Kent Sahlin

Q: What Schools Are Affiliated With Kent Sahlin

Kent Sahlin is affiliated with the following schools: Stockholm University, University of Southern Denmark, Linköping University, Karolinska Institute

Kent Sahlin's AcademicInfluence.com Rankings

Kent Sahlin

Biology

#10470

World Rank

#13803

Historical Rank

Zoology

#311

World Rank

#737

Historical Rank

biology Degrees

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Biology

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Kent Sahlin's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

Dietary inorganic nitrate improves mitochondrial efficiency in humans. (2011) (636)
Effects of dietary nitrate on blood pressure in healthy volunteers. (2006) (535)
Mitochondrial Respiration Is Decreased in Skeletal Muscle of Patients With Type 2 Diabetes (2007) (535)
The time course of phosphorylcreatine resynthesis during recovery of the quadriceps muscle in man (1976) (402)
Energy supply and muscle fatigue in humans. (1998) (400)
Tricarboxylic acid cycle intermediates in human muscle during prolonged exercise. (1990) (270)
Metabolic Factors in Fatigue (1992) (256)
Lactate content and pH in muscle samples obtained after dynamic exercise (1976) (255)
Relationship of contraction capacity to metabolic changes during recovery from a fatiguing contraction. (1989) (231)
Intracellular pH and energy metabolism in skeletal muscle of man. With special reference to exercise. (1978) (197)
Leg glucose uptake during maximal dynamic exercise in humans. (1986) (188)
Rate of oxidative phosphorylation in isolated mitochondria from human skeletal muscle: effect of training status. (1997) (184)
Resynthesis of creatine phosphate in human muscle after exercise in relation to intramuscular pH and availability of oxygen. (1979) (183)
Redox state and lactate accumulation in human skeletal muscle during dynamic exercise. (1987) (183)
Absence of phosphocreatine resynthesis in human calf muscle during ischaemic recovery. (1993) (179)
Regulation of lactic acid production during exercise. (1988) (178)
Creatine kinase equilibrium and lactate content compared with muscle pH in tissue samples obtained after isometric exercise. (1975) (178)
Cycling efficiency in humans is related to low UCP3 content and to type I fibres but not to mitochondrial efficiency (2006) (171)
Buffer capacity and lactate accumulation in skeletal muscle of trained and untrained men. (1984) (171)
The role of phosphorylcreatine and creatine in the regulation of mitochondrial respiration in human skeletal muscle (2001) (167)
Resistance exercise enhances the molecular signaling of mitochondrial biogenesis induced by endurance exercise in human skeletal muscle. (2011) (163)
Muscle fatigue and lactic acid accumulation. (1986) (160)
Intracellular pH and bicarbonate concentration in human muscle during recovery from exercise. (1978) (157)
Mitochondrial function and antioxidative defence in human muscle: effects of endurance training and oxidative stress (2000) (157)
Reduced oxidative power but unchanged antioxidative capacity in skeletal muscle from aged humans (2003) (156)
Four weeks of speed endurance training reduces energy expenditure during exercise and maintains muscle oxidative capacity despite a reduction in training volume. (2009) (155)
Regulation of glycogenolysis in human muscle at rest and during exercise. (1982) (151)
Effects of acute and chronic endurance exercise on mitochondrial uncoupling in human skeletal muscle (2004) (146)
Adenine nucleotide degradation in human skeletal muscle during prolonged exercise. (1989) (144)
Increased subsarcolemmal lipids in type 2 diabetes: effect of training on localization of lipids, mitochondria, and glycogen in sedentary human skeletal muscle. (2010) (138)
Functional complexes of mitochondria with Ca,MgATPases of myofibrils and sarcoplasmic reticulum in muscle cells. (2001) (135)
