Introduction
Alterations in energy metabolism in the diabetic can have profound effects on cardiac function, both in the presence and absence of coronary artery disease. It has been well documented that abnormalities in cardiac function (termed ‘diabetic cardiomyopathies’) can occur in the diabetic in the absence of ischemic heart disease.[1–5] Diabetes-induced alterations in myocardial fatty acid and glucose metabolism are an important contributing factor to these cardiomyopathies.[6] These changes in energy metabolism can also contribute to the complications and severity of ischemic heart disease in the diabetic. Diabetics have a significantly greater incidence and severity of angina, acute myocardial infarctions, congestive heart failure, and other manifestations of atherosclerosis than do nondiabetics.[1,7–9] While an increased incidence and severity of coronary artery disease are major contributors to the high prevalence of heart disease in the diabetic compared with the nondiabetic population, it is also clear that changes within the myocytes themselves contribute to the severity of ischemic injury.
One of the prominent cellular changes that occurs in the heart of a diabetic is an alteration in the control of energy metabolism. In particular, glucose uptake and oxidation decrease, while fatty acid oxidation increases.[6] These high fatty acid oxidation rates and low glucose metabolism rates can decrease contractile function and cardiac efficiency in the heart.[10] The inability to use glucose also contributes to the severity of an ischemic insult, and can impair functional recovery during and following ischemia.[10] Both heart failure following an acute myocardial infarction and diabetic cardiomyopathies have been correlated with the acute metabolic status of the patient.[9,11–14] Furthermore, cardiomyopathies in the absence of ischemic heart disease can be improved by correction of hyperglycemia.[11] As a result, diabetes-induced changes in energy metabolism have the potential to significantly impact cardiac function both in the presence and absence of ischemia.

Control of energy metabolism in the normal and diabetic heart
Glucose is the principal carbohydrate metabolized by the heart. Glucose is taken up by the cardiomyocytes in an insulin-dependent manner, and is then predominantly metabolized through glycolysis to form pyruvate.[15] Pyruvate generated from glycolysis, and to a lesser extent from lactate, is further metabolized within the mitochondria to produce the majority of carbohydrate-derived ATP (Figure 1). 

The conversion of pyruvate in the mitochondria to acetyl-CoA is catalyzed by pyruvate dehydrogenase (PDH). This acetyl-CoA undergoes further mitochondrial metabolism, culminating in the synthesis of ATP by the process of oxidative phosphorylation.
Fatty acids are the other major source of acetyl-CoA for the TCA cycle, and the oxidative production of myocardial ATP. Fatty acids seem to be the ‘preferred’ substrate of the myocardium, contributing approximately 60–70% of the heart’s energy requirements when supplied at physiologic levels.[15] However, fatty acids are not as efficient as glucose as a source of energy (with respect to oxygen consumption), and require approximately 10% more oxygen to produce the equivalent amount of ATP.

Diabetes-induced alterations in glucose metabolism
Myocardial glucose transport, glycolysis, and glucose oxidation are all decreased in diabetes (Figure 1). Accompanying the decrease in glucose transport is a decrease in the rate of glycolysis in the diabetic heart.[6] The rate of glucose oxidation is also significantly reduced in the diabetic heart.[16,17] This is due to a marked decrease in PDH activity, the rate-limiting enzyme for glucose oxidation. High circulating free fatty acid levels and myocardial fatty acid oxidation are the key factors responsible for the decreased myocardial PDH activity in diabetes. Numerous studies have now demonstrated that low PDH activity (and therefore low glucose oxidation rates) are detrimental to heart function in both the presence and absence of ischemia (see references [6, 10] and [18] for reviews). In support of this, therapeutic strategies that increase PDH and glucose oxidation have been to improve cardiac function in the diabetic heart, both in the absence and presence of ischemia.[6,10,18] This can be achieved by either directly stimulating PDH, or by directly inhibiting fatty acid oxidation.

Diabetes-induced alterations in fatty acid metabolism
While fatty acid oxidation normally provides 60–70% of the energy requirements of the heart, in uncontrolled diabetes fatty acid oxidation can provide between 90 and 100% of the heart’s energy requirements (Figure 2).[6,10] 

Figure 2. Contribution of fatty acid oxidation and glucose oxidation to mitochondrial TCA cycle activity in the diabetic rat heart. Isolated working hearts from control and 6-week streptozotocin diabetic rats were perfused with 5 mM [U-14]glucose, 1.2 mM [9,10-3H]palmitate, and 100 µU/ml insulin, palmitate and glucose oxidation measured, and the contribution of palmitate and glucose to TCA cycle activity determined, as described in reference 19.

