Role of Tissue-Specific Blood Flow and Tissue Recruitment in Insulin-Mediated Glucose Uptake of Human Skeletal Muscle

Background —Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake. Methods...

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Published inCirculation (New York, N.Y.) Vol. 98; no. 3; pp. 234 - 241
Main Authors Bonadonna, Riccardo C., Saccomani, Maria Pia, Del Prato, Stefano, Bonora, Enzo, DeFronzo, Ralph A., Cobelli, Claudio
Format Journal Article
LanguageEnglish
Published Hagerstown, MD Lippincott Williams & Wilkins 21.07.1998
American Heart Association, Inc
Subjects
Adult
Biological and medical sciences
Blood Glucose - analysis
Cardiovascular system
Extracellular Space - metabolism
Female
Forearm - blood supply
Glucose - metabolism
Glucose Clamp Technique
Humans
Insulin - blood
Insulin - pharmacology
Investigative techniques of hemodynamics
Investigative techniques, diagnostic techniques (general aspects)
Male
Medical sciences
Muscle, Skeletal - metabolism
Osmolar Concentration
Regional Blood Flow - drug effects
Human
Exploration
Glucose
Metabolism
Striated muscle
Insulin
Capture
Blood flow
Regulation(control)
Blood vessel
Circulatory system
Hemodynamics
Radial artery
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Abstract Background —Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake. Methods and Results —Twenty healthy subjects were studied with the forearm perfusion technique in combination with the euglycemic insulin clamp technique. Ten subjects were studied at physiological insulin concentrations (≈400 pmol/L) and the other 10 at supraphysiological insulin concentrations (≈5600 pmol/L). Four additional subjects underwent a saline control study. Pulse injections of a nonmetabolizable extracellular marker (1-[ 3 H]- l -glucose) were administered into the brachial artery, and its washout curves were measured in one ipsilateral deep forearm vein and used to estimate the extracellular volume of distribution and hence the amount of muscle tissue drained by the deep forearm vein. Both during saline infusion and at physiological levels of hyperinsulinemia we observed no changes in blood flow and/or muscle tissue drained by the deep forearm vein. However, supraphysiological hyperinsulinemia accelerated total forearm blood flow (45.0±1.8 versus 36.5±1.3 mL · min −1 · kg −1 , P <0.01) and increased the amount of muscle tissue drained by the deep forearm vein (305±46 versus 229±32 g, P <0.05). The amount of tissue newly recruited by insulin was strongly correlated to the concomitant increase in tissue glucose uptake ( r =0.789, P <0.01). Conclusions —Acceleration of forearm blood flow mediated by supraphysiological hyperinsulinemia is accompanied by tissue recruitment, which may be a relevant determinant of forearm (muscle) glucose uptake.
AbstractList Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake.BACKGROUNDConflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake.Twenty healthy subjects were studied with the forearm perfusion technique in combination with the euglycemic insulin clamp technique. Ten subjects were studied at physiological insulin concentrations (approximately 400 pmol/L) and the other 10 at supraphysiological insulin concentrations (approximately 5600 pmol/L). Four additional subjects underwent a saline control study. Pulse injections of a nonmetabolizable extracellular marker (1-[3H]-L-glucose) were administered into the brachial artery, and its washout curves were measured in one ipsilateral deep forearm vein and used to estimate the extracellular volume of distribution and hence the amount of muscle tissue drained by the deep forearm vein. Both during saline infusion and at physiological levels of hyperinsulinemia we observed no changes in blood flow and/or muscle tissue drained by the deep forearm vein. However, supraphysiological hyperinsulinemia accelerated total forearm blood flow (45.0+/-1.8 versus 36.5+/-1.3 mL x min(-1) x kg(-1), P<0.01) and increased the amount of muscle tissue drained by the deep forearm vein (305+/-46 versus 229+/-32 g, P<0.05). The amount of tissue newly recruited by insulin was strongly correlated to the concomitant increase in tissue glucose uptake (r=0.789, P<0.01).METHODS AND RESULTSTwenty healthy subjects were studied with the forearm perfusion technique in combination with the euglycemic insulin clamp technique. Ten subjects were studied at physiological insulin concentrations (approximately 400 pmol/L) and the other 10 at supraphysiological insulin concentrations (approximately 5600 pmol/L). Four additional subjects underwent a saline control study. Pulse injections of a nonmetabolizable extracellular marker (1-[3H]-L-glucose) were administered into the brachial artery, and its washout curves were measured in one ipsilateral deep forearm vein and used to estimate the extracellular volume of distribution and hence the amount of muscle tissue drained by the deep forearm vein. Both during saline infusion and at physiological levels of hyperinsulinemia we observed no changes in blood flow and/or muscle tissue drained by the deep forearm vein. However, supraphysiological hyperinsulinemia accelerated total forearm blood flow (45.0+/-1.8 versus 36.5+/-1.3 mL x min(-1) x kg(-1), P<0.01) and increased the amount of muscle tissue drained by the deep forearm vein (305+/-46 versus 229+/-32 g, P<0.05). The amount of tissue newly recruited by insulin was strongly correlated to the concomitant increase in tissue glucose uptake (r=0.789, P<0.01).Acceleration of forearm blood flow mediated by supraphysiological hyperinsulinemia is accompanied by tissue recruitment, which may be a relevant determinant of forearm (muscle) glucose uptake.CONCLUSIONSAcceleration of forearm blood flow mediated by supraphysiological hyperinsulinemia is accompanied by tissue recruitment, which may be a relevant determinant of forearm (muscle) glucose uptake.
