Source: Health Products Regulatory Authority (ZA) Revision Year: 2018 Publisher: Macleods Pharmaceuticals SA (Pty) Ltd, Office block 1, Bassonia Estate Office Park (East), 1 Cussonia Drive, Bassonia Rock, Ext.12, Alberton, South Africa
Category A: 20.2.8 Antimicrobial (Chemotherapeutic) Medicines. Antiviral Medicines.
Lamivudine, a nucleoside reverse transcriptase inhibitor (NRTI), is a selective inhibitor of HIV-1 and HIV-2 replication in vitro.
Lamivudine is metabolised intracellularly to the 5'-triphosphate which has an intracellular half-life of 16-19 hours. Lamivudine 5'-triphosphate is a weak inhibitor of the RNA and DNA dependent activities of HIV reverse transcriptase; its mode of action is a chain terminator of HIV reverse transcription.
Reduced in vitro sensitivity to lamivudine has been reported for HIV isolates from patients who have received lamivudine therapy. Lamivudine-resistant HIV-1 mutants are cross-resistant to didanosine and zalcitabine. In some patients treated with zidovudine plus didanosine or zalcitabine, isolates resistant to multiple reverse transcriptase inhibitors, including lamivudine, have emerged.
Lamivudine does not interfere with cellular deoxynucleotide metabolism and has little effect on mammalian cell and mitochondrial DNA content.
Tenofovir disoproxil fumarate is an acyclic nucleoside phosphonate diester analogue of adenosine monophosphate and is converted in vivo to tenofovir. It is a nucleoside reverse transcriptase inhibitor. Tenofovir is phosphorylated by cellular enzymes to form tenofovir diphosphate. Tenofovir diphosphate inhibits the activity of HIV-1 reverse transcriptase, by competing with the natural substrate deoxyadenosine 5'-triphosphate and, after incorporation in DNA, by chain termination. Tenofovir diphosphate is a weak inhibitor of mammalian DNA polymerases α,β and mitochondrial DNA polymerase Y.
HIV-1 isolates with reduced susceptibility to tenofovir have been selected in vitro and a K65R mutation in reverse transcriptase have been selected in vitro and in some patients treated with tenofovir in combination with certain antiretroviral medicines. In treatment naive patients treated with tenofovir + lamivudine + efavirenz, viral isolates from 17% patients with virologic failure showed reduced susceptibility to tenofovir.
In treatment-experienced patients, some of the tenofovir-treated patients with virologic failure through week 96 showed reduced susceptibility to tenofovir. Genotypic analysis of the resistant isolates showed a mutation in the HIV-1 reverse transcriptase gene resulting in the K65R amino acid substitution.
Cross-resistance among certain reverse transcriptase inhibitors has been recognised.
The K65R mutation can also be selected by abacavir, didanosine or zalcitabine and results in reduced susceptibility to these medicines plus lamivudine, emtricitabine and tenofovir. Tenofovir disoproxil fumarate should be avoided in antiretroviral experienced patients with strains harbouring the K65R mutation. Patients with HIV-1 expressing three or more thymidine analogue associated mutations (TAMs) that included either the M41L or L210W reverse transcriptase mutation showed reduced susceptibility to tenofovir disoproxil fumarate.
The in vitro antiviral activity of tenofovir against laboratory and clinical isolates of HIV-1 has been assessed in Iymphoblastoid cell lines, primary monocyte/macrophage cells and peripheral blood lymphocytes. The IC50, (50% inhibitory concentration) values for tenofovir were in the range of 0,04 μM to 8,5 μM. In medicine combination studies of tenofovir with nucleoside reverse transcriptase inhibitors (abacavir, didanosine, lamivudine, stavudine, zalcitabine, zidovudine), non-nucleoside reverse transcriptase inhibitors (delavirdine, efavirenz, nevirapine), and protease inhibitors (amprenavir, indinavir, nelfinavir, ritonavir, saquinavir), additive to synergistic effects were observed. Tenofovir displayed antiviral activity in vitro against HIV-1 clades A, B, C, D, E, F, G, and O (IC values ranged from 0,5 μM to 2,2 μM). The IC50 values of tenofovir against HIV- 2 ranged from 1,6 μM to 4,9 μM.
Paediatrics and the elderly
Pharmacokinetic studies have not been performed in children (<18 years) or in the elderly (>65 years).
Tenofovir pharmacokinetics after a 300 mg single dose have been studied in non-HIV infected patients with moderate to severe hepatic impairment There were no substantial alterations in tenofovir pharmacokinetics in patients with hepatic impairment compared with unimpaired patients. Change in tenofovir dosing is not required in patients with hepatic impairment.
