CELSENTRI, in combination with other antiretroviral medicinal products, is indicated for treatment-experienced adults infected with only CCR5-tropic HIV-1 detectable (see sections 4.2 and 5.1).

Therapy should be initiated by a physician experienced in the management of HIV infection.

Posology

Before taking CELSENTRI it has to be confirmed that only CCR5-tropic HIV-1 is detectable (i.e. CXCR4 or dual/mixed tropic virus not detected) using an adequately validated and sensitive detection method on a newly drawn blood sample. The Monogram Trofile assay was used in the clinical studies of CELSENTRI (see sections 4.4 and 5.1). The viral tropism cannot be safely predicted by treatment history and assessment of stored samples.

There are currently no data regarding the reuse of CELSENTRI in patients that currently have only CCR5-tropic HIV-1 detectable, but have a history of failure on CELSENTRI (or other CCR5 antagonists) with a CXCR4 or dual/mixed tropic virus. There are no data regarding the switch from a medicinal product of a different antiretroviral class to CELSENTRI in virologically suppressed patients. Alternative treatment options should be considered.  

Adults:

The recommended dose of CELSENTRI is 150 mg, (with potent CYP3A inhibitor with or without a potent CYP3A inducer), 300 mg (without potent CYP3A inhibitors or inducers) or 600 mg twice daily (with potent CYP3A inducer without a potent CYP3A inhibitor) depending on interactions with concomitant antiretroviral therapy and other medicinal products (see  section 4.5).

The recommended dose of CELSENTRI differs depending on interactions with concomitant antiretroviral therapy and other medicinal products. Refer to section 4.5 for corresponding adult dosage.

Many medicines have profound effects on maraviroc exposure due to drug-drug interactions. Prior to deciding the dose of CELSENTRI by weight, please refer to Table 2 in section 4.5 to carefully determine the corresponding adult dose. The corresponding paediatric dose can then be obtained from Table 1 below. If uncertainty still exists, contact a pharmacist for advice.

Table 1 Recommended dosing regimen

* Based on drug-drug Interactions (refer to section 4.5)

Special populations

Elderly

There is limited experience in patients >65 years of age (see section 5.2), therefore CELSENTRI should be used with caution in this population.

Renal impairment

In adult patients with a creatinine clearance of <80 mL/min, who are also receiving potent CYP3A4 inhibitors, the dose interval of maraviroc should be adjusted to 150 mg once daily (see sections 4.4 and 4.5). 

Examples of agents/regimens with such potent CYP3A4-inhibiting activity are:

·       ritonavir-boosted protease inhibitors (with the exception of tipranavir/ritonavir),

·       cobicistat,

·       itraconazole, voriconazole, clarithromycin and telithromycin,

·       telaprevir and boceprevir.

CELSENTRI should be used with caution in adult patients with severe renal impairment

(CLcr <30 mL/min) who are receiving potent CYP3A4 inhibitors (see sections 4.4 and 5.2).

There are no data available to recommend a specific dose in paediatric patients with renal impairment. Therefore, CELSENTRI should be used with caution in this population.

Hepatic impairment

Limited data are available in adult patients with hepatic impairment, and no data are available to recommend a specific dose for paediatric patients.  Therefore, CELSENTRI should be used with caution in patients with hepatic impairment (see sections 4.4 and 5.2).

Method of administration

Oral use.

CELSENTRI can be taken with or without food.

Hepatic disease  

The safety and efficacy of maraviroc have not been specifically studied in patients with significant underlying liver disorders.

Cases of hepatotoxicity and hepatic failure with allergic features have been reported in association with maraviroc. In addition, an increase in hepatic adverse reactions with maraviroc was observed during studies of treatment-experienced subjects with HIV infection, although there was no overall increase in ACTG Grade 3/4 liver function test abnormalities (see section 4.8). Hepatobiliary disorders reported in treatment naïve patients were uncommon and balanced between treatment groups (see section 4.8). Patients with pre-existing liver dysfunction, including chronic active hepatitis, can have an increased frequency of liver function abnormalities during combination antiretroviral therapy and should be monitored according to standard practice.

Discontinuation of maraviroc should be strongly considered in any patient with signs or symptoms of acute hepatitis, in particular if drug-related hypersensitivity is suspected or with increased liver transaminases combined with rash or other systemic symptoms of potential hypersensitivity (e.g. pruritic rash, eosinophilia or elevated IgE).

There are limited data in patients with hepatitis B and/or C virus co-infection (see section 5.1). Caution should be exercised when treating these patients. In case of concomitant antiviral therapy for hepatitis B and/or C, please refer to the relevant product information for these medicinal products.

There is limited experience in patients with reduced hepatic function, therefore maraviroc should be used with caution in this population (see sections 4.2 and 5.2).

Severe skin and hypersensitivity reactions

Hypersensitivity reactions including severe and potentially life threatening events have been reported in patients taking CELSENTRI, in most cases concomitantly with other medicinal products associated with these reactions. These reactions included rash, fever, and sometimes organ dysfunction and hepatic failure. Discontinue CELSENTRI and other suspect agents immediately if signs or symptoms of severe skin or hypersensitivity reactions develop. Clinical status and relevant blood chemistry should be monitored and appropriate symptomatic therapy initiated.

