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Utilization of lipids during exercise in human subjects: metabolic and dietary constraints

Published online by Cambridge University Press:  09 March 2007

Fred Brouns  and
Ger J. van der Vusse
Fred Brouns*
Affiliation:
Novartis Nutrition Research Unit, PO Box 1350, NL-6201 BJ Maastricht and Department of Human Biology, Nutrition Toxicology and Environment Research Institute, Maastricht, The Netherlands
Ger J. van der Vusse
Affiliation:
Department of Physiology, Cardiovascular Research Institute, Maastricht, Maastricht University, Maastricht, The Netherlands
*
*Corresponding author:Dr Fred Brouns, fax +31 43 3670676, email F.Brouns@hb.unimaas.nl
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Abstract

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During endurance exercise, skeletal muscle relies mainly on both carbohydrate (CHO) and fat oxidation to cover energy needs. Numerous scientific studies have shown that increasing the exercise intensity leads to a progressive utilization of CHO. The latter will induce a state of glycogen depletion which is generally recognized as being a limiting factor for the continuation of strenuous exercise. Different dietary interventions have been proposed to overcome this limitation. A high-CHO diet during periods of intense training and competition, as well as CHO intake during exercise, are known to maintain a high rate of CHO oxidation and to delay fatigue. However, it has been recognized also that enhancing fatty acid (FA) oxidation during exercise induces a reduced rate of glycogen degradation, resulting in an improved endurance capacity. This is most strikingly observed as a result of frequent endurance exercise which improves a number of factors known to govern the FA flux and the oxidative capacity of skeletal muscle. Such factors are: (1) blood flow and capillarization; (2) lipolysis of triacylglycerol (TAG) in adipose tissue and circulating TAG and transport of FA from blood plasma to the sarcoplasm; (3) availability and rate of hydrolysis of intramuscular TAG; (4) activation of the FA and transport across the mitochondrial membrane; (5) the activity of enzymes in the oxidative pathway; (6) hormonal adaptations, i.e. sensitivity to catecholamines and insulin. The observation that the plasma FA concentration is an important factor in determining the rate of FA oxidation, and that some dietary factors may influence the rate of FA supply to muscle as well as to the mitochondria, has led to a number of dietary interventions with the ultimate goal to enhance FA oxidation and endurance performance. It appears that experimental data are not equivocal that dietary interventions, such as a high-fat diet, medium-chain TAG-fat emulsions and caffeine intake during exercise, as well as L-carnitine supplementation, do significantly enhance FA oxidation during exercise. So far, only regular endurance exercise can be classified as successful in achieving adaptations which enhance FA mobilization and oxidation.

Keywords

Fat intakeExerciseMedium-chain triacylglycerolsCaffeineL-carnitine
Type
Review Article
Information
British Journal of Nutrition , Volume 79 , Issue 2 , February 1998 , pp. 117 - 128
Copyright
Copyright © The Nutrition Society 1998

References

Abernethy, PJ, Thayer, R & Taylor, AW (1990) Acute and chronic responses of skeletal muscle to endurance and sprint exercise. Sports Medicine 10, 365389.Google Scholar
Abumrad, NA, Tepperman, HM & Tepperman, J (1980) Control of endogenous triglyceride breakdown in the mouse diaphragm. Journal of Lipid Research 21, 149155.Google Scholar
Acheson, KJ, Campbell, IT, Edholm, OG, Miller, DS & Stock, MJ (1980) The measurement of daily energy expenditure - an evaluation of some techniques. American Journal of Clinical Nutrition 33, 11551164.CrossRefGoogle ScholarPubMed
Ahlborg, G & Felig, P (1982) Lactate and glucose exchange across the forearm, legs, and splanchnic bed during and after prolonged leg exercise. Journal of Clinical Investigation 69, 4554.Google Scholar
Ahlborg, G, Wahren, J & Felig, P (1986) Splanchnic and peripheral glucose and lactate metabolism during and after prolonged arm exercise. Journal of Clinical Investigation 77, 690699.Google Scholar