While decreased glucose uptake due to insulin deficiency can partly explain the decrease in glucose metabolism, high levels of circulating fatty acids and alterations in the control of fatty acid oxidation appear to be primarily responsible for this switch. Plasma free fatty acid levels are elevated in patients with either noninsulin-dependent or insulin-dependent diabetes. In diabetics, in whom plasma levels of both free fatty acids and triacylglycerol-rich lipoproteins are increased, fatty acid inhibition of both glycolysis and glucose oxidation in the heart is especially prominent.
Although high levels of circulating fatty acids contribute to low rates of glucose metabolism, alterations in the control of fatty acid oxidation also occur within the myocardium of diabetics. One site that appears to be particularly important is the control of fatty acid uptake by the mitochondria.[6,18]

Energy metabolism during and following cardiac ischemia in the 
diabetic
During a mild ischemic episode, fatty acid oxidation and glucose oxidation both decrease, with glycolysis becoming the dominant source of energy production.[15] A large increase in the amount of glycolysis relative to glucose oxidation occurs, resulting in the anaerobic hydrolysis of ATP and the production of excess cytosolic protons. This uncoupling of glycolysis from glucose oxidation is a major source of proton production in the myocardium during ischemia. Since coronary flow is diminished at this time, excess protons accumulate, resulting in intracellular acidosis. These protons exchange for other cations, and can lead to an increase in intracellular calcium overload. The need to use ATP to reestablish H+, Na+, and Ca2+ homeostasis can lead to a decrease in cardiac efficiency. As a result, low glucose oxidation rates contribute to a decrease in cardiac efficiency during ischemia.[19]
During reperfusion following an episode of ischemia, a rapid recovery of mitochondrial energy production must occur if contractile function is to recover. During this period, fatty acid oxidation quickly recovers and becomes the predominant source of myocardial ATP production, providing 80–90% of the heart’s energy requirements.[19] High rates of fatty acid oxidation during reperfusion of ischemic hearts markedly decrease glucose oxidation rates, contributing to contractile dysfunction during reperfusion.[19] In the diabetic, the problems associated with low glucose oxidation both during and following ischemia are exacerbated. While serum fatty acid concentrations in normal individuals range from 0.2 to 0.5 mM, during an acute myocardial infarction serum fatty acids can increase above 1 mM.[6] In diabetics, serum fatty acids can be elevated even in the absence of an acute myocardial infarction, and can rise during ischemia to very high levels. A number of experimental studies have examined the involvement of fatty acids during ischemia, and possible mechanisms by which fatty acids contribute to injury (see references 6, 10 and 18 for reviews). Fatty acid inhibition of glucose oxidation (via PDH inhibition) appears to be one contributing factor to ischemic injury. Fatty acids also promote and accelerate arrhythmias, decrease mechanical function, and impair membrane integrity and suborganelle performance.

Pharmacological modification of cardiac energy metabolism in the diabetic
Interventions aimed at decreasing proton production by increasing glucose oxidation have the potential to improve cardiac efficiency.[19] Recent experimental and clinical studies have shown that stimulating glucose oxidation can improve both cardiac function and cardiac efficiency.[6,10] Experimental studies have shown that direct stimulation of glucose oxidation can improve cardiac function in hearts from diabetic animals, and decrease the adverse effects of ischemia.[20] Stimulation of glucose oxidation can either be by direct stimulation of glucose oxidation, or indirectly by inhibiting fatty acid oxidation. For instance, direct stimulation of glucose oxidation with the PDH activator dichloroacetate improves cardiac function in the nonischemic heart,[20] and improves functional recovery and cardiac efficiency in the reperfused ischemic heart.[19] Overcoming fatty acid inhibition of PDH with L-carnitine is another effective approach to benefiting cardiac function in the nonischemic and ischemic heart.[21]
Another effective approach to increasing glucose oxidation in the heart is by inhibiting fatty acid oxidation. This can either be achieved by inhibiting fatty acid uptake into the mitochondria, or by inhibiting fatty acid b-oxidation within the mitochondria. Agents that block mitochondrial fatty acid uptake (such as etomoxir, methylpalmoxirate, and oxfenicine) have been shown in experimental studies to improve heart function and decrease ischemic injury in animal models of diabetes.[10] Direct inhibition of fatty acid b-oxidation within the mitochondria can also benefit the diabetic heart. Pharmacological agents that inhibit fatty acid oxidation and stimulate glucose oxidation are now being used clinically to treat ischemic heart disease. Trimetazidine, the first 3-KAT inhibitor which stimulates glucose oxidation in the heart secondary to an inhibition of fatty acid oxidation,[22] is licensed worldwide for the treatment of ischemic heart disease.[23] Whether a similar approach may be efficacious in diabetics with ischemic heart disease is presently being evaluated. Clinical studies in Poland coordinated by Dr Hanna Szwed have shown that trimetazidine can reduce the symptoms, severity, and frequency of angina attacks in diabetic patients with angina pectoris.[24] Further studies are necessary to evaluate whether diabetic cardiomyopathic changes can also be decreased with the use of this therapy.

Summary
Increased fatty acid oxidation and decreased glucose metabolism contribute to the development of diabetic cardiomyopathies, and can decrease the ability of the heart to withstand an ischemic insult. Optimizing energy metabolism is now recognized as an effective clinical approach to treating ischemic heart disease. This metabolic approach may also have clinical potential in treating the diabetic patient. 

REFERENCES

 

1. Circulation 1979 Jan;59(1):8-13

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Diabetes and cardiovascular risk factors: the Framingham study.

Kannel WB, McGee DL.

