Literature DB >> 27812541

Muscle oxidative phosphorylation quantitation using creatine chemical exchange saturation transfer (CrCEST) MRI in mitochondrial disorders.

Catherine DeBrosse1, Ravi Prakash Reddy Nanga1, Neil Wilson1, Kevin D'Aquilla1, Mark Elliott1, Hari Hariharan1, Felicia Yan2, Kristin Wade2, Sara Nguyen2, Diana Worsley2, Chevonne Parris-Skeete2, Elizabeth McCormick3, Rui Xiao4, Zuela Zolkipli Cunningham5, Lauren Fishbein6, Katherine L Nathanson7,8, David R Lynch5, Virginia A Stallings9,10, Marc Yudkoff3,10, Marni J Falk3,10, Ravinder Reddy1, Shana E McCormack2,10.   

Abstract

Systemic mitochondrial energy deficiency is implicated in the pathophysiology of many age-related human diseases. Currently available tools to estimate mitochondrial oxidative phosphorylation (OXPHOS) capacity in skeletal muscle in vivo lack high anatomic resolution. Muscle groups vary with respect to their contractile and metabolic properties. Therefore, muscle group-specific estimates of OXPHOS would be advantageous. To address this need, a noninvasive creatine chemical exchange saturation transfer (CrCEST) MRI technique has recently been developed, which provides a measure of free creatine. After exercise, skeletal muscle can be imaged with CrCEST in order to make muscle group-specific measurements of OXPHOS capacity, reflected in the recovery rate (τCr) of free Cr. In this study, we found that individuals with genetic mitochondrial diseases had significantly (P = 0.026) prolonged postexercise τCr in the medial gastrocnemius muscle, suggestive of less OXPHOS capacity. Additionally, we observed that lower resting CrCEST was associated with prolonged τPCr, with a Pearson's correlation coefficient of -0.42 (P = 0.046), consistent with previous hypotheses predicting that resting creatine levels may correlate with 31P magnetic resonance spectroscopy-based estimates of OXPHOS capacity. We conclude that CrCEST can noninvasively detect changes in muscle creatine content and OXPHOS capacity, with high anatomic resolution, in individuals with mitochondrial disorders.

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Year:  2016        PMID: 27812541      PMCID: PMC5085612          DOI: 10.1172/jci.insight.88207

Source DB:  PubMed          Journal:  JCI Insight        ISSN: 2379-3708


  52 in total

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Journal:  Biochim Biophys Acta       Date:  1995-05-24

2.  A mitochondrial bioenergetic etiology of disease.

Authors:  Douglas C Wallace
Journal:  J Clin Invest       Date:  2013-04-01       Impact factor: 14.808

3.  Deficit of in vivo mitochondrial ATP production in patients with Friedreich ataxia.

Authors:  R Lodi; J M Cooper; J L Bradley; D Manners; P Styles; D J Taylor; A H Schapira
Journal:  Proc Natl Acad Sci U S A       Date:  1999-09-28       Impact factor: 11.205

4.  Creatine transporter and mitochondrial creatine kinase protein content in myopathies.

Authors:  M A Tarnopolsky; A Parshad; B Walzel; U Schlattner; T Wallimann
Journal:  Muscle Nerve       Date:  2001-05       Impact factor: 3.217

5.  Frequencies of myohistological mitochondrial changes in patients with mitochondrial DNA deletions and the common m.3243A>G point mutation.

Authors:  Charlotte Maria Zierz; Pushpa Raj Joshi; Stephan Zierz
Journal:  Neuropathology       Date:  2014-11-06       Impact factor: 1.906

6.  Age-related changes in oxidative capacity differ between locomotory muscles and are associated with physical activity behavior.

Authors:  Ryan G Larsen; Damien M Callahan; Stephen A Foulis; Jane A Kent-Braun
Journal:  Appl Physiol Nutr Metab       Date:  2012-01-11       Impact factor: 2.665

7.  Method for controlled mitochondrial perturbation during phosphorus MRS in children.

Authors:  Melanie Cree-Green; Bradley R Newcomer; Mark Brown; Amber Hull; Amy D West; Debra Singel; Jane E B Reusch; Kim McFann; Judith G Regensteiner; Kristen J Nadeau
Journal:  Med Sci Sports Exerc       Date:  2014-10       Impact factor: 5.411

8.  Monitoring population health for Healthy People 2020: evaluation of the NIH PROMIS® Global Health, CDC Healthy Days, and satisfaction with life instruments.