Cardiovascular safety

Limited data exist with the use of maraviroc in patients with severe cardiovascular disease, therefore special caution should be exercised when treating these patients with maraviroc. In the pivotal studies of treatment experienced patients coronary heart disease events were more common in patients treated with maraviroc than with placebo (11 during 609 PY vs 0 during 111 PY of follow-up). In treatment naïve patients such events occurred at a similarly low rate with maraviroc and control (efavirenz).

Postural hypotension

When maraviroc was administered in studies with healthy volunteers at doses higher than the recommended dose, cases of symptomatic postural hypotension were seen at a greater frequency than with placebo. Caution should be used when administering maraviroc in patients on concomitant medicinal products known to lower blood pressure.  Maraviroc should also be used with caution in patients with severe renal insufficiency and in patients who have risk factors for, or have a history of postural hypotension.  Patients with cardiovascular co-morbidities could be at increased risk of cardiovascular adverse reactions triggered by postural hypotension.

Renal impairment

An increased risk of postural hypotension may occur in patients with severe renal insufficiency who are treated with potent CYP3A inhibitors or boosted protease inhibitors (PIs) and maraviroc. This risk is due to potential increases in maraviroc maximum concentrations when maraviroc is co-administered with potent CYP3A inhibitors or boosted PIs in these patients.

Immune reconstitution syndrome

In HIV infected patients with severe immune deficiency at the time of institution of combination antiretroviral therapy (CART), an inflammatory reaction to asymptomatic or residual opportunistic pathogens may arise and cause serious clinical conditions, or aggravation of symptoms. Typically, such reactions have been observed within the first few weeks or months of initiation of CART. Relevant examples are cytomegalovirus retinitis, generalised and/or focal mycobacterial infections, and pneumonia caused by Pneumocystis jiroveci (formerly known as Pneumocystis carinii). Any inflammatory symptoms should be evaluated and treatment initiated when necessary. Autoimmune disorders (such as Graves’ disease and autoimmune hepatitis) have also been reported to occur in the setting of immune reactivation; however, the reported time to onset is more variable and these events can occur many months after initiation of treatment.

Tropism

Maraviroc should only be used when only CCR5-tropic HIV-1 is detectable (i.e. CXCR4 or dual/mixed tropic virus not detected) as determined by an adequately validated and sensitive detection method (see sections 4.1, 4.2 and 5.1). The Monogram Trofile assay was used in the clinical studies of maraviroc. The viral tropism cannot be predicted by treatment history or assessment of stored samples.

Changes in viral tropism occur over time in HIV-1 infected patients. Therefore there is a need to start therapy shortly after a tropism test.

Background resistance to other classes of antiretrovirals have been shown to be similar in previously undetected CXCR4-tropic virus of the minor viral population, as that found in CCR5-tropic virus.

Maraviroc is not recommended to be used in treatment naïve patients based on the results of a clinical study in this population (see section 5.1).

Dose adjustment

Physicians should ensure that appropriate dose adjustment of maraviroc is made when maraviroc is co-administered with potent CYP3A4 inhibitors and/or inducers since maraviroc concentrations and its therapeutic effects may be affected (see sections 4.2 and 4.5). Please also refer to the respective Summary of Product Characteristics of the other antiretroviral medicinal products used in the combination.

Osteonecrosis

 Although the aetiology is considered to be multifactorial (including corticosteroid use, alcohol consumption, severe immunosuppression, higher body mass index), cases of osteonecrosis have been reported particularly in patients with advanced HIV-disease and/or long-term exposure to combination antiretroviral therapy (CART). Patients should be advised to seek medical advice if they experience joint aches and pain, joint stiffness or difficulty in movement.

Potential effect on immunity

CCR5 antagonists could potentially impair the immune response to certain infections. This should be taken into consideration when treating infections such as active tuberculosis and invasive fungal infections. The incidence of AIDS-defining infections was similar between CELSENTRI and placebo arms in the pivotal studies.

Excipients

CELSENTRI contains soya lecithin.

If a patient is hypersensitive to peanut or soya, CELSENTRI should not be used.

CELSENTRI contains less than 1 mmol sodium (23 mg) per tablet, that is to say essentially ‘sodium free’.

Maraviroc is metabolised by cytochrome P450 CYP3A4 and CYP3A5. Co-administration of maraviroc with medicinal products that induce CYP3A4 may decrease maraviroc concentrations and reduce its therapeutic effects. Co-administration of maraviroc with medicinal products that inhibit CYP3A4 may increase maraviroc plasma concentrations. Dose adjustment of maraviroc is recommended when maraviroc is co-administered with potent CYP3A4 inhibitors and/or inducers. Further details for concomitantly administered medicinal products are provided below (see Table 2). 

Maraviroc is a substrate for the transporters P-glycoprotein and OATP1B1, but the effect of these transporters on the exposure to maraviroc is not known.

Based on the in vitro and clinical data, the potential for maraviroc to affect the pharmacokinetics of co‑administered medicinal products is low.  In vitro studies have shown that maraviroc does not inhibit any of the major P450 enzymes at clinically relevant concentrations (CYP1A2, CYP2B6, CYP2C8, CYP2C9, CYP2C19, CYP2D6 and CYP3A4). Maraviroc had no clinically relevant effect on the pharmacokinetics of midazolam, the oral contraceptives ethinylestradiol and levonorgestrel, or urinary 6β-hydroxycortisol/cortisol ratio, suggesting no inhibition or induction of CYP3A4 in vivo. At higher exposure of maraviroc a potential inhibition of CYP2D6 cannot be excluded.