The impact of cardiovascular disease was compared in non-diabetics and diabetics in the Framingham cohort. In the first 20 years of the study about 6% of the women and 8% of the men were diagnosed as diabetics. The incidence of cardiovascular disease among diabetic men was twice that among non-diabetic men. Among diabetic women the incidence of cardiovascular disease was three times that among non-diabetic women. Judging from a comparison of standardized coefficients for the regression of incidence of cardiovascular disease on specified risk factors, there is no indication that the relationship of risk factors to the subsequent development of cardiovascular disease is different for diabetics and non-diabetics. This study suggests that the role of diabetes as a cardiovascular risk factor does not derive from an altered ability to contend with known risk factors.

PMID: 758126 [PubMed - indexed for MEDLINE]

 

2. Am Heart J 1980 Apr;99(4):446-58

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Clinical and morphological features of human hypertensive-diabetic cardiomyopathy.

Factor SM, Minase T, Sonnenblick EH.

PMID: 6444776 [PubMed - indexed for MEDLINE]

 

3. Am J Cardiol 1988 Dec 1;62(17):1273-9

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Impaired left ventricular systolic function during exercise in middle-aged insulin-dependent and noninsulin-dependent diabetic subjects without clinically evident cardiovascular disease.

Mustonen JN, Uusitupa MI, Tahvanainen K, Talwar S, Laakso M, Lansimies E, Kuikka JT, Pyorala K.

Department of Medicine, Kuopio University Central Hospital, Finland.

Equilibrium radionuclide angiocardiography was performed on 19 men and 17 women with insulin-dependent diabetes mellitus (IDDM) and on 24 men and 15 women with noninsulin-dependent diabetes mellitus (NIDDM) and on 24 male and 24 female control subjects aged 46 to 67 years. All were without clinically evident cardiovascular disease. No significant differences were found in left ventricular (LV) ejection fraction at rest between men with IDDM (56 +/- 1%; mean +/- standard error of the mean) or NIDDM (58 +/- 1%) and control men (58 +/- 1%), whereas LV ejection fraction was higher in women with IDDM (63 +/- 1%; p less than 0.01) and NIDDM (64 +/- 2%; p less than 0.01) than in control women (58 +/- 1%). An abnormal LV ejection fraction response to dynamic exercise (an increase of less than 5% units or a decrease) was observed in 1 control man (4%), in 8 men with IDDM (42%, p less than 0.01) and in 10 men with NIDDM (42%, p less than 0.01). The respective figures were 4 (17%) for control women, 7 (44%, difference not significant) for women with IDDM and 10 (71%, p less than 0.01) for women with NIDDM. Abnormal LV ejection fraction response to exercise in diabetic patients was not related to the metabolic control of diabetes, presence of microangiopathy or abnormalities in the autonomic nervous function. Myocardial perfusion scintigraphy performed in 18 diabetic patients in whom LV ejection fraction decreased during exercise showed a reversible perfusion defect in only 5 (28%).(ABSTRACT TRUNCATED AT 250 WORDS)

PMID: 3264106 [PubMed - indexed for MEDLINE]

 

4. Br Heart J 1985 Nov;54(5):466-72

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Myocardial infarct size and mortality in diabetic patients.

Gwilt DJ, Petri M, Lewis PW, Nattrass M, Pentecost BL.

The mortality rate from myocardial infarction is disproportionately high in diabetic patients. One explanation for this may be that diabetic patients incur more extensive myocardial necrosis. This possibility was examined in a three part study. Firstly, peak serum aspartate aminotransferase concentrations of all diabetic and non-diabetic patients admitted with myocardial infarction over a 16 year period were compared retrospectively. Secondly, peak aspartate aminotransferase concentrations in a series of diabetic patients and controls matched by age and sex were examined retrospectively. Thirdly, creatine kinase MB release and electrocardiographic measures of infarct size were investigated prospectively in a case/control study. Although cardiac failure and death were more common in the diabetic groups, there were no significant differences in estimates of infarct size between diabetic and non-diabetic patients in any of the studies. Therefore, the high case fatality rate amongst diabetic patients is not caused by increased myocardial damage. Presumably survival is prejudiced by factors operating before the infarction.

PMID: 4052287 [PubMed - indexed for MEDLINE]

 

5. Am Heart J 1984 Jul;108(1):31-7

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Increased congestive heart failure after myocardial infarction of modest extent in patients with diabetes mellitus.

Jaffe AS, Spadaro JJ, Schechtman K, Roberts R, Geltman EM, Sobel BE.

To elucidate the factors involved in the reduced survival rate of diabetic patients after acute myocardial infarction (AMI), we prospectively evaluated 100 patients with well-documented diabetes and 426 control patients. We characterized infarct size and analyzed the incidence and severity of congestive heart failure (CHF) and subsequent death with respect to infarct size. The extent of the index infarct was less in diabetic compared to nondiabetic patients, 16.2 +/- 2.2 CK-gm-eq/m2 compared with 19.2 +/- 0.9 (p less than 0.02). However, CHF was more prevalent in diabetic patients (31.2% of the diabetic patients compared to 15.7%). The difference was most prominent in diabetic patients who had sustained prior infarction (50% compared to 16%), but was evident also in diabetic patients with initial infarction (26% compared to 16%). The mortality rate was greater in diabetic patients (p less than 0.04). When diabetic and nondiabetic patients were stratified with respect to the presence or absence of CHF, survival curves were comparable. The increased incidence of CHF despite a smaller infarct size suggests that additional factors must contribute to myocardial dysfunction and the resultant excess in mortality.

