ROSUFEN Fenofibrate / Rosuvastatin Calcium 160mg / 10mg Film-Coated Tablet 1's

Rosuvastatin: There is no specific treatment in the event of overdose. In the event of overdose, the patient should be treated symptomatically and supportive measures instituted as required. Liver function and CPK levels should be monitored. Hemodialysis is unlikely to be of benefit.
Fenofibrate: No case of overdosage has been reported. No specific antidote is known. If an overdose is suspected, treat symptomatically and institute appropriate supportive measures as required. Fenofibrate cannot be eliminated by hemodialysis.

Pregnancy: Since statins decrease cholesterol synthesis and possibly the synthesis of other biologically active substances derived from cholesterol, they may cause fetal harm when administered to the pregnant woman. Rosuvastatin and Fenofibrate combination is therefore contraindicated during pregnancy. Rosuvastatin and Fenofibrate combination should be administered to women of childbearing age only when such patients are highly unlikely to conceive and have been informed of the potential hazards. If the patient becomes pregnant while taking this drug, therapy should be discontinued and the patient appraised of the potential hazard to the fetus.
Lactation: Rosuvastatin and Fenofibrate combination is contraindicated in nursing mothers. Because of the potential for adverse reactions in nursing infants, women taking Rosuvastatin and Fenofibrate combination should not breast-feed.

Store at temperatures not exceeding 30°C. Protect from light and moisture.