Renal clearance accounts for approximately 23% of total clearance of maraviroc when maraviroc is administered without CYP3A4 inhibitors. In vitro studies have shown that maraviroc does not inhibit OATP1B1, MRP2 or any of the major renal uptake transporters at clinically relevant concentrations (OAT1, OAT3, OCT2, OCTN1, and OCTN2). Additionally, co-administration of maraviroc with tenofovir (substrate for renal elimination) and cotrimoxazole (contains trimethoprim, a renal cation transport inhibitor), showed no effect on the pharmacokinetics of maraviroc. In addition, co-administration of maraviroc with lamivudine/zidovudine showed no effect of maraviroc on lamivudine (primarily renally cleared) or zidovudine (non-P450 metabolism and renal clearance) pharmacokinetics. Maraviroc inhibits P-glycoprotein in vitro (IC₅₀ is 183 μM). However, maraviroc does not significantly affect the pharmacokinetics of digoxin in vivo. It may not be excluded that maraviroc can increase the exposure to the P-glycoprotein substrate dabigatran etexilate.

Table 2. Interactions and adult^a dose recommendations with other medicinal products

^a Refer to Table 1 for maraviroc paediatric dosing recommendations when co-administered with antiretroviral therapy and other medicinal products.

Pregnancy

There are limited data from the use of maraviroc in pregnant women. The effect of maraviroc on human pregnancy is unknown. Studies in animals showed reproductive toxicity at high exposures. Primary pharmacological activity (CCR5 receptor affinity) was limited in the species studied (see section 5.3). Maraviroc should be used during pregnancy only if the excepted benefit justifies the potential risk to the foetus.

Breast-feeding

It is unknown whether maraviroc is excreted in human milk. Available toxicological data in animals has shown extensive excretion of maraviroc in milk. Primary pharmacological activity (CCR5 receptor affinity) was limited in the species studied (see section 5.3).  A risk to the newborn/infants cannot be excluded. 

It is recommended that women living with HIV do not breast-feed their infants in order to avoid transmission of HIV.

Fertility

There is no data on the effects of maraviroc on human fertility. In rats, there were no adverse effects on male or female fertility (see section 5.3).

Maraviroc may have a minor influence on the ability to drive and use machines. Patients should be informed that dizziness has been reported during treatment with maraviroc. The clinical status of the patient and the adverse reaction profile of maraviroc should be borne in mind when considering the patient's ability to drive, cycle or operate machinery.

Summary of the safety profile

Adults

Assessment of treatment related adverse reactions is based on pooled data from two Phase 2b/3 studies in treatment experienced adult patients (MOTIVATE 1 and MOTIVATE 2) and one study in treatment naïve adult patients (MERIT) infected with CCR5-tropic HIV-1 (see sections 4.4 and 5.1).

The most frequently reported adverse reactions occurring in the Phase 2b/3 studies were nausea, diarrhoea, fatigue and headache. These adverse reactions were common (≥ 1/100 to < 1/10).

Tabulated list of adverse reactions

The adverse reactions are listed by system organ class (SOC) and frequency. Within each frequency grouping, undesirable effects are presented in order of decreasing seriousness. Frequencies are defined as very common (≥ 1/10), common (≥ 1/100 to < 1/10), uncommon (≥1/1000 to <1/100), rare (≥1/10,000 to <1/1,000) , not known (cannot be estimated from the available data). The adverse reactions and laboratory abnormalities presented below are not exposure adjusted.

Table 3: Adverse reactions observed in clinical trials or post-marketing

Description of selected adverse reactions

Delayed type hypersensitivity reactions, typically occurring within 2-6 weeks after start of therapy and including rash, fever, eosinophilia and liver reactions have been reported (see also section 4.4). Skin and liver reactions can occur as single events, or in combination.

In HIV infected patients with severe immune deficiency at the time of initiation of combination antiretroviral therapy (CART), an inflammatory reaction to asymptomatic or residual opportunistic infections may arise. Autoimmune disorders (such as Graves’ disease and autoimmune hepatitis) have also been reported; however, the reported time to onset is more variable and these events can occur many months after initiation of treatment (see section 4.4).

Cases of osteonecrosis have been reported, particularly in patients with generally acknowledged risk factors, advanced HIV disease or long-term exposure to combination antiretroviral therapy (CART). The frequency of this is unknown (see section 4.4).

Cases of syncope caused by postural hypotension have been reported.

Laboratory abnormalities

Table 4 shows the incidence ≥1% of Grade 3-4 Abnormalities (ACTG Criteria) based on the maximum shift in laboratory test values without regard to baseline values.

Table 4: Incidence ≥1% of grade 3-4 abnormalities (ACTG criteria) based on maximum shift in laboratory test values without regard to baseline studies MOTIVATE 1 and MOTIVATE 2 (pooled analysis, up to 48 weeks)

ULN: Upper Limit of Normal

OBT: Optimised Background Therapy

* Percentages based on total patients evaluated for each laboratory parameter

The MOTIVATE studies were extended beyond 96 weeks, with an observational phase extended to 5 years in order to assess the long term safety of maraviroc. The Long Term Safety/Selected Endpoints (LTS/SE) included death, AIDS-defining events, hepatic failure, Myocardial infarction/cardiac ischaemia, malignancies, rhabdomyolysis and other serious infectious events with maraviroc treatment.  The incidence of these selected endpoints for subjects on maraviroc in this observational phase was consistent with the incidence seen at earlier timepoints in the studies.

