Intramuscular triglyceride content is increased in IDDM

Ebeling, Pertti; Essén‐Gustavsson, Birgitta; Tuominen, J. A.; Koivisto, Veikko A.

doi:10.1007/s001250050875

Cited by 44 publications

(34 citation statements)

References 28 publications

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“…Thus, minimizing hyperglycemia by achieving recommended glycemic control might help to normalize the potential muscle fat abnormalities observed in type 1 diabetic subjects. However, the results from the present study and those of Ebeling et al 12 and Perseghin et al…”

Section: Diabetes Status Central and Muscle Fat Relationscontrasting

confidence: 70%

“…In the Ebeling et al 12 study, where subjects had better metabolic control (mean HbA 1c of 7.7%), no relation between muscle fat and insulin resistance was found. In the present study, no relationship was found between muscle lipids, estimated by CT scan, and HbA 1c .…”

Section: Diabetes Status Central and Muscle Fat Relationsmentioning

confidence: 87%

“…To our knowledge, only two studies have examined the relationships between insulin sensitivity and muscle lipid content in type 1 diabetes and have presented conflicting results. 11,12 Perseghin et al 11 showed a positive association between intramyocellular lipid content (IMCL) and insulin resistance suggesting that accretion of lipids within skeletal muscle is a marker of insulin resistance in type 1 diabetes, while Ebeling et al 12 did not shown this relationship. This discrepancy may be explained by the method of assessment of the muscle lipids (magnetic resonance spectroscopy vs biopsy) and/or by the degree of glycemic control (HbA 1c values of 8.6 vs 7.7%).…”

Section: Introductionmentioning

confidence: 99%

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Muscle adiposity and body fat distribution in type 1 and type 2 diabetes: varying relationships according to diabetes type

et al. 2006

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Objective: To compare the relationships between markers of total and regional adiposity with muscle fat infiltration in type 1 diabetic and type 2 diabetic subjects and their respective nondiabetic controls, and to document these relationships in type 1 diabetic subjects. Design: Cross-sectional study. Subjects: In total, 86 healthy, with type 1 diabetes, type 2 diabetes or control subjects. Each diabetic group was matched for age, sex and body mass index with its respective nondiabetic control group. Measurements: Measures of body composition (hydrodensitometry), fat distribution (waist circumference, abdominal and mid-thigh computed tomography scans) and blood lipid profiles were assessed. Results: Low attenuation mid-thigh muscle surface correlated similarly with markers of adiposity and body composition in all groups, regardless of diabetes status, except for visceral adipose tissue and waist circumference. Indeed, relationships between visceral adiposity and muscle adiposity were significantly stronger in type 2 vs type 1 diabetic subjects (Po0.05 for comparison of slopes). In addition, in well-controlled type 1 diabetic subjects (mean HbA 1c of 6.8%), daily insulin requirements tended to correlate with low attenuation mid-thigh muscle surface, a specific component of fat-rich muscle (r ¼ 0.36, P ¼ 0.08), but not with glycemic control (HbA 1c ). Conclusion: This study suggests that the relationship of central adiposity and muscle adiposity is modulated by diabetes status and is stronger in the insulin resistant diabetes type (type 2 diabetes). In well-controlled nonobese type 1 diabetic subjects, the relationship between muscle fat accumulation and insulin sensitivity was also maintained.

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Section: Diabetes Status Central and Muscle Fat Relationscontrasting

confidence: 70%

Section: Diabetes Status Central and Muscle Fat Relationsmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

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Muscle adiposity and body fat distribution in type 1 and type 2 diabetes: varying relationships according to diabetes type

et al. 2006

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“…However, in single, homogeneous groups of subjects (9,(33)(34)(35) in the present study and in normoglycemic obese subjects (31), the inverse relationship between muscle triacylglycerol stores (measured by muscle biopsy, NMR, and Oil red O) and insulin sensitivity is normally not present, although exceptions exist (10,36). As for the extramyocellular triacylglycerol stores (fat and adipose cells stored outside the myofibrils but within the muscle fascia), most but not all studies (9) find no relation to insulin sensitivity (11,12,37).…”

