A strictly noninvasive MR setup dedicated to longitudinal studies of mechanical performance, bioenergetics, anatomy, and muscle recruitment in contracting mouse skeletal muscle

Giannesini, Benoı̂t; Vilmen, Christophe; Fur, Yann Le; Dalmasso, Christiane; Cozzone, Patrick J.; Bendahan, David

doi:10.1002/mrm.22386

Cited by 39 publications

(71 citation statements)

References 27 publications

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“…Continuous acquisition of 31 P spectra during exercise-recovery or ischemia-reperfusion provides the potential to assess mitochondrial oxidative capacity by quantifying the kinetics of PCr depletion and replenishment. Dynamic 31 P-MRS has been applied to assess skeletal muscle bioenergetics under physiological conditions (60,61,87,(96)(97)(98)(99), as well as to evaluate mitochondrial function in skeletal muscle in both diabetic patients and animal models of diabetes (8,(100)(101)(102). Figure 3 shows dynamic 31 P spectra and the changes of phosphate metabolites and pH during muscle contraction and recovery in human skeletal muscle (103).…”

Section: P-mrsmentioning

confidence: 99%

“…However, baseline ATP concentration may change in chronic diseases (77)(78)(79), limiting the use of this approach in diseased tissues. Alternatively, many studies have used metabolite concentration ratios such as PCr-to-P i and PCrto-ATP ratios to evaluate metabolic changes in a variety of diseased conditions (4,(80)(81)(82)(83)(84)(85)(86)(87)(88). Reduced PCr-to-ATP ratio has been reported as a consequence of reduced CK activity or a loss of the total Cr content in heart diseases (82,(89)(90)(91).…”

Section: P-mrsmentioning

confidence: 99%

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Assessing tissue metabolism by phosphorous-31 magnetic resonance spectroscopy and imaging: a methodology review

Liu

2017

Quant. Imaging Med. Surg.

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Many human diseases are caused by an imbalance between energy production and demand.Magnetic resonance spectroscopy (MRS) and magnetic resonance imaging (MRI) provide the unique opportunity for in vivo assessment of several fundamental events in tissue metabolism without the use of ionizing radiation. Of particular interest, phosphate metabolites that are involved in ATP generation and utilization can be quantified noninvasively by phosphorous-31 ( 31 P) MRS/MRI. Furthermore, 31 P magnetization transfer (MT) techniques allow in vivo measurement of metabolic fluxes via creatine kinase (CK) and ATP synthase. However, a major impediment for the clinical applications of 31 P-MRS/MRI is the prohibitively long acquisition time and/or the low spatial resolution that are necessary to achieve adequate signal-to-noise ratio. P-MRS/MRI techniques. Applications of these techniques to the investigation of a specific physiology/pathology will be discussed without detailed description. Interested readers are referred to recent review articles on the applications of 31 P-MRS/MRI in metabolic characterization of skeletal muscle (10-12), heart (13), brain (14), and liver (11), as well as in diseases such as cancer (15), heart failure (16), and obesity and diabetes (17,18). Historical perspectiveThe use of 31 P-MRS for metabolic investigations dates back to 1960. Cohn and Hughes were the first to obtain a high-resolution 31 P spectrum of a solution of ATP (19). In addition, they also observed a dependence of the chemical shifts of the phosphorus nuclei of ATP on the pH of the solution. In parallel to the early development of MRI methods by Lauterbur (20), the entire 1970s also witnessed the rapid advance of 31 P-MRS in metabolic investigation of a broad range of biological systems. In 1973, Moon and Richards performed the first 31 P-MRS study that measured intracellular pH in human red blood cells (21). In the following year, Henderson and colleagues obtained the first 31 P spectrum of ATP from human red blood cells (22). At the same time, the Oxford team led by Radda performed the first experiment to acquire 31 P spectra from an intact organ, i.e., the excised and superfused muscle of rat hindlimb (23). The first in vivo 31 P-MRS study was performed on mouse brain by Chance et al. (24). Within the short span of one decade, organelles including mitochondria (25,26) and chromaffin granules (27), cells including Escherichia coli (28), yeast (29), and hepatocytes (30), and organs including skeletal muscle (31,32), heart (33-35), brain (36), kidney (37), and liver (38,39) have all been studied using 31 P-MRS.It is worth noting that most of these organ studies were performed on excised organs to avoid the need for spatial localization. Although Lauterbur has demonstrated the feasibility of imaging water protons (20), it was considered impractical for 31 P imaging of living systems because of the low sensitivity and difficulties with spectral resolution.The 1980s began with the publication of two important studies that aimed a...

