Reduced skeletal muscle phosphocreatine concentration in type 2 diabetic patients: a quantitative image-based phosphorus-31 MR spectroscopy study

Ripley, E; Clarke, Geoffrey D.; Hamidi, Vala; Martinez, Robert A.; Settles, F; Solis, Carolina; Deng, Shengwen; Abdul‐Ghani, Muhammad; Tripathy, Devjit; DeFronzo, Ralph A.

doi:10.1152/ajpendo.00426.2017

Cited by 18 publications

(24 citation statements)

References 63 publications

(99 reference statements)

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“…These participants, while all obese, had a wide range in muscle mass markers (skeletal muscle index [SMI]: 6.2–11.0 ALM/hr 2 ; muscle volume: 1,073.1–2,709.4 cm 3 ) as well as muscle functionality (peak power: 25.0–227.8 W). Despite other reports linking phosphorus metabolites with insulin sensitivity (Ripley et al, 2018; Szendroedi et al, 2011), we found that type 2 diabetes status did not influence the in vivo metabolic phenotype (data not shown), and therefore, all subjects were grouped for correlative analyses. Next, we examined relationships with body composition measurements and found that SMI, an index of muscle mass used to define sarcopenic status, was associated with two metabolites, PCr ( r = .365; p ‐value = .008) and PDE2 ( r = −0.366; p ‐value = .008).…”

Section: Resultscontrasting

confidence: 90%

“…Though not as well studied, recent evidence has revealed that resting in vivo phosphorus metabolite levels may relate to whole‐body and muscle‐specific phenotypes. Previous reports have shown dysregulation of resting in vivo phosphorus metabolites under pathological conditions, including obesity, type 2 diabetes, spinal cord injury, and muscular dystrophy, and appear to be linked to clinical measures of glycemic control and body composition (Hooijmans et al, 2017; McCully, Mulcahy, Ryan, & Zhao, 2011; Ripley et al, 2018; Szendroedi et al, 2011). Specifically, resting phosphocreatine (PCr) levels have been shown to be negatively associated with HbA1c and fasting glucose levels, while heightened levels are linked with elevated intracellular ATP levels (Ripley et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Previous reports have shown dysregulation of resting in vivo phosphorus metabolites under pathological conditions, including obesity, type 2 diabetes, spinal cord injury, and muscular dystrophy, and appear to be linked to clinical measures of glycemic control and body composition (Hooijmans et al, 2017; McCully, Mulcahy, Ryan, & Zhao, 2011; Ripley et al, 2018; Szendroedi et al, 2011). Specifically, resting phosphocreatine (PCr) levels have been shown to be negatively associated with HbA1c and fasting glucose levels, while heightened levels are linked with elevated intracellular ATP levels (Ripley et al, 2018). Additionally, phosphodiester (PDE) content, a putative marker of skeletal muscle membrane damage, is elevated under conditions of lower muscle mass in spinal cord injury (McCully et al, 2011) and muscular dystrophy (Hooijmans et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, phosphodiester (PDE) content, a putative marker of skeletal muscle membrane damage, is elevated under conditions of lower muscle mass in spinal cord injury (McCully et al, 2011) and muscular dystrophy (Hooijmans et al, 2017). Furthermore, elevated PDE is associated with heightened HbA1c (Ripley et al, 2018; Szendroedi et al, 2011), reduced insulin sensitivity (Ripley et al, 2018; Szendroedi et al, 2011), increased body mass (Szendroedi et al, 2011), and elevated intramyocellular lipids (Ripley et al, 2018). Along with in vivo measures, biochemical analyses of muscle biospecimens have revealed an integral role of phosphorus metabolites in metabolic health.…”

