Summary Basis of Decision for Revolade ™
Review decision
The Summary Basis of Decision explains why the product was approved for sale in Canada. The document includes regulatory, safety, effectiveness and quality (in terms of chemistry and manufacturing) considerations.
Product type:
RevoladeTM
Eltrombopag olamine, 25 mg and 50 mg, Tablet, Oral
GlaxoSmithKline Inc.
Submission control no: 123984
Date issued: 2011-06-14
Foreword
Health Canada's Summary Basis of Decision (SBD) documents outline the scientific and regulatory considerations that factor into Health Canada regulatory decisions related to drugs and medical devices. SBDs are written in technical language for stakeholders interested in product-specific Health Canada decisions, and are a direct reflection of observations detailed within the evaluation reports. As such, SBDs are intended to complement and not duplicate information provided within the Product Monograph.
Readers are encouraged to consult the 'Reader's Guide to the Summary Basis of Decision - Drugs' to assist with interpretation of terms and acronyms referred to herein. In addition, a brief overview of the drug submission review process is provided in the Fact Sheet entitled 'How Drugs are Reviewed in Canada'. This Fact Sheet describes the factors considered by Health Canada during the review and authorization process of a drug submission. Readers should also consult the 'Summary Basis of Decision Initiative - Frequently Asked Questions' document.
The SBD reflects the information available to Health Canada regulators at the time a decision has been rendered. Subsequent submissions reviewed for additional uses will not be captured under Phase I of the SBD implementation strategy. For up-to-date information on a particular product, readers should refer to the most recent Product Monograph for a product. Health Canada provides information related to post-market warnings or advisories as a result of adverse events (AE).
For further information on a particular product, readers may also access websites of other regulatory jurisdictions. The information received in support of a Canadian drug submission may not be identical to that received by other jurisdictions.
Other Policies and Guidance
Readers should consult the Health Canada website for other drug policies and guidance documents. In particular, readers may wish to refer to the 'Management of Drug Submissions Guidance'.
1 Product and submission information
Brand name:
Manufacturer/sponsor:
Medicinal ingredient:
International non-proprietary Name:
Strength:
Dosage form:
Route of administration:
Drug identification number(DIN):
- 02361825 - 25 mg/tablet
- 02361833 - 50 mg/tablet
Therapeutic Classification:
Non-medicinal ingredients:
Submission type and control no:
Control Number: 123984
Date of Submission:
Date of authorization:
™REVOLADE used under license by GlaxoSmithKline Inc.
2 Notice of decision
On January 12, 2011, Health Canada issued a Notice of Compliance to GlaxoSmithKline Inc. for the drug product, Revolade™.
Revolade™ contains the medicinal ingredient eltrombopag (as eltrombopag olamine) which is a thrombopoietin receptor agonist.
Revolade™ is indicated for adult chronic immune (idiopathic) thrombocytopenic purpura (ITP) to increase platelet counts in splenectomized patients who are refractory to first-line treatments [for example (e.g.) corticosteroids, immunoglobulins]. Revolade™ may be considered as second line treatment for adult non-splenectomized patients where surgery is contraindicated. Revolade™ therapy should not exceed 1 year of continuous treatment. After 1 year of continuous treatment, therapeutic options should be reassessed.
Immune (idiopathic) thrombocytopenic purpura is an acquired immune-mediated disorder defined by a low platelet count and an associated increased risk of bleeding. Bleeding symptoms may range from minimal bruising or nose bleeds, to gastrointestinal or intracranial (brain) hemorrhage. Revolade™ interacts with the transmembrane domain of the human thrombopoietin receptor (TPO-R) and initiates signalling cascades similar but not identical to that of endogenous thrombopoietin (TPO), inducing proliferation and differentiation of megakaryocytes from bone marrow progenitor cells resulting in increased platelet production.
The market authorization was based on quality, non-clinical, and clinical information submitted. The results of one Phase II, randomized, double-blind, placebo-controlled study; two pivotal, Phase III, randomized, double-blind, placebo controlled studies and two ongoing open-label studies evaluated the safety and efficacy of Revolade™ in adult patients with previously treated chronic ITP. Overall, Revolade™ was administered to a total of 446 patients of whom 280 patients received Revolade™ for at least 6 months and 228 patients received Revolade™ for at least 1 year. Results demonstrated that one week after discontinuation of treatment, more than 40% of subjects treated with Revolade™ maintained platelet counts between 50-400 x 109/L, in contrast to placebo. In addition, Revolade™ was consistently associated with a reduction in the risk of bleeding in both the short- and moderate-term studies. Revolade™ therapy also enabled more patients to reduce or discontinue baseline ITP therapies in comparison to the placebo group. Long-term safety of Revolade™ has not been established in controlled studies longer than 6 months. As such, Revolade™ therapy should not exceed 1 year of continuous treatment. Following 1 year of continuous treatment, therapeutic options should be reassessed.
Revolade™ (25 mg and 50 mg, eltrombopag) is presented in tablet form. The recommended starting dose is 50 mg once daily. If after 2 to 3 weeks the platelet counts are below the clinically indicated levels (e.g., 50 x 109/L), the dose may be increased to a maximum of 75 mg once daily. Patient platelet counts should continue to be monitored with dose adjustments made based upon platelet count response. Further dosing guidelines are available in the Product Monograph.
Revolade™ is contraindicated for patients who are hypersensitive to this drug or to any of the excipients. For a complete listing of excipients, see the Dosage Forms, Composition and Packaging section of the Product Monograph. Revolade™ is contraindicated in patients with severe hepatic impairment (Child-Pugh score ≥ 10). Revolade™ should be administered under the conditions stated in the Product Monograph taking into consideration the potential risks associated with the administration of this drug product. Detailed conditions for the use of Revolade™ are described in the Product Monograph.
Based on the Health Canada review of data on quality, safety, and efficacy, Health Canada considers that the benefit/risk profile of Revolade™ is favourable for the indications stated above.
3 Scientific and Regulatory Basis for Decision
This New Drug Submission (NDS) for Revolade™ was issued a Notice of Deficiency (NOD) on October 29, 2009 for deficiencies identified in the clinical programme which prevented the assessment of the efficacy and safety of Revolade™ and elucidating its optimal role and placement in the management of standard adult chronic immune (idiopathic) thrombocytopenic purpura (ITP). The clinical programme also contained certain safety risks which required further delineation, characterization and management. The sponsor responded to the NOD on January 27, 2010 and addressed all the deficiencies identified in the NOD. A Notice of Compliance (NOC) was issued for Revolade™ on January 12, 2011. For more information, refer to section 3.3.4 Clinical Safety.
3.1 Quality Basis for Decision
3.1.1 Drug Substance (Medicinal Ingredient)
General Information
Eltrombopag (as eltrombopag olamine), the medicinal ingredient of Revolade™ is a small molecule thrombopoietin receptor (TPO-R) agonist which initiates a signalling cascade similar to that of endogenous thrombopoietin (TPO), thus inducing increased platelet production from the bone marrow.