PMID: 6731279 [PubMed - indexed for MEDLINE]

 

6. Coron Artery Dis 1996 Feb;7(2):116-23

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Abnormal mechanical function in diabetes: relationship to altered myocardial carbohydrate/lipid metabolism.

Lopaschuk GD.

Department of Pediatrics, University of Alberta, Edmonton, Canada.

Publication Types:

	Review
	Review, academic

PMID: 8813442 [PubMed - indexed for MEDLINE]

7. Bradley RF, Bryfogle JW. Survival of diabetic patients after myocardial infarction. Am J Med. 1956;30:207–216.

 

8. Diabetes 1985 Aug;34(8):787-92

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Long-term prognosis after myocardial infarction in men with diabetes.

Ulvenstam G, Aberg A, Bergstrand R, Johansson S, Pennert K, Vedin A, Wilhelmsen L, Wilhelmsson C.

Men (1306) who survived a first myocardial infarction (MI) were studied. The mean follow-up time was 6.5 yr, and at the end of the follow-up period survival status was known for all patients. By the time of the MI the prevalence of diabetes was 5.6%. Patients with and without diabetes were compared. There were no differences in the estimated primary or secondary risk. The cumulative survival rate 1, 2, and 5 yr after the MI was 82, 78, and 58% among the diabetic subjects compared with 94, 92, and 82% among the nondiabetic subjects (P less than 0.001). The difference remained even after allowance for age and estimated secondary risk in a multivariate regression analysis. There were no differences in mortality rates among patients with type I diabetes compared with type II diabetes, nor among patients treated with diet alone, sulfonylurea, or insulin, but the numbers were small. The cumulative rate of reinfarctions after 1, 2, and 5 yr was 18, 28, and 46% in diabetic subjects and 12, 17, and 27% in nondiabetic subjects (P = 0.004). A history of diabetes was an independent secondary risk factor among male survivors of a first MI with respect to deaths and reinfarctions.

PMID: 4018416 [PubMed - indexed for MEDLINE]

 

9. Am J Med 1971 Dec;51(6):715-24

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Mortality experience of diabetic patients. A twenty-six-year follow-up study.

Kessler II.

PMID: 5129542 [PubMed - indexed for MEDLINE]

 

10. Biochim Biophys Acta 1994 Aug 4; 1213(3):263-76

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Regulation of fatty acid oxidation in the mammalian heart in health and disease.

Lopaschuk GD, Belke DD, Gamble J, Itoi T, Schonekess BO.

Department of Pediatrics, Faculty of Medicine, University of Alberta, Edmonton, Canada.

Publication Types:

	Review
	Review, tutorial

PMID: 8049240 [PubMed - indexed for MEDLINE]

 

11. Am J Cardiol 1989 Oct 15;64(14):885-8

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Hyperglycemia and prognosis of acute myocardial infarction in patients without diabetes mellitus.

Bellodi G, Manicardi V, Malavasi V, Veneri L, Bernini G, Bossini P, Distefano S, Magnanini G, Muratori L, Rossi G, et al.

II Medical Division, Hospital of Guastalla, Reggio Emilia, Italy.

The present study assessed the prognostic value of hyperglycemia--a common feature in the early phase of acute myocardial infarction (AMI)--in 330 nondiabetic patients. Seventy-nine known diabetics and 10 (3%) unknown diabetics--diagnosed before discharge by stable glycosylated hemoglobin greater than 6.9% and by oral glucose tolerance testing--were excluded. Thirty-three (10%) patients died. The mortality rate was higher in women, in patients with anterior AMI, in older patients (greater than 65 years) and in the presence of heart failure. It was highest in patients with cardiogenic shock (24/36 vs 9/294; p less than 0.0001). Admission plasma glucose was significantly higher in nonsurvivors than in survivors (163 +/- 60 vs 114 +/- 36 mg/dl; p less than 0.0001). Mortality rate increased with increasing admission plasma glucose: 3% in normoglycemic patients (less than or equal to 120 mg/dl) versus 15% in patients with borderline plasma glucose (121 to 180 mg/dl) versus 43% in hyperglycemic patients (greater than 180 mg/dl) (p less than 0.0001). Multiple regression (stepwise) analysis identified cardiogenic shock, infarct site and age as the major determinants of mortality, while admission plasma glucose failed to reach full statistical significance (p = 0.067). Hyperglycemia was related to all 3 of these independent prognostic factors; when age and infarct site were accounted for, hyperglycemia was significantly associated with heart failure only and this association was characterized by a remarkable mortality rate. In nondiabetic patients with AMI, hyperglycemia is a correlate of heart failure and, therefore, an important factor of prognosis.

PMID: 2801556 [PubMed - indexed for MEDLINE]

 

12. Lancet 1984 Jun 9;1(8389):1264-7

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Prevalence and risks of hyperglycaemia and undiagnosed diabetes in patients with acute myocardial infarction.

Oswald GA, Corcoran S, Yudkin JS.

