Bosulif 50 mg Hard Capsules

Bosulif is indicated for the treatment of:

• Adult and paediatric patients aged 6 years and older with newly-diagnosed (ND) chronic phase (CP) Philadelphia chromosome-positive chronic myelogenous leukaemia (Ph+ CML).

• Adult and paediatric patients aged 6 years and older with CP Ph+ CML previously treated with one or more tyrosine kinase inhibitor(s) [TKI(s)] and for whom imatinib, nilotinib and dasatinib are not considered appropriate treatment options.

• Adult patients with accelerated phase (AP), and blast phase (BP) Ph+ CML previously treated with one or more tyrosine kinase inhibitor(s) [TKI(s)] and for whom imatinib, nilotinib and dasatinib are not considered appropriate treatment options.

Posology

Adult patients with newly-diagnosed CP Ph+ CML

The recommended dose is 400 mg bosutinib once daily.

Adult patients with CP, AP, or BP Ph+ CML with resistance or intolerance to prior therapy

The recommended dose is 500 mg bosutinib once daily.

In clinical studies for both indications, treatment with bosutinib continued until disease progression or intolerance to therapy.

Paediatric patients with newly-diagnosed CP Ph+ CML or with CP Ph+ CML with resistance or intolerance to prior therapy

The recommended dosage of bosutinib for newly-diagnosed paediatric patients is 300 mg/m² body surface area (BSA) orally once daily and the recommended dosage for paediatric patients resistant or intolerant (R/I) to prior therapies is 400 mg/m² BSA orally once daily; dose recommendations are provided in Table 1. As appropriate, the desired dose can be attained by combining different strengths of bosutinib film-coated tablets and/or hard capsules.

Table 1 – Dosing of bosutinib for paediatric patients with newly-diagnosed CP Ph+ CML or with CP Ph+ CML with resistance or intolerance to prior therapy

^* maximum starting dose (corresponding to maximum starting dose in adult indication)

Abbreviations: AP=accelerated phase; BP=blast phase; BSA=body surface area; CML=chronic myeloid leukaemia; CP=chronic phase; ND=newly‑diagnosed; Ph+=Philadelphia chromosome-positive; R/I=resistant or intolerant.

Dose adjustments

In adult patients with CML who are resistant or intolerant to prior therapy, doses can be escalated to 600 mg in those with unsatisfactory response or with signs of progression and in the absence of any Grade 3 or 4 or persistent Grade 2 adverse events.

In adult patients with newly-diagnosed CP CML, doses can be escalated by 100 mg increments to a maximum of 600 mg once daily if patients fail to demonstrate breakpoint cluster region Abelson (BCR-ABL) transcripts ≤ 10% at months 3 and do not have a grade 3 or 4 adverse reaction at the time of escalation and all Grade 2 non-haematological toxicities are resolved to at least Grade 1.

In paediatric patients with BSA < 1.1 m² and an insufficient response after 3 months consider increasing dose by 50 mg increments up to maximum of 100 mg above BSA-adjusted recommended dose. In paediatric patients with BSA ≥1.1 m² and an insufficient response after 3 months consider increasing dose similarly to adult recommendations in 100 mg increments. If there is inadequate clinical response and further dose escalation cannot be performed in paediatric patients, treatment will be stopped.

The maximum dose in paediatric patients is 600 mg once daily in previously treated CML and 500 mg once daily in newly-diagnosed CML.

Doses greater than 600 mg/day have not been studied and, therefore, should not be given.

Dose adjustments for adverse reactions

If clinically significant moderate or severe non-haematological toxicity develops, bosutinib should be interrupted, and may be resumed at a dose reduced by 100 mg taken once daily after the toxicity has resolved. If clinically appropriate, re‑escalation to the dose prior to the dose reduction taken once daily should be considered (see section 4.4). Doses less than 300 mg/day have been used in patients; however, efficacy has not been established.

Elevated liver transaminases

If elevations in liver transaminases > 5 × institutional upper limit of normal (ULN) occur, bosutinib should be interrupted until recovery to ≤ 2.5 × ULN and may be resumed at 400 mg once daily thereafter. If recovery takes longer than 4 weeks, discontinuation of bosutinib should be considered. If transaminase elevations ≥ 3 × ULN occur concurrently with bilirubin elevations > 2 × ULN and alkaline phosphatase < 2 × ULN, bosutinib should be discontinued (see section 4.4).

Diarrhoea

For NCI Common Terminology Criteria for Adverse Events (CTCAE) Grade 3‑4 diarrhoea, bosutinib should be interrupted and may be resumed at 400 mg once daily upon recovery to grade ≤ 1 (see section 4.4).

In paediatric patients, dose adjustments for non-haematologic toxicities can be conducted similarly to adults, however the dose reduction increments may differ. For paediatric patients with BSA < 1.1 m², consider dose reduction by 50 mg initially followed by additional 50 mg reductions if the adverse drug reaction (ADR) persists, in line with recommendations from Table 2. For paediatric patients with BSA ≥ 1.1 m² reduce dose similarly to adults.

