Your search keyword '"phosphorus MRS"' showing total 11 results

1. 31P magnetic resonance spectroscopy in skeletal muscle: Experts' consensus recommendations.

Author

Meyerspeer, Martin, Boesch, Chris, Cameron, Donnie, Dezortová, Monika, Forbes, Sean C., Heerschap, Arend, Jeneson, Jeroen A.L., Kan, Hermien E., Kent, Jane, Layec, Gwenaël, Prompers, Jeanine J., Reyngoudt, Harmen, Sleigh, Alison, Valkovič, Ladislav, Kemp, Graham J., Baligand, Céline, Carlier, Pierre G., Chatel, Benjamin, Damon, Bruce, and Heskamp, Linda

Subjects

NUCLEAR magnetic resonance spectroscopy, SKELETAL muscle, MUSCLE physiology, NEAR infrared spectroscopy, OXYGEN in the blood

Abstract

Skeletal muscle phosphorus‐31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal‐acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near‐infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology. [ABSTRACT FROM AUTHOR]

Published

2021

2. Effects of muscle damage on 31P‐MRS indices of energetic status and sarcolemma integrity in young mdx mice.

Subjects

SARCOLEMMA, DUCHENNE muscular dystrophy, MICE, NUCLEAR magnetic resonance spectroscopy, FREE radicals

Published

2022

3. Effects of muscle damage on P-31-MRS indices of energetic status and sarcolemma integrity in young mdx mice

Author

Kan, H.E.

Subjects

Duchenne muscular dystrophy, muscle damage, inflammation, phosphorus MRS, Molecular Medicine, Radiology, Nuclear Medicine and imaging, metabolism, Spectroscopy

Abstract

The article of Lopez et al describes the use of a multi-parametric MR approach to study muscle T-2 relaxation times and P-31-MRS indices of energetics and sarcolemma integrity in a mouse model of DMD, the mdx mouse. Muscular dystrophies have a multi-factorial disease cascade, and there are several MR methods used to assess these. Aspects that reflect disease progression are outlined on the left, while features that are more related to disease activity are outlined on the right.

Published

2022

4. A 13C/31P surface coil to visualize metabolism and energetics in the rodent brain at 3 Tesla.

Author

Vaidya, Manushka V., Zhang, Bei, Hong, DongHyun, Brown, Ryan, Batsios, Georgios, Viswanath, Pavithra, Paska, Jan, Wulf, Gerburg, Grant, Aaron K., Ronen, Sabrina M., and Larson, Peder E.Z.

Subjects

*QUALITY factor, *METABOLISM, *RODENTS, *BIOENERGETICS, *BICARBONATE ions

Abstract

[Display omitted] • Multinuclear coil for simultaneous acquisition of metabolism and energetics data. • Carbon/phosphorus coil designed for small animal imaging at 3 Tesla. • Coil shows decreased performance in comparison to single tuned coils. • Sufficient SNR to visualize bicarbonate and ATP. We constructed a 13C/31P surface coil at 3 T for studying cancer metabolism and bioenergetics. In a single scan session, hyperpolarized 13C-pyruvate MRS and 31P MRS was carried out for a healthy rat brain. All experiments were carried out at 3 Tesla. The multinuclear surface coil was designed as two coplanar loops each tuned to either the 13C or 31P operating frequency with an LCC trap on the 13C loop. A commercial volume proton coil was used for anatomical localization and B 0 shimming. Single tuned coils operating at either the 13C or 31P frequency were built to evaluate the relative performance of the multinuclear coil. Coil performance metrics consisted of measuring Q factor ratio, calculating system input power using a single-pulse acquisition, and acquiring SNR and flip angle maps using 2D CSI sequences. To observe in vivo spectra, a bolus of hyperpolarized [1-13C] pyruvate was administered via tail vein. In vivo 13C and endogenous 31P spectra were obtained in a single scan session using 1D slice selective acquisitions. When compared with single tuned surface coils, the multinuclear coil performance showed a decrease in Q factor ratio, SNR, and transmit efficiency. Flip angle maps showed adequate flip angles within the phantom when the transmit voltage was set using an external phantom. Results show good detection of 13C labeled lactate, alanine, and bicarbonate in addition to ATP from 31P MRS. The coil enables obtaining complementary information within a scan session, thus reducing the number of trials and minimizing biological variability for studies of metabolism and bioenergetics. [ABSTRACT FROM AUTHOR]

Published

2022

5. 31P magnetic resonance spectroscopy in skeletal muscle

Subjects

exercise, P-31, muscle, phosphorus MRS, metabolism, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus-31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology.

Published

2021

6. 31P magnetic resonance spectroscopy in skeletal muscle: experts' consensus recommendations

Author

Meyerspeer, Martin and Prompers, Jeanine J.

Subjects

exercise, P-31, muscle, phosphorus MRS, metabolism, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus-31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology.

Published

2021

7. P-31 magnetic resonance spectroscopy in skeletal muscle

Subjects

exercise, muscle, HUMAN CALF MUSCLE, HUMAN GASTROCNEMIUS-MUSCLE, CELLULAR ENERGETICS, MITOCHONDRIAL-FUNCTION, EXERCISING MUSCLE, P-31, phosphorus MRS, OXIDATIVE-PHOSPHORYLATION, RELAXATION-TIMES, PHOSPHOCREATINE RECOVERY KINETICS, metabolism, IN-VIVO, METABOLITE CONCENTRATIONS, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus-31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology.