Two studies were undertaken to assess the prevalence of undiagnosed diabetes mellitus in patients admitted with acute myocardial infarction (AMI), and the effect of diabetes mellitus and admission hyperglycaemia on outcome. In the retrospective study, admission levels of plasma glucose (APG) were higher (p less than 0.02) in patients dying from cardiogenic shock than in survivors, but they were not related to infarct size. In the prospective study APG was related (p less than 0.01) to concurrent levels of glycosylated haemoglobin (HbA1c), which were in turn related to outcome--the mortality rate was 23% for those with normal HbA1c (less than 7.5%), 33% for those with borderline abnormal HbA1c (7.5-8.5%), and 63% for those with clearly abnormal HbA1c (greater than 8.5%). Cardiogenic shock was commoner in the groups with higher HbA1c levels. In addition, admission hyperglycaemia was associated (p less than 0.01) with the incidence of cardiogenic shock even after correcting for the effects of HbA1c. All of the survivors from the clearly abnormal HbA1c group, but none of those from other groups, were diabetic at follow up, suggesting an overall prevalence of undiagnosed diabetes mellitus of 5.3%. The contribution of undiagnosed diabetes mellitus to total mortality following AMI seems at present to be underestimated.

PMID: 6144976 [PubMed - indexed for MEDLINE]

 

13. Br Med J (Clin Res Ed) 1986 Oct 11;293(6552):917-22

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Determinants and importance of stress hyperglycaemia in non-diabetic patients with myocardial infarction.

Oswald GA, Smith CC, Betteridge DJ, Yudkin JS.

Determinants of plasma glucose concentrations were studied in patients on admission to hospital with confirmed acute myocardial infarction but without previous glucose intolerance as evidenced by raised concentrations of glycosylated haemoglobin (HbAlc). Mortality in hospital increased significantly with increasing plasma concentrations of glucose in patients with both normal (p less than 0.0001, n = 311) and borderline (p less than 0.02, n = 70) concentrations of HbAlc. There was a weak relation between plasma glucose concentrations and infarct size as estimated by peak aspartate transaminase activity in both HbAlc groups (rs = 0.26, n = 101 and rs = 0.41, n = 35 respectively). A correlation was found between adrenaline and plasma glucose concentrations (r = 0.47, n = 27) and cortisol and plasma glucose concentrations (r = 0.75, n = 19), but the relation of plasma noradrenaline and plasma glucose suggested a threshold effect. Concentrations of adrenaline, but not those of noradrenaline or cortisol, correlated with infarct size as measured both by peak aspartate transaminase activity and cumulative release of creatine kinase MB isoenzyme. Multiple regression analysis showed that concentrations of cortisol, adrenaline, and noradrenaline (but not the concentration of HbAlc, infarct size, or age) are the main determinants of plasma glucose concentration measured in non-diabetic patients when admitted to hospital after acute myocardial infarction.

PMID: 3094714 [PubMed - indexed for MEDLINE]

 

14. N Engl J Med 1965 Aug 26;273(9):455-61

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Acute myocardial infarction in 258 cases of diabetes. Immediate mortality and five-year survival.

Partamian JO, Bradley RF.

PMID: 5826160 [PubMed - indexed for MEDLINE]

15. Neely JR, Morgan HE. Relationship between carbohydrate metabolism and energy balance of heart muscle. Ann Rev Physiol. 1974;36:413–459.

 

16. Biochem J 1964 Dec;93(3):678-87

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Regulation of glucose uptake by muscles. 10. Effects of alloxan-diabetes, starvation, hypophysectomy and adrenalectomy, and of fatty acids, ketone bodies and pyruvate, on the glycerol output and concentrations of free fatty acids, long-chain fatty acyl-coenzyme A, glycerol phosphate and citrate-cycle intermediates in rat heart and diaphragm muscles.

Garland PB, Randle PJ.

PMID: 5839199 [PubMed - indexed for MEDLINE]

 

17. Biochim Biophys Acta 1989 Nov 6;1006(1):97-103

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Glucose oxidation rates in fatty acid-perfused isolated working hearts from diabetic rats.

Wall SR, Lopaschuk GD.

Department of Pediatrics, Faculty of Medicine, University of Alberta, Edmonton, Canada.

The effect of fatty acids and the carnitine palmitoyltransferase I (CPT I) inhibitor, Etomoxir, on myocardial glucose oxidation in diabetes was studied. 14CO2 production from 11 mM [14C]glucose was measured in control or 6-week streptozotocin-diabetic isolated working rat hearts perfused with or without 1.2 mM palmitate (bound to 3% albumin). In control hearts, addition of palmitate to the buffer resulted in a marked reduction (13-fold) in glucose oxidation rates. Glucose oxidation in diabetic rat hearts perfused with palmitate was almost abolished. Even though glucose oxidation rates were low, exogenous palmitate oxidation rates, measured as 14CO2 production from [14C]palmitate, were not increased in diabetic versus control hearts. Addition of the CPT 1 inhibitor, Etomoxir (1.10(-6) M), resulted in a doubling of glucose oxidation rates in both control and diabetic rat hearts, in the presence or absence of palmitate. The effects of Etomoxir on glucose oxidation could not be explained by reduced exogenous palmitate oxidation or decreased levels of citrate. Cardiac function, as measured by the heart rate x peak systolic pressure product, was reduced in diabetic rat hearts. Etomoxir significantly increased heart function in palmitate-perfused hearts from both control and diabetic rats. These data suggest that fatty acids contribute to decreased glucose oxidation and cardiac function in diabetic rat hearts. These effects of fatty acids can be partially reversed with the CPT 1 inhibitor, Etomoxir.