Anselme, F, Collomp, K, Mercier, B, Ahmaïdi, S & Prefaut, Ch (1992) Caffeine increases maximal anaerobic power and blood lactate concentration. European Journal of Applied Physiology 65, 188191.Google Scholar
Armstrong, DT, Steele, R, Altszuler, N, Dunn, A, Bishop, JS & De Bodo, RC (1961) Regulation of plasma free fatty acid turnover. American Journal of Physiology 201, 915.Google Scholar
Arner, PE, Kriegholm, E, Engfeldt, P & Bolinder, J (1990) Adrenergic regulation of lipolysis in situ at rest and during exercise. Journal of Clinical Investigation 85, 893898.CrossRefGoogle ScholarPubMed
Arogyasami, J, Yang, HT & Winder, WW (1989) Effect of caffeine on glycogenolysis during exercise in endurance trained rats. Medicine and Science in Sports and Exercise 21, 173177.Google ScholarPubMed
Baldwin, KM, Klinkerfuss, GH, Terjung, RL, Molé, PA & Holloszy, JO (1972) Respiratory capacity of white, red, and intermediate muscle: adaptive response to exercise. American Journal of Physiology 222, 373378.Google Scholar
Barclay, JK & Stainsby, WN (1972) Intramuscular lipid store utilization by contracting dog skeletal muscle in situ. American Journal of Physiology 223, 115119.Google Scholar
Bassingthwaighte, JB, Noodleman, L, van der Vusse, GJ & Glatz, JFC (1989) Modeling of palmitate transport in the heart. Molecular and Cellular Biochemistry 88, 5159.Google Scholar
Beavo, JA, Rogers, NL, Crofford, OB, Hardman, JG, Sutherland, EW & Newman, EV (1970) Effects of xanthine derivatives on lipolysis and on adenosine 3',5'-monophosphate phosphodies-terase activity. Molecular Pharmacology 6, 597603.Google Scholar
Beckers, EJ, Jeukendrup, AE, Brouns, F, Wagenmakers, AJM & Saris, WHM (1992) Gastric emptying of carbohydrate-medium chain triglyceride suspensions at rest. International Journal of Sports Medicine 13, 581584.Google Scholar
Bellet, S, Kershbaum, A & Aspe, J (1965) The effect of caffeine on free fatty acids. Archives of Internal Medicine 116, 750752.CrossRefGoogle ScholarPubMed
Bellet, S, Kershbaum, A & Finck, EM (1968) Response of free fatty acids to coffee and caffeine. Metabolism 17, 702707.CrossRefGoogle ScholarPubMed
Bergström, J, Hermansen, L & Hultman, E (1967) Diet, muscle glycogen and physical performance. Acta Physiologica Scandinavia 71, 140150.Google Scholar
Bergström, J, Hultman, E, Jorfeldt, L, Pernow, B & Wahren, J (1969) Effect of nicotinic acid on physical work capacity and on metabolism of muscle glycogen in man. Journal of Applied Physiology 26, 170176.CrossRefGoogle Scholar
Berkowitz, BA & Spector, S (1971) Effect of caffeine and theophylline on peripheral catacholamines. European Journal of Pharmacology 13, 193196.CrossRefGoogle Scholar
Björkman, O (1986) Fuel utilization during exercise. Biochemical Aspects of Physical Exercise, pp. 245260, [Benzi, G, Packer, L and Siliprandi, N, editors]. Amsterdam: Elsevier Scientific Publishers.Google Scholar
Boesch, C, Slotboom, H, Hoppeler, H & Kreis, R (1997) In vivo determination of intra-myocellular lipids in human muscle by means of localized IH-MR-spectroscopy. Magnetic Resonance in Medicine 37, 484493.CrossRefGoogle Scholar
Bonen, A, Ness, GW, Belcastro, AN & Kirby, RL (1985) Mild exercise impedes glycogen repletion in muscle. Journal of Applied Physiology 58, 16221629.Google Scholar
Braun, JE, Severson, A & Severson, DL (1992) Regulation of the synthesis, processing and translocation of lipoprotein lipase. Biochemical Journal 287, 337347.Google Scholar
Brouns, F (1991) Gastrointestinal symptoms in athletes: physiological and nutritional aspects. In Advances in Nutrition and Top Sport, Vol. 32, pp. 166199 [Brouns, F editor]. Basel: Karger.Google Scholar
Brouns, F (1997) The effect of athletic training and dietary factors on the modulation of muscle glycogen. In Proceedings of the Esteve Foundation Symposium: The Clinical Pharmacology of Sport and Exercise, Vol. 7, pp. 181193 [Reilly, T and Orme, M, editors]. Amsterdam: Elsevier Scientific Publishers.Google Scholar
Brouns, F, Saris, WHM, Beckers, E, Adlercreutz, H, van der, Vusse GJ, Keizer, HA, Kuipers, H, Menheere, P, Wagenmakers, AJM & ten, Hoor F (1989) Metabolic changes induced by sustained exhaustive cycling and diet manipulation. International Journal of Sports Medicine 10, S49S62.CrossRefGoogle ScholarPubMed
Bülow, J (1988) Lipid mobilization and utilization. In Principles of Exercise Biochemistry, pp. 140163 [Poortmans, JR editor]. Basel: Karger.CrossRefGoogle Scholar