BACKGROUND: Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake. METHODS AND RESULTS: Twenty healthy subjects were studied with the forearm perfusion technique in combination with the euglycemic insulin clamp technique. Ten subjects were studied at physiological insulin concentrations (approximately 400 pmol/L) and the other 10 at supraphysiological insulin concentrations (approximately 5600 pmol/L). Four additional subjects underwent a saline control study. Pulse injections of a nonmetabolizable extracellular marker (1-[3H]-L-glucose) were administered into the brachial artery, and its washout curves were measured in one ipsilateral deep forearm vein and used to estimate the extracellular volume of distribution and hence the amount of muscle tissue drained by the deep forearm vein. Both during saline infusion and at physiological levels of hyperinsulinemia we observed no changes in blood flow and/or muscle tissue drained by the deep forearm vein. However, supraphysiological hyperinsulinemia accelerated total forearm blood flow (45.0+/-1.8 versus 36.5+/-1.3 mL x min(-1) x kg(-1), P0.01) and increased the amount of muscle tissue drained by the deep forearm vein (305+/-46 versus 229+/-32 g, P0.05). The amount of tissue newly recruited by insulin was strongly correlated to the concomitant increase in tissue glucose uptake (r=0.789, P0.01). CONCLUSIONS: Acceleration of forearm blood flow mediated by supraphysiological hyperinsulinemia is accompanied by tissue recruitment, which may be a relevant determinant of forearm (muscle) glucose uptake.
Background —Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake. Methods and Results —Twenty healthy subjects were studied with the forearm perfusion technique in combination with the euglycemic insulin clamp technique. Ten subjects were studied at physiological insulin concentrations (≈400 pmol/L) and the other 10 at supraphysiological insulin concentrations (≈5600 pmol/L). Four additional subjects underwent a saline control study. Pulse injections of a nonmetabolizable extracellular marker (1-[ 3 H]- l -glucose) were administered into the brachial artery, and its washout curves were measured in one ipsilateral deep forearm vein and used to estimate the extracellular volume of distribution and hence the amount of muscle tissue drained by the deep forearm vein. Both during saline infusion and at physiological levels of hyperinsulinemia we observed no changes in blood flow and/or muscle tissue drained by the deep forearm vein. However, supraphysiological hyperinsulinemia accelerated total forearm blood flow (45.0±1.8 versus 36.5±1.3 mL · min −1 · kg −1 , P <0.01) and increased the amount of muscle tissue drained by the deep forearm vein (305±46 versus 229±32 g, P <0.05). The amount of tissue newly recruited by insulin was strongly correlated to the concomitant increase in tissue glucose uptake ( r =0.789, P <0.01). Conclusions —Acceleration of forearm blood flow mediated by supraphysiological hyperinsulinemia is accompanied by tissue recruitment, which may be a relevant determinant of forearm (muscle) glucose uptake.
Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be predicted that if insulin augments blood flow by causing tissue recruitment, this mechanism would enhance limb glucose uptake. Twenty healthy subjects were studied with the forearm perfusion technique in combination with the euglycemic insulin clamp technique. Ten subjects were studied at physiological insulin concentrations (approximately 400 pmol/L) and the other 10 at supraphysiological insulin concentrations (approximately 5600 pmol/L). Four additional subjects underwent a saline control study. Pulse injections of a nonmetabolizable extracellular marker (1-[3H]-L-glucose) were administered into the brachial artery, and its washout curves were measured in one ipsilateral deep forearm vein and used to estimate the extracellular volume of distribution and hence the amount of muscle tissue drained by the deep forearm vein. Both during saline infusion and at physiological levels of hyperinsulinemia we observed no changes in blood flow and/or muscle tissue drained by the deep forearm vein. However, supraphysiological hyperinsulinemia accelerated total forearm blood flow (45.0+/-1.8 versus 36.5+/-1.3 mL x min(-1) x kg(-1), P<0.01) and increased the amount of muscle tissue drained by the deep forearm vein (305+/-46 versus 229+/-32 g, P<0.05). The amount of tissue newly recruited by insulin was strongly correlated to the concomitant increase in tissue glucose uptake (r=0.789, P<0.01). Acceleration of forearm blood flow mediated by supraphysiological hyperinsulinemia is accompanied by tissue recruitment, which may be a relevant determinant of forearm (muscle) glucose uptake.