In treatment-naïve patients, the incidence of grade 3 and 4 laboratory abnormalities using ACTG criteria was similar among the maraviroc and efavirenz treatment groups.

Paediatric population

The adverse reaction profile in paediatric patients is based on 48 Week safety data from study A4001031 in which 103 HIV-1 infected, treatment-experienced patients aged 2 to 18 years received maraviroc twice-daily with optimised background therapy (OBT). Overall, the safety profile in paediatric patients was similar to that observed in adult clinical studies.

To report any side effect(s):

Kingdom of Saudi Arabia

-National Pharmacovigilance centre (NPC)

• Reporting hotline: 19999
• E-mail: npc.drug@sfda.gov.sa
• Website: https://ade.sfda.gov.sa

-GSK - Head Office, Jeddah

• Tel:  +966-12-6536666
• Mobile: +966-56-904-9882
• Email:  saudi.safety@gsk.com
• website: https://gskpro.com/en-sa/
• P.O. Box 55850, Jeddah 21544, Saudi Arabia

For any information about this medicinal product, please contact:

GSK - Head Office, Jeddah

• Tel:  +966-12-6536666
• Mobile: +966-56-904-9882
• Email: gcc.medinfo@gsk.com
• Website: https://gskpro.com/en-sa/

• P.O. Box 55850, Jeddah 21544, Saudi Arabia

Symptoms

The highest dose administered in clinical studies was 1,200 mg. The dose limiting adverse reaction was postural hypotension.

Prolongation of the QT interval was seen in dogs and monkeys at plasma concentrations 6 and 12 times, respectively, those expected in humans at the maximum recommended dose of 300 mg twice daily. However, no clinically significant QT prolongation compared to placebo + OBT  was seen in the Phase 3 clinical studies using the recommended dose of maraviroc or in a specific pharmacokinetic study to evaluate the potential of maraviroc  to prolong the QT interval.

Management

There is no specific antidote for overdose with maraviroc. Treatment of overdose should consist of general supportive measures including keeping the patient in a supine position, careful assessment of patient vital signs, blood pressure and ECG.

If indicated, elimination of unabsorbed active maraviroc should be achieved by emesis or gastric lavage. Administration of activated charcoal may also be used to aid in removal of unabsorbed active substance. Since maraviroc is moderately protein bound, dialysis may be beneficial in removal of this medicine. Further management should be as recommended by the national poisons centre, where available.

Pharmacotherapeutic group: Antivirals for systemic use, other antivirals, ATC code: J05AX09 

Mechanism of action

Maraviroc is a member of a therapeutic class called CCR5 antagonists. Maraviroc selectively binds to the human chemokine receptor CCR5, preventing CCR5-tropic HIV-1 from entering cells.

Antiviral activity in vitro

Maraviroc has no antiviral activity in vitro against viruses which can use CXCR4 as their entry co-receptor (dual-tropic or CXCR4-tropic viruses, collectively termed ‘CXCR4-using’ virus below). The serum adjusted EC90 value in 43 primary HIV-1 clinical isolates was 0.57 (0.06 – 10.7) ng/mL without significant changes between different subtypes tested.  The antiviral activity of maraviroc against HIV-2 has not been evaluated. For details please refer to the pharmacology section of the CELSENTRI European Public Assessment Report (EPAR) on the European Medicines Agency (EMA) website.

When used with other antiretroviral medicinal products in cell culture, the combination of maraviroc was not antagonistic with a range of NRTIs ,NNRTIs, PIs or the HIV fusion inhibitor enfuvirtide.

Virologic Escape

Virologic escape from maraviroc can occur via 2 routes: the emergence of pre-existing virus which can use CXCR4 as its entry co-receptor (CXCR4-using virus) or the selection of virus that continues to use exclusively drug-bound CCR5 (CCR5-tropic virus). 

In vitro:

HIV-1 variants with reduced susceptibility to maraviroc have been selected in vitro, following serial passage of two CCR5-tropic viruses (0 laboratory strains, 2 clinical isolates). The maraviroc-resistant viruses remained CCR5-tropic and there was no conversion from a CCR5-tropic virus to a CXCR4-using virus.

Phenotypic resistance:

Concentration response curves for the maraviroc-resistant viruses were characterized phenotypically by curves that did not reach 100% inhibition in assays using serial dilutions of maraviroc (<100% maximal percentage inhibition (MPI)). Traditional IC₅₀/IC₉₀ fold-change was not a useful parameter to measure phenotypic resistance, as those values were sometimes unchanged despite significantly reduced sensitivity.

Genotypic resistance:

Mutations were found to accumulate in the gp120 envelope glycoprotein  (the viral protein that binds to the CCR5 co-receptor). The position of these mutations was not consistent between different isolates. Hence, the relevance of these mutations to maraviroc susceptibility in other viruses is not known.

Cross-resistance in vitro: 

HIV-1 clinical isolates resistant to NRTIs, NNRTIs, PIs and enfuvirtide were all susceptible to maraviroc in cell culture. Maraviroc-resistant viruses that emerged in vitro remained sensitive to the fusion inhibitor enfuvirtide and the PI, saquinavir.

