LeAnne T. Bloedon

Efficacy and safety of a microsomal triglyceride transfer protein inhibitor in patients with homozygous familial hypercholesterolaemia: a single-arm, open-label, phase 3 study

BACKGROUND Patients with homozygous familial hypercholesterolaemia respond inadequately to existing drugs. We aimed to assess the efficacy and safety of the microsomal triglyceride transfer protein inhibitor lomitapide in adults with this disease. METHODS We did a single-arm, open-label, phase 3 study of lomitapide for treatment of patients with homozygous familial hypercholesterolemia. Current lipid lowering therapy was maintained from 6 weeks before baseline through to at least week 26. Lomitapide dose was escalated on the basis of safety and tolerability from 5 mg to a maximum of 60 mg a day. The primary endpoint was mean percent change in levels of LDL cholesterol from baseline to week 26, after which patients remained on lomitapide through to week 78 for safety assessment. Percent change from baseline to week 26 was assessed with a mixed linear model. FINDINGS 29 men and women with homozygous familial hypercholesterolaemia, aged 18 years or older, were recruited from 11 centres in four countries (USA, Canada, South Africa, and Italy). 23 of 29 enrolled patients completed both the efficacy phase (26 weeks) and the full study (78 weeks). The median dose of lomitapide was 40 mg a day. LDL cholesterol was reduced by 50% (95% CI -62 to -39) from baseline (mean 8·7 mmol/L [SD 2·9]) to week 26 (4·3 mmol/L [2·5]; p<0·0001). Levels of LDL cholesterol were lower than 2·6 mmol/L in eight patients at 26 weeks. Concentrations of LDL cholesterol remained reduced by 44% (95% CI -57 to -31; p<0·0001) at week 56 and 38% (-52 to -24; p<0·0001) at week 78. Gastrointestinal symptoms were the most common adverse event. Four patients had aminotransaminase levels of more than five times the upper limit of normal, which resolved after dose reduction or temporary interruption of lomitapide. No patient permanently discontinued treatment because of liver abnormalities. INTERPRETATION Our study suggests that treatment with lomitapide could be a valuable drug in the management of homozygous familial hypercholesterolaemia. FUNDING FDA Office of the Orphan Product Development, Aegerion Pharmaceuticals.

Inhibition of microsomal triglyceride transfer protein alone or with ezetimibe in patients with moderate hypercholesterolemia

Background Many patients with coronary heart disease do not achieve recommended LDL-cholesterol levels, due to either intolerance or inadequate response to available lipid-lowering therapy. Microsomal triglyceride transfer protein (MTP) inhibitors might provide an alternative way to lower LDL-cholesterol levels. We tested the safety and LDL-cholesterol-lowering efficacy of an MTP inhibitor, AEGR-733 (Aegerion Pharmaceuticals Inc., Bridgewater, NJ), alone and in combination with ezetimibe.Methods We performed a multicenter, double-blind, 12-week trial, which included 84 patients with hypercholesterolemia. Patients were randomly assigned ezetimibe 10 mg daily (n = 29); AEGR-733 5.0 mg daily for the first 4 weeks, 7.5 mg daily for the second 4 weeks and 10 mg daily for the last 4 weeks (n = 28); or ezetimibe 10 mg daily and AEGR-733 administered with the dose titration described above (n = 28).Results Ezetimibe monotherapy led to a 20–22% decrease in LDL-cholesterol concentrations. AEGR-733 monotherapy led to a dose-dependent decrease in LDL-cholesterol concentration: 19% at 5.0 mg, 26% at 7.5 mg and 30% at 10 mg. Combined therapy produced similar but larger dose-dependent decreases (35%, 38% and 46%, respectively). The number of patients who discontinued study drugs owing to adverse events was five with ezetimibe alone, nine with AEGR-733 alone, and four with combined ezetimibe and AEGR-733. Discontinuations from AEGR-733 were due primarily to mild transaminase elevations.Conclusions Inhibition of LDL production with low-dose AEGR-733, either alone or in combination with ezetimibe, could be an effective therapeutic option for patients unable to reach target LDL-cholesterol levels.