Camps, L, Reina, M, Lobera, M, Villard, S & Olivecrona, T (1990) Lipoprotein lipase: cellular origin and functional distribution. American Journal of Physiology 258, C673C681.Google Scholar
Casal, DC & Leon, AS (1985) Failure of caffeine to affect substrate utilization during prolonged running. Medicine and Science in Sports and Exercise 17, 174179.CrossRefGoogle ScholarPubMed
Chesley, A, Hultman, E & Spriet, LL (1995) Effects of epinephrine infusion on muscle glycogenolysis during intense aerobic exercise. American Journal of Physiology 268, E127E134.Google ScholarPubMed
Collomp, K, Ahmaidi, S, Audran, M, Chanal, JL & Prefaut, Ch (1991) Effects of caffeine ingestion on performance and anaerobic metabolism during the Wingate test. International Journal of Sports Medicine 12, 439443.Google Scholar
Collomp, K, Caillaud, C, Audran, M, Chanal, JL & Prefaut, Ch (1990) Influence de la prise aiguë ou chronique de caféine sur la performance et les catécholamines au cours d'un exercice maximal (Influence of acute or chronic caffeine ingestion on plasma catecholamines and performance during maximal exercise). Cahiers de Recherche de la Société de Biologie 184, 8792.Google Scholar
Costill, DL, Coyle, E, Dalsky, G, Evans, W, Fink, W & Hoopes, D (1977) Effects of elevated plasma FFA and insulin on muscle glycogen usage during exercise. Journal of Applied Physiology 43, 695699.Google Scholar
Costill, DL, Dalsky, GP & Fink, WJ (1978) Effects of caffeine ingestion on metabolism and exercise performance. Medicine and Science in Sports and Exercise 10, 155158.Google Scholar
Côté, C, White, TP & Faulkner, JA (1988) Intramuscular depletion and fatigability of soleus grafts in rats. Canadian Journal of Physiology and Pharmacology 66, 829832.Google Scholar
Décombaz, J, Arnaud, M-J, Milon, H, Moesch, H, Philipposian, G, Thelin, AL & Howald, H (1983) Energy metabolism of medium-chain triglycerides versus carbohydrates during exercise. European Journal of Applied Physiology 52, 914.Google Scholar
Dodd, SL, Brooks, E, Powers, SK & Tulley, R (1991) The effects of caffeine on graded exercise performance in caffeine naive versus habituated subjects. European Journal of Applied Physiology 62, 424429.CrossRefGoogle ScholarPubMed
Doubt, TJ & Hsieh, SS (1991) Additive effects of caffeine and cold water during submaximal leg exercise. Medicine and Science in Sports and Exercise 23, 435442.Google Scholar
Douglas, BR, Jansen, JBMJ, de Jong, AJL & Lamers, LBHW (1990) Effects of various triglycerides on plasma cholecystokinin levels in rats. Journal of Nutrition 120, 686690.Google Scholar
Engel, AG & Rebouche, CJ (1984) Carnitine metabolism and inborn errors. Journal of Inherited Metabolic Diseases 7, 3843.Google Scholar
Essén, B (1977) Intramuscular substrate utilization during prolonged exercise. Annals of the New York Academy of Sciences 301, 3044.Google Scholar
Essén, B, Hagenfeldt, L & Kaijser, L (1977) Utilization of blood-borne and intramuscular substrates during continuous and intermittent exercise in man. Journal of Physiology 265, 489506.Google Scholar
Essig, D, Costill, DL & van Handel, PJ (1980) Effects of caffeine ingestion on utilization of muscle glycogen and lipid during leg ergometer cycling. International Journal of Sports Medicine 1, 8690.CrossRefGoogle Scholar
Fredholm, BB (1980) Are methylxanthine effects due to antagonism of endogenous adenosine? Trends in Pharmacological Science 1, 129132.Google Scholar
Fritz, IB (1968) The metabolic consequences of the effects of carnitine on long-chain fatty acid oxidation. In Cellular Compartmentalization and Control of Fatty Acid Metabolism, pp. 3963 [Gran, FC editor]. New York: Academic Press.Google Scholar
Fröberg, SO (1969) Metabolism of lipids in blood and tissues during exercise. Biochemistry of Exercise and Medicine in Sport 3, 100113.Google Scholar
Fröberg, SO, Hultman, E & Nilsson, LH (1975) Effect of noradrenaline on triglyceride and glycogen concentrations in liver and muscle from man. Metabolism 24, 119125.Google Scholar
Fröberg, SO & Mossfeldt, F (1971) Effect of prolonged strenuous exercise on the concentration of triglycerides, phospholipids and glycogen in muscle of man. Acta Physiologica Scandinavica 82, 167171.Google Scholar
Gaesser, GA & Rich, RG (1985) Influence of caffeine on blood lactate response during incremental exercise. International Journal of Sports Medicine 6, 207211.Google Scholar
