Hypertriglyceridemia: its etiology, effects and treatment

Elevated plasma triglyceride concentration is a common biochemical finding, but the evidence for the benefit of treating this lipid disturbance remains less robust than that for treating elevated low-density lipoprotein-cholesterol. Part of the difficulty in the provision of specific recommendations has been the frequent coexistence of elevated triglycerides with other conditions that affect cardiovascular disease risk, such as depressed high-density lipoprotein-cholesterol, obesity, metabolic syndrome, proinflammatory and prothrombotic biomarkers, and type 2 diabetes. Recent investigations of outcomes of cardiovascular disease when medications are used to reduce triglyceride levels suggest that, although a net benefit probably exists, both relative and absolute risk reductions seem underwhelming when compared with the benefit of reducing low-density lipoprotein-cholesterol levels with treatment. However, the totality of evidence suggests that elevated triglyceride levels likely contribute independently to increased risk of cardiovascular disease, although there is no consensus about appropriate target levels. Furthermore, severe hypertriglyceridemia is associated with an increased risk of acute pancreatitis, irrespective of its effect on risk of cardiovascular disease. We review the causes and classification of elevated triglyceride levels, the clinical manifestations of primary hypertriglyceridemia and the management of patients with elevated triglyceride levels.

Long-term follow-up of patients with acute hypertriglyceridemia-induced pancreatitis

BACKGROUND

An acute and potentially life-threatening complication of hypertriglyceridemia (HTG) is acute pancreatitis (AP). Hypertriglyceridemia, usually severe, may be primary in origin or secondary to alcohol abuse, diabetes mellitus, pregnancy, and use of drugs.

STUDY

The efficacy of treatment to prevent relapses in 17 patients with AP attributed to HTG was investigated in the current prospective study. The mean follow-up period of patients was 42 months. Hypertriglyceridemia-induced AP comprised 6.9% of all patients with AP (n = 246) hospitalized in our clinic during the study (6 years).

RESULTS

Causative conditions of HTG-induced AP were familial HTG in eight patients, HTG caused by uncontrolled diabetes mellitus in five, HTG aggravated by drugs in two (one by tamoxifen and one by fluvastatin), familial hyperchylomicronemia (HCM) in one, and lipemia of pregnancy in one. During the acute phase of pancreatitis, patients underwent standard treatment. Thereafter, HTG was efficiently controlled with high dosages of fibrates or a fibrate plus acipimox, except for the patient with HCM, who was on a specific diet (the only source of fat was a special oil consisting of medium chain triglyceride) and taking a high dosage of acipimox. One of the patients died during the acute phase of pancreatitis with acute respiratory distress syndrome. During follow-up, maintenance treatment was successful and only one patient relapsed, because he discontinued diet and drug treatment.

CONCLUSION

Appropriate diet and drug treatment, including dose titration, of severe HTG is very effective in preventing relapses of HTG-induced AP.

Hypertriglyceridemia

Hypertriglyceridemia (HTG) is commonly encountered in lipid and cardiology clinics. Severe HTG warrants treatment because of the associated increased risk of acute pancreatitis. However, the need to treat, and the correct treatment approach for patients with mild to moderate HTG are issues for ongoing evaluation. In the past, it was felt that triglyceride does not directly contribute to development of atherosclerotic plaques. However, this view is evolving, especially for triglyceride-related fractions and variables measured in the non-fasting state. Our understanding of the etiology, genetics and classification of HTG states is also evolving. Previously, HTG was considered to be a dominant disorder associated with variation within a single gene. The old nomenclature includes the term "familial" in the names of several hyperlipoproteinemia (HLP) phenotypes that included HTG as part of their profile, including combined hyperlipidemia (HLP type 2B), dysbetalipoproteinemia (HLP type 3), simple HTG (HLP type 4) and mixed hyperlipidemia (HLP type 5). This old thinking has given way to the idea that genetic susceptibility to HTG results from cumulative effects of multiple genetic variants acting in concert. HTG most is often a "polygenic" or "multigenic" trait. However, a few rare autosomal recessive forms of severe HTG have been defined. Treatment depends on the overall clinical context, including severity of HTG, concomitant presence of other lipid disturbances, and the patient's global risk of cardiovascular disease. Therapeutic strategies include dietary counselling, lifestyle management, control of secondary factors, use of omega-3 preparations and selective use of pharmaceutical agents.