Manufacturing Process and Process Controls
Eltrombopag is manufactured via a multi-step synthesis. Each step of the manufacturing process is considered to be controlled within justified limits.
Characterization
The structure of eltrombopag has been adequately elucidated and the representative spectra have been provided. Physical and chemical properties have been described and were found to be satisfactory.
Impurities and degradation products arising from manufacturing and/or storage were reported and characterized. These products were found to be within International Conference on Harmonisation (ICH) established limits and are therefore considered to be acceptable. Appropriate tests are adequately controlling the levels of product- and process-related impurities.
Control of Drug Substance
The drug substance specifications and analytical methods used for quality control of eltrombopag are considered acceptable.
The levels of product- and process-related impurities were adequately monitored throughout the manufacturing process. Results from process validation reports and in-process controls indicated that the impurities of the drug substance were adequately under control. The level of impurities reported for the drug substance was found to be within the established limits.
Batch analysis results were reviewed and all results comply with the specifications and demonstrate consistent quality of the batches produced.
The drug substance packaging is considered acceptable.
Stability
Stability study results based on accelerated, long-term, and stress testing show that eltrombopag is a stable compound when packaged as proposed over the proposed storage period. The bulk drug is also stable under the proposed storage conditions.
3.1.2 Drug Product
Description and Composition
Revolade™ is available as round, biconvex, film-coated tablets available in blister packs of 14 or 28 as 25 mg-white or 50 mg-brown tablets. The 25 mg tablets are debossed with 'GS NX3' and '25' and the 50 mg tablets are debossed with 'GS UFU' and '50' on one side.
Each tablet contains either 25 mg or 50 mg eltrombopag (as eltrombopag olamine) along with the following non-medicinal ingredients: magnesium stearate; mannitol; microcrystalline cellulose; povidone; sodium starch glycolate; hypromellose; macrogol; and titanium dioxide. Revolade™ 25 mg tablets also contain polysorbate. Revolade™ 50 mg tablets also contains iron oxide yellow and iron oxide red.
All non-medicinal ingredients (excipients) found in the drug product are acceptable for use in drugs according to the Food and Drug Regulations. The compatibility of eltrombopag with the excipients is demonstrated by the stability data presented on the proposed commercial formulation.
Revolade™ 25 mg and 50 mg tablets are packaged in blisters and sealed with aluminum foil. Each blister strip contains 7 tablets, with blister packs containing either 14 or 28 tablets.
Pharmaceutical Development
Changes to the manufacturing process and formulation made throughout the pharmaceutical development are considered acceptable upon review.
Manufacturing Process and Process Controls
The manufacturing process for both 25 mg and 50 mg Revolade™ tablets uses conventional manufacturing techniques, namely: dry mixing; granulation; wet milling; drying; compression; film-coating; and packaging.
The validated process is capable of consistently generating product that meets release specifications. The method of manufacturing is considered acceptable and the process is considered adequately controlled within justified limits.
The specifications for all of the ingredients are approved in accordance with European Pharmacopoeia (Ph. Eur.) standards, where applicable.
Control of Drug Product
Revolade™ is tested to verify that its identity, appearance, content uniformity, dissolution, levels of degradation products, and drug-related impurities are within acceptable limits.
Validation results of the analytical method used for the determination of eltrombopag and the drug-related impurities are considered acceptable.
Data from final batch analyses were reviewed and are considered to be acceptable according to the specifications of the drug product.
Stability
Based on the long-term and accelerated stability data submitted, a shelf-life of 36 months is considered acceptable for Revolade™ 25 mg and 50 mg tablets when stored below 30°C and protected from freezing.
3.1.3 Facilities and Equipment
The design, operations and controls of the facilities and equipment that are involved in the production of Revolade™ are considered suitable for the activities and products manufactured. The sites are compliant with Good Manufacturing Practices.
3.1.4 Adventitious Agents Safety Evaluation
Not applicable. The materials used in the product formulation are not derived from animal or human origin.
3.1.5 Conclusion
The Chemistry and Manufacturing information submitted for Revolade™ has demonstrated that the drug substance and drug product can be consistently manufactured to meet the approved specifications. Proper development and validation studies were conducted, and adequate controls are in place for the commercial processes.
3.2 Non-Clinical Basis for Decision
3.2.1 Pharmacodynamics
Primary Pharmacodynamics
Pharmacodynamic studies demonstrated that eltrombopag is selective to the thrombopoietin receptor (TPO-R) and behaves as a true TPO-R agonist. Eltrombopag stimulates some, but not all, signal transduction pathways known to be induced through TPO-R activation. The ability of eltrombopag to stimulate proliferation and megakaryocte differentiation within bone marrow progenitor cells supports its clinical efficacy. Furthermore, eltrombopag showed a targeted beneficial effect by promoting differentiation of bone marrow cells into platelets in healthy cells but not in leukemic cells.
An in vitro study was conducted to determine any potential effects eltrombopag may have on platelet function, given TPO is known to enhance agonist-dependent platelet aggregation and P-selection expression. Results from this study showed eltrombopag had no direct effect on in vitro platelet aggregation or activation, nor did it influence agonist-dependent aggregation or activation. Nonetheless, it is suggested that supplementary in vivo studies be conducted in both animals and humans to further support these in vitro observations.
Eltrombopag demonstrated a species-specific effect, where platelet activation was shown only in human or chimpanzee models, but not within other species such as mice, rats or monkeys. Consequently, this did not allow the typical in vivo non-clinical efficacy models to be used to evaluate the pharmacodynamic effect of eltrombopag. As a means of addressing this issue, an in vivo pharmacology, pharmacokinetics, and safety study at single and repeat oral doses of eltrombopag was conducted in chimpanzees. Results from this study showed eltrombopag was well tolerated in chimpanzees following either a single or 5 daily oral doses up to 10 mg/kg/day with no adverse clinical signs or clinical pathology. However, this study did not substantiate all the in vitro observations [for example (e.g.) megakaryocyte differentiation, eltrombopag-mediated necrosis, signal transduction or specificity of action]. Therefore, this single in vivo study remains limited in scope.
Secondary Pharmacodynamics
Eltrombopag was examined in enzyme and radioligand binding assays to evaluate possible interactions with the most common receptors, enzymes, and ion channels. Results from these assays indicate that eltrombopag showed inhibition (>25%) on 4 targets: I2-receptor (88%), oestrogen-α-receptor (85%), α2B-receptor (38%), and oestrogen-β-receptor (33%). This inhibition was observed at the intended therapeutic dose which warrants vigilance for both expected and unexpected adverse drug reactions (ADRs) within the conduct of clinical trials.