Geser, CA, Müller-Hess, R, Jéquier, E & Felber, JP (1974) Oxidation rate of carbohydrates and lipids, measured by indirect calorimetry, after administration of long-chain (LCT) and medium-chain triglycerides (MCT) in healthy subjects. Ernährung in der Medizin 1, 7172.Google Scholar
Gollnick, PD (1985) Metabolism of substrates: energy substrate metabolism during exercise and as modified by training. Federation Proceedings 44, 353357.Google Scholar
Gollnick, PD, Ianuzzo, CD & King, DW (1971) Ultrastructural and enzyme changes in muscles with exercise. In Advances in Experimental Medicine and Biology, vol. II, pp. 6986. [Pernow, B and Saltin, B, editors]. New York and London: Plenum Press.Google Scholar
Gollnick, PD & Saltin, B (1982) Significance of skeletal muscle oxidative enzyme enhancement with endurance training. Clinical Physiology 2, 112.Google Scholar
Gollnick, PD & Saltin, B (1988) Fuel for muscular exercise: role of fat. In Exercise, Nutrition and Energy Metabolism, pp. 71–88New York: MacMillan Publishing Co.Google Scholar
Górski, J (1992) Muscle triglyceride metabolism during exercise. Canadian Journal of Physiology and Pharmacology 70, 123131.Google Scholar
Górski, J & Stankiewicz-Choroszucha, B (1982) The effect of hormones on lipoprotein lipase activity in skeletal muscles of the rat. Hormone Metabolism Research 14, 189191.Google Scholar
Graham, TE & Spriet, LL (1991) Performance and metabolic responses to a high caffeine dose during prolonged exercise. Journal of Applied Physiology 71, 22922298.Google Scholar
Graham, TE & Spriet, LL (1995) Metabolic, catecholamine and exercise performance responses to varying doses of caffeine. Journal of Applied Physiology 78, 867874.Google Scholar
Green, HJ, Houston, ME, Thomson, JA, Sutton, JR & Gollnick, PD (1979) Metabolic consequences of supramaximal arm work performed during prolonged submaximal leg work. Journal of Applied Physiology 46, 249255.CrossRefGoogle ScholarPubMed
Groot, PHE, Oerlemans, MC & Scheek, LM (1979) Triglyceridase and phospholipase Al activities of rat heart lipoprotein lipase. Influence of apolipoprotein C-II and C-III. Biochimica et Biophysica Acta 530, 9198.Google Scholar
Groot, PHE, Scholte, H R & Hülsmann, WC (1976) Fatty acid activation: specificity, localization and function. In Advances in Lipid Research, pp. 75119 [Paoletti, R and Kritchevsky, D, editors]. New York: Academic Press.Google Scholar
Hagenfeldt, L & Wahren, J (1971) Metabolism of free fatty acids and ketone bodies in skeletal muscle. In Muscle Metabolism During Exercise, pp. 153163 [Pernow, B and Saltin, B, editors]. New York: Plenum Press.Google Scholar
Harmon, CM, Luce, P & Abumrad, NA (1992) Labelling of an 88 kDa adipocyte membrane protein by sulpho-N-succinimidyl long-chain fatty acids: inhibition of fatty acid transport. Biochemical Society Transactions 20, 811813.Google Scholar
Harris, RC, Foster, CV & Hultman, E (1987) Acetylcarnitine formation during intense muscular contractions in humans. Journal of Applied Physiology 63, 440442.Google Scholar
Havel, RJ, Pernow, B & Jones, NL (1967) Uptake and release of free fatty acids and other metabolites in the legs of exercising men. Journal of Applied Physiology 23, 9099.Google Scholar
Heaf, DJ, Kaijser, L, Eklund, B & Carlson, LA (1977) Differences in heparin-released lipolytic activity in the superficial and deep veins of the human forearm. European Journal of Clinical Investigation 7, 195199.Google Scholar
Helge, JW & Kiens, B (1997) Muscle enzyme activity in man: role of substrate availability and training. American Journal of Physiology 272, R1620R1624.Google Scholar
Helge, JW, Richter, EA & Kiens, B (1996) Interaction of training and diet on metabolism and endurance during exercise in man. Journal of Physiology 492, 293306.Google Scholar
Hiatt, WR, Regensteiner, JG, Wolfel, EE, Ruff, L & Brass, EP (1989) Carnitine and acylcarnitine metabolism during exercise in humans. Journal of Clinical Investigation 84, 11671173.Google Scholar
Holloszy, JO (1990) Utilization of fatty acids during exercise. In Biochemistry of Exercise, Vol. 7, pp. 319327. [Taylor, AW, Gollnick, PD, Green, HJ, Ianuzzo, CD, Noble, EG, Metivier, G and Sutton, RJ, editors]. Champaign, IL: Human Kinetics Publishers.Google Scholar