Localization of Rate-Limiting Defect for Glucose Disposal in Skeletal Muscle of Insulin-Resistant Type I Diabetic Patients (1990) (134)
Phosphocreatine content in single fibers of human muscle after sustained submaximal exercise. (1997) (133)
Effect of physical training on mitochondrial respiration and reactive oxygen species release in skeletal muscle in patients with obesity and type 2 diabetes (2010) (130)
Changes in plasma hypoxanthine and free radical markers during exercise in man. (1991) (129)
Lactate content and pH in muscle obtained after dynamic exercise. (1976) (122)
Muscle ammonia and amino acid metabolism during dynamic exercise in man. (1986) (119)
Maximal fat oxidation rates in endurance trained and untrained women (2006) (115)
Deficiency of skeletal muscle succinate dehydrogenase and aconitase. Pathophysiology of exercise in a novel human muscle oxidative defect. (1991) (113)
Mitochondrial dysfunction in type 2 diabetes and obesity. (2008) (113)
Effects of lactic acid accumulation and ATP decrease on muscle tension and relaxation. (1981) (109)
Mitochondrial oxidative function in human saponin‐skinned muscle fibres: effects of prolonged exercise (1998) (102)
Physical Exercise and Mitochondrial Function in Human Skeletal Muscle (2002) (102)
Muscle ATP turnover rate during isometric contraction in humans. (1986) (101)
Muscle carnitine metabolism during incremental dynamic exercise in humans. (1990) (101)
Effect of endurance training on oxidative and antioxidative function in human permeabilized muscle fibres (2001) (100)
Resistance exercise induced mTORC1 signaling is not impaired by subsequent endurance exercise in human skeletal muscle. (2013) (98)
Influence of glucose and fructose ingestion on the capacity for long-term exercise in well-trained men. (1984) (96)
Ultraendurance exercise increases the production of reactive oxygen species in isolated mitochondria from human skeletal muscle. (2010) (96)
Fatigue and phosphocreatine depletion during carbon dioxide-induced acidosis in rat muscle. (1983) (94)
Exercise with low glycogen increases PGC-1α gene expression in human skeletal muscle (2013) (94)
Regulation of glycogenolysis in human muscle in response to epinephrine infusion. (1983) (93)
Phosphagen and lactate contents of m. quadriceps femoris of man after exercise. (1977) (92)
Reduced insulin-mediated citrate synthase activity in cultured skeletal muscle cells from patients with type 2 diabetes: evidence for an intrinsic oxidative enzyme defect. (2005) (91)
The contents of high‐energy phosphates in different fibre types in skeletal muscles from rat, guinea‐pig and man. (1982) (90)
Prior heavy exercise eliminates slow component and reduces efficiency during submaximal exercise in humans (2005) (87)
Adenine nucleotide depletion in human muscle during exercise: causality and significance of AMP deamination. (1990) (82)
Regulation of glucose utilization in human skeletal muscle during moderate dynamic exercise. (1991) (82)
Effect of eccentric exercise on muscle oxidative metabolism in humans. (2001) (79)
Muscle ammonia metabolism during isometric contraction in humans. (1986) (77)
Effect of decreased oxygen availability on NADH and lactate contents in human skeletal muscle during exercise. (1987) (77)
No evidence of an intracellular lactate shuttle in rat skeletal muscle (2002) (76)
Acidotic depression of cyclic AMP accumulation and phosphorylase b to a transformation in skeletal muscle of man. (1983) (75)
Role of Oxygen in Regulation of Glycolysis and Lactate Production in Human Skeletal Muscle (1990) (73)
Mitochondrial function in human skeletal muscle is not impaired by high intensity exercise (1999) (71)
Mitochondrial oxygen affinity predicts basal metabolic rate in humans (2011) (71)
Muscle Energetics During Explosive Activities and Potential Effects of Nutrition and Training (2014) (70)