Published

2020

8. P-31 magnetic resonance spectroscopy in skeletal muscle

Author

Meyerspeer, M., Boesch, C., Cameron, D., Dezortova, M., Forbes, S.C., Heerschap, A., Jeneson, J.A.L., Kan, H.M.E., Kent, J., Layec, G., Prompers, J.J., Reyngoudt, H., Sleigh, A., Valkovic, L., Kemp, G.J., Baligand, C., Carlier, P.G., Chatel, B., Damon, B., Heskamp, L., Hajek, M., Jooijmans, M., Krssak, M., Reichenbach, J., Schmid, A., Slade, J., Vandenborne, K., Walter, G.A., Willis, D., and Experts Working Grp P MR

Subjects

P-31, exercise, muscle, phosphorus MRS, metabolism, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus-31 P-31 MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of P-31 MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how P-31 MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with P-31 MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and H-1 MRS measurements) can help in the physiological/metabolic interpretation of P-31 MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology.

Published

2020

9. 31 P magnetic resonance spectroscopy in skeletal muscle: Experts' consensus recommendations

Author

Meyerspeer, Martin, Boesch, Chris, Cameron, Donnie, Dezortová, Monika, Forbes, Sean C, Heerschap, Arend, Jeneson, Jeroen AL, Kan, Hermien E, Kent, Jane, Layec, Gwenaël, Prompers, Jeanine J, Reyngoudt, Harmen, Sleigh, Alison, Valkovič, Ladislav, Kemp, Graham J, Experts' Working Group On 31P MR Spectroscopy Of Skeletal Muscle, Meyerspeer, Martin [0000-0002-0295-8218], Boesch, Chris [0000-0001-8498-8543], Cameron, Donnie [0000-0001-9841-6909], Kan, Hermien E [0000-0002-5772-7177], Prompers, Jeanine J [0000-0002-4756-4474], Reyngoudt, Harmen [0000-0002-0777-2711], Sleigh, Alison [0000-0002-3859-8701], Valkovič, Ladislav [0000-0003-2567-3642], Kemp, Graham J [0000-0002-8324-9666], and Apollo - University of Cambridge Repository

Subjects

exercise, muscle, phosphorus MRS, 31P, metabolism, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus-31 31 P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31 P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31 P MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31 P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1 H MRS measurements) can help in the physiological/metabolic interpretation of 31 P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology.

Published

2020

10. 31P magnetic resonance spectroscopy in skeletal muscle: Experts' consensus recommendations

Author

Meyerspeer, Martin, Boesch, Chris, Cameron, Donnie, Dezortová, Monika, Forbes, Sean C., Heerschap, Arend, Jeneson, Jeroen A.L., Kan, Hermien E., Kent, Jane, Layec, Gwenaël, Prompers, Jeanine J., Reyngoudt, Harmen, Sleigh, Alison, Valkovič, Ladislav, Kemp, Graham J., Baligand, Céline, Carlier, Pierre G., Chatel, Benjamin, Damon, Bruce, Heskamp, Linda, Hájek, Milan, Jooijmans, Melissa, Krssak, Martin, Reichenbach, Juergen, Schmid, Albrecht, Slade, Jill, Vandenborne, Krista, Walter, Glenn A., Willis, David, and Radiology and Nuclear Medicine

Subjects

exercise, muscle, Urological cancers Radboud Institute for Molecular Life Sciences [Radboudumc 15], phosphorus MRS, Special Issue Review Articles, Special Issue Review Article, 31P, metabolism, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus‐31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal‐acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near‐infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology., 31P MRS can usefully probe skeletal muscle cellular energy metabolism. Choice of methodology depends on the research question. The recommendations given here will help researchers experienced in general MRS with the application of 31P MRS in skeletal muscle, covering the practicalities of data acquisition and muscle exercise as well as the physiological interpretation of the measurements. We also give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting results and acquisition parameters.

Published

2020

11. 31P magnetic resonance spectroscopy in skeletal muscle: Experts' consensus recommendations

Subjects

exercise, muscle, phosphorus MRS, metabolism, MRI, nuclear magnetic resonance spectroscopy

Abstract

Skeletal muscle phosphorus-31 31P MRS is the oldest MRS methodology to be applied to in vivo metabolic research. The technical requirements of 31P MRS in skeletal muscle depend on the research question, and to assess those questions requires understanding both the relevant muscle physiology, and how 31P MRS methods can probe it. Here we consider basic signal-acquisition parameters related to radio frequency excitation, TR, TE, spectral resolution, shim and localisation. We make specific recommendations for studies of resting and exercising muscle, including magnetisation transfer, and for data processing. We summarise the metabolic information that can be quantitatively assessed with 31P MRS, either measured directly or derived by calculations that depend on particular metabolic models, and we give advice on potential problems of interpretation. We give expected values and tolerable ranges for some measured quantities, and minimum requirements for reporting acquisition parameters and experimental results in publications. Reliable examination depends on a reproducible setup, standardised preconditioning of the subject, and careful control of potential difficulties, and we summarise some important considerations and potential confounders. Our recommendations include the quantification and standardisation of contraction intensity, and how best to account for heterogeneous muscle recruitment. We highlight some pitfalls in the assessment of mitochondrial function by analysis of phosphocreatine (PCr) recovery kinetics. Finally, we outline how complementary techniques (near-infrared spectroscopy, arterial spin labelling, BOLD and various other MRI and 1H MRS measurements) can help in the physiological/metabolic interpretation of 31P MRS studies by providing information about blood flow and oxygen delivery/utilisation. Our recommendations will assist in achieving the fullest possible reliable picture of muscle physiology and pathophysiology.

Published

2020