Hoppel, CL & Davis, AT (1986) Inter-tissue relationship in the synthesis and distribution of carnitine. Biochemical Society Transactions 14, 673674.Google Scholar
Hoppeler, H, Howald, H, Conley, K, Lindstedt, SL, Claassen, H, Vock, P & Weibel, ER (1985) Endurance training in humans: aerobic capacity and structure of skeletal muscle. Journal of Applied Physiology 59, 320327.Google Scholar
Hoppeler, H, Lüthi, P, Claassen, H, Weibel, ER & Howald, H (1973) The ultrastructure of the normal human skeletal muscle. A morphometric analysis on untrained men, women and well-trained orienteers. Pflügers Archives 344, 217232.Google Scholar
Howald, H, Hoppeler, H, Claassen, H, Mathieu, O & Straub, R (1985) Influences of endurance training on the ultrastructural composition of the different muscle fiber types in humans. Pflügers Archives 403, 369376.Google Scholar
Hultman, E & Harris, RC (1988) Carbohydrate metabolism. In Principles of Exercise Biochemistry, pp. 78119 [Poortmans, JR editor]. Basel: Karger.Google Scholar
Hurley, BF, Nemeth, PM, Martin, WH, III, Hagberg JM, Dalsky, GP & Holloszy, JO (1986) Muscle triglyceride utilization during exercise: effect of training. Journal of Applied Physiology 60, 562567.Google Scholar
Issekutz, B (1985) Effect of epinephrine on carbohydrate metabolism in exercising dogs. Metabolism 34, 457464.Google Scholar
Ivy, JL, Costill, DL, Fink, WJ & Lower, RW (1979) Influence of caffeine and carbohydrate feedings on endurance performance. Medicine and Science in Sports and Exercise 11, 611.Google Scholar
Ivy, JL, Costill, DL, Fink, WJ & Maglischo, E (1980) Contribution of medium and long chain triglyceride intake to energy metabolism during prolonged exercise. International Journal of Sports Medicine 1, 1520.Google Scholar
Janssen, GME, Scholte, HR, Vandrager-Verduin, MHM & Ross, JD (1989) Muscle carnitine level in endurance training and running a marathon. International Journal of Sports Medicine 10, S153S155.Google Scholar
Jansson, E & Kaijser, L (1982) Effect of diet on the utilization of blood-borne and intramuscular substrates during exercise in man. Acta Physiologica Scandinavica 115, 1930.Google Scholar
Jansson, E & Kaijser, L (1984) Leg citrate metabolism at rest and during exercise in relation to diet and substrate utilization in man. Acta Physiologica Scandinavica 122, 145153.Google Scholar
Jansson, E & Kaijser, L (1987) Substrate utilization and enzymes in skeletal muscle of extremely endurance-trained men. Journal of Applied Physiology 62, 9991005.Google Scholar
Jeukendrup, AE, Saris, WHM, Schrauwen, P, Brouns, F & Wagenmakers, AJM (1995) Metabolic availability of medium-chain triglycerides coingested with carbohydrates during prolonged exercise. Journal of Applied Physiology 79, 756762.Google Scholar
Jeukendrup, A, Saris, W, Brouns, F, Halliday, D & Wagenmakers, AJM (1996 a) Effects of carbohydrate (CHO) and fat supplementation on CHO metabolism during prolonged exercise. Metabolism 45, 915921.Google Scholar
Jeukendrup, AE, Saris, WHM, van Diesen, R, Brouns, F & Wagenmakers, AJM (1996 b). Effect of endogenous carbohydrate availability on oral medium-chain triglyceride oxidation during prolonged exercise. Journal of Applied Physiology 80, 949954.Google Scholar
Jeukendrup, AE, Thielen, JJHC, Wagenmakers, AJM, Brouns, F & Saris, WHM (1998) Effect of MCT and carbohydrate ingestion on substrate utilization and cycling performance. American Journal of Clinical Nutrition (In the Press).Google Scholar
Johannessen, A, Hagen, C & Galbo, H (1981) Prolactin, growth hormone, thyrotropin, 3,5,3' triiodothyronine, and thyroxine responses to exercise after fat- and carbohydrate-enriched diet. Journal of Clinical Endocrinology and Metabolism 52, 5661.Google Scholar
Kiens, B, Éssen-Gustavsson, B, Christensen, NJ & Saltin, B (1993) Skeletal muscle substrate utilization during submaximal exercise in man: effect of endurance training. Journal of Physiology 469, 459478.CrossRefGoogle ScholarPubMed
Kiens, B, Kristiansen, S, Jensen, P, Richter, EA & Turcotte, LP (1997) Membrane associated fatty acid binding protein (FABPpm) in human skeletal muscle is increased by endurance training. Biochemical and Biophysical Research Communications 231, 463465.Google Scholar
Kiens, B & Lithell, H (1989) Lipoprotein metabolism influenced by training-induced changes in human skeletal muscle. Journal of Clinical Investigation 83, 558564.Google Scholar
