Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation.

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Standard

Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation. / Steensberg, Adam; van Hall, Gerrit; Keller, Charlotte; Osada, Takuya; Schjerling, Peter; Pedersen, Bente Klarlund; Saltin, Bengt; Febbraio, Mark A.

I: Journal of Physiology, Bind 541, Nr. Pt 1, 2002, s. 273-81.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Steensberg, A, van Hall, G, Keller, C, Osada, T, Schjerling, P, Pedersen, BK, Saltin, B & Febbraio, MA 2002, 'Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation.', Journal of Physiology, bind 541, nr. Pt 1, s. 273-81.

APA

Steensberg, A., van Hall, G., Keller, C., Osada, T., Schjerling, P., Pedersen, B. K., Saltin, B., & Febbraio, M. A. (2002). Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation. Journal of Physiology, 541(Pt 1), 273-81.

Vancouver

Steensberg A, van Hall G, Keller C, Osada T, Schjerling P, Pedersen BK o.a. Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation. Journal of Physiology. 2002;541(Pt 1):273-81.

Author

Steensberg, Adam ; van Hall, Gerrit ; Keller, Charlotte ; Osada, Takuya ; Schjerling, Peter ; Pedersen, Bente Klarlund ; Saltin, Bengt ; Febbraio, Mark A. / Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation. I: Journal of Physiology. 2002 ; Bind 541, Nr. Pt 1. s. 273-81.

Bibtex

@article{208c2370ac0211ddb5e9000ea68e967b,
title = "Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation.",
abstract = "There are many factors that can influence glucose uptake by contracting skeletal muscle during exercise and although one may be intramuscular glycogen content, this relationship is at present not fully elucidated. To test the hypothesis that muscle glycogen concentration influences glucose uptake during exercise, 13 healthy men were studied during two series of experiments. Seven men completed 4 h of two-legged knee extensor exercise 16 h after reducing of muscle glycogen by completing 60 min of single-legged cycling (Series 1). A further six men completed 3 h of two-legged knee extensor exercise on two occasions: one after 60 min of two-legged cycling (16 h prior to the experimental trial) followed by a high carbohydrate diet (HCHO) and the other after the same exercise followed by a low carbohydrate diet (LCHO) (Series 2). Muscle glycogen was decreased by 40 % when comparing the pre-exercised leg (EL) with the control leg (CL) prior to exercise in Series 1. In addition, muscle glycogen was decreased by the same magnitude when comparing LCHO with HCHO in Series 2. In Series 1, glucose uptake was 3-fold higher in the first 60 min of exercise, in the presence of unchanged pre-exercise GLUT4 protein in EL compared with CL, suggesting that the lower glycogen, and not the exercise the day before, might have provided the stimulus for increased glucose uptake. Despite the same magnitude of difference in pre-exercise glycogen concentration when comparing Series 1 with Series 2, neither direct-nor isotopic tracer-determined glucose uptake was higher in LCHO compared with HCHO in Series 2. However, arterial concentrations of insulin and glucose were lower, while free fatty acids and adrenaline were higher in LCHO compared with HCHO. These data suggest that pre-exercise glycogen content may influence glucose uptake during subsequent exercise. However, this is only the case when delivery of substrates and hormones remains constant. When delivery of substrates and hormones is altered, the potential effect of glycogen on glucose uptake is negated.",
author = "Adam Steensberg and {van Hall}, Gerrit and Charlotte Keller and Takuya Osada and Peter Schjerling and Pedersen, {Bente Klarlund} and Bengt Saltin and Febbraio, {Mark A}",
note = "Keywords: Adult; Bicycling; Blood Glucose; Blotting, Northern; Diet; Exercise; Fatty Acids, Nonesterified; Glucose; Glucose Transporter Type 4; Glycogen; Hormones; Humans; Insulin; Leg; Male; Monosaccharide Transport Proteins; Muscle Proteins; Muscle, Skeletal; RNA, Messenger; Regional Blood Flow",
year = "2002",
language = "English",
volume = "541",
pages = "273--81",
journal = "The Journal of Physiology",
issn = "0022-3751",
publisher = "Wiley-Blackwell",
number = "Pt 1",

}

RIS

TY - JOUR

T1 - Muscle glycogen content and glucose uptake during exercise in humans: influence of prior exercise and dietary manipulation.