Haematological adverse reactions

Dose reductions are recommended for severe or persistent neutropenia and thrombocytopenia as described in Table 2:

Table 2 – Dose adjustments for neutropenia and thrombocytopenia in adult and paediatric patients

^a ANC=absolute neutrophil count; BSA=body surface area

Missed dose

If a dose is missed by more than 12 hours, the patient should not be given an additional dose. The patient should take the usual prescribed dose on the following day.

Special populations

Elderly patients (≥ 65 years)

No specific dose recommendation is necessary in the elderly. Since there is limited information in the elderly, caution should be exercised in these patients.

Renal impairment

Patients with serum creatinine > 1.5×ULN were excluded from CML studies. Increasing exposure (area under curve [AUC]) in patients with moderate and severe renal impairment during studies was observed.

Newly‑diagnosed CP Ph+ CML

In adult patients with moderate renal impairment (creatinine clearance [CL_Cr] 30 to 50 mL/min, estimated by the Cockcroft‑Gault formula), the recommended dose of bosutinib is 300 mg daily with food (see sections 4.4 and 5.2).

In adult patients with severe renal impairment (CL_Cr < 30 mL/min, estimated by the Cockcroft-Gault formula), the recommended dose of bosutinib is 200 mg daily with food (see sections 4.4 and 5.2).

Dose escalation to 400 mg once daily with food for adult patients with moderate renal impairment or to 300 mg once daily for patients with severe renal impairment may be considered if they do not experience severe or persistent moderate adverse reactions and if they do not achieve an adequate haematological, cytogenetic, or molecular response.

CP, AP, or BP Ph+ CML with resistance or intolerance to prior therapy

In adult patients with moderate renal impairment (CL_Cr 30 to 50 mL/min, calculated by the Cockcroft‑Gault formula), the recommended dose of bosutinib is 400 mg daily (see sections 4.4 and 5.2).

In patients with severe renal impairment (CL_Cr < 30 mL/min, calculated by the Cockcroft‑Gault formula), the recommended dose of bosutinib is 300 mg daily (see sections 4.4 and 5.2).

Dose escalation to 500 mg once daily for adult patients with moderate renal impairment or to 400 mg once daily in patients with severe renal impairment may be considered in those who did not experience severe or persistent moderate adverse reactions, and if they do not achieve an adequate haematological, cytogenetic, or molecular response.

Cardiac disorders

In clinical studies, patients with uncontrolled or significant cardiac disease (e.g., recent myocardial infarction, congestive heart failure or unstable angina) were excluded. Caution should be exercised in patients with relevant cardiac disorders (see section 4.4).

Recent or ongoing clinically significant gastrointestinal disorder

In clinical studies, patients with recent or ongoing clinically significant gastrointestinal disorder (e.g., severe vomiting and/or diarrhoea) were excluded. Caution should be exercised in patients with recent or ongoing clinically significant gastrointestinal disorder (see section 4.4).

Paediatric population

The safety and efficacy of bosutinib in paediatric patients below the age of 1 year with newly‑diagnosed, or resistant or intolerant Ph+ CML in CP have not been established. No data are available. The information from paediatric patients below the age of 6 years are too limited so that no dose recommendations can be made (see section 5.1).

Method of administration

Bosulif should be taken orally once daily with food (see section 5.2).

The hard capsules may be swallowed whole. For patients who are unable to swallow a whole hard capsule(s), each hard capsule can be opened and the contents mixed with applesauce or yogurt. Mixing the hard capsule contents with applesauce or yogurt is no substitute of a proper meal, the dose should be taken with food to increase gastrointestinal tolerability.

If mixing with applesauce or yogurt, patients should immediately consume the full mixture in its entirety, without chewing. The mixture should not be stored for later use. If the entire preparation is not swallowed, an additional dose should not be administered, and it is advised to wait until the next day to resume dosing. In order to facilitate the administration, the recommended volume of applesauce or yogurt is provided in Table 3.

Table 3 – Bosutinib dose using hard capsules and soft food volumes

Hypersensitivity to the active substance or to any of the excipients listed in section 6.1.

Hepatic impairment (see sections 5.1 and 5.2).

Liver function abnormalities

Treatment with bosutinib in adult and paediatric patients is associated with elevations in serum transaminases (alanine aminotransferase [ALT], aspartate aminotransferase [AST]).

Transaminase elevations generally occurred early in the course of treatment (of the patients who experienced transaminase elevations of any grade, > 80% experienced their first event within the first 3 months). Patients receiving bosutinib should have liver function tests prior to treatment initiation and monthly for the first 3 months of treatment, and as clinically indicated.

Patients with transaminase elevations should be managed by withholding bosutinib temporarily (with consideration given to dose reduction after recovery to Grade 1 or baseline), and/or discontinuation of bosutinib. Elevations of transaminases, particularly in the setting of concomitant increases in bilirubin, may be an early indication of drug-induced liver injury and these patients should be managed appropriately (see sections 4.2 and 4.8).