Author Bonadonna, Riccardo C.
DeFronzo, Ralph A.
Bonora, Enzo
Del Prato, Stefano
Saccomani, Maria Pia
Cobelli, Claudio
Author_xml – sequence: 1
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  organization: From the Division of Endocrinology and Metabolic Diseases (R.C.B., E.B.), University of Verona and Azienda Ospedaliera di Verona (Italy); the Department of Electronics and Informatics (M.P.S., C.C.) and the Division of Metabolic Diseases (S.D.P.), University of Padua (Italy); and the Division of Diabetes (R.A.D.), University of Texas Health Science Center and Audie L. Murphy Veterans Administration Hospital, San Antonio, Tex
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  givenname: Maria Pia
  surname: Saccomani
  fullname: Saccomani, Maria Pia
  organization: From the Division of Endocrinology and Metabolic Diseases (R.C.B., E.B.), University of Verona and Azienda Ospedaliera di Verona (Italy); the Department of Electronics and Informatics (M.P.S., C.C.) and the Division of Metabolic Diseases (S.D.P.), University of Padua (Italy); and the Division of Diabetes (R.A.D.), University of Texas Health Science Center and Audie L. Murphy Veterans Administration Hospital, San Antonio, Tex
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  givenname: Stefano
  surname: Del Prato
  fullname: Del Prato, Stefano
  organization: From the Division of Endocrinology and Metabolic Diseases (R.C.B., E.B.), University of Verona and Azienda Ospedaliera di Verona (Italy); the Department of Electronics and Informatics (M.P.S., C.C.) and the Division of Metabolic Diseases (S.D.P.), University of Padua (Italy); and the Division of Diabetes (R.A.D.), University of Texas Health Science Center and Audie L. Murphy Veterans Administration Hospital, San Antonio, Tex
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  givenname: Enzo
  surname: Bonora
  fullname: Bonora, Enzo
  organization: From the Division of Endocrinology and Metabolic Diseases (R.C.B., E.B.), University of Verona and Azienda Ospedaliera di Verona (Italy); the Department of Electronics and Informatics (M.P.S., C.C.) and the Division of Metabolic Diseases (S.D.P.), University of Padua (Italy); and the Division of Diabetes (R.A.D.), University of Texas Health Science Center and Audie L. Murphy Veterans Administration Hospital, San Antonio, Tex
– sequence: 5
  givenname: Ralph A.
  surname: DeFronzo
  fullname: DeFronzo, Ralph A.
  organization: From the Division of Endocrinology and Metabolic Diseases (R.C.B., E.B.), University of Verona and Azienda Ospedaliera di Verona (Italy); the Department of Electronics and Informatics (M.P.S., C.C.) and the Division of Metabolic Diseases (S.D.P.), University of Padua (Italy); and the Division of Diabetes (R.A.D.), University of Texas Health Science Center and Audie L. Murphy Veterans Administration Hospital, San Antonio, Tex
– sequence: 6
  givenname: Claudio
  surname: Cobelli
  fullname: Cobelli, Claudio
  organization: From the Division of Endocrinology and Metabolic Diseases (R.C.B., E.B.), University of Verona and Azienda Ospedaliera di Verona (Italy); the Department of Electronics and Informatics (M.P.S., C.C.) and the Division of Metabolic Diseases (S.D.P.), University of Padua (Italy); and the Division of Diabetes (R.A.D.), University of Texas Health Science Center and Audie L. Murphy Veterans Administration Hospital, San Antonio, Tex
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Issue 3
Keywords Human
Exploration
Glucose
Metabolism
Striated muscle
Insulin
Capture
Blood flow
Regulation(control)
Blood vessel
Circulatory system
Hemodynamics
Radial artery
Language English
License CC BY 4.0
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PublicationTitle Circulation (New York, N.Y.)
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PublicationYear 1998
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American Heart Association, Inc
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Snippet Background —Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It...
Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It can be...
BACKGROUND: Conflicting evidence exists concerning whether insulin-induced vasodilation plays a mechanistic role in the regulation of limb glucose uptake. It...
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SubjectTerms Adult
Biological and medical sciences
Blood Glucose - analysis
Cardiovascular system
Extracellular Space - metabolism
Female
Forearm - blood supply
Glucose - metabolism
Glucose Clamp Technique
Humans
Insulin - blood
Insulin - pharmacology
Investigative techniques of hemodynamics
Investigative techniques, diagnostic techniques (general aspects)
Male
Medical sciences
Muscle, Skeletal - metabolism
Osmolar Concentration
Regional Blood Flow - drug effects
Title Role of Tissue-Specific Blood Flow and Tissue Recruitment in Insulin-Mediated Glucose Uptake of Human Skeletal Muscle
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