Glucosyl Hesperidin Lowers Serum Triglyceride Level in Hypertriglyceridemic Subjects through the Improvement of Very Low-Density Lipoprotein Metabolic Abnormality

To examine the serum triglyceride (TG)-lowering effect of a soluble hesperidin derivative, glucosyl hesperidin (G-hesperidin), and its mechanisms, we carried out a G-hesperidin administration test in hypertriglyceridemic subjects. G-Hesperidin was administered to the subjects at 500 mg/d for 24 wk. In this study, the subjects were classified into high-TG type (TG > 150 mg/dL), borderline-TG type (TG 110-150 mg/dL) and normal-TG type (TG < 110 mg/dL) on the basis of their initial serum TG values. Among these phenotypes, serum TG level significantly decreased in the high-TG type during the G-hesperidin administration period. It was also observed that elevated values of serum remnant-like particle cholesterol (RLP-C), apolipoprotein (apo) B, apo C-II, apo C-III and apo E occurred in the high-TG type and that these serum levels were significantly reduced by G-hesperidin administration. Moreover, polyacrylamide gel electrophoresis analysis of serum lipoproteins revealed that the very low-density lipoprotein (VLDL)/low-density lipoprotein (LDL) ratio and LDL migration index of the high-TG type were remarkably higher than those of the other phenotypes but that their high values were significantly reduced by the administration. These results indicate that G-hesperidin preferentially lowers serum TG in hypertriglyceridemic subjects and that this effect is possibly caused by the improvement of VLDL metabolic abnormality, leading to the reduction of small dense LDL.

Treatment options for hypertriglyceridemia: from risk reduction to pancreatitis

While there has been considerable focus on the role and treatment of LDL cholesterol levels, a definitive role of triglycerides in the management of cardiovascular disease has been uncertain. Notably, with increasing triglyceride levels, there is a parallel increase in cholesterol levels carried by triglyceride-rich lipoproteins, which has prompted interest in the use of non-HDL cholesterol levels as a tool guiding interventions. Recent studies have provided evidence for an independent role of triglyceride levels as a cardiovascular risk factor, and recently, an Endocrine Society guideline was published for treatment of hypertriglyceridemia. In contrast to the relative uncertainty regarding triglycerides and cardiovascular disease, a role of very high triglyceride levels as a risk factor for pancreatitis has been well known. The present paper summarizes the underlying evidence for a risk role for triglyceride levels in cardiovascular disease and pancreatitis, current treatment recommendations and areas of future research.

Uptake of type III hypertriglyceridemic VLDL by macrophages is enhanced by oxidation, especially after remnant formation