Muscle glycogen content modifies SR Ca2+ release rate in elite endurance athletes. (2014) (68)
Cardiovascular and neuroendocrine responses to exercise in hypoxia during impaired neural feedback from muscle. (1999) (65)
Formation of inosine monophosphate (IMP) in human skeletal muscle during incremental dynamic exercise. (1989) (65)
The creatine kinase reaction: a simple reaction with functional complexity (2011) (65)
Increased activity of citrate synthase in human skeletal muscle after a single bout of prolonged exercise. (1997) (62)
Endurance training increases stimulation of uncoupling of skeletal muscle mitochondria in humans by non-esterified fatty acids: an uncoupling-protein-mediated effect? (2000) (60)
Turning down lipid oxidation during heavy exercise--what is the mechanism? (2008) (58)
Reduced efficiency, but increased fat oxidation, in mitochondria from human skeletal muscle after 24-h ultraendurance exercise. (2007) (57)
Influence of ATP turnover and metabolite changes on IMP formation and glycolysis in rat skeletal muscle. (1990) (57)
Sodium bicarbonate ingestion prior to training improves mitochondrial adaptations in rats. (2010) (57)
Effects of prolonged exercise on the contractile properties of human quadriceps muscle (2004) (57)
Non-invasive measurements of O2 availability in human skeletal muscle with near-infrared spectroscopy. (1992) (57)
Tricarboxylic acid cycle intermediates during incremental exercise in healthy subjects and in patients with McArdle's disease. (1995) (53)
Effect of Q10 supplementation on tissue Q10 levels and adenine nucleotide catabolism during high-intensity exercise. (1999) (53)
The potential for mitochondrial fat oxidation in human skeletal muscle influences whole body fat oxidation during low-intensity exercise. (2007) (52)
Quantitative estimation of anaerobic and oxidative energy metabolism and contraction characteristics in intact human skeletal muscle in response to electrical stimulation. (1983) (51)
Repetitive static muscle contractions in humans —a trigger of metabolic and oxidative stress? (2004) (51)
Plasma hypoxanthine and ammonia in humans during prolonged exercise (1999) (51)
NADH in human skeletal muscle during short-term intense exercise (1985) (49)
Redox state changes in human skeletal muscle after isometric contraction. (1986) (49)
Similar expression of oxidative genes after interval and continuous exercise. (2009) (48)
Maximal lipid oxidation in patients with type 2 diabetes is normal and shows an adequate increase in response to aerobic training (2009) (46)
Influence of severe potassium depletion and subsequent repletion with potassium on muscle electrolytes, metabolites and amino acids in man. (1976) (45)
NADH and NADPH in human skeletal muscle at rest and during ischaemia. (1983) (45)
Adenine nucleotide and IMP contents of the quadriceps muscle in man after exercise (1978) (45)
Influence of reduced glycogen level on glycogenolysis during short-term stimulation in man. (1990) (44)
Mitochondrial efficiency in rat skeletal muscle: influence of respiration rate, substrate and muscle type. (2005) (44)
Adenine nucleotide content of human liver. Normal values and fructose-induced depletion. (1975) (44)
Hypoxaemia increases the accumulation of inosine monophosphate (IMP) in human skeletal muscle during submaximal exercise. (1989) (42)
Impaired oxidative metabolism increases adenine nucleotide breakdown in McArdle's disease. (1990) (42)
Oxygen deficit at the onset of submaximal exercise is not due to a delayed oxygen transport. (1988) (42)
Quantitative and qualitative adaptation of human skeletal muscle mitochondria to hypoxic compared with normoxic training at the same relative work rate (2007) (41)
Strength training improves muscle aerobic capacity and glucose tolerance in elderly (2016) (40)