Safety Pharmacology
In vitro studies were conducted to evaluate the effect of eltrombopag on cardiac ion channels. The effects of eltrombopag on the human Ether-a-go-go (hERG) currents recorded from human embryonic kidney cells transfected with hERG-1 complementary deoxyribonucleic acid (cDNA), was found to inhibit hERG channel tail current in a concentration dependent manner with an estimated half inhibitory concentration (IC50) of 0.69 µM (0.31 µg/mL). The effects on the action potential duration, repolarisation, maximum rate of depolarization, upstroke amplitude, and resting membrane potential were investigated in isolated dog Purkinje fibres. Stimulation of these fibres at frequencies of 0.5 and 1 Hz with an exposure to eltrombopag at concentrations of 10 µM (4.4 µg/mL) or 25 µM (11.1 µg/mL) revealed no association with action potential prolongation, but did cause a decrease in the upstroke amplitude, maximum rate of depolarization and action potential durations.
In vivo studies were conducted to evaluate the effect of eltrombopag on overt and peripheral central nervous system, cardiovascular, and respiratory systems. The overt central and peripheral effects of eltrombopag on the central nervous system were studied in rats following oral administration of eltrombopag at doses of 3, 10, or 40 mg/kg. Results showed eltrombopag did not produce any adverse effects on neurobehavioral function, even at the highest dose (no-observed-adverse-effect-level 40 mg/kg). Nevertheless, extrapolation of these observations to humans should be interpreted with caution given that the rat TPO-R sequence is different from the one expressed in humans.
Eltrombopag's action on the cardiovascular system was evaluated in dogs that received administration of a single oral doses up to 30 mg/kg. Results showed no effect on arterial blood pressure, heart rate or electrocardiographic (ECG) parameters for up to 48-hours post-dose administration. Repeat oral doses up to 30 mg/kg/day given for 52 weeks also showed no evidence of cardiac abnormalities.
Eltrombopag's effect on the respiratory system was assessed in rats up to a maximum dose of 30 mg/kg/day. Results showed eltrombopag did not produce any adverse effects on respiratory function.
3.2.2 Pharmacokinetics
Absorption
The plasma clearance of eltrombopag following a single intravenous administration was generally low in the rat, dog, and monkey with half-lives of 12, 14, and 7.7 hours, respectively.
Following a single oral administration, eltrombopag was more quickly absorbed in the rat and dog with a time to maximum plasma concentration (tmax) of 1 to 2.5 hours than in the monkey (tmax of 4 hours). With this observed difference in absorption among non-clinical species [rat, and dog versus (vs) monkey], generalization of observations from these species to humans is limited.
The oral bioavailability of eltrombopag, when administered as a solution, revealed to be low and variable in the rat (12% to 34%) while high in the dog and monkey (83% and 89%).
Repeat-dose toxicity studies conducted in mice, rats, and dogs showed that systemic exposures of eltrombopag increased approximately proportionally in mice and dogs but greater than proportionally in rats. No gender-related differences in systemic exposure were shown between male versus female.
Distribution
In vitro studies which evaluated the distribution of eltrombopag showed that eltrombopag was highly bound (>99%) to plasma proteins in the mouse, rat, dog, and monkey. Also observed in these non-clinical models was a moderate concentration-dependent partitioning of eltrombopag to blood cells.
In vivo studies showed that eltrombopag was widely distributed into peripheral tissues following oral or intravenous administration in mice and rats. In mice, there was no evidence of accumulation within peripheral tissues, including kidney, skin and eyes. In the rat however, slight accumulation in peripheral tissues was noted after repeat administration.
Metabolism
In vitro and in vivo studies showed that eltrombopag was primarily metabolized through cleavage, oxidation and conjugation with glucuronic acid, glutathione, or cysteine. Minor metabolites (<10%), arising from glucuronidation and oxidation were noted. No notable gender-related differences in metabolism were observed in mice, rats, or dogs.
Elimination
Eltrombopag was predominately eliminated in the faeces, with urinary excretion representing a minor route of elimination. Most of the administered dose was eliminated in the first 72 hours following dose administration. Elimination by biliary secretion accounted for 7-43% of the drug according to the species. However, given there was a significant difference noted in the proportion of the drug eliminated in the faeces, urine and bile among non-clinical species (rats, mice, and dog), a further study with chimpanzees would be practical to assist in the extrapolation of the results to humans.
3.2.3 Toxicology
Given that eltrombopag has a species-specific effect known to be only pharmacologically active in chimpanzees and not other species [that is (i.e.) mice, rat, or dog], a unique challenge was present when selecting appropriate non-clinical species for use in the eltrombopag toxicology program. With the chimpanzee identified as an endangered species, this restricted access to conduct non-clinical studies within this species. In addition, terminal studies to evaluate potential target organ effects in chimpanzees were also not permitted. As such, the species (mice, rats, and dogs) chosen for the toxicology evaluation were selected on the basis of similarities in their pharmacokinetic and metabolic profiles to humans. While it was not possible to assess potential effects of exaggerated pharmacology in these species (i.e., effects associated with excessive TPO-R agonism), the toxicology evaluation was therefore limited to identify potential off-target mediated effects.
Acute Toxicity
The acute toxicity of eltrombopag was evaluated in dogs with the administration of a single oral dose at 100 mg/kg and in other species up to 300 mg/kg to establish the maximum tolerated dose. The 100 mg/kg dose was well tolerated with clinical signs limited to slight reduction in food consumption and body weight. The 300 mg/kg dose was poorly tolerated and associated with vomiting, abnormal stool consistency, decreased activity, lack of appetite, and moderate weight loss.
Repeat-Dose Toxicity
The repeat-dose toxicity studies were conducted in rabbits, mice, rats, and dogs. The duration of the toxicity studies were up to 1, 13, 28, and 52 weeks, respectively. Furthermore, repeat dose toxicity was evaluated in mice and rats in two carcinogenicity studies, each having a duration of two years. Major findings from these studies are summarized below.
Mortality
Treatment-related mortality in mice occurred with doses of ≥150 mg/kg/day (≥1,083 µg/mL), and ≥60 mg/kg/day (1,044 µg.h/mL) in rats, which represents 6.2-fold the maximum proposed human exposure. Although the cause of death, in either mice or rats, was undetermined, these deaths were generally preceded by decreased food consumption, loss of body weight and adverse clinical signs (e.g., abnormal respiration, decreased activity, and hunched posture).
Dogs that received doses of eltrombopag at ≥60 mg/kg/day (2,170 µg.h/mL) showed poor tolerance with increased liver enzymes and/or elevated bilirubin levels along with microscopic findings of cell necrosis in the liver. However, no deaths were observed at doses up to 100 mg/kg/day (3,185 µg.h/mL).