Tenofovir pharmacokinetics are altered in patients with renal impairment. In patients with creatinine clearance <50 ml/min or with end-stage renal disease (ESRD) requiring dialysis, Cmax, and AUC0-∞ of tenofovir were increased. It is recommended that the dosing interval for tenofovir be modified in patients with creatinine clearance <50 ml/min or in patients with ESRD who require dialysis (see DOSAGE AND DIRECTIONS FOR USE). Tenofovir is efficiently removed by haemodialysis with an extraction coefficient of approximately 54%. Following a single 300 mg dose of tenofovir, a four-hour haemodialysis session removed approximately 10% of the administered tenofovir dose.
Dolutegravir inhibits HIV integrase by binding to the integrase active site and blocking the strand transfer step of retroviral Deoxyribonucleic acid (DNA) integration which is essential for the HIV replication cycle. In vitro, dolutegravir dissociates slowly from the active site of the wild-type integrase-DNA complex (t1/2 71 hours).
Isolation from wild type HIV-1: Viruses highly resistant to dolutegravir have not been observed during HIV-1 passage. During wild type HIV-1 passage in the presence of dolutegravir integrase substitutions observed were S153Y and S153F with FCs ≤4,1 for strain IIIB, or E92Q with FC = 3,1 and G193E with FC = 3,2 for strain NL432. Additional passage of wild- type subtype B, C, and A/G viruses in the presence of dolutegravir selected for R263K, G118R and S153T.
Anti-HIV Activity Against Resistant Strains: Reverse Transcriptase Inhibitor- and Protease Inhibitor-Resistant Strains: Dolutegravir demonstrated equivalent potency against 2 non-nucleoside (NN)-RTI-resistant, 3 nucleoside (N)-RTI-resistant and 2 PI-resistant HIV-1 mutant clones (1 triple and 1 sextuple) compared to the wild type strain.
lntegrase Inhibitor-Resistant HIV-1 Strains: Dolutegravir showed anti-HIV activity (susceptibility) with FC <5 against 27 of 28 integrase inhibitor-resistant mutant viruses with single substitutions including T66A/I/K, E92Q/V, Y143C/H/R, Q148H/K/R, and N155H.
lntegrase lnhibitor-Resistant HIV-2 Strains: Site directed mutant HIV-2 viruses were constructed based on subjects infected with HIV-2 and treated with raltegravir who showed virologic failure. Overall the HIV-2 FCs observed were similar to HIV-1 FCs observed for similar pathway mutations.
Resistance in vivo: integrase inhibitor naïve patients: No integrase inhibitor (lNI) resistant mutations or treatment emergent resistance to the NRTI backbone therapy were isolated with dolutegravir 50 mg once daily in treatment – naïve studies.
Effects on Renal Function: The effect of dolutegravir on serum creatinine clearance (CrCI), glomerular filtration rate (GFR) using iohexol as the probe and effective renal plasma flow (ERPF) using para-aminohippurate (PAH) as the probe was evaluated. A small decrease of 10-14% in mean serum creatinine clearance (CrCI) was observed with dolutegravir within the first week of treatment. Dolutegravir had no significant effect on glomerular filtration rate (GFR) or the effective renal plasma flow (ERPF). In vitro studies suggest that the increases in creatinine observed in clinical studies are due to the non-pathologic inhibition of the organic cation transporter 2 (OCT2) in the proximal renal tubules, which mediates the tubular secretion of creatinine.
The pharmacokinetics of dolutegravir in 10 antiretroviral treatment-experienced HIV-1 infected adolescents (12 to <18 years of age) showed that dolutegravir 50 mg once daily dosage resulted in dolutegravir exposure comparable to that observed in adults who received dolutegravir 50 mg once daily.
Table 1. Adolescent pharmacokinetic parameters:
| Age/Weight | Dolutegravir Dose | Dolutegravir Pharmacokinetic Parameters Estimates Geometric Mean (CV %) | ||
|---|---|---|---|---|
| AUC(0-24) μg.hr/ml | Cmax μg/ml | C24 μg/ml | ||
| 12 <18 years ≥40 kga | 50 mg once daily | 46 (43) | 3,49 (38) | 0,90 (59) |
a one subject weighing 37 kg received 35 mg once daily.
Population pharmacokinetic analysis of dolutegravir using data in HIV-1 infected adults showed that there was no clinically relevant effect of age on dolutegravir exposure. Pharmacokinetic data for dolutegravir in subjects of > 65 years old are limited.