Pharmacology: Pharmacodynamics: Rosuvastatin: Rosuvastatin is a selective and competitive inhibitor of HMG-CoA reductase, the rate-limiting enzyme that converts 3-hydroxy-3-methylglutaryl coenzyme A to mevalonate, a precursor of cholesterol. Studies have shown Rosuvastatin to have a high uptake into, and selectivity for, action in the liver, the target organ for cholesterol lowering. Rosuvastatin produces its lipid-modifying effects in two ways. First, it increases the number of hepatic Low Density Lipoprotein (LDL) receptors on the cell-surface to enhance uptake and catabolism of LDL. Second, it inhibits hepatic synthesis of Very Low Density Lipoprotein (VLDL), which reduces the total number of VLDL and LDL particles. Rosuvastatin reduces total cholesterol (total-C), Low Density Lipoprotein-Cholesterol (LDL-C), Apoprotein-B (Apo-B), and non-High Density Lipoprotein-Cholesterol (non-HDL-C) (total cholesterol minus High Density Lipoprotein-Cholesterol (HDL-C)). Rosuvastatin also reduces Triglyceride (TG) and produces increases in HDL-C. Rosuvastatin reduces total-C, LDL-C, Very Low Density Lipoprotein-Cholesterol (VLDL-C), Apo-B, non-HDL-C and TG, and increases HDL-C in patients with isolated hypertriglyceridemia.
Fenofibrate: Fenofibrate is a lipid-regulating agent. Fenofibric acid, the active metabolite of fenofibrate, produces reductions in total-C, LDL-C, apo-B, total triglycerides and VLDL in treated patients. In addition, treatment with fenofibrate results in increases in HDL-C and apoproteins apo-AI and apo-AII. The effects of fenofibric acid seen in clinical practice have been explained by the activation of peroxisome proliferator activated receptor (alpha) [PPAR (alpha)]. Through this mechanism, Fenofibrate increases lipolysis and elimination of triglyceride-rich particles from plasma by activating lipoprotein lipase and reducing production of apoprotein C-III (an inhibitor of lipoprotein lipase activity). The resulting fall in triglycerides produces an alteration in the size and composition of LDL from small, dense particles (which are thought to be atherogenic due to their susceptibility to oxidation), to large buoyant particles. These larger particles have a greater affinity for cholesterol receptors and are catabolized rapidly. Activation of PPAR (alpha) also induces an increase in the synthesis of apoproteins A-I, A-II and HDL-cholesterol. Fenofibrate also reduces serum uric acid levels in hyperuricemic and normal individuals by increasing the urinary excretion of uric acid.
Pharmacokinetics: Rosuvastatin: Absorption: In clinical pharmacology studies in man, peak plasma concentrations of Rosuvastatin were reached 3 to 5 hours following oral dosing. Both peak concentration (C_max) and area under the plasma concentration-time curve (AUC) increased in approximate proportion to Rosuvastatin dose. The absolute bioavailability of Rosuvastatin is approximately 20%. Administration of Rosuvastatin with food decreased the rate of drug absorption by 20% as assessed by C_max, but there was no effect on the extent of absorption as assessed by AUC. Plasma concentrations of Rosuvastatin do not differ following evening or morning drug administration. Significant LDL-C reductions are seen when Rosuvastatin is given with or without food, and regardless of the time of day of drug administration.
Distribution: Mean volume of distribution at steady state of Rosuvastatin is approximately 134 liters. Rosuvastatin is 88% bound to plasma proteins, mostly albumin. This binding is reversible and independent of plasma concentrations.
Metabolism: Rosuvastatin is not extensively metabolized; approximately 10% of a radio labeled dose is recovered as metabolite. The major metabolite is N-desmethyl Rosuvastatin, which is formed principally by cytochrome P450 2C9, and in vitro studies have demonstrated that N-desmethyl Rosuvastatin has approximately one-sixth to one-half the HMG-CoA reductase inhibitory activity of Rosuvastatin. Overall, greater than 90% of active plasma HMG-CoA reductase inhibitory activity is accounted for by Rosuvastatin.
Excretion: Following oral administration, Rosuvastatin and its metabolites are primarily excreted in the feces (90%). The elimination half-life (t_1/2) of Rosuvastatin is approximately 19 hours.
Renal Insufficiency: Plasma concentrations of Rosuvastatin increased to a clinically significant extent (about 3-fold) in patients with severe renal impairment (ClCr <30 mL/min/1.73m2) compared with healthy subjects (ClCr >80 mL/min/1.73m2).
Hemodialysis: Steady-state plasma concentrations of Rosuvastatin in patients on chronic hemodialysis were approximately 50% greater compared with healthy volunteer subjects with normal renal function.
Hepatic insufficiency: In patients with chronic alcohol liver disease, plasma concentrations of Rosuvastatin were modestly increased. In patients with Child-Pugh A disease, C_max and AUC were increased by 60% and 5%, respectively, as compared with patients with normal liver function. In patients with Child-Pugh B disease, Cmax and AUC were increased 100% and 21%, respectively, compared with patients with normal liver function.
Fenofibrate: Absorption: The absolute bioavailability of Fenofibrate cannot be determined as the compound is virtually insoluble in aqueous media suitable for injection. However, Fenofibrate is well absorbed from the gastrointestinal tract. Following oral administration in healthy volunteers, approximately 60% of a single dose of radiolabelled Fenofibrate appeared in urine, primarily as Fenofibric acid and its glucuronate conjugate, and 25% was excreted in the feces. Peak plasma levels of fenofibric acid occur within 6 to 8 hours after administration. The bioavailability of Fenofibrate is optimized when taken with meals.
Distribution: Upon multiple dosing of Fenofibrate, fenofibric acid steady state is achieved within 9 days. Plasma concentrations of fenofibric acid at steady state are approximately double those following a single dose. Serum protein binding was approximately 99% in normal and hyperlipidemic subjects.
Metabolism: Fenofibrate is a minor substrate of CYP3A4 isoenzymes and weakly inhibits CYP1A6, CYP2C9 and CYP2C19 activity. Following oral administration, Fenofibrate is rapidly hydrolyzed by esterases to the active metabolite, fenofibric acid; no unchanged fenofibrate is detected in plasma. Fenofibric acid is primarily conjugated with glucuronic acid and then excreted in urine. A small amount of fenofibric acid is reduced at the carbonyl moiety to a benzhydrol metabolite which is, in turn, conjugated with glucuronic acid and excreted in urine.
Excretion: After absorption, Fenofibrate is mainly excreted in the urine in the form of metabolites, primarily fenofibric acid and fenofibric acid glucuronide. After administration of radiolabelled Fenofibrate, approximately 60% of the dose appeared in the urine and 25% was excreted in the feces. Fenofibric acid is eliminated with a half-life of 20 hours, allowing once daily administration in a clinical setting.
Elderly: In elderly volunteers 77-87 years of age, the oral clearance of fenofibric acid following a single oral dose of Fenofibrate was 1.2 L/h, which compares to 1.1 L/h in young adults. This indicates that a similar dosage regimen can be used in the elderly, without increasing accumulation of the drug or metabolites.
Children: Fenofibrate has not been investigated in adequate and well-controlled trials in children.
Renal Impairment: The pharmacokinetics of fenofibric acid was examined in patients with mild, moderate, and severe renal impairment. Patients with severe renal impairment (creatinine clearance [CrCl] ≤30 mL/min) showed 2.7-fold increase in exposure for fenofibric acid and increased accumulation of fenofibric acid during chronic dosing compared to that of healthy subjects. Patients with mild to moderate renal impairment (CrCl 30-80 mL/min) had similar exposure but an increase in the half-life for fenofibric acid compared to that of healthy subjects. Based on these findings, the use of Fenofibrate should be avoided in patients who have severe renal impairment and dose reduction is required in patients having mild to moderate renal impairment.
Hepatic Insufficiency: No pharmacokinetic studies have been conducted in patients having hepatic insufficiency.