Authors:  John P Barile; Bryce B Reeve; Ashley Wilder Smith; Matthew M Zack; Sandra A Mitchell; Rosemarie Kobau; David F Cella; Cecily Luncheon; William W Thompson
Journal:  Qual Life Res       Date:  2012-08-18       Impact factor: 4.147

9.  In vivo muscle magnetic resonance spectroscopy in the clinical investigation of mitochondrial disease.

Authors:  P M Matthews; C Allaire; E A Shoubridge; G Karpati; S Carpenter; D L Arnold
Journal:  Neurology       Date:  1991-01       Impact factor: 9.910

10.  Orthostatic tremor, progressive external ophthalmoplegia, and Twinkle.

Authors:  Margherita Milone; Bryan T Klassen; Megan L Landsverk; Richard H Haas; Lee-Jun Wong
Journal:  JAMA Neurol       Date:  2013-11       Impact factor: 18.302
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  17 in total

1.  CEST MR-Fingerprinting: Practical considerations and insights for acquisition schedule design and improved reconstruction.

Authors:  Or Perlman; Kai Herz; Moritz Zaiss; Ouri Cohen; Matthew S Rosen; Christian T Farrar
Journal:  Magn Reson Med       Date:  2019-08-09       Impact factor: 4.668

Review 2.  Mitochondrial Dysfunction in Heart Failure With Preserved Ejection Fraction.

Authors:  Anupam A Kumar; Daniel P Kelly; Julio A Chirinos
Journal:  Circulation       Date:  2019-03-12       Impact factor: 29.690

3.  Early detection of elevated lactate levels in a mitochondrial disease model using chemical exchange saturation transfer (CEST) and magnetic resonance spectroscopy (MRS) at 7T-MRI.

Authors:  Shigeyoshi Saito; Yusuke Takahashi; Akiko Ohki; Yasunori Shintani; Takahiro Higuchi
Journal:  Radiol Phys Technol       Date:  2018-11-22

Review 4.  Nutritional Interventions for Mitochondrial OXPHOS Deficiencies: Mechanisms and Model Systems.

Authors:  Adam J Kuszak; Michael Graham Espey; Marni J Falk; Marissa A Holmbeck; Giovanni Manfredi; Gerald S Shadel; Hilary J Vernon; Zarazuela Zolkipli-Cunningham
Journal:  Annu Rev Pathol       Date:  2017-11-03       Impact factor: 23.472

5.  Amplified detection of phosphocreatine and creatine after supplementation using CEST MRI at high and ultrahigh magnetic fields.

Authors:  KowsalyaDevi Pavuluri; Jens T Rosenberg; Shannon Helsper; Shaowei Bo; Michael T McMahon
Journal:  J Magn Reson       Date:  2020-02-27       Impact factor: 2.229

Review 6.  Impaired Exercise Tolerance in Heart Failure With Preserved Ejection Fraction: Quantification of Multiorgan System Reserve Capacity.

Authors:  Matthew Nayor; Nicholas E Houstis; Mayooran Namasivayam; Jennifer Rouvina; Charles Hardin; Ravi V Shah; Jennifer E Ho; Rajeev Malhotra; Gregory D Lewis
Journal:  JACC Heart Fail       Date:  2020-06-10       Impact factor: 12.035

7.  Recovery kinetics of creatine in mild plantar flexion exercise using 3D creatine CEST imaging at 7 Tesla.

Authors:  Dushyant Kumar; Ravi Prakash Reddy Nanga; Deepa Thakuri; Neil Wilson; Abigail Cember; Melissa Lynne Martin; Dan Zhu; Russell T Shinohara; Qin Qin; Hari Hariharan; Ravinder Reddy
Journal:  Magn Reson Med       Date:  2020-08-15       Impact factor: 4.668

8.  A real-time monitoring platform of myogenesis regulators using double fluorescent labeling.

Authors:  Etai Sapoznik; Guoguang Niu; Yu Zhou; Peter M Prim; Tracy L Criswell; Shay Soker
Journal:  PLoS One       Date:  2018-02-14       Impact factor: 3.240

Review 9.  Role of frataxin protein deficiency and metabolic dysfunction in Friedreich ataxia, an autosomal recessive mitochondrial disease.

Authors:  Elisia Clark; Joseph Johnson; Yi Na Dong; Elizabeth Mercado-Ayon; Nathan Warren; Mattieu Zhai; Emily McMillan; Amy Salovin; Hong Lin; David R Lynch
Journal:  Neuronal Signal       Date:  2018-11-02

Review 10.  Biomarkers for Detecting Mitochondrial Disorders.

Authors:  Josef Finsterer; Sinda Zarrouk-Mahjoub
Journal:  J Clin Med       Date:  2018-01-30       Impact factor: 4.241
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