Renal clearance of unchanged medicine is a minor pathway of elimination for dolutegravir. A study of the pharmacokinetics of dolutegravir was performed in subjects with severe renal impairment (CLcr <30 ml/min). No clinically important pharmacokinetic differences between subjects with severe renal impairment (CLcr <30 ml/min) and matching healthy subjects were observed, AUC, Cmax and C24 of dolutegravir were decreased by 40%, 23%, and 43%, respectively, compared with those in matched healthy subjects. No dosage adjustment is necessary for patients with renal impairment. Dolutegravir has not been studied in patients on dialysis, though differences in exposure are not expected.
Dolutegravir is primarily metabolised and eliminated by the liver. In a study comparing 8 subjects with moderate hepatic impairment (Child-Pugh category B score 7 to 9) to 8 matched healthy adult controls, the single 50 mg dose exposure of dolutegravir was similar between the two groups. No dosage adjustment is necessary for patients with mild hepatic impairment. The effect of severe hepatic impairment on the pharmacokinetics of dolutegravir has not been studied.
There is no evidence that common polymorphisms in metabolising enzymes alter dolutegravir pharmacokinetics to a clinically meaningful extent. In a meta-analysis using pharmacogenomics samples collected in clinical studies in healthy subjects, subjects with UGT1A1 (n=7) genotypes conferring poor dolutegravir metabolism had a 32% lower clearance of dolutegravir and 46% higher AUC compared with subjects with genotypes associated with normal metabolism via UGT1A1 (n=41). Polymorphisms in CYP3A4, CYP3A5, and NR1/2 were not associated with differences in the pharmacokinetics of dolutegravir.
Population pharmacokinetic analysis indicated that hepatitis C virus co-infection had no clinically relevant effect on the exposure to dolutegravir. There are limited data on subjects with hepatitis B co-infection.
Pharmacokinetics in adults:
Lamivudine is well absorbed from the gastrointestinal tract, and the bioavailability of oral lamivudine in adults is normally between 80% and 85%. Following oral administration of KOVATRAX TABLETS in healthy volunteers under fasting conditions, lamivudine was absorbed with median Tmax of 1,33 hours, Cmax 2,499 μg/ml (range 1,416-4,085 μg/ml), AUC 12,7833 μg*hr/ml (range 7,2402-20,7702 μg*hr/ml) and AUC0-t 13,1391 μg*hr/ml (range 7,5587-21,3589 μg*hr/ml ).
When co-administered with food, lamivudine bioavailability is not altered, although a delay in Tmax and reduction in Cmax have been observed.
From intravenous studies, the mean volume of distribution is 1,3 L/kg. Lamivudine exhibits linear pharmacokinetics over the therapeutic dose range and displays limited binding to the major plasma protein albumin.
Limited data shows lamivudine penetrates the central nervous system and reaches the cerebrospinal fluid (CSF). The true extent of penetration or relationship with any clinical efficacy is unknown.
The mean systemic clearance of lamivudine is approximately 0,32 L/kg/h, with predominantly renal clearance (>70%) via active tubular secretion, but little (<10%) hepatic metabolism. T½ of lamivudine in KOVATRAX TABLETS was approximately 3,6 hours and the elimination rateconstant Ke was found to be 0,1190-0,2837 h-1
Lamivudine is principally eliminated by the kidney. Lamivudine elimination will be affected by renal impairment, whether it is disease or age-related. KOVATRAX TABLETS is a combination product and the dose of the individual components cannot be altered. KOVATRAX TABLETS is not recommended for patients with creatinine clearance <50 ml/min or patients who require haemodialysis (see WARNINGS AND SPECIAL PRECAUTIONS).
The pharmacokinetics of tenofovir disoproxil fumarate have been evaluated in healthy volunteers and HIV-1 infected individuals. Tenofovir pharmacokinetics are similar between these populations.
Tenofovir disoproxil fumarate is a water soluble diester prodrug of the active ingredient tenofovir. The oral bioavailability of tenofovir from tenofovir disoproxil fumarate in fasted patients is approximately 25%. Following oral administration of KOVATRAX TABLETS to healthy volunteers in the fasted state, tenofovir was absorbed with median Tmax of 1,17 hours, Cmax 0,304 μg/ml (range 0,120-0,463 μg/ml), AUC0-t 2,3739 μg*hr/ml (range 1,3691-3,8855 μg*hr/ml ) and AUC0-t 2,5943 μg*hr/ml (range 1,5178-4,1238 μg*hr/ml).