Ocular Effects
Treatment-related cataracts were observed in rats in the 28-week oral toxicity study and in mice and rats in the two-year carcinogenicity studies which were dose- and time-dependent. There was however, no evidence of eltrombopag accumulating in ocular tissues. In young mice, the rapidly developing lens was shown to be more susceptible to exposure at the no-observed-effect-level (NOEL) of 25 mg/kg (202 µg.h/mL). This NOEL in mice represents approximately 1.2-fold the maximum proposed human exposure. No treatment-related ocular abnormalities were observed in dogs following oral administration of eltrombopag for 52 weeks at 2.5-fold the maximum proposed human exposure.
Given eltrombopag was not shown to be retained within ocular tissues; this likely represented a strain difference in sensitivity of cataract formation. While data from the clinical trials suggest that eltrombopag does not pose a meaningful risk for cataract formation, routine monitoring in humans for cataracts is recommended.
Renal Effects
Renal tubular toxicity was observed in studies of up to 14 days duration in mice and rats and in a two-year carcinogenicity study in mice at exposures generally associated with mortality (≥6.2-fold the maximum proposed human exposure). While the cause of death was often undetermined, these deaths were generally attributed to renal tubular degeneration and necrosis, although pulmonary and hepatic toxicity may also have been contributing factors.
In a two-year mouse study, at 1.2-and 3.5-fold the maximum proposed human exposure, regenerative changes were noted in the renal tubules; however this observation is often a common occurrence in mice of this age and strain. In rats, an increase in the incidence or severity of spontaneous, age-related chronic progressive nephropathy was observed at a similar exposure level (4-fold the maximum proposed human exposure). The clinical relevance of this finding to the renal effects observed in mice is unknown. No renal tubular toxicity was observed following repeated oral administration to rats for two years or dogs for 52 weeks at exposures up to 4- and 2.5-fold the maximum proposed human exposure, respectively.
Hepatic Effects
Hepatocyte degeneration and/or necrosis, often associated with a large increase in liver enzymes, was observed in mice, rats, and dogs following repeated oral administration of eltrombopag at exposures generally associated with mortality. Although the mechanism of eltrombopag-induced hepatotoxicity is undetermined, no treatment-related effects were observed after chronic dosing at maximum tolerated doses in rats (28 weeks) or dogs (52 weeks) at exposures up to 3.9- or 2.5-fold the maximum proposed human exposure, respectively.
Genotoxicity and Carcinogenicity
Eltrombopag showed no evidence of mutagenic or clastogenic potential in vitro in the bacterial mutation assays or in the two in vivo assays in rats. Eltrombopag was marginally positive (<3-fold increase in mutation frequency) in the in vitro mouse lymphoma assay. These findings suggest eltrombopag does not pose a genotoxic or carcinogenic risk.
The sponsor submitted 2-year carcinogenicity studies in rats and mice. Due to eltrombopag's unique TPO receptor specificity, these animal species do not model any potential on-target adverse effects related to the pharmacology of eltrombopag in the general toxicology, reproductive toxicology, and carcinogenicity studies.
Reproductive and Developmental Toxicity
Eltrombopag caused no adverse effects on female fertility, early embryonic development or embryo-foetal development in rats at doses up to 20 mg/kg/day (2 times the proposed human exposure). In male rats, doses up to 40 mg/kg/day did not affect fertility. Additionally, in rabbit studies, no effect on embryo-foetal development was detected at doses up to 150 mg/kg/day.
At a maternally toxic dose of 60 mg/kg/day (6 times the proposed human exposure) in rats, eltrombopag was associated with embryo lethality, reduced foetal body weight and gravid uterine weight (female fertility study), low incidence of cervical ribs (a non-teratogenic foetal variation), and reduced foetal body weight (embryo-foetal development study).
At maternally non-toxic doses (10 and 20 mg/kg/day), pre- and post-natal development studies in rats, showed no effects on growth, development, neurobehavioural or reproductive function of the offspring. However, eltrombopag was detected in the plasma of offspring pups following administration of the medicinal product to the maternal dams, suggesting that rat pup exposure to eltrombopag was likely through lactation.
Phototoxicity Studies
In vitro phototoxicity was noted following ultraviolet (UV) exposure. However, in vivo UV exposure to treated hairless mice did not reveal cutaneous phototoxicity nor ocular phototoxicity in comparative pigmented/albino mouse and rat studies.
Immunotoxicity
In repeat-dose toxicity studies, no evidence was seen of immunotoxicity (i.e., no effects on haematology parameters and lymphoid organ weights or histology) in rats after 28 weeks dosing (661 µg.h/mL), or in dogs after 52 weeks dosing (418 µg.h/mL). In addition, a 4-week immunotoxicity study in rats assessing potential effects on primary antibody response showed eltrombopag did not adversely affect immune function at doses up to 40 mg/kg/day. These results suggest that treatment with eltrombopag should not increase a cause for concern of immunosuppression in ITP patients.
Local Tolerance
Local tolerance studies were conducted in vitro and in vivo. Eltrombopag was non-irritating to skin but was found to be an ocular irritant in vitro. Eltrombopag was not a sensitizer in vivo.
3.2.4 Summary and Conclusion
In conclusion, the toxic potential of eltrombopag was characterized through the conduct of numerous non-clinical studies. The principal non-clinical findings included cataract formation (mice and rats), renal toxicity (mice and rats), and hepatotoxicity (mice, rats and dogs). Furthermore, eltrombopag was identified to be phototoxic in vitro, yet in vivo no phototoxicity was observed following either single or repeated dosing in rats or mice.
Despite these results, the non-clinical studies presented were limited to the identification of off-target effects due to the distinct species specificity of eltrombopag in regards to its mechanism of action. In the absence of non-clinical models available to evaluate potential on-target effects, it is acknowledged that the toxicology program lacks the ability to fully evaluate the safety of eltrombopag through study of the exaggerated pharmacology. As a result, the Revolade™ clinical program had to carefully evaluate these effects directly in humans.
3.3 Clinical basis for decision
3.3.1 Pharmacodynamics
Following repeat dose administration of Revolade™, platelet counts were observed to increase in a dose-dependent manner. After ten days of dosing, peak values were reached a maximum 2 weeks after the initiation of dosing, and returned to baseline within approximately 2 weeks after the last dose of eltrombopag. Platelet function tests indicated no increase or decrease in platelet activation in Revolade™-treated ITP patients compared to untreated ITP patients or healthy volunteers.
3.3.2 Pharmacokinetics
Absorption
Revolade™ plasma levels increased in a dose proportional manner, with peak absorption concentration observed 2-6 hours following oral administration. The elimination half-life was between 21-32 hours.
Distribution
Following oral administration of a radiolabelled dose, Revolade™ accounted for most (64%) of the radioactivity circulating in plasma. In vitro data showed that Revolade™ was highly bound to human plasma proteins (>99%), predominately to albumin.
Metabolism
Revolade™ is metabolised through various pathways, but primarily through cytochrome P450 (CYP) 1A2 and CYP 2C8 and in conjugation with glucuronic acid. In vitro data and one clinical interaction study indicated that Revolade™ did not induce or inhibit CYP450 enzymes.