In vivo:

Treatment Experienced Adult Patients

In the pivotal studies (MOTIVATE 1 and MOTIVATE 2), 7.6% of patients had a change in tropism result from CCR5-tropic to CXCR4-tropic or dual/mixed-tropic between screening and baseline (a period of 4-6 weeks).  

Failure with CXCR4-using virus:

CXCR4-using virus was detected at failure in approximately 60% of subjects who failed treatment on maraviroc, as compared to 6% of subjects who experienced treatment failure in the placebo + OBT  arm. To investigate the likely origin of the on-treatment CXCR4-using virus, a detailed clonal analysis was conducted on virus from 20 representative subjects (16 subjects from the maraviroc arms and 4 subjects from the placebo + OBT  arm) in whom CXCR4-using virus was detected at treatment failure. This analysis indicated that CXCR4-using virus emerged from a pre-existing CXCR4-using reservoir not detected at baseline, rather than from mutation of CCR5-tropic virus present at baseline.  An analysis of tropism following failure of maraviroc therapy with CXCR4 -using virus in patients with CCR5 virus at baseline, demonstrated that the virus population reverted back to CCR5 tropism in 33 of 36 patients with more than 35 days of follow up. 

At the time of failure with CXCR4-using virus, the resistance pattern to other antiretrovirals appears similar to that of the CCR5-tropic population at baseline, based on available data. Hence, in the selection of a treatment regimen, it should be assumed that viruses forming part of the previously undetected CXCR4 -using population (i.e. minor viral population) harbours the same resistance pattern as the CCR5-tropic population.

Failure with CCR5-tropic virus:

Phenotypic resistance

In patients with CCR5-tropic virus at time of treatment failure with maraviroc, 22 out of 58 patients had virus with reduced sensitivity to maraviroc. In the remaining 36 patients, there was no evidence of virus with reduced sensitivity as identified by exploratory virology analyses on a representative group. The latter group had markers correlating to low compliance (low and variable drug levels and often a calculated high residual sensitivity score of the OBT). In patients failing therapy with CCCR5-tropic virus only, maraviroc might be considered still active if the MPI value is ≥95% (PhenoSense Entry assay). Residual activity in vivo for viruses with MPI-values <95% has not been determined.

Genotypic resistance

A relatively small number of individuals receiving maraviroc-containing therapy have failed with phenotypic resistance (i.e. the ability to use drug-bound CCR5 with MPI <95%).   To date, no signature mutation(s) have been identified.  The gp120 amino acid substitutions identified so far are context dependent and inherently unpredictable with regards to maraviroc susceptibility.

Treatment-Experienced Paediatric Patients

In the Week 48 analysis (N=103), non-CCR5 tropic-virus was detected in 5/23 (22%) subjects at virologic failure. One additional subject had CCR5 tropic-virus with reduced susceptibility to maraviroc at virologic failure, although this was not retained at the end of treatment.  Subjects with virologic failure generally appeared to have low compliance to both maraviroc and the background antiretroviral elements of their regimens. Overall, the mechanisms of resistance to maraviroc observed in this treatment-experienced paediatric population were similar to those observed in adult populations.

Clinical results

Studies in Treatment-Experienced Adult Patients Infected with CCR5-tropic Virus:

The clinical efficacy of maraviroc (in combination with other antiretroviral medicinal products) on plasma HIV RNA levels and CD4+ cell counts  have been investigated in two pivotal, randomized, double blind, multicentre studies (MOTIVATE 1 and MOTIVATE 2, n=1076 ) in patients infected with CCR5 tropic HIV-1 as determined by the Monogram Trofile Assay.

Patients who were eligible for these studies had prior exposure to at least 3 antiretroviral medicinal product classes [≥1 NRTIs, ≥1 NNRTIs, ≥2 PIs, and/or enfurvirtide] or documented resistance to at least one member of each class. Patients were randomised in a 2:2:1 ratio to maraviroc 300 mg (dose equivalence) once daily, twice daily or placebo in combination with an optimized background consisting of 3 to 6 antiretroviral medicinal products (excluding low-dose ritonavir). The OBT was selected on the basis of the subject’s prior treatment history and baseline genotypic and phenotypic viral resistance measurements.

Table 5:  Demographic and baseline characteristics of patients  (pooled studies MOTIVATE 1 and MOTIVATE 2)

¹Based on GeneSeq resistance assay

Limited numbers of patients from ethnicities other than Caucasian were included in the pivotal clinical studies, therefore very limited data are available in these patient populations.

The mean increase in CD4+ cell count from baseline in patients who failed with a change in tropism result to dual/mixed tropic or CXCR4, in the maraviroc 300 mg twice daily + OBT (+56 cells/mm³) group was greater than that seen in patients failing placebo + OBT  (+13.8 cells/mm³) regardless of tropism.

Table 6. Efficacy Outcomes at week 48 (pooled studies MOTIVATE 1 and MOTIVATE 2)

¹ p-values < 0.0001

² For all efficacy endpoints the confidence intervals were 95%, except for HIV-1 RNA Change from baseline which was 97.5%

In a retrospective analysis of the MOTIVATE studies with a more sensitive assay for screening of tropism (Trofile ES), the response rates (<50 copies/mL at week 48) in patients with only CCR5-tropic virus detected at baseline was 48.2% in those treated with maraviroc + OBT (n=328), and 16.3% in those treated with placebo + OBT (n=178).