We previously showed that hypertriglyceridemic VLDL (HTG-VLDL, Sf 60 to 400) from subjects with type III (E2/E2) hyperlipoproteinemia do not induce appreciable cholesteryl ester (CE) accumulation in cultured macrophages (J774A.1). In the present study, we examined whether oxidation of type III HTG-VLDL would enhance their uptake by J774A.1 cells. Type III HTG-VLDL were oxidized as measured by both conjugated-diene formation and increased electrophoretic mobility on agarose gels. Both LDL and type III HTG-VLDL undergo oxidation, albeit under different kinetic parameters. From the conjugated-diene curve, type III HTG-VLDL, compared with LDL, were found to have a 6-fold longer lag time, to take 6-fold longer to reach maximal diene production, and to produce a 2-fold greater amount of dienes but at half the rate (all P < .005). Incubation of macrophages with either native type III HTG-VLDL or LDL (50 micrograms lipoprotein cholesterol/mL media for 16 hours) caused small increases (4-fold and 2.7-fold, respectively) in cellular CE levels relative to control cells (both P = .0001). After 24 hours of CuSO4 exposure, we found that oxidized type III HTG-VLDL and LDL caused a 9.4-fold and 10.5-fold increase, respectively, in cellular CE levels (P = .0001). We next examined whether extending the exposure period for type III HTG-VLDL to CuSO4 beyond 24 hours would further enhance its ability to induce macrophage CE accumulation. After 48 hours of CuSO4 exposure, type III HTG-VLDL and LDL caused 21.3-fold and 11.6-fold increases, respectively, in cellular CE levels (P = .0001). The cellular CE loading achieved with 48 hour-oxidized type III HTG-VLDL was significantly higher than either 24 hour-oxidized type III HTG-VLDL (2.3-fold, P = .003) or 48 hour-oxidized LDL (1.8-fold, P = .012). There was no significant difference between the CE loading achieved by incubation of cells with either 24 hour-oxidized type III HTG-VLDL, 24 hour-oxidized LDL, or 48 hour-oxidized LDL (P > or = .518). In this study, we also examined whether partial lipolysis (19% to 50% triglyceride hydrolysis) of type III HTG-VLDL to produce remnants would increase the susceptibility of the lipoprotein to oxidative modification and subsequent cellular CE loading. Forty-eight hour-oxidized type III VLDL-remnants stimulated CE accumulation 30.4-fold over baseline (P = .0001). In contrast, nonoxidized type III VLDL-remnants caused the same very low level of CE loading as did native type III HTG-VLDL (P = .680). The increase in cellular CE levels achieved with 48 hour-oxidized type III VLDL-remnants was significantly higher than that achieved with 48 hour-oxidized type III HTG-VLDL (P = .047). In conclusion, we have shown that oxidized type III HTG-VLDL will induce macrophage CE accumulation well above levels achieved with oxidized LDL. In addition, we also showed that by forming a VLDL-remnant before oxidative modification, we can further enhance macrophage CE accumulation. These results provide a potential mechanism for the atherogenicity of type III HTG-VLDL and their remnants.

Rare Variants in Triglycerides-Related Genes Increase Pancreatitis Risk in Multifactorial Chylomicronemia Syndrome

CONTEXT

Severe hypertriglyceridemia (fasting triglycerides [TG] concentration ≥10 mmol/L) can be caused by multifactorial chylomicronemia syndrome (MCS) or familial chylomicronemia syndrome (FCS). Both conditions are associated with an increased risk of acute pancreatitis. The clinical differences between MCS patients with or without a rare variant in TG-related genes have never been studied.

OBJECTIVE

To compare the clinical and biochemical characteristics of FCS, positive-MCS patients, and negative-MCS patients, as well as to investigate the predictors of acute pancreatitis in MCS patients.

METHODS

All patients referred at the clinic for severe hypertriglyceridemia underwent genetic testing for the 5 canonical genes involved in TG metabolism (LPL, APOC2, GPIHBP1, APOA5, and LMF1) using next-generation sequencing.

RESULTS

A total of 53 variant negative-MCS, 22 variant positive-MCS and 28 FCS subjects were included in this retrospective cross-sectional study. A significant difference was observed in the prevalence of pancreatitis (9%, 41%, and 61%) and multiple pancreatitis (6%, 23%, and 46%) in the negative-MCS, the positive-MCS, and the FCS groups, respectively (P < 0.0001). Predictors of pancreatitis among MCS subjects included the presence of a rare variant, lower apolipoprotein B, as well as higher gamma-glutamyl transferase, maximal TG value, and fructose consumption.

CONCLUSION

We observed that the MCS individuals who carried a rare variant have an intermediate phenotype between FCS and negative-MCS subjects. Since novel molecules such as the antisense oligonucleotide against APOC3 mRNA showed high efficacy in reducing TG levels in patients with multifactorial chylomicronemia, identification of higher-risk MCS patients who would benefit from additional treatment is essential.