Flaxseed and Cardiovascular Risk Factors: Results from a Double Blind, Randomized, Controlled Clinical Trial

Objective: Flaxseed is a rich source of alpha linolenic acid (ALA), fiber and lignans, making it a potentially attractive functional food for modulating cardiovascular risk. We studied the effects of flaxseed on markers of cardiovascular risk in hypercholesterolemic adults. Methods: Sixty-two men and post-menopausal women with pre-study low density lipoprotein cholesterol (LDL-C) between 130 and 200 mg/dl were randomized to 40g/day of ground flaxseed-containing baked products or matching wheat bran products for 10 weeks while following a low fat, low cholesterol diet. Fasting lipoproteins, measures of insulin resistance, inflammation, oxidative stress, and safety were assessed at 0, 5 and 10 weeks. Results: Flaxseed was well-tolerated, and increased serum levels of ALA (p < 0.001). Compared to wheat, flaxseed significantly reduced LDL-C at 5 weeks (−13%, p < 0.005), but not at 10 weeks (−7%, p = 0.07). Flaxseed reduced lipoprotein a (Lp[a]) by a net of 14% (p = 0.02), and reduced the homeostatic model assessment of insulin resistance (HOMA-IR) index by 23.7% (p = 0.03) compared to wheat at 10 weeks, but did not affect markers of inflammation (IL-6, Hs-CRP) or oxidative stress (ox LDL, urinary isoprostanes) at any time points. In men, flaxseed reduced HDL-C concentrations by a net of 16% (p = 0.03) and 9% (p = 0.05) at 5 and 10 weeks, respectively. Conclusions: Ground flaxseed has a modest but short lived LDL-C lowering effect, yet reduces Lp(a) and improves insulin sensitivity in hyperlipidemic adults. The HDL-C lowering effect of flaxseed in men warrants additional study.

Effects of Pioglitazone on Lipoproteins, Inflammatory Markers, and Adipokines in Nondiabetic Patients with Metabolic Syndrome

Objective—The purpose of this research was to evaluate the short-term effects of pioglitazone (PIO) on high-density lipoprotein cholesterol (HDL-C) and other metabolic parameters in nondiabetic patients with metabolic syndrome (MetSyn). Methods and Results—Sixty nondiabetic adults with low HDL-C and MetSyn were randomized to PIO or matching placebo for 12 weeks. PIO increased HDL-C by 15% and 14% at 6 and 12 weeks, respectively, compared with placebo (P<0.001). Changes in HDL-C were correlated to changes in adiponectin (r=0.34; P=0.01) but not to changes in insulin resistance. PIO did not affect serum triglycerides or low-density lipoprotein (LDL) cholesterol concentrations but reduced the number of small LDL particles by 18% (P<0.001). PIO reduced median C-reactive protein levels by 31% (P<0.001) and mean resistin levels by 10% (P=0.02) while increasing mean serum levels of adiponectin by 111% (P<0.001) compared with placebo. PIO did not affect weight and modestly decreased insulin resistance. Conclusions—In nondiabetic patients with low HDL-C and MetSyn, PIO significantly raised HDL-C and favorably affected lipoprotein particle size, markers of inflammation, and adipokines without changes in triglycerides, LDL-C, or weight. These results suggest that PIO has direct effects on HDL, which may contribute to its antiatherogenic effects.

Effects of Rosiglitazone on Lipids, Adipokines, and Inflammatory Markers in Nondiabetic Patients With Low High-Density Lipoprotein Cholesterol and Metabolic Syndrome

Background—PPAR-γ agonists improve insulin sensitivity and glycemic control in type 2 diabetes and may reduce atherosclerosis progression. Thus, PPAR-γ agonists may be an effective therapy for metabolic syndrome. However, the full spectrum of potentially antiatherogenic mechanisms of PPAR-γ agonists have not been fully tested in nondiabetic patients with metabolic syndrome. Methods and Results—We performed a prospective, double-blinded, placebo-controlled study of 60 nondiabetic subjects with low high-density lipoprotein cholesterol (HDL-C) level and metabolic syndrome to rosiglitazone 8 mg daily or placebo for 12 weeks. We found no significant effect of rosiglitazone on HDL-C (+5.5% versus +5.8%, P=0.89), and an increase in total cholesterol (+8% versus −1%; P=0.03). Nevertheless, rosiglitazone significantly increased adiponectin (+168% versus +25%; P<0.001), and lowered resistin (−6% versus +4%; P=0.009), C-reactive protein (−32% versus +36%, P=0.002), interleukin (IL)-6 (−22% versus +4%, P<0.001), and soluble tumor-necrosis factor-α receptor-2 (−5% versus +7%, P<0.001). Conclusions—These findings suggest that rosiglitazone, presumably through its PPAR-γ agonist properties, has direct effects on inflammatory markers and adipokines in the absence of favorable lipid effects. These findings may help explain the mechanism underlying the possible antiatherosclerotic effects of rosiglitazone.