Diarrhoea and vomiting

Treatment with bosutinib in adult and paediatric patients is associated with diarrhoea and vomiting; therefore, patients with recent or ongoing clinically significant gastrointestinal disorder should use this medicinal product with caution and only after a careful benefit-risk assessment as respective patients were excluded from the clinical studies. Patients with diarrhoea and vomiting should be managed using standard-of-care treatment, including an antidiarrhoeal or antiemetic medicinal product and/or fluid replacement. In addition, diarrhoea and vomiting can also be managed by withholding bosutinib temporarily, dose reduction, and/or discontinuation of bosutinib (see sections 4.2 and 4.8). The antiemetic agent, domperidone, has the potential to increase QT interval (QTc) prolongation and to induce “torsade de pointes”- arrhythmias; therefore, co-administration with domperidone should be avoided. It should only be used, if other medicinal products are not efficacious. In these situations an individual benefit-risk assessment is mandatory and patients should be monitored for occurrence of QTc prolongation.

Myelosuppression

Treatment with bosutinib in adult and paediatric patients is associated with myelosuppression, defined as anaemia, neutropenia, and thrombocytopenia. Complete blood counts should be performed weekly for the first month and then monthly thereafter, or as clinically indicated. Myelosuppression should/can be managed by withholding bosutinib temporarily, dose reduction, and/or discontinuation of bosutinib (see sections 4.2 and 4.8).

Fluid retention

Treatment with bosutinib in adult patients may be associated with fluid retention including pericardial effusion, pleural effusion, pulmonary oedema and/or peripheral oedema. Treatment with bosutinib in paediatric patients may be associated with low-grade pericardial effusion and peripheral oedema.

Patients should be monitored and managed using standard‑of‑care treatment.

In addition, fluid retention can also be managed by withholding bosutinib temporarily, dose reduction, and/or discontinuation of bosutinib (see sections 4.2 and 4.8).

Serum lipase

Elevation in serum lipase has been observed. Caution is recommended in patients with previous history of pancreatitis. In case lipase elevations are accompanied by abdominal symptoms, bosutinib should be interrupted and appropriate diagnostic measures considered to exclude pancreatitis (see section 4.2).

Infections

Bosutinib may predispose patients to bacterial, fungal, viral, or protozoan infections.

Cardiovascular toxicity

Bosulif can cause cardiovascular toxicity including cardiac failure and cardiac ischaemic events. Cardiac failure events occurred more frequently in previously treated patients than in patients with newly-diagnosed CML and were more frequent in patients with advanced age or risk factors, including previous medical history of cardiac failure. Cardiac ischaemic events occurred in both previously treated patients and in patients with newly-diagnosed CML and were more common in patients with coronary artery disease risk factors, including history of diabetes, body mass index greater than 30, hypertension and vascular disorders.

Patients should be monitored for signs and symptoms consistent with cardiac failure and cardiac ischaemia and treated as clinically indicated. Cardiovascular toxicity can also be managed by dose interruption, dose reduction and/or discontinuation of bosutinib.

Proarrhythmic potential

Automated machine-read QTc prolongation without accompanying arrhythmia has been observed. Bosutinib should be administered with caution to patients who have a history of or predisposition for QTc prolongation, who have uncontrolled or significant cardiac disease including recent myocardial infarction, congestive heart failure, unstable angina or clinically significant bradycardia, or who are taking medicinal products that are known to prolong the QTc (e.g., anti-arrhythmic medicinal products and other substances that may prolong QTc [see section 4.5]). The presence of hypokalaemia and hypomagnesaemia may further enhance this effect.

Monitoring for an effect on the QTc is advisable and a baseline electrocardiogram (ECG) is recommended prior to initiating therapy with bosutinib and as clinically indicated. Hypokalaemia or hypomagnesaemia must be corrected prior to bosutinib administration and should be monitored periodically during therapy.

Renal impairment

Treatment with bosutinib may result in a clinically significant decline in renal function in CML adult and paediatric patients. A decline over time in estimated glomerular filtration rate (eGFR) has been observed in patients treated with bosutinib in clinical studies (see section 4.8).

It is important that renal function is assessed prior to treatment initiation and closely monitored during therapy with bosutinib, with particular attention in those patients who have preexisting renal compromise or in those patients exhibiting risk factors for renal dysfunction, including concomitant use of medicinal products with potential for nephrotoxicity, such as diuretics, angiotensin-converting enzyme (ACE) inhibitors, angiotensin receptor blockers, and nonsteroidal anti-inflammatory drugs (NSAIDs).

In a renal impairment study, bosutinib exposures were increased in subjects with moderately and severely impaired renal function. Dose reduction is recommended for patients with moderate or severe renal impairment (see sections 4.2 and 5.2).

Patients with serum creatinine > 1.5 × ULN were excluded from the CML studies. (see sections 4.2 and 5.2).