The pharmacokinetics of tenofovir are dose proportional over a dose range of 75 to 600 mg and are not affected by repeated dosing.
Administration of tenofovir disoproxil fumarate following a high-fat meal (~700 to 1000 kcal containing 40 to 50% fat) increases the oral bioavailability, with an increase in tenofovir AUC0-∞ of approximatelym 40% and an increase in Cmax of approximately 14%. However, administration of tenofovir with a light meal does not have a significant effect on the pharmacokinetics of tenofovir when compared to fasted administration of tenofovir. Food delays the time to tenofovir Cmax by approximately 1 hour.
In vitro binding of tenofovir to human plasma or serum proteins is less than 0,7% and 7,2%, respectively, over the tenofovir concentration range 0,01 to 25 μg/ml. The volume of distribution at steady-state is 1,3 ± 0,6 L/kg and 1,2 ± 0,4 L/kg, following intravenous administration of tenofovir 1,0 mg/kg and 3,0 mg/kg.
In vitro studies indicate that neither tenofovir disoproxil nor tenofovir are substrates of CYP450 enzymes.
Following IV administration of tenofovir, approximately 70-80% of the dose is recovered in the urine as unchanged tenofovir within 72 hours of dosing. Following oral administration of KOVATRAX TABLETS, the terminal elimination half-life of tenofovir was approximately 17,4 hours. The elimination rate constant Ke was found to be 0,0231-0,0628 h-1
Tenofovir is eliminated by a combination of glomerular filtration and active tubular secretion. There may be competition for elimination with other compounds that are also renally eliminated.
The linearity of dolutegravir pharmacokinetics is dependent on dose and formulation. Following oral administration of tablet formulations, dolutegravir exhibited non linear pharmacokinetics with less than dose-proportional increases in plasma exposure from 2 to 100 mg; however increase in dolutegravir exposure appears dose proportional from 25 mg to 50 mg.
After oral administration of KOVATRAX TABLETS under fasting conditions, dolutegravir was absorbed with median Tmax of 2,67 hours, Cmax 2,736 μg/ml (range 1,666-4,995 μg/ml), AUC0-t 54,9036 μg*hr/ml (range 30,7975-94,0202 μg*hr/ml) and AUC0-∞ 58,0582 μg*hr/ml (range 31,6266-98,15200 μg*hr/ml).
Dolutegravir may be administered with or without food. Food increases the extent and slowed the rate of absorption of dolutegravir. Bioavailability of dolutegravir depends on meal content: low, moderate and high fat meals increased dolutegravir AUC0-∞ by 34%, 41% and 66%, increased Cmax by 46%, 52% and 67%, prolonged Tmax to 3, 4, and 5 hours from 2 hours under fasted conditions, respectively.max These increases are not clinically significant.
The absolute bioavailability of dolutegravir has not been established.
Dolutegravir is highly bound (approximately 99,3%) to human plasma proteins. The apparent volume of distribution (following oral administration of suspension formulation, Vd/F) is estimated at 12,5 L. Binding of dolutegravir to plasma proteins was independent of concentration. Total blood and plasma drug-related radioactivity concentration ratios averaged between 0,441 to 0,535 indicating minimal association of radioactivity with blood cellular components. Free fraction of dolutegravir in plasma is estimated at approximately 0,2 to 1,1% in healthy subjects, approximately 0,4 to 0,5% in subjects with moderate hepatic impairment, and 0,8 to 1,0% in subjects with severe renal impairment and 0,5% in HIV-1 infected patients. Dolutegravir is present in cerebrospinal fluid (CSF).
Dolutegravir is primarily metabolised via UGT1A1 with a minor CYP3A component (9,7% of total dose administered in a human mass balance study). Dolutegravir is the predominant circulating compound in plasma; renal elimination of unchanged medicine is low (<1% of the dose). Fifty-three percent of total oral dose is excreted unchanged in the faeces. It is unknown if all or part of this is due to unabsorbed medicine or biliary excretion of the glucuronidate conjugate, which can be further degraded to form the parent compound in the gut lumen. Thirty-one percent of the total oral dose is excreted in the urine, represented by ether glucuronide of dolutegravir (18,9% of total dose), N- dealkylation metabolite (3,6% of total dose) and a metabolite formed by oxidation at the benzylic carbon (3,0% of total dose).
Dolutegravir has a terminal half-life of 15,2 hours (range 10,9229-19,0807 hours). The elimination rate constant K was found to be 0,0363-0,0635 h-1.
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