Maraviroc 300 mg twice daily + OBT was superior to placebo + OBT across all subgroups of patients analysed (see Table 7). Patients with very low CD4+ count at baseline (i.e. <50 cells/ µL) had a less favourable outcome. This subgroup had a high degree of bad prognostic markers, i.e. extensive resistance and high baseline viral loads. However, a significant treatment benefit for maraviroc compared to placebo + OBT was still demonstrated (see Table 7).

Table 7: Proportion of patients achieving <50 copies/mL at Week 48 by subgroup (pooled Studies MOTIVATE 1 and MOTIVATE 2)

¹Based on GSS.

Studies in Treatment-Experienced Adult Patients Infected with Non-CCR5-tropic Virus

Study A4001029 was an exploratory study in patients infected with dual/mixed or CXCR4 tropic  HIV-1 with a similar design as the studies MOTIVATE 1 and MOTIVATE 2. Use of maraviroc was not associated with a significant decrease in HIV 1 RNA compared with placebo in these subjects and no adverse effect on CD4+ cell count was noted.

Studies in Treatment‑Naïve Adult Patients Infected with CCR5-tropic Virus

A randomised, double-blinded study (MERIT) explored maraviroc versus efavirenz, both in combination with zidovudine/lamivudine (n=721, 1:1). After 48 weeks of treatment, maraviroc did not reach non-inferiority to efavirenz for the endpoint of HIV-1 RNA < 50 copies/mL (65.3 vs. 69.3 % respectively, lower confidence bound -11.9%). More patients treated with maraviroc discontinued due to lack of efficacy (43 vs.15) and among patients with lack of efficacy, the proportion acquiring NRTI resistance (mainly lamivudine) was higher in the maraviroc arm. Fewer patients discontinued maraviroc due to adverse events (15 vs. 49).

Studies in Adult Patients Co-infected with Hepatitis B and/or Hepatitis C virus 

The hepatic safety of maraviroc in combination with other antiretroviral agents in CCR5-tropic HIV-1-infected subjects with HIV RNA <50 copies/mL, co-infected with Hepatitis C and/or Hepatitis B Virus was evaluated in a multicentre, randomized, double blinded, placebo-controlled  study. 70 subjects (Child-Pugh Class A, n=64; Child-Pugh Class B, n=6) were randomized to the maraviroc group and 67 subjects (Child-Pugh Class A, n=59; Child-Pugh Class B, n=8) were randomized to the placebo group.

The primary objective assessed the incidence of Grade 3 and 4 ALT abnormalities (>5x upper limit of normal (ULN) if baseline ALT ≤ ULN; or >3.5x baseline if baseline ALT > ULN) at Week 48. One subject in each treatment arm met the primary endpoint by Week 48 (at Week 8 for placebo and Week 36 for the maraviroc arm). 

Studies in Treatment‑Experienced Paediatric Patients Infected with CCR5-tropic Virus 

Study A4001031 is an open-label, multicenter trial in paediatric patients (aged 2 years to less than 18 years) infected with CCR5‑tropic HIV‑1, determined by the enhanced-sensitivity Trofile assay.

Subjects were required to have HIV‑1 RNA greater than 1,000 copies per mL at Screening.

All subjects (n = 103) received maraviroc twice daily and OBT.  Maraviroc dosing was based on body surface area and doses were adjusted based on whether the subject was receiving potent CYP3A inhibitors and/or inducers.

In paediatric patients with a successful tropism test, dual mixed/CXCR4-tropic virus was detected in around 40% of screening samples (8/27, 30% in 2-6 year-olds, 31/81, 38% in 6-12 year-olds and 41/90, 46% in 12-18 year-olds), underscoring the importance of tropism testing also in the paediatric population.

The population was 52% female and 69% black, with mean age of 10 years (range: 2 years to 17 years). At baseline, mean plasma HIV-1 RNA was 4.3 log₁₀ copies/mL (range 2.4 to 6.2 log₁₀ copies per mL), mean CD4+ cell count was 551 cells/mm³ (range 1 to 1654 cells/mm³) and mean CD4+ % was 21% (range 0% to 42%).

At 48 weeks, using a missing, switch or discontinuation equals failure analysis, 48% of subjects treated with maraviroc and OBT achieved plasma HIV-1 RNA less than 48 copies/mL and 65% of subjects achieved plasma HIV-1 RNA less than 400 copies per mL. The mean CD4+ cell count (percent) increase from baseline to Week 48 was 247 cells/mm³ (5%).

Absorption:

The absorption of maraviroc is variable with multiple peaks. Median peak maraviroc plasma concentrations are attained at 2 hours (range 0.5-4 hours) following single oral doses of 300 mg commercial tablet administered to healthy volunteers. The pharmacokinetics of oral maraviroc are not dose proportional over the dose range. The absolute bioavailability of a 100 mg dose is 23% and is predicted to be 33% at 300 mg. Maraviroc is a substrate for the efflux transporter P-glycoprotein.

Co-administration of a 300 mg tablet with a high fat breakfast reduced maraviroc C_max and AUC by 33% and co-administration of 75 mg of oral solution with a high fat breakfast reduced maraviroc AUC by 73% in adult healthy volunteers. Studies with the tablets demonstrated a reduced food-effect at higher doses.