Clinical data are very limited (n=3) for CML patients with moderate renal impairment receiving an escalated dose of 600 mg bosutinib.

Asian race

According to population pharmacokinetic analyses, Asians had a lower clearance resulting in increased exposure. Therefore, these patients should be closely monitored for adverse reactions especially in case of dose escalation.

Severe skin reactions

Bosutinib can induce severe skin reactions such as Stevens‑Johnson Syndrome and Toxic Epidermal Necrolysis. Bosutinib should be permanently discontinued in patients who experience a severe skin reaction during treatment.

Tumour lysis syndrome

Due to the possible occurrence of tumour lysis syndrome (TLS), correction of clinically significant dehydration and treatment of high uric acid levels are recommended prior to initiation of bosutinib (see section 4.8).

Hepatitis B reactivation

Reactivation of hepatitis B (HBV) in patients who are chronic carriers of this virus has occurred after these patients received BCR‑ABL TKIs. Some cases resulted in acute hepatic failure or fulminant hepatitis leading to liver transplantation or a fatal outcome.

Patients should be tested for HBV infection before initiating treatment with bosutinib. Experts in liver disease and in the treatment of HBV should be consulted before treatment is initiated in patients with positive HBV serology (including those with active disease) and for patients who test positive for HBV infection during treatment. Carriers of HBV who require treatment with bosutinib should be closely monitored for signs and symptoms of active HBV infection throughout therapy and for several months following termination of therapy (see section 4.8).

Photosensitivity

Exposure to direct sunlight or ultraviolet (UV) radiation should be avoided or minimised due to the risk of photosensitivity associated with bosutinib treatment. Patients should be instructed to use measures such as protective clothing and sunscreen with high sun protection factor (SPF).

Cytochrome P‑450 (CYP)3A inhibitors

The concomitant use of bosutinib with strong or moderate CYP3A inhibitors should be avoided, as an increase in bosutinib plasma concentration will occur (see section 4.5).

Selection of an alternate concomitant medicinal product with no or minimal CYP3A inhibition potential, if possible, is recommended.

If a strong or moderate CYP3A inhibitor must be administered during bosutinib treatment, an interruption of bosutinib therapy or a dose reduction in bosutinib should be considered.

CYP3A inducers

The concomitant use of bosutinib with strong or moderate CYP3A inducers should be avoided as a decrease in bosutinib plasma concentration will occur (see section 4.5).

Food effect

Grapefruit products, including grapefruit juice and other foods that are known to inhibit CYP3A should be avoided (see section 4.5).

Sodium

This medicinal product contains less than 1 mmol sodium (23 mg) per 50 mg hard capsules. Patients on low sodium diets should be informed that this product is essentially 'sodium-free'.

Effects of other medicinal products on bosutinib

CYP3A inhibitors

The concomitant use of bosutinib with strong CYP3A inhibitors (including, but not limited to itraconazole, ketoconazole, posaconazole, voriconazole, clarithromycin, telithromycin, nefazodone, mibefradil, indinavir, lopinavir/ritonavir, nelfinavir, ritonavir, saquinavir, boceprevir, telaprevir, grapefruit products including grapefruit juice) or moderate CYP3A inhibitors (including, but not limited to fluconazole, ciprofloxacin, erythromycin, diltiazem, verapamil, amprenavir, atazanavir, darunavir/ritonavir, fosamprenavir, aprepitant, crizotinib, imatinib) should be avoided, as an increase in bosutinib plasma concentration will occur.

Caution should be exercised if mild CYP3A inhibitors are used concomitantly with bosutinib.

Selection of an alternate concomitant medicinal product with no or minimal CYP3A enzyme inhibition potential, if possible, is recommended.

If a strong or moderate CYP3A inhibitor must be administered during bosutinib treatment, an interruption of bosutinib therapy or a dose reduction in bosutinib should be considered.

In a study of 24 healthy subjects in whom 5 daily doses of 400 mg ketoconazole (a strong CYP3A inhibitor) were co‑administered with a single dose of 100 mg bosutinib under fasting conditions, ketoconazole increased bosutinib C_max by 5.2‑fold, and bosutinib AUC in plasma by 8.6‑fold, as compared with administration of bosutinib alone.

In a study of 20 healthy subjects, in whom a single dose of 125 mg aprepitant (a moderate CYP3A inhibitor) was co-administered with a single dose of 500 mg bosutinib under fed conditions, aprepitant increased bosutinib C_max by 1.5‑fold, and bosutinib AUC in plasma by 2.0‑fold, as compared with administration of bosutinib alone.

CYP3A inducers

The concomitant use of bosutinib with strong CYP3A inducers (including, but not limited to carbamazepine, phenytoin, rifampicin, St. John's Wort), or moderate CYP3A inducers (including, but not limited to bosentan, efavirenz, etravirine, modafinil, nafcillin) should be avoided, as a decrease in bosutinib plasma concentration will occur.