Section: Introductionmentioning

confidence: 99%

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Older adults with sarcopenia have distinct skeletal muscle phosphodiester, phosphocreatine, and phospholipid profiles

et al. 2020

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The loss of skeletal muscle mass and function with age (sarcopenia) is a critical healthcare challenge for older adults. 31‐phosphorus magnetic resonance spectroscopy (31P‐MRS) is a powerful tool used to evaluate phosphorus metabolite levels in muscle. Here, we sought to determine which phosphorus metabolites were linked with reduced muscle mass and function in older adults. This investigation was conducted across two separate studies. Resting phosphorus metabolites in skeletal muscle were examined by 31P‐MRS. In the first study, fifty‐five older adults with obesity were enrolled and we found that resting phosphocreatine (PCr) was positively associated with muscle volume and knee extensor peak power, while a phosphodiester peak (PDE2) was negatively related to these variables. In the second study, we examined well‐phenotyped older adults that were classified as nonsarcopenic or sarcopenic based on sex‐specific criteria described by the European Working Group on Sarcopenia in Older People. PCr content was lower in muscle from older adults with sarcopenia compared to controls, while PDE2 was elevated. Percutaneous biopsy specimens of the vastus lateralis were obtained for metabolomic and lipidomic analyses. Lower PCr was related to higher muscle creatine. PDE2 was associated with glycerol‐phosphoethanolamine levels, a putative marker of phospholipid membrane damage. Lipidomic analyses revealed that the major phospholipids, (phosphatidylcholine, phosphatidylethanolamine, and phosphatidylglycerol) were elevated in sarcopenic muscle and were inversely related to muscle volume and peak power. These data suggest phosphorus metabolites and phospholipids are associated with the loss of skeletal muscle mass and function in older adults.

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Section: Resultscontrasting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Older adults with sarcopenia have distinct skeletal muscle phosphodiester, phosphocreatine, and phospholipid profiles

et al. 2020

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“…In human patients with type II diabetes, ATP and ADP were measured in vivo in vastus lateralis [67]. Compared to age, sex, and BMI matched non-diabetic controls, diabetic patients display significantly less ATP, ADP, and PCr (phosphocreatine).…”

Section: Diabetesmentioning

confidence: 99%

Increased Adenine Nucleotide Degradation in Skeletal Muscle Atrophy

Miller

Hafen

Brault

2019

IJMS

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Adenine nucleotides (AdNs: ATP, ADP, AMP) are essential biological compounds that facilitate many necessary cellular processes by providing chemical energy, mediating intracellular signaling, and regulating protein metabolism and solubilization. A dramatic reduction in total AdNs is observed in atrophic skeletal muscle across numerous disease states and conditions, such as cancer, diabetes, chronic kidney disease, heart failure, COPD, sepsis, muscular dystrophy, denervation, disuse, and sarcopenia. The reduced AdNs in atrophic skeletal muscle are accompanied by increased expression/activities of AdN degrading enzymes and the accumulation of degradation products (IMP, hypoxanthine, xanthine, uric acid), suggesting that the lower AdN content is largely the result of increased nucleotide degradation. Furthermore, this characteristic decrease of AdNs suggests that increased nucleotide degradation contributes to the general pathophysiology of skeletal muscle atrophy. In view of the numerous energetic, and non-energetic, roles of AdNs in skeletal muscle, investigations into the physiological consequences of AdN degradation may provide valuable insight into the mechanisms of muscle atrophy.

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Multiparametric Aging Study Across Adulthood in the Leg Through Quantitative MR Imaging, ¹H Spectroscopy, and ³¹P Spectroscopy at 3T