Effects of omega-3 fatty acids in hypertriglyceridemic states

In the experimental studies reported in this review, dietary omega-3 fatty acids from fish and fish oil had profound hypolipidemic effects in normal subjects and in hypertriglyceridemic patients with combined hyperlipidemia (type IIb) and type V hyperlipidemia. In these studies, 68 adults participated in carefully controlled metabolic experiments. In all subjects and patients, there were marked reductions in plasma cholesterol and triglyceride concentrations, with triglyceride lowering being especially great. There were also reductions in VLDL, chylomicrons, remnants, LDL, apo B, and apo E. The HDL changes were inconstant and varied from subject to subject. Whereas the mechanism of the hypolipidemic action of the omega-6-rich vegetable oils containing linoleic acid, such as corn or safflower oil, still remains obscure, the mechanism of action of the omega-3 fatty acids in fish oil has been well documented within a few years of their use as hypolipidemic agents. The synthesis of triglyceride and VLDL in the liver is greatly reduced by omega-3 fatty acids. At the same time, the turnover of VLDL in plasma is greatly shortened. LDL production is decreased. Combined with other dietary manipulations, such as a reduction in saturated fat and dietary cholesterol, the use of omega-3 fatty acids to treat hyperlipidemic and especially hypertriglyceridemic patients would appear to have a well-supported rationale. Further studies are required to delineate exact doses and precise indications for different types of hyperlipidemia and to differentiate the effects of, if any, the two major omega-3 fatty acids in fish oil, EPA and DHA. Coupled with the known antithrombotic actions of omega-3 fatty acids from fish oil because of changes in prostaglandin secretion and platelet function, these hypolipidemic effects would appear to have an important potential role in the control of coronary heart disease and other atherosclerotic disorders.

Risk factors for coronary artery disease: a study comparing hypercholesterolaemia and hypertriglyceridaemia in angiographically characterized patients

Fifty-two male patients undergoing coronary angiography were allocated to four groups each consisting of 13 subjects: group I had normal coronary arteries and patients in groups II-IV exhibited coronary artery disease. In group II, plasma cholesterol was below 250 mg dl-1 and triglycerides below 160 mg dl-1; in group III, cholesterol was above 270 mg dl-1 and triglycerides under 160 mg dl-1; and in group IV, cholesterol was under 270 mg dl-1 and triglycerides above 180 mg dl-1. The hypertriglyceridaemic group IV had the highest coronary score. In addition, it had lowest lipoprotein lipase activity, lowest HDL-cholesterol and lowest high-density lipoproteins-2 (HDL-2) levels, suggesting that this type of hypertriglyceridaemia is caused--at least in part--by lipoprotein lipase deficiency with impaired removal of the triglyceride-rich lipoproteins and increased catabolism of HDL-2. Our findings point towards a type of hypertriglyceridaemia strongly associated with coronary artery disease which should therefore be treated accordingly.

Acarbose is an effective adjunct to dietary therapy in the treatment of hypertriglyceridaemias

AIMS

In diabetics, acarbose causes a reduction of blood glucose and triglyceride levels. The aim of this study was to assess the effect of this drug in non diabetic subjects with hypertriglyceridaemia.

METHODS

Thirty non diabetic patients with hypertriglyceridaemia type IIb or IV (24 males, six females; mean age 51.1+/-10.2 years) were studied. They were stratified into two groups depending on their basal triglyceride concentration (group A: triglyceride values </=4.5 mmol l-1; group B triglyceride values >4.5 mmol l-1 ). Treatment consisted of 4 week courses of diet plus acarbose (50 mg twice daily) alternating with 4 weeks of diet alone for a total period of 16 weeks.

RESULTS

Mean triglyceride values decreased significantly during the first and third cycles of therapy, i.e. diet plus acarbose treatment cycles in both patient groups. Group A also had significant reductions in total cholesterol and HDL cholesterol concentrations after completion of the acarbose treatment. Reduction of triglyceride levels was observed after both acarbose courses in patients affected by hypertriglyceridaemia type IIb. A marked reduction of triglyceride concentrations was achieved by patients affected by hypertriglyceridaemia type IV after the second acarbose course only.

CONCLUSIONS

Diet alone did not reduce triglyceride concentrations to normal values in our patients. The data suggest that acarbose is a useful adjunct to dietary control in non-diabetic patients affected by severe hypertriglyceridaemia.