PMID: 2804076 [PubMed - indexed for MEDLINE]

18. Stanley WC, Lopaschuk GD, Kivilo KM. Alterations 
in myocardial energy metabolism in streptozotocin diabetes. In: McNeill JH, ed. Experimental Models of Diabetes. Boca Raton, FL: CRC Press; 1999:19–38.

 

19. Circ Res 1996 Nov;79(5):940-8

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Cardiac efficiency is improved after ischemia by altering both the source and fate of protons.

Liu B, Clanachan AS, Schulz R, Lopaschuk GD.

Department of Pediatrics, University of Alberta, Edmonton, Canada.

Cardiac efficiency is decreased in hearts after severe ischemia. We determined whether reducing the production of H+ from glucose metabolism or inhibiting the clearance of H+ via Na(+)-H+ exchange could increase cardiac efficiency during reperfusion. This was achieved using dichloroacetate (DCA) to stimulate glucose oxidation and 5-(N,N-dimethyl)-amiloride (DMA) to inhibit Na(+)-H+ exchange, respectively. Isolated working rat hearts were subjected to 30 minutes of global ischemia and 60 minutes of reperfusion. Glycolysis and oxidation rates of glucose, lactate, and palmitate were measured. Recovery of cardiac work, O2 consumption (MVO2), and rates of acetyl-coenzyme A and ATP production during reperfusion were determined. After ischemia, cardiac work recovered to 35 +/- 5% of preischemic values in control hearts (n = 23), although MVO2, tricarboxylic acid (TCA) cycle activity, and ATP production from glycolysis and oxidative metabolism rapidly recovered to preischemic levels. This decrease in cardiac efficiency was accompanied by a substantial production of H+ from glucose metabolism DCA caused a 2.2-fold increase in glucose oxidation, a 46 +/- 17% decrease in H+ production, a 1.6-fold increase in cardiac efficiency, and a 2.0-fold increase in cardiac work during reperfusion (n = 17). Inhibition of Na(+)-H+ exchange with DMA did not alter TCA cycle activity and ATP production rates but did result in a 1.8-fold increase in cardiac efficiency and a 1.7-fold increase in cardiac work (n = 12). These data show that cardiac efficiency and the contractile function after ischemia can be improved by either reducing the rate of H+ production from glucose metabolism during reperfusion or inhibiting the clearance of H+ via Na(+)-H+ exchange. Our data suggest that an increased requirement for ATP to restore ischemia-reperfusion-induced alterations in ion homeostasis contributes to the decrease in cardiac efficiency and contractile function after ischemia.

PMID: 8888686 [PubMed - indexed for MEDLINE]

 

20. Am J Physiol 1991 Oct;261(4 Pt 2):H1053-9

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Effects of free fatty acids and dichloroacetate on isolated working diabetic rat heart.

Nicholl TA, Lopaschuk GD, McNeill JH.

Faculty of Pharmaceutical Sciences, University of British Columbia, Vancouver, Canada.

It is well established that cardiac dysfunction independent of atherosclerosis develops in both humans and animals with diabetes mellitus. The etiology is complex, involving many different processes, one of which may be increased fatty acid utilization and/or a concomitant decrease in glucose utilization by the diabetic heart. We compared control and 6-wk streptozotocin (STZ)-induced diabetic isolated working rat hearts and were able to demonstrate cardiac dysfunction in the diabetic as assessed by depressed heart rate (HR), heart rate peak systolic pressure product (HR.PSP), left ventricular developed pressure (LVDP), and rate of pressure rise (+dP/dt). Paralleling depressed cardiac function in the diabetic were hyperglycemia, hyperlipidemia, and decreased body weight gain compared with age-matched controls. The addition of free fatty acids, in the form of 1.2 mM palmitate, to the isolated working heart perfusate had no effect on either control or diabetic heart function, with the exception of a depressive effect on +dP/dt of diabetic hearts. But diabetic hearts perfused with palmitate-containing perfusate plus the glucose oxidation stimulator dichloroacetate (DCA) showed a marked improvement in function. HR and HR.PSP in spontaneously beating hearts, as well as LVDP and +dP/dt in paced hearts were all restored to control heart values in diabetic hearts perfused in the presence of DCA. Creatine phosphate and ATP levels were similar under all perfusion conditions, thus eliminating energy stores as the limiting factor in heart function. Results indicate that DCA will acutely reverse diabetic cardiac function depression. Therefore glucose oxidation depression in the diabetic heart may be a significant factor contributing to cardiac dysfunction.

PMID: 1928388 [PubMed - indexed for MEDLINE]

 

21. Cardiovasc Res 1995 Mar;29(3):373-8

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L-carnitine increases glucose metabolism and mechanical function following ischaemia in diabetic rat heart.

Broderick TL, Quinney HA, Lopaschuk GD.