Flaxseed Reduces Plasma Cholesterol Levels in Hypercholesterolemic Mouse Models

Objective: We examined the effects of whole ground flaxseed added to a Western diet on plasma and hepatic lipids and hepatic gene expression in male and female human apolipoprotein B-100 transgenic (hApoBtg) mice which have a plasma lipid profile more closely resembling man than wild type mice and in mice lacking the low density lipoprotein receptor (LDLr) and apolipoprotein B mRNA editing enzyme complex 1 (LDLr−/−/apobec−/−). Methods: The Westernized control diet containing 0.1% cholesterol and 30% kcal as fat was fed for 10 days to hApoBtg mice and for 14 days to LDLr−/−/apobec−/− mice. Animals from each genetic background were then divided into 2 groups based on gender and mean plasma total cholesterol (TC). The hApoBtg and LDLr−/−/apobec−/− mice either continued on the control diet for a total of 31 and 35 days, respectively or were fed 20% w/w whole ground flaxseed (flax) with comparable caloric, macronutrient and fiber content for 21 days. Blood was obtained after a 4 hour fast from all mice prior to feeding both control and flax diets, after 10 days on the flax diet, and after 21 days on the flax at which time all mice were exsanguinated. Results: The control diet increased TC by >100 mg/dl in the hApoBtg with a greater increase observed in males and by 800 mg/dl in mice lacking the LDLr. After 3 weeks, the flax diet significantly reduced plasma TC by 19% and 22% in hApoBtg and LDLr−/−/apobec−/−, respectively and non-high density lipoprotein cholesterol (non-HDL-C) by 24% in both models (p for all <0.05). Flax significantly reduced hepatic cholesterol in hApoBtg by 32% and 47% in males and females, respectively and LDLr−/−/apobec−/− mice by 66%. Flax had no effect on the expression of the following hepatic genes: LDLr, 3-hydroxy-3-methylglutaryl (HMG) CoA reductase, phospholipid transfer protein, cholesterol 7α hydroxylase, fatty acid synthase, and acyl CoA oxidase in either mouse model. Conclusions: Flaxseed reduces plasma and hepatic cholesterol in hApoBtg mice, but had no effect on hepatic lipogenic genes and was equally effective in mice lacking LDLr. The combined data suggest that the lipid lowering effect of flax is not hepatic mediated and may be at the level of cholesterol absorption and/or bile acid reabsorption.

Potent and Selective PPAR-α Agonist LY518674 Upregulates Both ApoA-I Production and Catabolism in Human Subjects With the Metabolic Syndrome

Objective—The study of PPAR-α activation on apoA-I production in humans has been limited to fibrates, relatively weak PPAR-α agonists that may have other molecular effects. We sought to determine the effect of a potent and highly specific PPAR-α agonist, LY518674, on apoA-I, apoA-II, and apoB-100 kinetics in humans with metabolic syndrome and low levels of HDL cholesterol (C). Methods and Results—Subjects were randomized to receive LY518674 (100 &mgr;g) once daily (n=13) or placebo (n=15) for 8 weeks. Subjects underwent a kinetic study using a deuterated leucine tracer to measure apolipoprotein production and fractional catabolic rates (FCR) at baseline and after treatment. LY518674 significantly reduced VLDL-C (−38%, P=0.002) and triglyceride (−23%, P=0.002) levels whereas LDL-C and HDL-C levels were unchanged. LY518674 significantly reduced VLDL apoB-100 (−12%, P=0.01) levels, attributable to an increased VLDL apoB-100 FCR with no change in VLDL apoB-100 production. IDL and LDL apoB-100 kinetics were unchanged. LY518674 significantly increased the apoA-I production rate by 31% (P<0.0001), but this was accompanied by a 33% increase in the apoA-I FCR (P=0.002), resulting in no change in plasma apoA-I. There was a 71% increase in the apoA-II production rate (P<0.0001) accompanied by a 25% increase in the FCR (P<0.0001), resulting in a significant increase in plasma apoA-II. Conclusions—Activation of PPAR-α with LY518674 (100 &mgr;g) in subjects with metabolic syndrome and low HDL-C increased the VLDL apoB-100 FCR consistent with enhanced lipolysis of plasma triglyceride. Significant increases in the apoA-I and apoA-II production rates were accompanied by increased FCRs resulting in no change in HDL-C levels. These data indicate a major effect of LY518674 on the production and clearance of apoA-I and HDL despite no change in the plasma concentration. The effect of these changes on reverse cholesterol transport remains to be determined.