Based on the large reduction in bosutinib exposure that occurred when bosutinib was co‑administered with rifampicin, increasing the dose of bosutinib when co‑administering with strong or moderate CYP3A inducers is unlikely to sufficiently compensate for the loss of exposure.

Caution is warranted if mild CYP3A inducers are used concomitantly with bosutinib.

Following concomitant administration of a single dose bosutinib with 6 daily doses of 600 mg rifampicin, in 24 healthy subjects in fed state bosutinib exposure (C_max and AUC in plasma) decreased to 14% and 6%, respectively, of the values when bosutinib 500 mg was administered alone.

Proton pump inhibitors (PPIs)

Caution should be exercised when administering bosutinib concomitantly with PPIs. Short‑acting antacids should be considered as an alternative to PPIs and administration times of bosutinib and antacids should be separated (i.e. take bosutinib in the morning and antacids in the evening) whenever possible. Bosutinib displays pH‑dependent aqueous solubility in vitro. When a single oral dose of bosutinib (400 mg) was co‑administered with multiple‑oral doses of lansoprazole (60 mg) in a study of 24 healthy fasting subjects, bosutinib C_max and AUC decreased to 54% and 74%, respectively, of the values seen when bosutinib (400 mg) was given alone.

Effects of bosutinib on other medicinal products

In a study of 27 healthy subjects, in whom a single dose of 500 mg bosutinib was co‑administered with a single dose of 150 mg dabigatran etexilate mesylate (a P‑glycoprotein [P‑gp] substrate) under fed conditions, bosutinib did not increase C_max or AUC of dabigatran in plasma, as compared with administration of dabigatran etexilate mesylate alone. The study results indicate that bosutinib does not exhibit clinically relevant P‑gp inhibitory effects.

An in vitro study indicates that drug‑drug interactions are unlikely to occur at therapeutic doses as a result of induction by bosutinib on the metabolism of medicinal products that are substrates for CYP1A2, CYP2B6, CYP2C9, CYP2C19, and CYP3A4.

In vitro studies indicate that clinical drug‑drug interactions are unlikely to occur at therapeutic doses as a result of inhibition by bosutinib on the metabolism of medicinal products that are substrates for CYP1A2, CYP2A6, CYP2C8, CYP2C9, CYP2C19, CYP2D6, or CYP3A4/5.

In vitro studies indicate that bosutinib has a low potential to inhibit breast cancer resistance protein (BCRP, systemically), organic anion transporting polypeptide (OATP)1B1, OATP1B3, organic anion transporter (OAT)1, OAT3, organic cation transporter (OCT)2 at clinically relevant concentrations, but may have the potential to inhibit BCRP in the gastrointestinal tract and OCT1.

Anti‑arrhythmic medicinal products and other substances that may prolong QT

Bosutinib should be used with caution in patients who have or may develop prolongation of QT, including those patients taking anti-arrhythmic medicinal products such as amiodarone, disopyramide, procainamide, quinidine and sotalol or other medicinal products that may lead to QT prolongation such as chloroquine, halofantrine, clarithromycin, domperidone, haloperidol, methadone, and moxifloxacin (see section 4.4).

Women of childbearing potential/contraception

Women of childbearing potential should be advised to use effective contraception during treatment with bosutinib and for at least 1 month after the last dose and to avoid becoming pregnant while receiving bosutinib. In addition, the patient should be advised that vomiting or diarrhoea may reduce the efficacy of oral contraceptives by preventing full absorption.

Pregnancy

There are limited amount of data in pregnant women from the use of bosutinib. Studies in animals have shown reproductive toxicity (see section 5.3). Bosutinib is not recommended for use during pregnancy, or in women of childbearing potential not using contraception. If bosutinib is used during pregnancy, or the patient becomes pregnant while taking bosutinib, she should be apprised of the potential hazard to the foetus.

Breast‑feeding

It is unknown whether bosutinib and its metabolites are excreted in human milk. A study of [¹⁴C] radiolabelled bosutinib in rats demonstrated excretion of bosutinib-derived radioactivity in breast milk (see section 5.3). A potential risk to the breast‑feeding infant cannot be excluded. Breast‑feeding should be discontinued during treatment with bosutinib.

Fertility

Based on non‑clinical findings, bosutinib has the potential to impair reproductive function and fertility in humans (see section 5.3). Men being treated with bosutinib are advised to seek advice on conservation of sperm prior to treatment because of the possibility of decreased fertility due to therapy with bosutinib.

Bosutinib has no or negligible influence on the ability to drive and use machines. However, if a patient taking bosutinib experiences dizziness, fatigue, visual impairment or other undesirable effects with a potential impact on the ability to drive or use machines safely, the patient should refrain from these activities for as long as the undesirable effects persist.

Summary of safety profile

A total of 1372 leukaemia adult patients received at least 1 dose of single‑agent bosutinib. The median duration of therapy was 26.30 months (range: 0.03 to 170.49 months). These patients were either newly‑diagnosed, with CP CML or were resistant or intolerant to prior therapy with chronic, accelerated, or blast phase CML or Ph+ acute lymphoblastic leukaemia (ALL). The safety analyses included data from a completed extension study.