Cardiovascular Disease Research Group, University of Alberta, Edmonton, Canada.

OBJECTIVE: Stimulation of glucose oxidation by L-carnitine improves mechanical recovery of ischaemic hearts from non-diabetic rats perfused with high levels of fatty acids. The aim of this study was to determine whether L-carnitine also increases glucose oxidation and function in diabetic rat hearts, which have suppressed glucose metabolism. METHODS: Isolated working hearts from six week streptozotocin diabetic and control rats were perfused with 11 mM (5-3H/U-14C)-glucose, 1.2 mM palmitate. Hearts were paced at 260 beats.min-1 during 60 min of low flow ischaemia, and were then subjected to 30 min of aerobic reperfusion. Total myocardial carnitine content in these hearts was first increased by a 60 min aerobic perfusion with 10 mM L-carnitine. RESULTS: Steady state glucose oxidation rates (measured as 14CO2 production) were depressed in diabetic rat hearts compared to control hearts during the initial aerobic period. However, L-carnitine treatment dramatically increased glucose oxidation rates in the diabetic rat hearts, as well as in control hearts. Glycolysis was also lower in diabetic rat hearts compared to control hearts, although L-carnitine treatment significantly increased glycolysis only in the diabetic animals. During reperfusion, steady state rates of glucose oxidation and glycolysis returned to preischaemic values in both the control and diabetic groups. L-carnitine treatment stimulated glucose oxidation during reperfusion in control and diabetic rat hearts. Mechanical function of control hearts returned to 38(SEM 9)% of preischaemic values, whereas in L-carnitine treated hearts function returned to 90(7)% of preischaemic values. Recovery of function was 80(15)% of preischaemic in the diabetic rat hearts, and was increased to 100% of preischaemic function with L-carnitine. CONCLUSIONS: Carnitine improves recovery of function of ischaemic non-diabetic rats by stimulating glucose oxidation during reperfusion, whereas it may be beneficial in diabetic rat hearts by stimulating both glycolysis during ischaemia and glucose oxidation during reperfusion.

PMID: 7781011 [PubMed - indexed for MEDLINE]

 

22. Circ Res 2000 Mar 17;86(5):580-8

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Comment in:

Circ Res. 2000 Mar 17;86(5):487-9

The antianginal drug trimetazidine shifts cardiac energy metabolism from fatty acid oxidation to glucose oxidation by inhibiting mitochondrial long-chain 3-ketoacyl coenzyme A thiolase.

Kantor PF, Lucien A, Kozak R, Lopaschuk GD.

Cardiovascular Research Group and the Division of Pediatric Cardiology, University of Alberta, Edmonton, Canada.

Trimetazidine is a clinically effective antianginal agent that has no negative inotropic or vasodilator properties. Although it is thought to have direct cytoprotective actions on the myocardium, the mechanism(s) by which this occurs is as yet undefined. In this study, we determined what effects trimetazidine has on both fatty acid and glucose metabolism in isolated working rat hearts and on the activities of various enzymes involved in fatty acid oxidation. Hearts were perfused with Krebs-Henseleit solution containing 100 microU/mL insulin, 3% albumin, 5 mmol/L glucose, and fatty acids of different chain lengths. Both glucose and fatty acids were appropriately radiolabeled with either (3)H or (14)C for measurement of glycolysis, glucose oxidation, and fatty acid oxidation. Trimetazidine had no effect on myocardial oxygen consumption or cardiac work under any aerobic perfusion condition used. In hearts perfused with 5 mmol/L glucose and 0.4 mmol/L palmitate, trimetazidine decreased the rate of palmitate oxidation from 488+/-24 to 408+/-15 nmol x g dry weight(-1) x minute(-1) (P<0.05), whereas it increased rates of glucose oxidation from 1889+/-119 to 2378+/-166 nmol x g dry weight(-1) x minute(-1) (P<0.05). In hearts subjected to low-flow ischemia, trimetazidine resulted in a 210% increase in glucose oxidation rates. In both aerobic and ischemic hearts, glycolytic rates were unaltered by trimetazidine. The effects of trimetazidine on glucose oxidation were accompanied by a 37% increase in the active form of pyruvate dehydrogenase, the rate-limiting enzyme for glucose oxidation. No effect of trimetazidine was observed on glycolysis, glucose oxidation, fatty acid oxidation, or active pyruvate dehydrogenase when palmitate was substituted with 0.8 mmol/L octanoate or 1.6 mmol/L butyrate, suggesting that trimetazidine directly inhibits long-chain fatty acid oxidation. This reduction in fatty acid oxidation was accompanied by a significant decrease in the activity of the long-chain isoform of the last enzyme involved in fatty acid beta-oxidation, 3-ketoacyl coenzyme A (CoA) thiolase activity (IC(50) of 75 nmol/L). In contrast, concentrations of trimetazidine in excess of 10 and 100 micromol/L were needed to inhibit the medium- and short-chain forms of 3-ketoacyl CoA thiolase, respectively. Previous studies have shown that inhibition of fatty acid oxidation and stimulation of glucose oxidation can protect the ischemic heart. Therefore, our data suggest that the antianginal effects of trimetazidine may occur because of an inhibition of long-chain 3-ketoacyl CoA thiolase activity, which results in a reduction in fatty acid oxidation and a stimulation of glucose oxidation.