Kiens, B, Lithell, H, Mikines, KJ & Richter, EA (1989) Effects of insulin and exercise on muscle lipoprotein lipase. Activity in man and its relation to insulin action. Journal of Clinical Investigation 84, 11241129.Google Scholar
Knapik, JJ, Jones, BH, Toner, MM, Daniels, WL & Evans, WJ (1983) Influence of caffeine on serum substrate changes during running in trained and untrained individuals. In Biochemistry of Exercise, Vol. 13, pp. 514519 [Knuttgen, HG, Vogel, J & Poortmans, J, editors]. Champaign, IL: Human Kinetics Publishers.Google Scholar
Lambert, EV, Speechly, DP, Dennis, SC & Noakes, TD (1994) Enhanced endurance in trained cyclists during moderate intensity exercise following 2 weeks adaptation to a high fat diet. European Journal of Applied Physiology 69, 287293.Google Scholar
Leddy, J, Horvath, P, Rowland, J & Pendergast, D (1997) Effect of a high or a low fat diet on cardiovascular risk factors in male and female runners. Medicine and Science in Sports and Exercise 29, 1725.Google Scholar
Leijten, PAA & van Breeman, C (1984) The effects of caffeine on the noradrenaline-sensitive calcium store in rabbit aorta. Journal of Physiology 357, 327339.CrossRefGoogle ScholarPubMed
Linder, C, Chernick, SS, Fleck, TR & Scow, RO (1976) Lipoprotein lipase and uptake of chylomicron triglyceride by skeletal muscle of rats. American Journal of Physiology 231, 860864.CrossRefGoogle ScholarPubMed
Linssen, MCJG, Vork, MM, De Jong, YF, Glatz, JFC & van der Vusse, GJ (1990) Fatty acid oxidation capacity and fatty acid-binding protein content of different cell types isolated from rat heart. Molecular Cell Biochemistry 89, 1926.Google Scholar
Lithell, H & Broberg, J (1978) Determination of lipoprotein-lipase activity in human skeletal muscle tissue. Biochimica Biophysica Acta 528, 5568.Google Scholar
Lithell, H, Örlander, J, Schéle, R, Sjödin, B & Karlsson, J (1979) Changes in lipoprotein-lipase activity and lipid stores in human skeletal muscle with prolonged heavy exercise. Acta Physiologica Scandinavica 107, 257261.CrossRefGoogle ScholarPubMed
Maassen, N, Schroder, P & Schneider, G (1995) Carnitine does not enhance maximum oxygen uptake and does not increase performance in endurance exercise in the range of one hour. International Journal of Sports Medicine 15, 375. Abstr.Google Scholar
McDermott, JC, Elder, GCB & Bonen, A (1987) Adrenal hormones enhance glycogenolysis in nonexercising muscle during exercise. Journal of Applied Physiology 63, 12751283.Google Scholar
McDermott, JC, Elder, GCB & Bonen, A (1991) Non-exercising muscle metabolism during exercise. Pflügers Archives 418, 301307.Google Scholar
McGarry, JD, Mills, SE, Long, CS & Foster, C (1983) Observations on the affinity for carnitine, and malonyl-CoA sensitivity, of carnitine palmitoyltransferase I in animal and human tissues. Biochemistry Journal 214, 2128.Google Scholar
McGilvery, JD, Stark, M J & Foster, DW (1975) The use of fuels for muscular work. In Metabolic Adaptation to Prolonged Physical Exercise, pp. 1230 [Howald, H and Poortmans, JR, editors]. Basel: Birkhauser Verlag.Google Scholar
MacLean, PS & Winder, WW (1995) Caffeine decreases malonyl-CoA in isolated perfused skeletal muscle of rats. Journal of Applied Physiology 78, 14961501.Google Scholar
MartinWH III, WH III,, Dalsky, GP, Hurley, BF, Matthews, DE, Bier, DM, Hagberg, JM, Rogers, MA, King, DS & Holloszy, JO (1993) Effect of endurance training on plasma free fatty acid turnover and oxidation during exercise. American Journal of Physiology 265, E708E714.Google Scholar
Massicotte, D, Peronnet, F & Brisson, GR (1992) Oxidation of exogenous medium-chain free fatty acids during prolonged exercise: comparison with glucose. Journal of Applied Physiology 73, 13341339.Google Scholar
Mazzeo, RS & Marshall, P (1989) Influence of plasma catecholamines on the lactate threshold during graded exercise. Journal of Applied Physiology 67, 13191322.Google Scholar
Miller, WC, Bryce, GR & Conlee, RK (1984) Adaptations to a high-fat diet that increase exercise endurance in male rats. Journal of Applied Physiology 56, 7883.Google Scholar
Morgan, TE, Cobb, LA, Short, FA, Ross, R & Gunn, DR (1971) Effects of long-term exercise on human muscle mitochondria. In Advances in Experimental Medicine and Biology, Vol 11, pp. 8795 [Pernow, B and Saltin, B, editors]. New York and London: Plenum Press.Google Scholar