AU - Steensberg, Adam

AU - van Hall, Gerrit

AU - Keller, Charlotte

AU - Osada, Takuya

AU - Schjerling, Peter

AU - Pedersen, Bente Klarlund

AU - Saltin, Bengt

AU - Febbraio, Mark A

N1 - Keywords: Adult; Bicycling; Blood Glucose; Blotting, Northern; Diet; Exercise; Fatty Acids, Nonesterified; Glucose; Glucose Transporter Type 4; Glycogen; Hormones; Humans; Insulin; Leg; Male; Monosaccharide Transport Proteins; Muscle Proteins; Muscle, Skeletal; RNA, Messenger; Regional Blood Flow

PY - 2002

Y1 - 2002

N2 - There are many factors that can influence glucose uptake by contracting skeletal muscle during exercise and although one may be intramuscular glycogen content, this relationship is at present not fully elucidated. To test the hypothesis that muscle glycogen concentration influences glucose uptake during exercise, 13 healthy men were studied during two series of experiments. Seven men completed 4 h of two-legged knee extensor exercise 16 h after reducing of muscle glycogen by completing 60 min of single-legged cycling (Series 1). A further six men completed 3 h of two-legged knee extensor exercise on two occasions: one after 60 min of two-legged cycling (16 h prior to the experimental trial) followed by a high carbohydrate diet (HCHO) and the other after the same exercise followed by a low carbohydrate diet (LCHO) (Series 2). Muscle glycogen was decreased by 40 % when comparing the pre-exercised leg (EL) with the control leg (CL) prior to exercise in Series 1. In addition, muscle glycogen was decreased by the same magnitude when comparing LCHO with HCHO in Series 2. In Series 1, glucose uptake was 3-fold higher in the first 60 min of exercise, in the presence of unchanged pre-exercise GLUT4 protein in EL compared with CL, suggesting that the lower glycogen, and not the exercise the day before, might have provided the stimulus for increased glucose uptake. Despite the same magnitude of difference in pre-exercise glycogen concentration when comparing Series 1 with Series 2, neither direct-nor isotopic tracer-determined glucose uptake was higher in LCHO compared with HCHO in Series 2. However, arterial concentrations of insulin and glucose were lower, while free fatty acids and adrenaline were higher in LCHO compared with HCHO. These data suggest that pre-exercise glycogen content may influence glucose uptake during subsequent exercise. However, this is only the case when delivery of substrates and hormones remains constant. When delivery of substrates and hormones is altered, the potential effect of glycogen on glucose uptake is negated.

AB - There are many factors that can influence glucose uptake by contracting skeletal muscle during exercise and although one may be intramuscular glycogen content, this relationship is at present not fully elucidated. To test the hypothesis that muscle glycogen concentration influences glucose uptake during exercise, 13 healthy men were studied during two series of experiments. Seven men completed 4 h of two-legged knee extensor exercise 16 h after reducing of muscle glycogen by completing 60 min of single-legged cycling (Series 1). A further six men completed 3 h of two-legged knee extensor exercise on two occasions: one after 60 min of two-legged cycling (16 h prior to the experimental trial) followed by a high carbohydrate diet (HCHO) and the other after the same exercise followed by a low carbohydrate diet (LCHO) (Series 2). Muscle glycogen was decreased by 40 % when comparing the pre-exercised leg (EL) with the control leg (CL) prior to exercise in Series 1. In addition, muscle glycogen was decreased by the same magnitude when comparing LCHO with HCHO in Series 2. In Series 1, glucose uptake was 3-fold higher in the first 60 min of exercise, in the presence of unchanged pre-exercise GLUT4 protein in EL compared with CL, suggesting that the lower glycogen, and not the exercise the day before, might have provided the stimulus for increased glucose uptake. Despite the same magnitude of difference in pre-exercise glycogen concentration when comparing Series 1 with Series 2, neither direct-nor isotopic tracer-determined glucose uptake was higher in LCHO compared with HCHO in Series 2. However, arterial concentrations of insulin and glucose were lower, while free fatty acids and adrenaline were higher in LCHO compared with HCHO. These data suggest that pre-exercise glycogen content may influence glucose uptake during subsequent exercise. However, this is only the case when delivery of substrates and hormones remains constant. When delivery of substrates and hormones is altered, the potential effect of glycogen on glucose uptake is negated.

M3 - Journal article

C2 - 12015435

VL - 541

SP - 273

EP - 281

JO - The Journal of Physiology

JF - The Journal of Physiology

SN - 0022-3751

IS - Pt 1

ER -

ID: 8442712