PMID: 10720420 [PubMed - indexed for MEDLINE]

 

23. Drugs 1999 Jul;58(1):143-57

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Trimetazidine. A review of its use in stable angina pectoris and other coronary conditions.

McClellan KJ, Plosker GL.

Adis International Limited, Auckland, New Zealand. demail@adis.co.nz

The orally administered antianginal agent trimetazidine increases cell tolerance to ischaemia by maintaining cellular homeostasis. In theory, this cytoprotective activity should limit myocyte loss during ischaemia in patients with angina pectoris. Data from studies in patients with coronary artery disease indicate that, unlike the effects of other antianginals, the anti-ischaemic effects of trimetazidine 20 mg are not associated with alterations in haemodynamic determinants of myocardial oxygen consumption such as heart rate, systolic blood pressure and the rate-pressure product. Furthermore, limited evidence suggests trimetazidine may improve left ventricular function in patients with chronic coronary artery disease or ischaemic cardiomyopathy and in patients experiencing acute periods of ischaemia when undergoing percutaneous transluminal coronary angioplasty. Clinical studies have shown that oral trimetazidine 20 mg 3 times daily reduces the frequency of anginal attacks and nitroglycerin use and increases exercise capacity when used as monotherapy in patients with angina pectoris. Its clinical effects are broadly similar to those of nifedipine 40 mg/day and propranolol 120 to 160 mg/day but, unlike these agents, trimetazidine does not affect the rate-pressure product during peak exercise or at rest. Adjunctive trimetazidine 60 mg/day reduces the frequency of anginal attacks and nitroglycerin use and improves exercise capacity in patients with angina pectoris not sufficiently controlled by conventional antianginal agents. Furthermore, the drug appears to be more effective than isosorbide dinitrate 30 mg/day when used adjunctively in patients with angina pectoris poorly controlled by propranolol 120 mg/day. The tolerability profile of trimetazidine 60 mg/day was similar to that of placebo when used as add-on therapy in patients with angina pectoris insufficiently controlled by other antianginal agents and was superior to that of either nifedipine 40 mg/day or propranolol 120 to 160 mg/day when used as monotherapy. The most frequently reported adverse events in trimetazidine recipients were gastrointestinal disorders, although the incidence of these events was low. CONCLUSIONS: Trimetazidine is an effective and well tolerated anti-ischaemic agent which, in addition to providing symptom relief and functional improvement in patients with angina pectoris, has a cytoprotective action during ischaemia. The drug is suitable for initial use as monotherapy in patients with angina pectoris and, because of its different mechanism of action, as adjunctive therapy in those with symptoms not sufficiently controlled by nitrates, beta-blockers or calcium antagonists. The role of trimetazidine in other coronary conditions has yet to be clearly established.

Publication Types:

	Review
	Review, tutorial

PMID: 10439934 [PubMed - indexed for MEDLINE]

 

24. Cardiovasc Drugs Ther 1999 May;13(3):217-22

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The antiischemic effects and tolerability of trimetazidine in coronary diabetic patients. A substudy from TRIMPOL-1.

Szwed H, Sadowski Z, Pachocki R, Domzal-Bochenska M, Szymczak K, Szydlowski Z, Paradowski A, Gajos G, Kaluza G, Kulon I, Wator-Brzezinska A, Elikowski W, Kuzniak M.

National Institute of Cardiology, Warsaw, Poland.

Diabetes mellitus, a disease with a wide prevalence, has major cardiovascular effects, being a risk factor for the development of ischemic heart disease and congestive heart failure. The aim of this open, multicenter study was to assess the antiischemic efficacy and tolerability of trimetazidine, a metabolic agent acting at the myocardial mitochondrial level, in diabetic patients with stable effort angina treated previously with a single conventional antianginal drug. Fifty diabetic patients (mean age 58 years) with proven coronary artery disease, stable effort angina for at least 3 months, and positive, comparable results of two initial treadmill exercise tests separated by a 1-week interval were included in the study. They continued their conventional antianginal monotherapy with a long-acting nitrate, beta-blocker, or calcium channel blocker. After stabilization, 4-week therapy with trimetazidine, three times daily, 20 mg was initiated in combination with previous treatment. The results showed a significant improvement in exercise tolerance (440.2 vs. 383.2 s; P < 0.01), time to 1-mm ST-segment depression (358.3 vs. 301.6 s; P < 0.01), time to onset of anginal pain (400.0 vs. 238.3 s; P < 0.01), and total work (9.39 vs. 8.67 metabolic equivalents, P < 0.01). Maximal ST-segment depression was attenuated compared with baseline (1.82 vs. 1.91 mm). Other findings included a significant decrease in the mean frequency of anginal episodes (3.06 vs. 4.79 per week; P < 0.01) and in mean nitrate consumption (2.29 vs. 4.2 doses/week). These results suggest that trimetazidine may be effective and is well tolerated as combination therapy for diabetic coronary artery disease patients uncontrolled with a single hemodynamic agent.

Publication Types:

	Clinical trial
	Multicenter study

PMID: 10439884 [PubMed - indexed for MEDLINE]