At least 1 adverse reaction of any toxicity grade was reported for 1,349 (98.3%) patients. The most frequent adverse reactions reported for ≥ 20% of patients were diarrhoea (80.4%), nausea (41.5%), abdominal pain (35.6%), thrombocytopenia (34.4%), vomiting (33.7%), rash (32.8%), ALT increased (28.0%), anaemia (27.2%), pyrexia (23.4%), AST increased (22.5%), fatigue (32.0%), and headache (20.3%). At least 1 Grade 3 or Grade 4 adverse reaction was reported for 943 (68.7%) patients. The Grade 3 or Grade 4 adverse reactions reported for ≥ 5% of patients were thrombocytopenia (19.7%), ALT increased (14.6%), neutropenia (10.6%), diarrhoea (10.6%), anaemia (10.3%), lipase increased (10.1%), AST increased (6.7%), and rash (5.0%).

Tabulated list of adverse reactions

These adverse reactions are presented by system organ class and frequency. Frequency categories are defined as: very common (≥ 1/10), common (≥ 1/100 to < 1/10), uncommon (≥ 1/1 000 to < 1/100), rare (≥ 1/10 000 to < 1/1 000), very rare (< 1/10 000), not known (cannot be estimated from the available data). Within each frequency grouping, adverse reactions are presented in order of decreasing seriousness.

Paediatric populations

A total of 55 paediatric patients ≥ 1 year of age received at least 1 dose of bosutinib in the Phase I/II, multicentre, international, single-arm, open-label BCHILD study. The median duration of treatment was 13.5 months (range: 0.2 to 60.9 months). These patients were either newly-diagnosed CP Ph+ CML or resistant or intolerant Ph+ CML-CP and CML-AP.

At least 1 adverse reaction of any toxicity grade was reported for 54 (98.2%) paediatric patients. The most frequent adverse reactions reported were diarrhoea (82%), abdominal pain (65%), vomiting (56%), nausea (51%), rash (36%), fatigue (35%), thrombocytopenia (35%), headache (33%), pyrexia (33%), ALT increased (29%), and decreased appetite (24%).

The most frequent Grade 3 or Grade 4 adverse reactions reported were thrombocytopenia (18%), ALT increased (15%) and diarrhoea (13%).

Blood and lymphatic system disorders

Blood and lymphatic events in 55 paediatric patients in the BCHILD study include thrombocytopenia in 19 (34.5%) patients, anaemia in 10 patients (18.2%), and neutropenia in 7 patients (12.7%). One patient discontinued treatment due to Grade 4 neutropenia. Among patients with blood and lymphatic events, 37.5% were managed with treatment interruption and 16.7% required dose reduction. Among patients with dose interruptions, none had a positive rechallenge when bosutinib was restarted. The median time to first event was 13 days (range: 1 to 757 days) and the median cumulative duration of grade 3/4 events was 16.0 (range: 4 to 47) days.

Hepatobiliary disorders

Of the 55 participants, the incidence based on laboratory data of ALT and AST increased was 67.3% and 63.6%, respectively and 43 (78.2% participants experienced an increase in either ALT or AST). Most cases of transaminase elevation occurred early in treatment; of participants who experienced transaminase elevations of any grade, 83.7% experienced their first event within 3 months. The median time to onset of ALT and AST increased was 22.0 days (range: 9 to 847 days) and 18.5 days (range: 9 to 169 days), respectively. The median duration of Grade 3/4 events was 18.0 days (range: 2 to 132 days) and 12 days (range: 5 to 19 days) for ALT and AST increased, respectively.

Gastrointestinal disorders

Gastrointestinal disorders of diarrhoea, vomiting and nausea occurred in 81.8%, 56.4%, and 50.9% of the 55 paediatric patients treated with bosutinib in the BCHILD study, respectively. Three (5.5%) patients discontinued bosutinib treatment due to diarrhoea (n=3), abdominal pain (n=2), nausea (n=1) and/or vomiting (n=1). Among paediatric patients with gastrointestinal disorders, 9 (19%) were managed with treatment interruption and 4 (8.3%) required dose reduction. Among the 9 patients who required a treatment interruption, 8 (88.9%) were rechallenged. Of these, 55.6% were successfully rechallenged. The median time to onset for diarrhoea was 2 days and the median duration of any grade diarrhoea was 2 days.

Renal disorders

In the paediatric study, 45 (82%) of the total 55 patients had normal eGFR (≥ 90 mL/min/1.73 m² estimated by Bedside Schwartz Equation) at baseline. Among these 45 patients, 19 (34.5%) experienced a decline in eGFR to Grade 1 (60 < 90 mL/min/1.73 m²) and 1 (1.8%) patient to Grade 2 (30 < 60 mL/min/1.73 m²) at 13.47 months. No participant had a post‑baseline eGFR < 45 mL/min/1.73 m² regardless of baseline values.