Effects of lengthening contraction on calcium kinetics and skeletal muscle contractility in humans. (2005) (39)
Effect of beta-adrenoceptor blockade on H+ and K+ flux in exercising humans. (1985) (39)
Glycolytic and oxidative energy metabolism and contraction characteristics of intact human muscle. (1981) (38)
Increased concentrations of P(i) and lactic acid reduce creatine-stimulated respiration in muscle fibers. (2002) (38)
The effect of continuous and interval exercise on PGC‐1α and PDK4 mRNA in type I and type II fibres of human skeletal muscle (2012) (36)
Control of lipid oxidation during exercise: role of energy state and mitochondrial factors (2008) (35)
Erratum to: Mitochondrial gene expression in elite cyclists: effects of high-intensity interval exercise (2010) (35)
Force, relaxation and energy metabolism of rat soleus muscle during anaerobic contraction. (1987) (33)
NADH content in type I and type II human muscle fibres after dynamic exercise. (1988) (33)
Lactate production cannot be measured with tracer techniques. (1987) (33)
Hyperammoniemia during prolonged exercise: an effect of glycogen depletion? (1988) (33)
Control of energetic processes in contracting human skeletal muscle. (1991) (31)
Acid-base balance in blood during exhaustive bicycle exercise and the following recovery period. (1978) (30)
Purine Nucleotide Metabolism (1988) (30)
The content of NADH in rat skeletal muscle at rest and after cyanide poisoning. (1986) (29)
Control of Glycolysis and Glycogen Metabolism (2011) (29)
FAT/CD36 is localized in sarcolemma and in vesicle-like structures in subsarcolemma regions but not in mitochondria (2010) (28)
Carbohydrate restricted recovery from long term endurance exercise does not affect gene responses involved in mitochondrial biogenesis in highly trained athletes (2015) (27)
Release of K+ from muscle during prolonged dynamic exercise. (1989) (27)
Effect of freeze-drying on measurements of pH in biopsy samples of the middle gluteal muscle of the horse: comparison of muscle pH to the pyruvate and lactate content. (1989) (26)
Mitochondrial Plasticity with Exercise Training and Extreme Environments (2014) (26)
Glycolysis in contracting rat skeletal muscle is controlled by factors related to energy state. (2009) (24)
Propranolol enhances adenine nucleotide degradation in human muscle during exercise. (1988) (24)
Metabolic Aspects of Fatigue in Human Skeletal Muscle (1992) (24)
Effect of hypoxia on muscle oxygenation and metabolism during arm exercise in humans. (2008) (24)
Cardiovascular and neuroendocrine responses to exercise in hypoxia during impaired neural feedback from muscle. (1999) (23)
Effect of muscle mass on lactate formation during exercise in humans (2004) (23)
Failure of glutamate dehydrogenase system to predict oxygenation state of human skeletal muscle. (1990) (22)
Adding strength to endurance training does not enhance aerobic capacity in cyclists (2015) (22)
Muscle glucose metabolism during exercise. (1990) (21)
Control of lipid oxidation at the mitochondrial level. (2009) (21)
Glycolytic intermediates in human muscle after isometric contraction (1981) (21)
Glucose formation in human skeletal muscle. Influence of glycogen content. (1989) (20)
Induction and treatment of metabolic acidosis: A study of pH changes in porcine skeletal muscle and cerebrospinal fluid (1985) (20)
NADH content and lactate production in the perfused rabbit heart. (1987) (20)
High lactate and NH3 release during arm vs. leg exercise is not due to beta-adrenoceptor stimulation. (1993) (20)
Reduced sarcoplasmic reticulum content of releasable Ca2+ in rat soleus muscle fibres after eccentric contractions (2007) (18)
Intracellular pH and bicarbonate concentration as determined in biopsy samples from the quadriceps muscle of man at rest. (1977) (18)