In vitro studies demonstrated that Revolade™ is not a substrate for the organic anion transporter polypeptide, OATP1B1, but is an inhibitor of this transporter. In vitro studies also demonstrated that Revolade™ is a breast cancer resistance protein (BCRP) substrate and inhibitor. Rosuvastatin being a substrate for those transporters, co-administration with Revolade™ resulted in a 55% increase in exposure, as measured by the area under the curve (AUC).
Elimination
The primary route of elimination was through the faeces (59%) and to a minor extent via the urine (31%). Urinary elimination was essentially complete within the first 48 hours post administration. Faecal elimination continued for several more days, with most of the dose recovered by 144 hours after dosing.
Drug-Drug Interactions
Co-administration of Revolade™ with rosuvastatin increased the maximum serum concentration (Cmax) of rosuvastatin by 2.03-fold and the AUC by 55%. Therefore a reduced dose of rosuvastatin should be considered when administered concomitantly with Revolade™ and careful monitoring of possible side effects should be undertaken. Interactions may be expected with other statins (e.g., pravastatin, simvastatin, and lovastatin), however clinically significant interactions are not expected between Revolade™ and either atorvastatin or fluvastatin. When co-administered with Revolade™, a reduced dose of statins should be considered and carefully monitored. In addition, concomitant administration of Revolade™ and other OATP1B1 and BCRP substrates should be undertaken with caution.
Co-administration of Revolade™ with lopinavir/ritonavir (LPV/RTV) may cause a decrease in the concentration of Revolade™. Therefore, caution should be used when co-administering Revolade™ with LPV/RTV therapy; and platelet counts should be carefully monitored in order to ensure appropriate medical management of the dose of Revolade™.
Revolade™ combines with polyvalent cations such as aluminium, calcium, iron, magnesium, selenium and zinc. Antacids, dairy products and other products containing polyvalent cations such as mineral supplements should be administered at least four hours apart from Revolade™ dosing to avoid significant reduction in Revolade™ absorption.
Food-Drug Interactions
Administration of a single 50 mg dose of Revolade™ with a standard high-calorie, high-fat breakfast that included dairy products reduced plasma Revolade™ concentrations. Food low in calcium (<50 mg calcium) did not significantly impact plasma Revolade™ exposure, regardless of calorie or fat content.
Special Populations
Renal Impairment
A pharmacokinetic analysis investigating use of Revolade™ in patients with mild, moderate, and severe renal impairment compared to healthy volunteers following administration of a single 50 mg dose of Revolade™ showed that plasma Revolade™ AUC was 32%, 36%, and 60% lower and Cmax was 30%, 19%, and 54% lower in patients with mild, moderate, and, severe renal impairment, respectively, compared to healthy volunteers. Caution is therefore warranted when administering Revolade™ in patients with mild to moderate renal impairment. Administration of Revolade™ is not recommended for use in patients with severe renal impairment (creatinine clearance <30 mL/min) unless the expected benefit outweighs the risk.
Hepatic/Biliary Impairment
Results from a pharmacokinetic study conducted in patients with mild (Child-Pugh score of 5 to 6), moderate (Child-Pugh score of 7 to 9), and severe hepatic impairment (Child-Pugh score of 10 to 15) compared to healthy volunteers, following administration of a single 50 mg dose of Revolade™ showed that plasma Revolade™ AUC values were 41% higher in patients with mild hepatic impairment and 80% to 93% higher in patients with moderate to severe hepatic impairment. Therefore, Revolade™ should not be used in ITP patients with moderate hepatic impairment (Child-Pugh score 7 to 9) unless the expected benefit outweighs the risk. For patients with severe hepatic impairment, use of Revolade™ is contraindicated.
Following administration of Revolade™, abnormal liver function was also observed with increases in serum alanine aminotransferase (ALT), and aspartate aminotransferase (AST). These findings were mostly mild (Grade 1-2), reversible and not accompanied by clinically significant symptoms that would indicate impaired liver function. Across three placebo-controlled studies, one patient in the placebo group and one patient in the Revolade™ group experienced a Grade 4 liver test abnormality. Therefore, careful measuring of serum ALT, AST and bilirubin levels prior to initiating treatment with Revolade™, in addition to ongoing monitoring of these levels every 2 weeks during the dose adjustment phase, and monthly following the establishment of a stable dose is recommended. Further guidelines for monitoring liver enzymes have been provided in the Product Monograph.
Race
Based upon a population pharmacokinetic analysis, data showed that East Asian ITP patients had approximately 87% higher Revolade™ plasma values compared to non-East Asian ITP patients (mainly Caucasian in origin). Similar results were also observed between East Asian and non-Asian healthy volunteers. The pharmacokinetic difference observed between East Asian and Caucasian might suggest that multiple factors such as body weight and genetic differences in metabolizing enzymes and transporters may contribute to this observed difference. Evaluation of platelet response across ITP studies also suggests that East Asian ITP patients were more likely to achieve platelet counts >400 x 109/L. In addition, there was a trend to a higher incidence of hepatobiliary laboratory abnormalities in this patient population. A starting dose of 25 mg once daily is recommended in patients of East Asian ancestry.
Geriatric
There is limited data on the use of Revolade™ in elderly patients (>65 years of age). Based on the clinical studies conducted, age did not appear to influence the pharmacokinetics of Revolade™. However, given this patient population may be more prone to decreased hepatic, renal, or cardiac function, and of concomitant disease or other drug therapy, caution should be used when prescribing Revolade™ to patients (>65 years of age).
Paediatric
The safety and efficacy of Revolade™ in paediatric patients have not been established.
3.3.3 Clinical Efficacy
A total of five studies in 493 adult subjects with previously-treated chronic ITP were presented in this submission: three double-blind, randomized, multicentre, placebo-controlled studies (TRA100773A, TRA100773B and RAISE) and two open-label multicentre studies (REPEAT and EXTEND).
TRA100773A Study
TRA100773A was a 6-week, dose-ranging Phase II study conducted in ITP patients who had either not responded to one or more prior therapies (refractory), or who had relapsed within three months of prior therapy (relapse). The goal of this study was to identify an optimal dose for Revolade™. The primary efficacy endpoint was the proportion of patients who achieved a platelet count ≥50 x 109/L at Day 43 from a baseline platelet count <30 x 109/L. The study design consisted of a 1:1:1:1 randomization to either a placebo, or one of three Revolade™ dosing arms (30 mg, 50 mg or 75 mg). Patients were administered study medication once daily for up to 6 weeks. Patients were also stratified based on use or non-use of ITP medications at baseline, splenectomy status and baseline platelet count (≤15 x 109/L or >15 x 109/L). Patients who attained a platelet count >200 x 109/L were discontinued from the study to reduce the risk of developing thrombocytosis. Additionally, no dose adjustments were permitted for the duration of the study.