Description of selected adverse reactions

Blood and lymphatic system disorders

Of the 372 (27.1%) adult patients with reports of adverse reactions of anaemia, 6 patients discontinued bosutinib due to anaemia. Maximum toxicity of Grade 1 occurred in 95 (25.5%) patients, Grade 2 in 135 (36.3%) patients, Grade 3 in 113 patients (30.4%), and Grade 4 in 29 (7.8%) patients. Among these patients, the median time to first event was 29 days (range: 1 to 3 999 days) and the median duration per event was 22 days (range: 1 to 3 682 days).

Of the 209 (15.2%) adult patients with reports of adverse reactions of neutropenia, 19 patients discontinued bosutinib due to neutropenia. Maximum toxicity of Grade 1 occurred in 19 patients (9.1%), Grade 2 in 45 (21.5%) patients, Grade 3 in 95 (45.5%) patients, and Grade 4 in 50 (23.9%) patients. Among these patients, the median time to first event was 56 days (range: 1 to 1 769 days), and the median duration per event was 15 days (range: 1 to 913 days).

Of the 472 (34.4%) adult patients with reports of adverse reactions of thrombocytopenia, 42 patients discontinued bosutinib due to thrombocytopenia. Maximum toxicity of Grade 1 occurred in 114 (24.2%) patients, Grade 2 in 88 (18.6%) patients, Grade 3 in 172 (36.4%) patients, and Grade 4 in 98 (20.8%) patients. Among these patients, the median time to first event was 28 days (range: 1 to 1 688 days), and median duration per event was 15 days (range: 1 to 3 921 days).

Hepatobiliary disorders

Among adult patients with reports of adverse reactions of elevations in either ALT or AST (all grades), the median time of onset observed was 29 days with a range of onset 1 to 3 995 days for ALT and AST. The median duration of an event was 17 days (range: 1 to 1 148 days), and 15 days (range: 1 to 803 days) for ALT and AST, respectively.

Two cases consistent with drug‑induced liver injury (defined as concurrent elevations in ALT or AST ≥ 3 × ULN with total bilirubin > 2 × ULN and with alkaline phosphatase < 2 × ULN) without alternative causes have occurred in 2/1 711 (0.1%) adult subjects treated with bosutinib.

Hepatitis B reactivation

Hepatitis B reactivation has been reported in association with BCR‑ABL TKIs. Some cases resulted in acute hepatic failure or fulminant hepatitis leading to liver transplantation or a fatal outcome (see section 4.4).

Gastrointestinal disorders

Of the 1 103 (80.4%) patients that experienced diarrhoea, 14 patients discontinued bosutinib due to this event. Concomitant medicinal products were given to treat diarrhoea in 756 (68.5%) patients. Maximum toxicity of Grade 1 occurred in 575 (52.1%) patients, Grade 2 in 383 (34.7%) patients, Grade 3 in 144 (13.1%) patients; 1 patient (0.1%) experienced a Grade 4 event. Among patients with diarrhoea, the median time to first event was 2 days (range: 1 to 2 702 days) and the median duration of any grade of diarrhoea was 2 days (range: 1 to 4 247 days).

Among the 1 103 patients with diarrhoea, 218 patients (19.8%) were managed with treatment interruption and of these 208 (95.4%) were rechallenged with bosutinib. Of those who were rechallenged, 201 (96.6%) did not have a subsequent event or did not discontinue bosutinib due to a subsequent event of diarrhoea.

Cardiac disorders

Among 1372 patients, cardiac failure occurred in 50 (3.6%) patients and cardiac ischaemic events in 57 (4.2%) patients.

Seven patients (0.5%) experienced QTcF prolongation (greater than 500 ms). Eleven (0.8%) patients experienced QTcF increase > 60 ms from baseline. Patients with uncontrolled or significant cardiovascular disease including QTc prolongation, at baseline, were not included in clinical studies (see sections 5.1 and 5.3).

Renal disorders

In patients with newly-diagnosed‑ CP CML treated with 400 mg, the median decline from baseline in eGFR (estimated by MDRD Equation) was 11.1 mL/min/1.73 m² at 1 year and 14.1 mL/min/1.73 m² at 5 years for patients on_‑treatment. Treatment-naïve CML patients treated with 500 mg showed a median eGFR decline of 9.2 mL/min/1.73 m² at 1 year, 12.0 mL/min/1.73 m² at 5 years and 16.6 mL/min/1.73 m² at 10 years for patients on-treatment. In pre‑treated patients with CP and advanced stage CML treated with 500 mg the median eGFR decline was 7.6 mL/min/1.73 m² at 1 year, 12.3 mL/min/1.73 m² at 5 years and 15.9 mL/min/1.73 m² at 10 years for patients on-treatment. In patients with Ph+ CML previously treated with 1 or more TKI(s) treated with 500 mg, the median eGFR decline from baseline was 9.2 mL/min/1.73 m² at 1 year and 14.5 mL/min/1.73 m² at 4 years for patients on-treatment.