Pharmacokinetic Interactions of the Microsomal Triglyceride Transfer Protein Inhibitor, Lomitapide, with Drugs Commonly Used in the Management of Hypercholesterolemia

To characterize the effects of two doses (10 and 60 mg) of lomitapide—a microsomal triglyceride transfer protein inhibitor approved as adjunct treatment to lower low‐density lipoprotein cholesterol levels in patients with homozygous familial hypercholesterolemia—on the pharmacokinetics of several lipid‐lowering therapies: atorvastatin, simvastatin, rosuvastatin, fenofibrate, ezetimibe, and niacin.

Long-Term Efficacy and Safety of the Microsomal Triglyceride Transfer Protein Inhibitor Lomitapide in Patients With Homozygous Familial Hypercholesterolemia

Homozygous familial hypercholesterolemia is a genetic disorder characterized by low-density lipoprotein (LDL)-receptor dysfunction, markedly elevated levels of LDL-cholesterol (LDL-C) and premature atherosclerosis. Patients are often poorly responsive to conventional lipid-lowering therapies that upregulate LDL-receptor expression.1 Lomitapide inhibits microsomal triglyceride transfer protein, which lipidates nascent apolipoprotein (apo)B-containing lipoproteins. In a pivotal 78-week open-label trial, lomitapide, titrated to the maximal tolerable dose, decreased LDL-C by 50% at the end of the efficacy phase (week 26) in patients with homozygous familial hypercholesterolemia.2 The principal adverse events included gastrointestinal disturbances, hepatic enzyme elevations, and increased liver fat. Here we provide additional long-term efficacy and safety data, including an exploratory analysis of the potential metabolic consequences of hepatic fat accumulation from an extension trial (NCT00943306). Patients continued on lomitapide at the maximally tolerated dose until transition to commercial or compassionate lomitapide. Lipid-lowering therapies, including apheresis, could be modified at the investigator’s discretion if LDL-C was <100 mg/dL. Both studies received institutional review board and regulatory approval, and all participants provided informed consent. Significance of the percent changes from baseline was assessed using a mixed linear model; correlations were assessed with Pearson correlation. Nineteen (mean age, 30.4 years; 10 male/9 female) of the 23 patients who completed the pivotal trial enrolled in the extension trial, and 17 completed week 126 (78 weeks pivotal + 48 weeks extension) assessments (primary efficacy end point). Three patients discontinued prematurely (relocation, elevated transaminases and excess alcohol, sudden cardiac death). The median lomitapide dose remained mostly consistent at 40 mg (range, 20–60 mg) from week 36 in the pivotal study to week 282 in the extension trial. Overall, the median treatment duration with lomitapide across both trials was 5.1 years (range, 2.1–5.7 years). Among the 17 patients who completed week 126, LDL-C decreased from 356±127 mg/dL at baseline to …

Effect of rosiglitazone on HDL metabolism in subjects with metabolic syndrome and low HDL.

Treatment with the peroxisome proliferator-activated receptor γ agonist rosiglitazone has been reported to increase HDL-cholesterol (HDL-C) levels, although the mechanism responsible for this is unknown. We sought to determine the effect of rosiglitazone on HDL apolipoprotein A-I (apoA-I) and apoA-II metabolism in subjects with metabolic syndrome and low HDL-C. Subjects were treated with placebo followed by rosiglitazone (8 mg) once daily. At the end of each 8 week treatment, subjects (n = 15) underwent a kinetic study to measure apoA-I and apoA-II production rate (PR) and fractional catabolic rate. Rosiglitazone significantly reduced fasting insulin and high-sensitivity C-reactive protein (hsCRP) and increased apoA-II levels. Mean apoA-I and HDL-C levels were unchanged following rosiglitazone treatment, although there was considerable individual variability in the HDL-C response. Rosiglitazone had no effect on apoA-I metabolism, whereas the apoA-II PR was increased by 23%. The change in HDL-C in response to rosiglitazone was significantly correlated with the change in apoA-II concentration but not to changes in apoA-I, measures of glucose homeostasis, or hsCRP. Treatment with rosiglitazone significantly increased apoA-II production in subjects with metabolic syndrome and low HDL-C but had no effect on apoA-I metabolism. The change in HDL-C in response to rosiglitazone treatment was unrelated to effects on apoA-I, instead being related to the change in the metabolism of apoA-II.