Practical definitions of severe versus familial hypercholesterolaemia and hypertriglyceridaemia for adult clinical practice

Diagnostic scoring systems for familial hypercholesterolaemia and familial chylomicronaemia syndrome often cannot differentiate between adults who have extreme dyslipidaemia based on a simple monogenic cause versus people with a more complex cause involving polygenic factors and an environmental component. This more complex group of patients carries a substantial risk of atherosclerotic cardiovascular disease in the case of marked hypercholesterolaemia and pancreatitis in the case of marked hypertriglyceridaemia. Complications are mainly a function of the degree of disturbance in lipid metabolism resulting in elevated lipid levels, so the added value of knowing the precise genetic cause in clinical decision making is unclear and does not lead to clinically meaningful benefit. We propose that for severe elevations of plasma low density lipoprotein cholesterol or triglyceride, the primary factor driving intervention should be the biochemical perturbation rather than the clinical risk score. This underscores the importance of expanding the definition of severe dyslipidaemias and to not rely solely on clinical scoring systems to identify individuals who would benefit from appropriate treatment approaches. We advocate for the use of simple, practical, clinical, and largely biochemically based definitions for severe hypercholesterolaemia (eg, LDL cholesterol >5 mmol/L) and severe hypertriglyceridaemia (triglyceride >10 mmol/L), which complement current definitions of familial hypercholesterolaemia and familial chylomicronaemia syndrome. Irrespective of the precise genetic cause, individuals diagnosed with severe hypercholesterolaemia and severe hypertriglyceridaemia require intensive therapy, including special consideration for new effective but more expensive therapies.

Does hypertriglyceridemia increase risk for CAD? Growing evidence suggests it plays a role

High triglyceride levels are associated with several risk factors that substantially increase the risk of CAD. The metabolic syndrome is a constellation of signs and symptoms (e.g., postprandial hypertriglyceridemia, low LDL cholesterol levels, insulin resistance) that has been linked to a high incidence of heart disease. Treatment of hypertriglyceridemia begins with an aggressive lifestyle modification program. Dietary restriction of alcohol and carbohydrates can significantly lower triglyceride levels in many patients. Pharmacotherapy should be considered for patients at high risk of cardiac disease.

Apolipoprotein E allele frequencies in non-insulin-dependent diabetes mellitus with hypertriglyceridemia (type IIb, III, IV, and V hyperlipoproteinemia)

We examined apolipoprotein E (apo E) allele frequencies in non-insulin-dependent diabetes mellitus (NIDDM) patients with normolipidemia or various types of hypertriglyceridemia to elucidate the association of the apo E alleles with hypertriglyceridemia in NIDDM. NIDDM patients with normolipidemia (N = 134) or hypertriglyceridemia [type IIb hyperlipoproteinemia (HLP) (N = 42), III HLP (N = 7), IV HLP (N = 96), and V HLP (N = 8)] were randomly selected from our Diabetic Clinics. Apo E phenotypes (genotypes) were determined by our rapid flat-gel isoelectric focusing method. The frequency of the epsilon 4 allele was significantly higher in the type IIb (20.2%, P less than .01) and V (25.0%, P less than .05) HLP patients than in the normolipidemic patients (8.9%), whereas the frequency of the epsilon 3 allele was significantly (P less than .025) lower in the type IIb HLP patients (78.6%) than in the normolipidemic patients (89.2%). The frequency of the epsilon 2 allele was significantly higher in the type III (64.3%, P less than .001) and IV (5.2%, P less than .05) HLP patients than in the normolipidemic patients (1.9%), whereas the frequency of the epsilon 3 allele was significantly lower in the type III (28.6%, P less than .001) and IV (82.8%, P less than .05) HLP patients than in the normolipidemic patients. Thus, it has proven that the epsilon 2 allele is related to type III and IV HLP in NIDDM, whereas the epsilon 4 allele is related to type IIb and V HLP in NIDDM.(ABSTRACT TRUNCATED AT 250 WORDS)

Primary Hypertriglyceridemia: A Look Back on the Clinical Classification and Genetics of the Disease

INTRODUCTION

Hypertriglyceridemia (HTG) is one of the most common metabolic disorders leading to pancreatitis and cardiovascular disease. HTG develops mostly due to impaired metabolism of triglyceride-rich lipoproteins. Although monogenic types of HTG exist, most reported cases are polygenic in nature.