Activation of glycogen phosphorylase by electrical stimulation of isolated fast-twitch and slow-twitch muscles from rat. (1985) (15)
Effect of hypoxia on glucose metabolism in human skeletal muscle during exercise. (1989) (15)
Actively phosphorylating mitochondria are more resistant to lactic acidosis than inactive mitochondria. (1999) (15)
Acute exercise reverses starvation-mediated insulin resistance in humans. (2013) (15)
Boosting fat burning with carnitine: an old friend comes out from the shadow (2011) (14)
Oxygen deficit is not affected by the rate of transition from rest to submaximal exercise. (1989) (12)
Carbohydrate metabolism in human skeletal muscle during exercise is not regulated by G-1,6-P2. (1988) (12)
High anaerobic energy release during submaximal arm exercise. (1993) (11)
Effect of prostacyclin on the severity of ischaemic injury in rabbit hearts subjected to coronary ligation. (1986) (11)
Effect of short-term CO2-breathing on the CO2 content and intracellular pH in skeletal muscle of man. (1981) (11)
Repeated static contractions increase mitochondrial vulnerability toward oxidative stress in human skeletal muscle. (2006) (10)
Point:Counterpoint authors respond to commentaries on "Lactic acid accumulation is an advantage/disadvantage during muscle activity". (2006) (9)
High-Energy Phosphates and Muscle Energetics (2004) (9)
consumption in trained human skeletal muscle (2015) (8)
The effect of long-term circulatory occlusion on pH and energy metabolism of the quadriceps muscle in man. (1985) (8)
Adenine Nucleotide Metabolism1 (1993) (8)
Determination of muscle pH and glycolytic flux by magnetic resonance spectroscopy in contracting human skeletal muscle may have systematic errors. (2005) (7)
Actively phosphorylating mitochondria are more resistant to lactic acidosis than inactive mitochondria. (1999) (7)
Metabolism during Exercise – Energy Expenditure and Hormonal Changes (2008) (7)
Lactate formation and tissue hypoxia. (1989) (7)
Comments on Point:Counterpoint: Muscle lactate and H⁺ production do/do not have a 1:1 association in skeletal muscle. Why add complexity/confusion to a simple issue? (2011) (6)
Intracellular pH and electrolytes in human skeletal muscle during adrenaline and insulin infusions. (1984) (5)
Improving Strength, Power, Muscle Aerobic Capacity, and Glucose Tolerance through Short-term Progressive Strength Training Among Elderly People. (2017) (4)
Determination of metabolites by observing the change in reaction rate during the early course of a first order reaction, as applied to fructose-1 phosphate. (1975) (4)
Response to point:counterpoint on "lactic acid". (2008) (4)
Energy Metabolism and Muscle Fatigue During Exercise (1996) (4)
Jens Jung Nielsen , Maria Fernström , Kent Sahlin and oxidative capacity despite a reduction in training volume expenditure during exercise and maintains muscle Four weeks of speed endurance training reduces energy (2008) (3)
Mitochondrial gene expression in elite cyclists: effects of high-intensity interval exercise. (2010) (3)
LEG GLUCOSE UPTAKE DURING MAXIMAL EXERCISE IN HUMANS (1986) (3)
Skeletal muscle mitochondrial function and ROS production in response to extreme endurance exercise in athletes (2006) (2)
Improved Mitochondrial Efficiency in Humans by Dietary Nitrate (2010) (2)
Metabolic Factors in Fatigue 1 (1992) (2)
The leaky mitochondrion (2004) (1)
Principles of Exercise Biochemistry (2003) (1)
Mitochondrial Adaptation to Exercise and Training: A Physiological Approach (2007) (1)
Does six-weeks of high-intensity cycle training with induced changes in acid-base balance lead to mitochondrial adaptations? (2014) (1)
Endurance Exercise Does Not Impair mTOR Signalling After Resistance Exercise: 697 (2011) (0)
Exercise with low glycogen increases PGC-1α gene expression in human skeletal muscle (2012) (0)
muscle skeletal vulnerability toward oxidative stress in human Repeated static contractions increase mitochondrial (2006) (0)
