Correction factor is determined by numerical simulation of Bloch McConnell equations using known spin and experimental parameters. Optimal parameters and error estimate in calculation of CK reaction rate constant were determined by simulations. The technique was validated in calf muscles by direct comparison with saturation transfer measurements. [Formula: see text] pulse sequence was incorporated with 1D-image selected in vivo spectroscopy, combined with 2D-chemical shift spectroscopic imaging (1D-ISIS/2D-CSI) for studies in heart. The myocardial CK reaction rate constant was then measured in 7 volunteers. Skeletal muscle kf determined by conventional approach and [Formula: see text] approach were the same 0.31 ± 0.02 s-1 and 0.30 ± 0.04 s-1 demonstrating the validity of the technique. Results are reported as mean ± SD. Myocardial CK reaction rate constant was 0.29 ± 0.05 s-1, consistent with previously reported studies. [Formula: see text] method enables acquisition of 31P saturation transfer MRS under partially relaxed conditions and enables 2D-CSI of kf in myocardium. 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Fast saturation transfer method ([Formula: see text] nominal) to measure CK reaction rate constant (kf) was previously demonstrated in open chest swine hearts. The goal of this work is to further develop this method for measuring the kf in human myocardium at 7T. [Formula: see text] approach is combined with 1D-ISIS/2D-CSI for in vivo spatial localization and myocardial CK forward rate constant was then measured in 7 volunteers at 7T. [Formula: see text] method uses two partially relaxed saturation transfer (ST) spectra and correction factor to determine CK rate constant. Correction factor is determined by numerical simulation of Bloch McConnell equations using known spin and experimental parameters. Optimal parameters and error estimate in calculation of CK reaction rate constant were determined by simulations. The technique was validated in calf muscles by direct comparison with saturation transfer measurements. [Formula: see text] pulse sequence was incorporated with 1D-image selected in vivo spectroscopy, combined with 2D-chemical shift spectroscopic imaging (1D-ISIS/2D-CSI) for studies in heart. The myocardial CK reaction rate constant was then measured in 7 volunteers. Skeletal muscle kf determined by conventional approach and [Formula: see text] approach were the same 0.31 ± 0.02 s-1 and 0.30 ± 0.04 s-1 demonstrating the validity of the technique. Results are reported as mean ± SD. Myocardial CK reaction rate constant was 0.29 ± 0.05 s-1, consistent with previously reported studies. [Formula: see text] method enables acquisition of 31P saturation transfer MRS under partially relaxed conditions and enables 2D-CSI of kf in myocardium. 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Fast saturation transfer method ([Formula: see text] nominal) to measure CK reaction rate constant (kf) was previously demonstrated in open chest swine hearts. The goal of this work is to further develop this method for measuring the kf in human myocardium at 7T. [Formula: see text] approach is combined with 1D-ISIS/2D-CSI for in vivo spatial localization and myocardial CK forward rate constant was then measured in 7 volunteers at 7T. [Formula: see text] method uses two partially relaxed saturation transfer (ST) spectra and correction factor to determine CK rate constant. Correction factor is determined by numerical simulation of Bloch McConnell equations using known spin and experimental parameters. Optimal parameters and error estimate in calculation of CK reaction rate constant were determined by simulations. The technique was validated in calf muscles by direct comparison with saturation transfer measurements. [Formula: see text] pulse sequence was incorporated with 1D-image selected in vivo spectroscopy, combined with 2D-chemical shift spectroscopic imaging (1D-ISIS/2D-CSI) for studies in heart. The myocardial CK reaction rate constant was then measured in 7 volunteers. Skeletal muscle kf determined by conventional approach and [Formula: see text] approach were the same 0.31 ± 0.02 s-1 and 0.30 ± 0.04 s-1 demonstrating the validity of the technique. Results are reported as mean ± SD. Myocardial CK reaction rate constant was 0.29 ± 0.05 s-1, consistent with previously reported studies. [Formula: see text] method enables acquisition of 31P saturation transfer MRS under partially relaxed conditions and enables 2D-CSI of kf in myocardium. This work enables applications for in vivo CSI imaging of energetics in heart and other organs in clinically relevant acquisition time.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>32191723</pmid><doi>10.1371/journal.pone.0229933</doi><orcidid>https://orcid.org/0000-0003-2030-9294</orcidid><orcidid>https://orcid.org/0000-0002-6695-4777</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Adenosine triphosphate Adenosine Triphosphate - metabolism Adult Bandwidths Biology and Life Sciences Chemical equilibrium Computer engineering Computer simulation Creatine Creatine - metabolism Creatine kinase Creatine Kinase - isolation & purification Creatine Kinase - metabolism Energy Energy metabolism Energy Metabolism - physiology Female Heart - diagnostic imaging Heart - physiology Heart failure Heart rate Humans In vivo methods and tests Kinases Kinetics Livestock Localization Magnetic Resonance Imaging - methods Magnetic Resonance Spectroscopy Male Mathematical models Medicine and Health Sciences Metabolism Metabolites Muscle, Skeletal - enzymology Muscle, Skeletal - metabolism Muscles Myocardium Myocardium - enzymology Myocardium - pathology Numerical simulations Organs Parameter estimation Phosphorus Isotopes - chemistry Physical Sciences Research and Analysis Methods Saturation Skeletal muscle Spatial discrimination Spectroscopy Spectrum analysis Swine
title	Creatine kinase rate constant in the human heart at 7T with 1D-ISIS/2D CSI localization
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