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Section: P-mrsmentioning

confidence: 99%

Section: P-mrsmentioning

confidence: 99%

Assessing tissue metabolism by phosphorous-31 magnetic resonance spectroscopy and imaging: a methodology review

Liu

2017

Quant. Imaging Med. Surg.

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“…Mechanical performance, muscular volume, and energy production from the net breakdown of phosphocreatine (PCr) via CK reaction, oxidative phosphorylation, and anaerobic glycolysis were assessed strictly noninvasively in electrostimulated gastrocnemius muscle of Mstn Ϫ/Ϫ and wild-type (Mstn ϩ/ϩ ) mice using an original experimental setup (14) Animal care and feeding. Thirteen 4-mo-old female Mstn ϩ/ϩ (n ϭ 7) and Mstn Ϫ/Ϫ mice (n ϭ 6) generated from a colony maintained on a C57Bl/6 background (Centre d'Expérimentation Fonctionnelle, Faculté de Médecine Pitié Salpêtrière, Paris, France) were used for these experiments.…”

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confidence: 99%

Lack of myostatin impairs mechanical performance and ATP cost of contraction in exercising mouse gastrocnemius muscle in vivo

Giannesini

Vilmen

Amthor

et al. 2013

American Journal of Physiology-Endocrinology and Metabolism

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Although it is well established that the lack of myostatin (Mstn) promotes skeletal muscle hypertrophy, the corresponding changes regarding force generation have been studied mainly in vitro and remain conflicting. Furthermore, the metabolic underpinnings of these changes are very poorly documented. To clarify this issue, we have investigated strictly noninvasively in vivo the impact of the lack of Mstn on gastrocnemius muscle function and energetics in Mstn-targeted knockout (Mstn Ϫ/Ϫ ) mice using 1 H-magnetic resonance (MR) imaging and 31 P-MR spectroscopy during maximal repeated isometric contractions induced by transcutaneous electrostimulation. In Mstn Ϫ/Ϫ animals, although body weight, gastrocnemius muscle volume, and absolute force were larger (ϩ38, ϩ118, and ϩ34%, respectively) compared with wild-type (Mstn ϩ/ϩ ) mice, specific force (calculated from MR imaging measurements) was significantly lower (Ϫ36%), and resistance to fatigue was decreased. Besides, Mstn deficiency did not affect phosphorylated compound concentrations and intracellular pH at rest but caused a large increase in ATP cost of contraction (up to ϩ206% compared with Mstn ϩ/ϩ ) throughout the stimulation period. Further, Mstn deficiency limits the shift toward oxidative metabolism during muscle activity despite the fact that oxidative ATP synthesis capacity was not altered. Our data demonstrate in vivo that the absence of Mstn impairs both mechanical performance and energy cost of contraction in hypertrophic muscle. These findings must be kept in mind when considering Mstn as a potential therapeutic target for increasing muscle mass in patients suffering from muscle-wasting disorders. adenosine 5=-triphosphate; skeletal muscle; hypertrophy; energy metabolism; fatigue; nuclear magnetic resonance MYOSTATIN (Mstn) is part of the transforming growth factor-␤ signaling molecule family and acts as an endogenous negative regulator of skeletal muscle growth in mammalians (23). The absence or postnatal blockade of Mstn results in a large and widespread increase in skeletal muscle mass (20,23,24).

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“…The left hindlimb was shaved before an electrode cream was applied at the knee and heel regions to optimize transcutaneous electrostimulation. An anesthetized animal was placed supine in a home-built cradle that had been especially designed for the strictly noninvasive MR investigation of gastrocnemius muscle function (20). This muscle was chosen because it is easily accessible for MR measurements and preferentially activated using our experimental methodology.…”

Section: Noninvasive Investigation Of Gastrocnemius Muscle Function Amentioning

confidence: 99%

“…Absolute force production (expressed as force-time integral, in N·s) was calculated by integrating the isometric force (in N) with respect to time. During the force-frequency protocol, gastrocnemius muscle was electrostimulated with trains (0.75 s duration, rest interval of 30 s) of incremental frequencies (1,10,20,30,50,75, 100, and 150 Hz), and the corresponding force data were processed as follows. The isometric peak force was measured for each train, and the overall dataset was fitted to the Hill equation for calculating f50, i.e., the electrostimulation frequency for which 50% of the maximal force was exerted.…”