AIM

This review article is focused on the classification of Primary HTG and the genetic factors behind its development with the aim of providing clinicians a useful tool for early detection of the disease in order to administer proper and effective treatment.

DISCUSSION

HTG is often characterized by a complex phenotype resulting from interactions between genetic and environmental factors. In many instances, the complexity, perplexing causes, and classification of HTG make it difficult for clinicians to properly diagnose and manage the disorder. Better availability of information on its pathophysiology, genetic factors involved, environmental causes, and their interactions could help in understanding such complex disorders and could support its effective diagnosis and treatment.

CONCLUSION

The current review has summarized the case definition, epidemiology, pathophysiology, clinical presentation, classification, associated genetic factors, and scope of genetic screening in the diagnosis of primary HTG.

Treatment of hypertriglyceridemia

Hypertriglyceridemia is a disorder commonly encountered in clinical practice. Treatment of this condition aims to prevent the major complications of hypertriglyceridemia, which differ depending on whether triglyceride elevations are moderate or severe. This review discusses the pathophysiology and clinical consequences of hypertriglyceridemia and outlines treatment approaches based on the degree of triglyceride elevation. Special consideration is given to clinical trials using medications that primarily target triglycerides.

Estimating low-density lipoprotein cholesterol by the Friedewald equation is adequate for classifying patients on the basis of nationally recommended cutpoints

We compared low-density lipoprotein cholesterol (LDL) values obtained by the Friedewald formula--i.e., total cholesterol minus high-density lipoprotein (HDL) cholesterol minus very-low-density lipoprotein (VLDL) cholesterol (estimated as triglyceride divided by 5)--with those obtained by lipoprotein fractionation, using 4736 specimens. When triglycerides were less than 2.0 g/L, greater than 90% of estimated LDL cholesterol values were acceptable, within +/- 10% of measured values. At triglyceride concentrations of 2.0-4.0 g/L and 4.0-6.0 g/L, only 72% and 39%, respectively, of the estimates were acceptable. LDL values derived from an alternative formula, estimating VLDL as triglycerides divided by 6, were even less accurate. Nevertheless, the use of estimated LDL for risk classification based on the National Cholesterol Education Program Adult Treatment Panel cutpoints of 1.30 and 1.60 g/L was considered acceptable. At triglyceride concentrations less than or equal to 5.0 g/L, 88% of classifications based on estimated LDL (using triglycerides divided by 5) were concordant with those by measured LDL. Eleven percent of classifications were shifted across one cutpoint, evenly distributed between high and low. Fewer than 1% of classifications, all with Type III hyperlipoproteinemia, were misclassified two cutpoints high. Refinements in the estimation model did not substantially improve LDL estimation or concordance of risk classification.

Effect of triiodothyronine on triglyceride synthesis in human fibroblasts in different types of hypertriglyceridemia

Fibroblasts from 12 normotriglyceridemic subjects and 30 hypertriglyceridemic patients and family members were used to investigate triglyceride synthesis and the influence of triiodothyronine on it. The monolayers were incubated for 72 hours with and without the thyroid hormone, followed by incorporation studies of radiolabeled acetic acid or palmitic acid into the cellular triglyceride fraction. Triiodothyronine had no influence on triglyceride synthesis of normal cell lines and of cells derived from patients with secondary hypertriglyceridemia, whereas fibroblasts from endogenous type IV patients showed higher rates of triglyceride synthesis under identical conditions. Values for type IV were in the range of 134% to 466% of the hormone-free control incubations. In cultures derived from patients with familial combined hyperlipidemia, no stimulation by triiodothyronine was observed: values were in the range of 64% to 144% of the hormone-free controls. Three out of four lines with type V gave "normal" values and are supposed to represent secondary hypertriglyceridemia, whereas one line may express endogenous type IV. The evidence obtained in vitro with cultured cells indicates different metabolic defects in endogenous type IV and familial combined hyperlipidemia; it also shows the biochemically heterogenous nature of the disease "hypertriglyceridemia."