Results from the TRA100773A study demonstrated that Revolade™ effectively raised platelet counts compared to placebo following up to 6-weeks of treatment irrespective of ITP medication use and baseline platelet count. Also, a dose-dependent increase in response was observed, and the primary endpoint was achieved by 11% of patients on placebo in comparison to 28%, 70% , and 81% of patients on Revolade™ 30 mg, 50 mg, and 75 mg, respectively. Furthermore, patients treated with either Revolade™ 50 mg or 75 mg showed a statistical greater odds of responding at Day 43 than patients treated with a placebo. Given these observations, the 50 mg dose was determined to be the most efficacious starting dose.
TRA100773B Study
TRA100773B was a 6-week, Phase III study conducted in ITP patients who, like in the TRA100773A study, had experienced response to prior ITP therapy. Patients were randomized on a 1:2 ratio to a placebo versus Revolade™ 50 mg starting dose (lowest effective dose identified from TRA100773A). The study design of TRA100773B was similar to TRA100773A, with the exception that patients with platelet counts <50 x 109/L on or after Day 22 were allowed to increase their dose of Revolade™ to 75 mg (or matching placebo). The same primary efficacy endpoint as in TRA100773A was used.
Treatment response from the TRA100773B study confirmed the results observed from the TRA100773A study, with 16% of patients on placebo and 59% of patients on Revolade™ achieving platelet counts ≥50 x 109/L (p<0.001). In addition, the incidence and severity of symptoms associated with chronic ITP, such as bleeding, bruising, and petechiae (as assessed by the (World Health Organization [WHO] bleeding scale) was lower in the Revolade™ treatment group compared to the placebo group.
Although both TRA100773A and TRA100773B study results were positive for both patient populations with or without splenectomy, the design of both studies was not meant to assess Revolade™ versus splenectomy comparatively in the treatment of ITP. Therefore, the current data submitted was considered insufficient to determine the efficacy of Revolade™ in the population of non-splenectomized patients.
RAISE Study
RAISE was a 6-month Phase III study similar in design to TRA100773B with randomization being on a 1:2 ratio to a placebo versus Revolade™ 50 mg (starting dose). However patients were now instructed to follow specific dosing modifications based upon their individual platelet count response. The dose modification guidelines were as follows:
- increase the dose of study medication to a maximum of 75 mg or matching placebo once daily if the platelet count elevation was insufficient (e.g., <50 x 109/L);
- maintain the dose of study medication if platelet counts were between 50-200 x 109/L;
- reduce the dose of study medication if platelet counts had risen to values between 200-400 x 109/L; or
- interrupt treatment with study medication if platelet counts exceeded 400 x 109/L and restart at a lower dose when platelet counts returned to ≤150 x 109/L.
The primary efficacy endpoint of the study was the odds of achieving a platelet count ≥50 x 109/L and ≤ 400 x 109/L during the 6-month treatment period, for patients receiving Revolade™ treatment compared to a placebo.
Results from the RAISE study confirmed the efficacy findings observed in the two short-term studies TRA100773A and TRA100773B that Revolade™ treatment did raise and maintain platelet counts to safe levels (between ≥50 x 109/L and ≤ 400 x 109/L). Fifty-four percent of patients treated with Revolade™ and 13% of placebo-treated patients achieved platelet counts between ≥50 x 109/L and ≤ 400 x 109/L following 6 weeks of treatment. Furthermore, 53% maintained these levels within the Revolade™ treatment group compared to 16% in the placebo group over a 6-month period. The incidence and severity of symptoms associated with chronic ITP (i.e., bleeding) was also clinically significantly lower in the Revolade™ treatment group compared to the placebo-treated group. In addition, there was also a greater reduction in the use of baseline concomitant ITP medications and use of rescue medication in the Revolade™ treatment group compared to the placebo group.
Long-Term Studies
The REPEAT and EXTEND studies were ongoing global, open-label, single-group studies evaluating the effect of re-treatment (REPEAT) and long-term treatment (EXTEND) with Revolade™. Both open-label studies had different entrance criteria with regard to platelet count compared to the previous three double-blind studies. In REPEAT, patients were required to have a baseline platelet count between 20 x 109/L and 50 x 109/L. However, no platelet count entry criteria was specified for eligibility into the EXTEND study.
REPEAT Study
The REPEAT study was designed to evaluate the efficacy, safety, and tolerability of Revolade™ 50 mg (starting dose) administered once daily over three cycles of repeated, intermittent dosing. A cycle was defined as administering Revolade™ treatment for up to 6 weeks (on-therapy) followed by stopping Revolade™ treatment up to 4 weeks (off-therapy). The duration of both the on-therapy and the off-therapy periods of each cycle were determined by each patient's individual platelet count. The primary endpoint of this study was the proportion of patients who achieved a platelet count ≥50 x 109/L and at least two times above the baseline count in cycle 2 or 3, given this response in cycle 1.
As in the TRA100773A and TRA100773B studies, patients in REPEAT interrupted treatment for the cycle if they achieved a platelet count >200 x 109/L, or if they had completed 6 weeks of dosing. The next cycle of treatment with Revolade™ was initiated when their platelet counts fell <20 x 109/L, or when they reached week 4 of the off-therapy period, and had platelet counts <50 x 109/L. Patients who did not respond in the first cycle (platelet count ≥50 x 109/L and at least two times above the baseline count) were not eligible to continue into the second or third cycle. Similar to the double-blind Phase III study design (TRA100773B and RAISE), the Revolade™ dose (or matched placebo) could be increased to 75 mg on or after Day 22 of each cycle if a patient's platelet count did not increase above 50 x 109/L.
Of the 52 patients who responded in cycle 1, out of 66 patients enrolled, 80% achieved a platelet count of ≥50 x 109/L and at least two times baseline on Day 43. Of the 52 patients who responded in cycle 1, 63% and 79% satisfied the response criteria by Day 8 and Day 15 in cycle 1, respectively. Forty-one patients (80%) responded again in cycle 2 and 38 (78%) patients responded again in cycle 3. A reduction in any bleeding (WHO Grade 1-4) and clinically significant bleeding (WHO Grade 2-4) during the treatment phases was demonstrated in each cycle. At the baseline visit of cycle 1, 50% and 19% of patients reported any bleeding and clinically significant bleeding, respectively. At the Day 43 visit of cycle 1, the proportion of patients bleeding was reduced; 12% and 0% of patients reported any bleeding and clinically significant bleeding, respectively. Similar results were found during the subsequent treatment cycles.
EXTEND Study
EXTEND is an ongoing long-term extension study designed to evaluate the safety and efficacy of Revolade™ in patients with chronic ITP who were previously enrolled in a Revolade™ study. The dosing instructions for the EXTEND study were similar to those in RAISE and were based upon each patient's individual platelet count response to treatment with Revolade™. In this study, patients were permitted to modify their dose of study medication, as well as, decrease or discontinue concomitant ITP medications, in addition to having access to rescue treatment as needed for standard care.