Lopez Kolkovsky,

Matot,

Baudin

et al. 2024

Magnetic Resonance Imaging

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BackgroundImproved characterization of healthy muscle aging is needed to establish early biomarkers in age‐related diseases.PurposeTo quantify age‐related changes on multiple MRI and clinical variables evaluated in the same cohort and identify correlations among them.Study TypeProspective.Population70 healthy subjects (30 men) from 20 to 81 years old.Field Strength/Sequence3T/water T2 (multiecho SE, multi‐TE STEAM), water T1 (GRE MR Fingerprinting), fat‐fraction (multiecho GRE, multi‐TE STEAM), carnosine (PRESS), multicomponent water T2 (ISIS‐CPMG SE train), and 31P pulse‐acquire spectroscopy.AssessmentAge‐ and sex‐related changes on: Imaging: fat‐fraction (FFMRI), water T1 (T1‐H2O), and T2 (T2‐H2O‐MRI) and their heterogeneities ΔT1‐H2O and ΔT2‐H2O‐MRI in the posterior compartment (PC) and anterior compartment (AC) of the leg. 1H spectroscopy: Carnosine concentration, pH, water T2 components (T2‐H2O‐CPMG), fat‐fraction (FFMRS), and water T2 (T2‐H2O‐MRS) in the gastrocnemius medialis. 31P spectroscopy: Phosphodiesters (PDE), phosphomonoesters, inorganic phosphates (Pi), and phosphocreatine (PCr) normalized to adenosine triphosphate (ATP) and pH in the calf. Clinical evaluation: Body‐mass index (BMI), gait speed (GS), plantar flexion strength, handgrip strength (HS), HS normalized to wrist circumference (HSnorm), physical activity assessment. Statistical TestsMultilinear regressions with sex and age as fixed factors. Spearman correlations calculated between variables. Benjamini–Hochberg procedure for false positives reduction (5% rate). A P < 0.05 significance level was used.ResultsSignificant age‐related increases were found for BMI (ρAge = 0.04), HSnorm (ρAge = −0.01), PDE/ATP (ρAge = 2.8 × 10−3), Pi/ATP (ρAge = 2.0 × 10−3), Pi/PCr (ρAge = 0.3 × 10−3), T2‐H2O‐MRS (ρAge = 0.051 msec), FFMRS (ρAge = 0.036) the intermediate T2‐H2O‐CPMG component time (ρAge = 0.112 msec), and fraction (ρAge = −0.3 × 10−3); and in both compartments for FFMRI (ρAge = 0.06, PC; ρAge = 0.06, AC), T2‐H2O‐MRI (ρAge = 0.05, PC; ρAge = 0.05, AC; msec), ΔT2‐H2O‐MRI (ρAge = 0.02, PC; ρAge = 0.02, AC; msec), T1‐H2O (ρAge = 1.08, PC; ρAge = 1.06, AC; msec), and ΔT1‐H2O (ρAge = 0.22, PC; ρAge = 0.37, AC; msec). The best age predictors, accounting for sex‐related differences, were HSnorm (R2 = 0.52) and PDE/ATP (R2 = 0.44). In both leg compartments, the imaging measures and HSnorm were intercorrelated. In PC, T2‐H2O‐MRS and FFMRS also showed numerous correlations to the imaging measures. PDE/ATP correlated to T1‐H2O, T2‐H2O‐MRI, ΔT2‐H2O‐MRI, FFMRI, FFMRS, the intermediate T2‐H2O‐CPMG, BMI, Pi/PCr, and HSnorm.Data ConclusionOur multiparametric MRI approach provided an integrative view of age‐related changes in the leg and revealed multiple correlations between these parameters and the normalized HS.Level of Evidence1Technical EfficacyStage 3

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Reduced skeletal muscle phosphocreatine concentration in type 2 diabetic patients: a quantitative image-based phosphorus-31 MR spectroscopy study

Cited by 18 publications

References 63 publications

Older adults with sarcopenia have distinct skeletal muscle phosphodiester, phosphocreatine, and phospholipid profiles

Older adults with sarcopenia have distinct skeletal muscle phosphodiester, phosphocreatine, and phospholipid profiles

Increased Adenine Nucleotide Degradation in Skeletal Muscle Atrophy

Multiparametric Aging Study Across Adulthood in the Leg Through Quantitative MR Imaging, ¹H Spectroscopy, and ³¹P Spectroscopy at 3T

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Reduced skeletal muscle phosphocreatine concentration in type 2 diabetic patients: a quantitative image-based phosphorus-31 MR spectroscopy study

Cited by 18 publications

References 63 publications

Older adults with sarcopenia have distinct skeletal muscle phosphodiester, phosphocreatine, and phospholipid profiles

Older adults with sarcopenia have distinct skeletal muscle phosphodiester, phosphocreatine, and phospholipid profiles

Increased Adenine Nucleotide Degradation in Skeletal Muscle Atrophy

Multiparametric Aging Study Across Adulthood in the Leg Through Quantitative MR Imaging, 1H Spectroscopy, and 31P Spectroscopy at 3T

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Multiparametric Aging Study Across Adulthood in the Leg Through Quantitative MR Imaging, ¹H Spectroscopy, and ³¹P Spectroscopy at 3T