Morgan, TE, Short, FA & Cobb, LA (1969) Effect of long-term exercise on skeletal muscle lipid composition. American Journal of Physiology 216, 8286.Google Scholar
Muoio, DM, Leddy, JJ, Horvath, PJ, Awad, AB & Pendergast, DR (1994) Effect of dietary fat on metabolic adjustments to maximal VO2 and endurance in runners. Medicine and Science in Sports and Exercise 26, 8188.Google Scholar
Newsholme, EA (1988 a) Basic aspects of metabolic regulation and their application to provision of energy in exercise. In Principles of Exercise Biochemistry, pp. 4077 [Poortmans, JR editor]. Basel: Karger.Google Scholar
Newsholme, EA (1988 b) Application of knowledge of metabolic integration to the problem of metabolic limitations in sprints, middle distance and marathon running. In Principles of Exercise Biochemistry, pp. 194211 [Poortmans, JR editor]. Basel: Karger.Google Scholar
Nikkilä, EA, Taskinen, R, Rehunen, S & Härkönen, M (1978) Lipoprotein lipase activity in adipose tissue and skeletal muscle of runners: Relation to serum lipoproteins. Metabolism 27, 16611671.Google Scholar
Oscai, LB (1983) Type L hormone-sensitive lipase hydrolyzes endogenous triacylglycerols in muscle in exercised rats. Medicine and Science in Sports and Exercise 15, 336339.Google Scholar
Oscai, LB, Caruso, R A & Wergeles, C (1982) Lipoprotein lipase hydrolyzes endogenous triacylglycerols in muscle in exercised rats. Journal of Applied Physiology 52, 10591063.CrossRefGoogle ScholarPubMed
Pasman, WJ, van Baak, MA, Jeukendrup, AE & de Haan, A (1995) The effect of different dosages of caffeine on endurance performance time. International Journal of Sports Medicine 16, 225230.Google Scholar
Phinney, SD, Bistrian, BR, Evans, WJ, Gervino, E & Blackburn, GL (1983) The human metabolic response to chronic ketosis without caloric restriction: preservation of submaximal exercise capability with reduced carbohydrate oxidation. Metabolism 32, 769777.Google Scholar
Powers, SK, Byrd, RJ, Tulley, R & Calender, T (1983) Effects of caffeine ingestion on metabolism and performance during graded exercise. European Journal of Applied Physiology 50, 301307.Google Scholar
Pratt, CA (1989) Lipoprotein lipase and triglyceride in skeletal and cardiac muscles of rats fed lard or glucose. Nutritional Research 9, 4755.Google Scholar
Richter, EA, Garetto, LP, Goodman, MN & Ruderman, NB (1984) Enhanced muscle glucose metabolism after exercise: modulation by local factors. American Journal of Physiology 246, E476E482.Google Scholar
Romijn, JA, Coyle, EF, Sidossis, LS, Gastaldelli, A, Horowitz, JF, Endert, E & Wolfe, RR (1993) Regulation of endogenous fat and carbohydrate metabolism in relation to exercise intensity and duration. American Journal of Physiology 265, E380E391.Google Scholar
Saggerson, D, Ghadiminejad, I & Awan, M (1992) Regulation of mitochondrial carnitine palmitoyltransferase from liver and extrahepatic tissues. Advances in Enzyme Regulation 32, 285306.Google Scholar
Saltin, B & Åstrand, PO (1993) Free fatty acids and exercise. American Journal of Clinical Nutrition 57, 752S758S.Google Scholar
Saltin, B, Kiens, B & Savard, G (1986) A quantitative approach to the evaluation of skeletal muscle substrate utilization in prolonged exercise. In Biochemical Aspects of Physical Exercise, pp. 235244 [Benzi, G, Packer, L and Siliprandi, N, editors]. Amsterdam: Elsevier Science Publishers.Google Scholar
Sasaki, H, Maeda, J, Usui, S & Ishiko, T (1987) Effect of sucrose and caffeine ingestion on performance of prolonged strenuous running. International Journal of Sports Medicine 8, 261265.Google Scholar
Sonne, B & Galbo, H (1985) Carbohydrate metabolism during and after exercise in rats. Studies with radioglucose. Journal of Applied Physiology 59, 16271639.Google Scholar
Soop, M, Björkman, O, Cederblad, G & Hagenfeldt, L (1988) Influence of carnitine supplementation on muscle substrate and carnitine metabolism during exercise. Journal of Applied Physiology 64, 23942399.Google Scholar
Spector, AA, Fletcher, JE & Ashbrook, JD (1971) Analysis of long-chain free fatty acid binding to bovine serum albumin by determination of stepwise equilibrium constants. Biochemistry 10, 32293233.Google Scholar
Spriet, LL, Heigenhauser, GJF & Jones, NL (1986) Endogenous triacylglycerol utilization by rat skeletal muscle during tetanic stimulation. Journal of Applied Physiology 60, 410415.Google Scholar