The study was designed in stages which depended on each patient's use of concomitant ITP medications. In stage 1, patients were administered a starting dose of 50 mg per day in order to reach a platelet count of ≥50 x 109/L or ≥100 x 109/L depending on whether they were taking a concomitant ITP medication at study entry. Concomitant ITP medications, if taken at study entry, were then tapered to a minimal dose or discontinued entirely (stage 2), while maintaining a platelet count of ≥50 x 109/L. The Revolade™ treatment dose was then titrated to a minimal effective dose to maintain platelet counts of ≥50 x 109/L (stage 3) and continued for as long as the patient continued to benefit (stage 4).
Two hundred and forty-nine patients completed ≥6 months of treatment, 210 completed ≥12 months of treatment, 138 patients completed ≥2 years of treatment, and 24 patients completed ≥3 years of treatment. The median follow-up was 100 weeks. The majority of patients had baseline platelet counts of <30 x 109/L (70%). The median daily dose of Revolade™ following 6 months of therapy was 50 mg.
At baseline, 56% of patients had any bleeding (WHO bleeding Grades 1-4) and 16% had clinically significant bleeding. The proportion of patients with any bleeding and clinically significant bleeding decreased from baseline by approximately 50% for the majority of assessments up to one year.
Sixty-five percent of patients who reduced a baseline medication permanently discontinued or had a sustained reduction of their baseline ITP medication and did not require any subsequent rescue treatment. Ninety-six percent of these patients maintained this discontinuation or reduction for at least 24 weeks. Fifty-four percent of these patients completely discontinued at least one baseline ITP medication, and 49% of patients permanently discontinued all baseline ITP medications, without subsequent rescue treatment.
Results from the EXTEND study therefore showed that the majority of patients who responded in a previous Revolade™ study and received study medication in EXTEND responded again in EXTEND, indicating that a prior response to Revolade™ is predictive of a subsequently rise in platelets when patients are re-treated with Revolade™. The use of concomitant ITP medication was also significantly reduced, if not permanently discontinued, without need of any subsequent rescue treatment.
3.3.4 Clinical Safety
The safety data presented was collected from three double-blind, placebo-controlled studies (TRA100773A, TRA100773B, and RAISE), two open-label studies (REPEAT and EXTEND), one non-treatment observational study, thirteen completed pharmacology studies, and one study conducted and halted before completion in non-ITP patients with chronic liver disease. Across all studies, Revolade™ was well-tolerated with similar incidences overall of adverse events (AEs), serious adverse events (SAEs), and AEs leading to discontinuation from the study medication.
In the 6-week studies (TRA100773A and TRA100773B), the most common AEs (≥5%) reported in the Revolade™ 50 mg treatment group were headache, nasopharyngitis, nausea, fatigue, and arthralgia. Nausea was reported more frequently in the Revolade™ treatment group while headache and arthralgia were reported more frequently in the placebo treatment group. No dose-dependent patterns in the incidence or severity of AEs were noted across treatment groups. No apparent organ-specific toxicity profile emerged during comprehensive analyses of the pooled data.
In the 6-month RAISE study, the most common AEs observed in ≥10% of patients in the Revolade™ treatment group were headache, diarrhoea, nausea, nasopharyngitis, fatigue and upper respiratory tract infection. The rates for these AEs were similar in the placebo treatment group.
The incidence of SAEs (18% and 11%) and AEs leading to withdrawal (7% and 9%) was similar in both the Revolade™ treatment group and placebo treatment group. In addition, patients treated with Revolade™ had a significant reduction in bleeding AEs and in side-effects typically associated with corticosteroid use.
There were eight deaths reported across all studies: four occurred on-therapy, and four occurred between 42 days and 6 months after discontinuation of treatment with Revolade™. All eight deaths were unrelated to the study medication.
A safety issue raised in both the non-clinical and clinical program was the risk of developing liver toxicity during treatment with Revolade™. In the non-clinical studies, dogs showed increased liver enzymes and/or elevated bilirubin levels along with microscopic changes in the liver. In clinical studies, hepatobiliary laboratory abnormalities, such as increases in ALT, AST, and bilirubin serum levels were observed more frequently in ITP patients treated with Revolade™ compared to the placebo treatment group. Also, more hepatobiliary AEs were observed in the Revolade™ group compared to the placebo group. These findings were mostly mild (Grade 1-2), reversible and not accompanied by clinically significant symptoms that would indicate impaired liver function. Nonetheless, a cautionary statement has been inserted in the Product Monograph when administering Revolade™ to patients with moderate hepatic impairment; and Revolade™ is contraindicated for those patients with severe hepatic impairment.
Renal tubular toxicity was observed in a 2-year oral carcinogenicity study in mice at doses of 25, 75, and 150 mg/kg/day. The exposure at the lowest dose was 1.2 times the human clinical exposure based on AUC. Renal tubular toxicity however, was not observed in the placebo-controlled clinical studies. In addition, no cases of grade 3 or 4 creatinine elevations were observed within these clinical studies. However, based on these observations, a cautionary statement was inserted in the Product Monograph regarding administration of Revolade™ treatment to patients who are renally impaired. Given there is limited data with the use of Revolade™ in patients with severe renal impairment, treatment with Revolade™ is not recommended in these patients unless the expected benefit outweighs the risk.
A total of fourteen patients treated with Revolade™ experienced a thromboembolic event. These events were not associated with abnormally elevated platelet counts. In the placebo-controlled studies, there were four patients in the Revolade™ group who developed such events, compared to none in the placebo group. Therefore the following cautionary statement is included in the Product Monograph: "Caution should be used when administering Revolade™ to patients with known risk factors for thromboembolism including but not limited to inherited (e.g. Factor V Leiden) or acquired risk factors (e.g. ATIII deficiency, antiphospholipid syndrome), advanced age, patients with prolonged periods of immobilisation, malignancies, contraceptives and hormone replacement therapy, surgery/trauma, obesity and smoking."
Review of the safety data revealed no apparent evidence of clinically relevant bone marrow alterations or clinical findings in patients treated with Revolade™, based on the blood smear and bone marrow data available to date. Several patients had reticulin and/or collagen findings without any clinical signs or symptoms that would indicate bone marrow dysfunction.
Transient decreases in platelet counts following discontinuation or interruption of Revolade™ occurred in a minority of patients in both treatment arms, but generally they were not associated with clinically meaningful bleeding events. The incidence of post-therapy bleeding AEs within 4 weeks following discontinuation of therapy was similar or less in the Revolade™ group compared to the placebo group in all three double-blind studies.
In non-clinical studies, the formation of cataracts was observed in rodents at exposure levels similar to those achieved in humans. However, in the placebo-controlled studies conducted in humans there was no apparent increase in the incidence of cataracts with up to six months treatment. Despite this observation, routine monitoring of patients for possible cataract development has been recommended.
