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Magnetic Resonance Spectroscopy Studies of Cardiac Muscle Metabolism

Sponsor
Johns Hopkins University (Other)
Overall Status
Recruiting
CT.gov ID
NCT00181259
Collaborator
National Heart, Lung, and Blood Institute (NHLBI) (NIH)
500
Enrollment
1
Location
427
Duration (Months)
1.2
Patients Per Site Per Month

Study Details

Study Description

Brief Summary

The metabolism of the heart provides the chemical energy needed to fuel ongoing normal heart contraction. Magnetic resonance spectroscopy is a technique used in a MRI scanner that can be used to measure and study heart metabolism directly but without blood sampling or obtaining tissue biopsies. One of the hypotheses this study aims to investigate is whether energy metabolism is reduced in heart failure and whether that contributes to the poor heart function.

Condition or Disease Intervention/Treatment Phase

    Detailed Description

    This study uses magnetic resonance (MR) spectroscopy to study heart metabolism and function in normal subjects and patients with left ventricular hypertrophy, dilated cardiomyopathy, and those with coronary artery disease.

    Study Design

    Study Type:
    Observational
    Anticipated Enrollment :
    500 participants
    Observational Model:
    Other
    Time Perspective:
    Prospective
    Official Title:
    In Vivo Cardiac Metabolism in Normal, Ischemic, and Cardiomyopathic Patients During Rest and Stress
    Study Start Date :
    Jan 1, 1988
    Anticipated Primary Completion Date :
    Aug 1, 2022
    Anticipated Study Completion Date :
    Aug 1, 2023

    Outcome Measures

    Primary Outcome Measures

    1. Phosphocreatine/adenosine triphosphate (PCr/ATP) and creatine kinase (CK) flux [At time of magnetic resonance spectroscopy (MRS)]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    Secondary Outcome Measures

    1. Phosphocreatine (PCr) [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    2. ATP [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    3. [Cr] or total creatine (CR), or CR/water ratio [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    4. Sodium (NA) [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    5. ATP flux [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    6. 31P distribution or metabolite map [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    7. 23Na distribution or metabolite map [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    8. CR distribution or metabolite map [At time of MRS]

      Can non-invasive magnetic resonance imaging and spectroscopy techniques be developed, validated, and implemented on clinical MR scanners in order to address the questions of a.) the extent to which myocardial high-energy phosphate (HEP), creatine (Cr), or sodium concentrations change in response to and after transient ischemia or chronic ischemic injury, b.) the extent to which myocardial high-energy phosphates, creatine, or sodium concentrations as well as HEP flux are altered in cardiomyopathic patients with and without/ congestive heart failure, c.) can spatial differences in cardiac metabolites (HEP, Cr) or ions (Na) induced by ischemic injury be identified with novel, non-invasive imaging techniques?

    Eligibility Criteria

    Criteria

    Ages Eligible for Study:
    18 Years and Older
    Sexes Eligible for Study:
    All
    Accepts Healthy Volunteers:
    Yes
    Inclusion Criteria:

    • age > 18 years

    • Healthy subjects: no history of heart disease

    • Dilated cardiomyopathy: history of heart failure, ejection fraction (EF) <40%

    • Left ventricular hypertrophy: wall thickness >1.2cm

    • Coronary artery disease: >50% coronary lesion or positive stress test

    Exclusion Criteria:
    • contraindication to MRI

    Contacts and Locations

    Locations

    Site City State Country Postal Code
    1 Johns Hopkins Medical Institutions Baltimore Maryland United States 21205

    Sponsors and Collaborators

    • Johns Hopkins University
    • National Heart, Lung, and Blood Institute (NHLBI)

    Investigators

    • Principal Investigator: Robert G. Weiss, MD, Johns Hopkins University

    Study Documents (Full-Text)

    None provided.

    More Information

    Publications

    None provided.
    Responsible Party:
    Johns Hopkins University
    ClinicalTrials.gov Identifier:
    NCT00181259
    Other Study ID Numbers:
    • NA_00044690
    • R01HL061912-14
    First Posted:
    Sep 16, 2005
    Last Update Posted:
    Sep 21, 2021
    Last Verified:
    Sep 1, 2021
    Individual Participant Data (IPD) Sharing Statement:
    No
    Plan to Share IPD:
    No
    Additional relevant MeSH terms:
    Heart Failure

    Study Results

    No Results Posted as of Sep 21, 2021