Spriet, LL, MacLean, DA, Dyck, DJ, Hultman, E, Cederblad, G & Graham, TE (1992) Caffeine ingestion and muscle metabolism during prolonged exercise in humans. American Journal of Physiology 262, E891E898.Google Scholar
Staron, RS, Hikida, RS, Murray, TF, Hagerman, FC & Hagerman, MT (1989) Lipid depletion and repletion in skeletal muscle following a marathon. Journal of Neurological Sciences 94, 2940.Google Scholar
Storlien, LH, Jenkins, AB, Chisholm, DJ, Pasco, WS, Khouri, S & Kraeger, EW (1991) Influence of dietary fat composition on development of insulin resistance in rats. Relationship to muscle triglyceride and ω-3 fatty acids in muscle phospholipid. Diabetes 40, 280289.Google Scholar
Tarnopolsky, MA, Atkinson, SA, MacDougall, JD, Sale, DG & Sutton, JR (1989) Physiological responses to caffeine during endurance running in habitual caffeine users. Medicine and Science in Sports and Exercise 21, 418424.Google Scholar
Terjung, RL & Kaciuba-Uscilko, H (1986) Lipid metabolism during exercise: influence of training. Diabetes Metabolism Review 2, 3551.Google Scholar
Terjung, RL, Mackie, BG, Dudley, GA & Kaciuba-Uschilko, H (1983) Influence of exercise on chylomicron triacylglycerol metabolism: plasma turnover and muscle uptake. Medicine and Science in Sports and Exercise 15, 340347.Google Scholar
Trappe, SW, Costill, DL, Goodpaster, B, Vukovich, MD & Fink, WJ (1994) The effects of l-carnitine supplementation on performance during interval swimming. International Journal of Sports Medicine 15, 181185.Google Scholar
van der, Vusse GJ, Glatz, JFC, Stam, HCG & Reneman, RS (1992) Fatty acid homeostasis in the normoxic and ischemic heart. Physiological Reviews 72, 881940.Google Scholar
van der, Vusse GJ & Reneman, RS (1996) Lipid metabolism in muscle. In Handbook of Physiology, sect. 12, Exercise: Regulation and Integration of Multiple Systems, pp. 952994 [Rowell, LB and Shepherd, JT, editors]. New York: Oxford University Press.Google Scholar
van der Vusse, GJ & Roemen, THM (1995) Gradient of fatty acids from blood plasma to skeletal muscle in dogs. Journal of Applied Physiology 78, 18391843.Google Scholar
Van Zyl, CG, Lambert, EV, Hawley, JA, Noakes, TD & Dennis, SC (1996) Effects of medium-chain triglyceride ingestion on carbohydrate metabolism and cycling performance. Journal of Applied Physiology, 80, 22172225.Google Scholar
Vork, MM, Glatz, JFC & Vusse van der, GJ (1993) On the mechanism of long chain fatty acid transport in cardiomyocytes as facilitated by cytoplasmic fatty acid-binding protein. Journal of Theoretical Biology 160, 207222.Google Scholar
Vukovich, MD, Costill, DL & Fink, WJ (1994 a) L-carnitine supplementation: effect on muscle carnitine content and glycogen utilization during exercise. Medicine and Science in Sports and Exercise 26, S8.Google Scholar
Vukovich, MD, Costill, DL & Fink, WJ (1994 b) Carnitine supplementation: effect on muscle carnitine and glycogen content during exercise. Medicine and Science in Sports and Exercise 26, 11221129 Abstr.Google Scholar
Vukovich, MD, Costill, DL, Hickey, MS, Trappe, SW, Cole, KJ & Fink, WJ (1993) Effect of fat emulsion and fat feeding on muscle glycogen utilization during cycle exercise. Journal of Applied Physiology 75, 15131518.Google Scholar
Wagenmakers, AJM (1991) L-Carnitine supplementation and performance in man. In Advances in Nutrition and Top Sport Vol. 32, pp. 110127 [Brouns, F editor]. Basel: S. Karger.Google Scholar
Wahrenberg, H, Engfeldt, P, Bolinder, J & Arner, P (1987) Acute adaptation in adrenergic control of lipolysis during physical exercise in humans. American Journal of Physiology 253, E383E390.Google Scholar
Wendling, PS, Peters, SJ, Heigenhauser, GJF & Spriet, LL (1996) Epinephrine infusion does not enhance net muscle glycogenolysis during prolonged aerobic exercise. Canadian Journal of Applied Physiology 21, 271284.CrossRefGoogle Scholar
Winder, WW (1985) Control of hepatic glucose production during exercise. Medicine and Science in Sports and Exercise 17, 25.Google Scholar
Winder, WW, Arogyasami, J, Barton, RJ, Elayan, IM & Vehrs, R (1989) Muscle malonyl-CoA decreases during exercise. Journal of Applied Physiology 67, 22302233.Google Scholar
Zhang, Y & Wells, J (1990) The effects of chronic caffeine administration on peripheral adenosine receptors. Journal of Pharmacology and Experimental Therapeutics 254, 757763.Google Scholar