In the clinical studies, there was no confirmation of potential cardiotoxicity as seen in non-clinical studies. In addition, there were no meaningful differences in the safety profile of Revolade™ with regard to age, sex, and race with the exception of more hepatobiliary laboratory abnormalities in Asians compared to Caucasians.
During the clinical review, the sponsor was issued a Notice of Deficiency (NOD) based on the following safety concerns. The most robust safety data from controlled clinical trials spanned over a six month duration which did not provide sufficient time-course analysis in support of long-term treatment. In addition, no animal model could be used to adequately perform purposeful on-target toxicity studies. Furthermore, the following safety risks and concerns which included thrombotic/thromboembolic complications, bone marrow abnormalities or cytopenia(s), hepatotoxicity, hematologic malignancies (myelodysplastic syndrome), drug interactions, ophthalmologic risks, worsening thrombocytopenia upon discontinuation, unknown long-term risks (given only controlled studies that were ≤ 6 months in duration) required further delineation, characterization and management. It was also difficult to determine given the design of the pivotal trials, where Revolade™ treatment would optimally ‘best fit' in the ITP population (splenectomy vs non-splenectomy) and current strategies of care.
In response to these deficiencies, the following recommendations were made: To limit Revolade™ treatment for no more than one year of continuous therapy and closely monitor the risks and uncertainties, as outlined above, through implementation of a rigorous Risk Management Plan. In addition, given the benefit-risk balance was not able to be evaluated in patients who were non-splenectomized the risk profile could not be stated as positive for this patient population. Accordingly, the proposed indication in this patient population has been restricted to the use of Revolade™ treatment as a second-line alternative in non-splenectomized patients for whom splenectomy is contraindicated.
3.4 Benefit/Risk Assessment and Recommendation
3.4.1 Benefit/Risk Assessment
The efficacy of Revolade™ and its ability to increase platelet counts in patients with chronic ITP refractory to standard first-line treatments have been confirmed in the clinical program. No controlled studies longer than 6 months in duration have been submitted, and the limited open-label, long-term safety data submitted were considered insufficient to support long-term use beyond one year. The risk of bleeding in both pivotal trials, TRA100773B and RAISE, was greatly reduced with Revolade™ treatment.
Given Revolade's™ unique TPO receptor specificity, the non-clinical evaluation was limited to the monitoring of potential off-target adverse effects related to the pharmacology of Revolade™ in the general toxicology, reproductive toxicology, and carcinogenicity studies. In the absence of non-clinical models to study potential on-target effects, it is acknowledged that the toxicology program lacks the ability to fully evaluate the safety of Revolade™ through study of the exaggerated pharmacology. Therefore, compilation of safety pharmacology and toxicology data is limited. The most robust safety data for Revolade™ derived from controlled clinical trials is up to six months duration of treatment.
During the treatment with Revolade™ a number of risks and uncertainties have been identified which include: hepatobiliary laboratory abnormalities; thromboembolism events and post-therapy recurrence of thrombocytopenia; bone marrow reticulin formation; haematological malignancies; renal toxicity; phototoxicity; and cataracts. Due to the limited data in severely renally impaired patients (creatinine clearance <30 mL/min), a precautionary statement is included in the Product Monograph indicating that Revolade™ is not recommended for use in patients with severe renal impairment (creatinine clearance <30 mL/min), unless the expected benefit outweighs the risk. In addition, the safety signal for hepatoxicity and increased risk of thromboembolism would contraindicate the use of Revolade™ in those patients with severe hepatic impairment (Child-Pugh score ≥10).
In chronic ITP splenectomised patients who are refractory or relapsed to first-line treatments (e.g., corticosteroids, immunoglobulins), the benefits of Revolade™ treatment outweigh the risks with treatment not exceeding one year of continuous therapy. Beyond one year of continuous therapy the risk of adverse events, both known and unknown, were not evaluable and cannot be assured from the 6 month, controlled clinical trial data submitted.
In regards to those patients who were non-splenectomized, the benefit-risk balance was considered not evaluable based on the structural design of the studies submitted. The benefit from splenectomy as a treatment option was not studied in comparison to Revolade™ for these patients. Therefore, the risk profile cannot be stated as positive for this patient population. Accordingly, the indication proposed is to restrict the use of Revolade™ treatment as a second-line alternative in non-splenectomized patients for whom splenectomy is contraindicated.
The recommendation to limit Revolade™ therapy for not more than one year of continuous therapy is in response to the lack of on-target non-clinical data available, and the lack of controlled clinical trial data beyond 6 months in duration.
Furthermore, to address the numerous risks and uncertainties identified through the safety evaluation, ongoing safety data shall continue to be collected and be closely scrutinized through implementation of a rigorous Risk Management Plan.
Overall, the benefit to risk profile is favourable and supports the use of Revolade™ for the authorized indication.
3.4.2 Recommendation
Based on the Health Canada review of data on quality, safety and efficacy, Health Canada considers that the benefit/risk profile of Revolade™ is favourable in the treatment of adult chronic immune (idiopathic) thrombocytopenic purpura (ITP) to increase platelet counts in splenectomized patients who are refractory to first-line treatments (e.g., corticosteroids, immunoglobulins). Revolade™ may be considered as second line treatment for adult non-splenectomized patients where surgery is contraindicated. Revolade™ therapy should not exceed one year of continuous treatment. After one year of continuous treatment, therapeutic options should be reassessed. This New Drug Submission complies with the requirements of sections C.08.002 and C.08.005.1 and therefore Health Canada has granted the Notice of Compliance pursuant to section C.08.004 of the Food and Drug Regulations.
4 Submission Milestones
Submission Milestones: RevoladeTM
Submission Milestone | Date |
---|---|
Submission filed: | 2008-12-08 |
Screening 1 | |
Screening Acceptance Letter issued: | 2009-01-08 |
Review 1 | |
Quality Evaluation complete: | 2009-10-28 |
Clinical Evaluation complete: | 2009-10-28 |
Labelling Review complete: | 2009-10-28 |
Notice of Deficiency (NOD) issued by Director General (Safety issues): | 2009-10-29 |
Response filed: | 2010-01-27 |
Screening 2 | |
Screening Acceptance Letter issued: | 2010-03-18 |
Review 2 | |
Quality Evaluation complete: | 2011-01-11 |
Clinical Evaulation complete: | 2011-01-12 |
Labelling Review complete: | 2011-01-12 |
Notice of Compliance issued by Director General: | 2011-01-12 |
Related Drug Products
Product name | DIN | Company name | Active ingredient(s) & strength |
---|---|---|---|
REVOLADE | 02361833 | NOVARTIS PHARMACEUTICALS CANADA INC | ELTROMBOPAG (ELTROMBOPAG OLAMINE) 50 MG |
REVOLADE | 02361825 | NOVARTIS PHARMACEUTICALS CANADA INC | ELTROMBOPAG (ELTROMBOPAG OLAMINE) 25 MG |