Section: Training Insulin Sensitivity and Structural Muscle Lipidsmentioning

confidence: 99%

Effect of Training on Muscle Triacylglycerol and Structural Lipids

Helge

Dela

2003

Diabetes

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We studied whether endurance training impacts insulin sensitivity by affecting the structural and storage lipids in humans. Eight male subjects participated (age 25 ؎ 1 years, height 178 ؎ 3 cm, weight 76 ؎ 4 kg [mean ؎ SE]). Single-leg training was performed for 30 min/day for 4 weeks at ϳ70% of single-leg maximal oxygen uptake. After 8, 14, and 30 days, a two-step hyperinsulinemiceuglycemic glucose clamp, combined with catheterization of an artery and both femoral veins, was performed. In addition, a muscle biopsy was obtained from vastus lateralis of both legs. Maximal oxygen uptake increased by 7% in the trained leg (T), and training workload increased (P < 0.05) from 79 ؎ 12 to 160 ؎ 15 W. At day 8, glucose uptake was higher (P < 0.01) in the trained (0.8 ؎ 0.2, 6.0 ؎ 0.8, 13.4 ؎ 1.2 mg ⅐ min ؊1 ⅐ kg ؊1 leg wt) than the untrained leg (0.5 ؎ 0.2, 3.7 ؎ 0.6, 10.5 ؎ 1.5 mg ⅐ min ؊1 ⅐ kg ؊1 leg wt) at basal and the two succeeding clamp steps, respectively. After day 8, training did not further increase leg glucose uptake. Individual muscle triacylglycerol fatty acid composition and total triacylglycerol content were not significantly affected by training and thus showed no relation to leg glucose uptake. Individual muscle phospholipid fatty acids were not affected by training, but the content of phospholipid polyunsaturated fatty acids was higher (P < 0.06) after 30 than 8 days in T. Furthermore, after 30 days of training, the sum of phospholipid long-chain polyunsaturates was correlated to leg glucose uptake (r ‫؍‬ 0.574, P < 0.04). Endurance training did not influence muscle triacylglycerol content or total triacylglycerol fatty acid composition. In contrast, training induced a minor increase in the content of phospholipid fatty acid membrane polyunsaturates, which may indicate that membrane lipids may have a role in the training-induced increase in insulin sensitivity.

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“…Furthermore, an inverse relationship between the amount of TG deposited in muscle and sensitivity to insulin-induced glucose uptake has been recently observed in the normal state and in various insulin-resistant conditions (14)(15)(16)(17)(18). These findings suggest that FFAs derived from skeletal muscle lipolysis may be an important endogenous energy source and indicate that increased TG deposition and enhanced lipolysis and FFA mobilization/oxidation in skeletal muscle are important in the pathogenesis of peripheral insulin resistance via interactions between glucose and FFA utilization in muscle cells.…”

mentioning

confidence: 98%

Rates of skeletal muscle and adipose tissue glycerol release in nonobese and obese subjects.

et al. 2000

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Skeletal muscle and adipose tissue lipolysis rates were quantitatively compared in 12 healthy nonobese and 14 insulin-resistant obese subjects for 3.5 h after an oral glucose load using microdialysis measurements of interstitial glycerol concentrations and determinations of local blood flow with 133 Xe clearance in the gastrocnemius muscle and in abdominal subcutaneous adipose tissue. Together with measurements of arterialized venous plasma glycerol, the absolute rates of glycerol mobilization were estimated. In the basal state, skeletal muscle and adipose tissue glycerol levels were 50% higher (P < 0.05-0.01) and adipose tissue blood flow (ATBF) and muscle blood flow (MBF) rates were 30-40% lower (P < 0.02-0.05) in obese versus nonobese subjects. After glucose ingestion, adipose tissue glycerol levels were rapidly and transiently reduced, whereas in muscle, a progressive and less pronounced fall in glycerol levels was evident. MBF remained unchanged in both study groups, whereas ATBF increased more markedly (P < 0.01) in the nonobese versus obese subjects after the oral glucose load. The fasting rates of glycerol release per unit of tissue weight from skeletal muscle were between 20 and 25% of that from adipose tissue in both groups. After glucose ingestion, the rates of glycerol release from skeletal muscle and from adipose tissue were almost identical in nonobese and obese subjects. However, the kinetic patterns differed markedly between tissues; in adipose tissue, the rate of glycerol mobilization was suppressed by 25-30% (P < 0.05) after glucose ingestion, whereas no significant reduction was registered in skeletal muscle. We conclude that significant amounts of glycerol are released from skeletal muscle, which suggests that muscle lipolysis provides an important endogenous energy source in humans. In response to glucose ingestion, the regulation of skeletal muscle glycerol release differs from that in adipose tissue; although the rate of glycerol release from adipose tissue is clearly suppressed, the rate of glycerol mobilization from skeletal muscle remains unaltered. In quantitative terms, the rate of glycerol release per unit of tissue weight in adipose tissue and in skeletal muscle is similar in nonobese and obese subjects in both the postabsorptive state and after glucose ingestion. Diabetes 49:797-802, 2000 S keletal muscle insulin resistance, as reflected by attenuated insulin-mediated glucose disposal, is a key finding of the various clinical components of the metabolic syndrome (e.g., obesity, dyslipidemia, hypertension, and type 2 diabetes) and thus is a predisposing factor in the pathogenesis of premature atherosclerotic cardiovascular disease (1). Among the putative mechanisms underlying insulin resistance, increased attention has been paid to elevated circulating concentrations of free fatty acids (FFAs). We have known for many years that an inverse relationship exists regarding the use of lipids and carbohydrates as metabolic fuels and that inappropriate elevation of FFA levels mediates an i...

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Intramuscular triglyceride content is increased in IDDM

Cited by 44 publications

References 28 publications

Muscle adiposity and body fat distribution in type 1 and type 2 diabetes: varying relationships according to diabetes type

Muscle adiposity and body fat distribution in type 1 and type 2 diabetes: varying relationships according to diabetes type

Effect of Training on Muscle Triacylglycerol and Structural Lipids

Rates of skeletal muscle and adipose tissue glycerol release in nonobese and obese subjects.

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