There were no food restrictions in the adult studies (using tablet formulations) or in the paediatric study (using both tablet and oral solution formulations).  The results did not indicate any relevant efficacy or safety concern related to either fed or fasted dosing conditions. Therefore, maraviroc tablets and oral solution can be taken with or without food at the recommended doses in adults (see section 4.2).

Distribution

Maraviroc is bound (approximately 76%) to human plasma proteins, and shows moderate affinity for albumin and alpha-1 acid glycoprotein. The volume of distribution of maraviroc is approximately 194 L.

Biotransformation

Studies in humans and in vitro studies using human liver microsomes and expressed enzymes have demonstrated that maraviroc is principally metabolized by the cytochrome P450 system to metabolites that are essentially inactive against HIV-1. In vitro studies indicate that CYP3A4 is the major enzyme responsible for maraviroc metabolism. In vitro studies also indicate that polymorphic enzymes CYP2C9, CYP2D6 and CYP2C19 do not contribute significantly to the metabolism of maraviroc.

Maraviroc is the major circulating component (approximately 42% radioactivity) following a single oral dose of 300 mg. The most significant circulating metabolite in humans is a secondary amine (approximately 22% radioactivity) formed by N-dealkylation. This polar metabolite has no significant pharmacological activity. Other metabolites are products of mono-oxidation and are only minor components of plasma radioactivity.

Elimination

A mass balance/excretion study was conducted using a single 300 mg dose of ¹⁴C-labeled maraviroc. Approximately 20% of the radiolabel was recovered in the urine and 76% was recovered in the faeces over 168 hours. Maraviroc was the major component present in urine (mean of 8% dose) and faeces (mean of 25% dose). The remainder was excreted as metabolites. After intravenous administration (30 mg), the half-life of maraviroc was 13.2 h, 22% of the dose was excreted unchanged in the urine and the values of total clearance and renal clearance were 44.0 L/h and 10.17 L/h respectively.

Special patient populations:

Elderly

Population analysis of the Phase 1/2a and Phase 3 studies (16-65 years of age) has been conducted and no effect of age have been observed (see section 4.2).

Renal impairment:

A study compared the pharmacokinetics of a single 300 mg dose of maraviroc in

subjects with severe renal impairment (CLcr < 30 mL/min, n=6) and end stage renal disease (ESRD) to healthy volunteers (n=6). The geometric mean AUCinf (CV%) for maraviroc was as follows: healthy volunteers (normal renal function) 1348.4 ng·h/mL (61%); severe renal impairment 4367.7 ng·h/mL (52%); ESRD (dosing after dialysis) 2677.4 ng·h/mL (40%); and ESRD (dosing before dialysis) 2805.5 ng·h/mL (45%). The C max (CV%) was 335.6 ng/mL (87%) in healthy volunteers (normal renal function); 801.2 ng/mL (56%) in severe renal impairment ; 576.7 ng/mL (51%) in ESRD (dosing after dialysis) and 478.5 ng/mL (38%) in ESRD (dosing before dialysis). Dialysis had a minimal effect on exposure in subjects with ESRD. Exposures observed in subjects with severe renal impairment and ESRD were within the range observed in single maraviroc 300 mg dose studies in healthy volunteers with normal renal function. Therefore, no dose adjustment is necessary in patients with renal impairment receiving maraviroc without a potent CYP3A4 inhibitor (see sections 4.2, 4.4 and 4.5).

In addition, the study compared the pharmacokinetics of multiple dose maraviroc in combination with saquinavir/ritonavir 1000/100 mg BID (a potent CYP3A4 inhibitor) for 7 days in subjects with mild renal impairment (CLcr >50 and £80 mL/min, n=6) and moderate renal impairment (CLcr ³30 and £50 mL/min, n=6) to healthy volunteers (n=6). Subjects received 150 mg of maraviroc at different dose frequencies (healthy volunteers – every 12 hours; mild renal impairment – every 24 hours; moderate renal impairment – every 48 hours). The average concentration (Cavg) of

maraviroc over 24 hours was 445.1 ng/mL, 338.3 ng/mL, and 223.7 ng/mL for subjects with normal renal function, mild renal impairment, and moderate renal impairment, respectively. The Cavg of maraviroc from 24-48 hours for subjects with moderate renal impairment was low (Cavg: 32.8 ng/mL). Therefore, dosing frequencies of longer than 24 hours in subjects with renal impairment may result in inadequate exposures between 24-48 hours. Dose adjustment is necessary in patients with renal impairment receiving maraviroc with potent CYP3A4 inhibitors (see sections 4.2 and 4.4 and 4.5).

Hepatic impairment

Maraviroc is primarily metabolized and eliminated by the liver. A study compared the pharmacokinetics of a single 300 mg dose of maraviroc  in patients with mild (Child-Pugh Class A, n=8), and moderate (Child-Pugh Class B, n=8) hepatic impairment compared to healthy subjects (n=8). Geometric mean ratios for Cmax and AUC_last were 11% and 25% higher respectively for subjects with mild hepatic impairment, and 32% and 46% higher respectively for subjects with moderate hepatic impairment compared to subjects with normal hepatic function. The effects of moderate hepatic impairment may be underestimated due to limited data in patients with decreased metabolic capacity and higher renal clearance in these subjects. The results should therefore be interpreted with caution. The pharmacokinetics of maraviroc has not been studied in subjects with severe hepatic impairment (see sections 4.2 and 4.4).

Race

No relevant difference between Caucasian, Asian and Black subjects has been observed.  The pharmacokinetics in other races has not been evaluated.