Section: Noninvasive Investigation Of Gastrocnemius Muscle Function Amentioning

confidence: 99%

Mitochondrial impairment induced by postnatal ActRIIB blockade does not alter function and energy status in exercising mouse glycolytic muscle in vivo

Béchir

Pecchi

Relizani

et al. 2016

American Journal of Physiology-Endocrinology and Metabolism

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-Because it leads to a rapid and massive muscle hypertrophy, postnatal blockade of the activin type IIB receptor (ActRIIB) is a promising therapeutic strategy for counteracting muscle wasting. However, the functional consequences remain very poorly documented in vivo. Here, we have investigated the impact of 8-wk ActRIIB blockade with soluble receptor (sActRIIB-Fc) on gastrocnemius muscle anatomy, energy metabolism, and force-generating capacity in wild-type mice, using totally noninvasive magnetic resonance imaging (MRI) and dynamic 31 P-MRS. Compared with vehicle (PBS) control, sActRIIB-Fc treatment resulted in a dramatic increase in body weight (ϩ29%) and muscle volume (ϩ58%) calculated from hindlimb MR imaging, but did not alter fiber type distribution determined via myosin heavy chain isoform analysis. In resting muscle, sActRIIB-Fc treatment induced acidosis and PCr depletion, thereby suggesting reduced tissue oxygenation. During an in vivo fatiguing exercise (6-min repeated maximal isometric contraction electrically induced at 1.7 Hz), maximal and total absolute forces were larger in sActRIIB-Fc treated animals (ϩ26 and ϩ12%, respectively), whereas specific force and fatigue resistance were lower (Ϫ30 and Ϫ37%, respectively). Treatment with sActRIIB-Fc further decreased the maximal rate of oxidative ATP synthesis (Ϫ42%) and the oxidative capacity (Ϫ34%), but did not alter the bioenergetics status in contracting muscle. Our findings demonstrate in vivo that sActRIIB-Fc treatment increases absolute force-generating capacity and reduces mitochondrial function in glycolytic gastrocnemius muscle, but this reduction does not compromise energy status during sustained activity. Overall, these data support the clinical interest of postnatal ActRIIB blockade. skeletal muscle hypertrophy; activin type IIB receptor; myostatin; force; fatigue ACTIVIN TYPE IIB RECEPTOR (ActRIIB) is a transmembrane serinethreonine kinase receptor highly expressed in mammalian skeletal muscle. It mediates signaling for myostatin (GDF8) and other members of the transforming growth factor-␤ family that are involved in the negative regulation of skeletal muscle development (16,37). Disruption of the ActRIIB signaling pathway leads to a rapid and massive increase in muscle mass resulting from fiber hypertrophy with increased myofiber protein synthesis (10, 58). In that context, several pharmacological approaches based on the postnatal ActRIIB signaling blockade have been considered for counteracting muscle wasting commonly associated to aging, neuromuscular disorders and various catabolic diseases (17,33,38). These approaches mainly include the systemic delivery of neutralizing antibodies against ActRIIB or myostatin (31, 36), and injection of a soluble recombinant form of ActRIIB (sActRIIB-Fc), which acts as a decoy receptor disrupting the interaction of endogenous ActRIIB receptor with its ligands (5,38,44).Although ActRIIB signaling blockade has been already tested in patients (30, 57) and animal models (10,44,47) suffering from dystrophi...

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A strictly noninvasive MR setup dedicated to longitudinal studies of mechanical performance, bioenergetics, anatomy, and muscle recruitment in contracting mouse skeletal muscle

Cited by 39 publications

References 27 publications

Assessing tissue metabolism by phosphorous-31 magnetic resonance spectroscopy and imaging: a methodology review

Assessing tissue metabolism by phosphorous-31 magnetic resonance spectroscopy and imaging: a methodology review

Lack of myostatin impairs mechanical performance and ATP cost of contraction in exercising mouse gastrocnemius muscle in vivo

Mitochondrial impairment induced by postnatal ActRIIB blockade does not alter function and energy status in exercising mouse glycolytic muscle in vivo

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