Oxidative Gene Expression in Single Muscle Fibres after Continuous and Intermittent Exercise (2010) (0)
training volume muscle oxidative capacity despite a reduction in energy expenditure during exercise and maintains Four weeks of speed endurance training reduces (2015) (0)
Effects of Aerobic Training on Intramyocellular Lipid and Glycogen Localization in Type 2 Diabetic Patients (2009) (0)
Effects of induced changes in acid-base balance on mitochondrial adaptations to training (2014) (0)
Restricting carbohydrate during recovery from prolonged exercise does not effect intramuscular triglyceride resynthesis (2018) (0)
to lactic acidosis than inactive mitochondria Actively phosphorylating mitochondria are more resistant (2016) (0)
EXERCISE ATTENUATES CALCIUM-TRIGGERED MITOCHONDRIAL PERMEABILITY TRANSITION IN SKELETAL MUSCLE MITOCHONDRIA (2003) (0)
Reduced oxidative power but unchanged antioxidative capacity in skeletal muscle from aged subjects: Pflugers Arch (2003) (0)
Martin Mogensen and Michail Tonkonogi muscle skeletalvulnerability toward oxidative stress in human Repeated static contractions increase mitochondrial (2006) (0)
in trained and untrained individuals Muscle glycogen accumulation after endurance exercise (2015) (0)
Acute exercise during starvation improves insulin sensitivity and increases mitochondrial FA oxidation (2012) (0)
Mitochondrial Gene Expression In Well Trained Cyclists: Effects Of Low Glycogen Levels: 809 (2011) (0)
Acute exercise and starvation induced insulin resistance (2012) (0)
mitochondrial adaptations in rats Sodium bicarbonate ingestion prior to training improves (2016) (0)
human skeletal muscle reactive oxygen species in isolated mitochondria from Ultraendurance exercise increases the production of (2015) (0)
Mitochondrial function during exercise (2016) (0)
Acute Carbohydrate Restriction During Recovery From Prolonged Exercise Enhances Intramuscular Triglyceride Resynthesis (2019) (0)
The Effect Of Exercise On Oxidative Stress In Glycogen Depleted Skeletal Muscle: 1652 (2011) (0)
and protein in human skeletal muscle mRNA α Rapid exercise-induced changes in PGC-1 (2015) (0)
ultraendurance exercise mitochondria from human skeletal muscle after 24-h Reduced efficiency, but increased fat oxidation, in (2015) (0)
Vascular Endothelial Growth Factor in Skeletal Muscle following Glycogen-Depleting Exercise in Humans: 1677 Board #22 May 28, 3 (2015) (0)
MAXIMAL RATE OF PHOSPHOCREATINE DEPLETION IS DEPENDENT ON THE METABOLIC STATE. (2003) (0)
Mitochondrial quality influences whole body fat oxidation during low-intensity exercise in humans (2006) (0)
Resistance exercise enhances the effect of endurance training on molecular signaling in human skeletal muscle (2012) (0)
Intracellular lactate shuttle does not exist in skeletal muscle (2002) (0)
Endurance Exercise Does Not Impair mTOR Signalling After Resistance Exercise: D-58 Thematic Poster - Skeletal Muscle Cell Signaling: JUNE 2, 2011 3:15 PM - 5:15 PM: ROOM: 304 (2011) (0)
Features Pn 27 (0)
Vo2 Slow Component Correlates With Skeletal Muscle Mitochondrial UCP3 In Untrained But Not In Trained Individuals: 2050 (2007) (0)
INTRAMUSCULAR AND CSF pH DURING BUFFERING WITH TRADITIONAL SODIUM BICARBONATE OR A NEW BUFFER COMPOSITION (1984) (0)
Restriction and Protein Supplementation on Mitochondrial Biogenesis Optimizing Intramuscular Adaptations to Aerobic Exercise: Effects of Carbohydrate (2014) (0)

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What Schools Are Affiliated With Kent Sahlin?

Kent Sahlin is affiliated with the following schools:

Kent Sahlin's Academic­Influence.com Rankings

Why Is Kent Sahlin Influential?

Kent Sahlin's Published Works

Published Works

What Schools Are Affiliated With Kent Sahlin?

Kent Sahlin's AcademicInfluence.com Rankings