Gender

No relevant differences in pharmacokinetics have been observed.

Pharmacogenomics

The pharmacokinetics of maraviroc is dependent on CYP3A5 activity and expression level, which can be modulated by genetic variation. Subjects with a functional CYP3A5 (CYP3A5*1 allele) have been shown to have a reduced exposure to maraviroc compared to subjects with defect CYP3A5 activity (e.g., CYP3A5*3, CYP3A5*6, and CYP3A5*7). The CYP3A5 allelic frequency depends on ethnicity: the majority of Caucasians (~90%) are poor metabolisers of CYP3A5 substrates (i.e., subjects with no copy of functional CYP3A5 alleles) while approximately 40% of African-Americans and 70% of Sub-Saharan Africans are extensive metabolisers (i.e., subjects with two copies of functional CYP3A5 alleles).

In a Phase 1 study conducted in healthy subjects, Blacks with a CYP3A5 genotype conferring extensive maraviroc metabolism (2 CYP3A5*1 alleles; n=12) had a 37% and 26% lower AUC when dosed with maraviroc 300 mg twice daily compared with Black (n=11) and Caucasian (n=12) subjects with CYP3A5 genotype conferring poor maraviroc metabolism (no CYP3A5*1 allele), respectively. The difference in maraviroc exposure between CYP3A5 extensive and poor metabolisers was reduced when maraviroc was administered together with a strong CYP3A inhibitor: extensive CYP3A5 metabolisers (n=12) had a 17% lower maraviroc AUC compared with poor CYP3A5 metabolisers (n=11) when dosed with maraviroc 150 mg once daily in the presence of darunavir/cobicistat (800/150 mg).

All subjects in the Phase 1 study achieved the Cavg concentrations that have been shown to be associated with near maximal virologic efficacy with maraviroc (75 ng/mL) in the Phase 3 study in treatment‑naïve adult patients (MERIT).  Therefore, despite differences in CYP3A5 genotype prevalence by race, the effect of CYP3A5 genotype on maraviroc exposure is not considered clinically significant and no maraviroc dose adjustment according to CYP3A5 genotype, race or ethnicity is needed. 

Primary pharmacological activity (CCR5 receptor affinity) was present in the monkey (100% receptor occupancy) and limited in the mouse, rat, rabbit and dog. In mice and human beings that lack CCR5 receptors through genetic deletion, no significant adverse consequences have been reported.

In vitro and in vivo studies showed that maraviroc has a potential to increase QTc interval at supratherapeutic doses with no evidence of arrhythmia.

Repeated dose toxicity studies in rats identified the liver as the primary target organ for toxicity (increases in transaminases, bile duct hyperplasia, and necrosis).

Maraviroc was evaluated for carcinogenic potential by a 6 month transgenic mouse study and a 24 month study in rats. In mice, no statistically significant increase in the incidence of tumours was reported at systemic exposures from 7 to 39-times the human exposure (unbound AUC 0-24h measurement) at a dose of 300 mg twice daily. In rats, administration of maraviroc at a systemic exposure 21-times the expected human exposure produced thyroid adenomas associated with adaptive liver changes. These findings are considered of low human relevance. In addition, cholangiocarcinomas (2/60 males at 900 mg/kg) and cholangioma (1/60 females at 500 mg/kg) were reported in the rat study at a systemic exposure at least 15-times the expected free human exposure.

Maraviroc was not mutagenic or genotoxic in a battery of in vitro and in vivo assays including bacterial reverse mutation, chromosome aberrations in human lymphocytes and mouse bone marrow micronucleus.

Maraviroc did not impair mating or fertility of male or female rats, and did not affect sperm of treated male rats up to 1000 mg/kg. The exposure at this dose level corresponded to 39-fold the estimated free clinical AUC for a 300 mg twice daily dose.

Embryofoetal development studies were conducted in rats and rabbits at doses up to 39- and 34-fold the estimated free clinical AUC for a 300 mg twice daily dose. In rabbit, ,7 foetuses had external anomalies at maternally toxic doses and 1 foetus at the mid dose of 75 mg/kg.

Pre- and post-natal developmental studies were performed in rats at doses up to 27-fold the estimated free clinical AUC for a 300 mg twice daily dose. A slight increase in motor activity in high-dose male rats at both weaning and as adults was noted, while no effects were seen in females. Other developmental parameters of these offspring, including fertility and reproductive performance, were not affected by the maternal administration of maraviroc. 

Tablet core:

Cellulose, microcrystalline

Calcium hydrogen phosphate, anhydrous

Sodium starch glycolate

Magnesium stearate

Film-coat: 

Poly (vinyl alcohol)

Titanium dioxide

Macrogol 3350

Talc

Soya lecithin

Indigo carmine aluminium lake (E132)

Not applicable.

Do not store above 30°C

High density polyethylene bottles (HDPE) with polypropylene child resistant (CR) closures and an aluminium foil/polyethylene heat induction seal containing 180 film-coated tablets.

Polyvinyl chloride (PVC) blisters with child-resistant (CR) aluminium/polyethylene terephthalate (PET) lidding foil in a carton containing 30, 60, 90 film-coated tablets and multipacks containing 180 (2 packs of 90) film-coated tablets.

Not all pack sizes may be marketed.

Any unused product or waste material should be disposed of in accordance with local requirements.

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