Reporting of suspected adverse reactions

If you get any side effects, talk to your doctor, pharmacist or nurse. This includes any possible side effects not listed in this leaflet. You can also report side effects directly via the Yellow Card Scheme at: www.mhra.gov.uk/yellowcard or search for MHRA Yellow Card in the Google Play or Apple App Store. By reporting side effects you can help provide more information on the safety of this medicine.

Experience with bosutinib overdose in clinical studies was limited to isolated cases. Patients who take an overdose of bosutinib should be observed and given appropriate supportive treatment.

Pharmacotherapeutic group: Antineoplastic agents, protein kinase inhibitors, ATC code: L01EA04.

Mechanism of action

Bosutinib belongs to a pharmacological class of medicinal products known as kinase inhibitors. Bosutinib inhibits the abnormal BCR‑ABL kinase that promotes CML. Modelling studies indicate that bosutinib binds the kinase domain of BCR‑ABL. Bosutinib is also an inhibitor of Src family kinases including Src, Lyn and Hck. Bosutinib minimally inhibits platelet‑derived growth factor (PDGF) receptor and c‑Kit.

In in vitro studies, bosutinib inhibits proliferation and survival of established CML cell lines, Ph+ ALL cell lines, and patient-derived primary primitive CML cells. Bosutinib inhibited 16 of 18 imatinib‑resistant forms of BCR‑ABL expressed in murine myeloid cell lines. Bosutinib treatment reduced the size of CML tumours growing in nude mice and inhibited growth of murine myeloid tumours expressing imatinib‑resistant forms of BCR‑ABL. Bosutinib also inhibits receptor tyrosine kinases c‑Fms, EphA and B receptors, Trk family kinases, Axl family kinases, Tec family kinases, some members of the ErbB family, the non‑receptor tyrosine kinase Csk, serine/threonine kinases of the Ste20 family, and 2 calmodulin‑dependent protein kinases.

Pharmacodynamic effects

The effect of bosutinib 500 mg administration on corrected QTc was evaluated in a randomised, single‑dose, double‑blind (with respect to bosutinib), crossover, placebo‑ and open‑label moxifloxacin‑controlled study in healthy subjects.

The data from this study indicate that bosutinib does not prolong the QTc in healthy subjects at the dose of 500 mg daily with food, and under conditions that give rise to supratherapeutic plasma concentrations. Following administration of a single oral dose of bosutinib 500 mg (therapeutic dose) and bosutinib 500 mg with ketoconazole 400 mg (to achieve supratherapeutic concentrations of bosutinib) in healthy subjects, the upper bound of the 1‑sided 95% confidence interval (CI) around the mean change in QTc was less than 10 ms at all post‑dose time points, and no adverse events suggestive of QTc prolongation were observed.

In a study in liver impaired subjects, an increasing frequency of QTc prolongation > 450 ms with declining hepatic function was observed. In the Phase 1/2 clinical study in patients with previously treated Ph+ leukaemias treated with bosutinib 500 mg, QTcF increase > 60 ms from baseline was observed in 9 (1.6%) of 570 patients. In the Phase 3 clinical study in patients with newly‑diagnosed CP CML treated with bosutinib 400 mg, there were no patients in the bosutinib treatment group (N=268) with a QTcF increase of > 60 ms from baseline. In the Phase 3 clinical study in patients with newly‑diagnosed Ph+ CP CML treated with bosutinib 500 mg, QTcF increase > 60 ms from baseline was observed in 2 (0.8%) of 248 patients receiving bosutinib. In the Phase 4 clinical study in patients with Ph+ CML previously treated with 1 or more TKI(s) treated with bosutinib 500 mg (N=163), there were no patients with a QTcF increase > 60 ms from baseline. A proarrhythmic potential of bosutinib cannot be ruled out.

Clinical efficacy

Clinical study in CP previously untreated CML in adult patients

Bosutinib 400 mg study

A 2‑arm, Phase 3, open‑label, multicentre superiority trial was conducted to investigate the efficacy and safety of bosutinib 400 mg once daily alone compared with imatinib 400 mg once daily alone in adult patients with newly‑diagnosed Ph+ CP CML. The trial randomised 536 patients (268 in each treatment group) with Ph+ or Ph‑ newly‑diagnosed CP CML (intent‑to‑treat population [ITT]) including 487 patients with Ph+ CML harbouring b2a2 and/or b3a2 transcripts and baseline BCR‑ABL copies > 0 (modified intent‑to‑treat [mITT] population).

The primary efficacy endpoint was the proportion demonstrating a major molecular response (MMR) at 12 months (48 weeks) in the bosutinib treatment group compared with that in the imatinib treatment group in the mITT population. MMR was defined as ≤ 0.1% BCR‑ABL/ABL ratio by international scale (corresponding to ≥ 3 log reduction from standardised baseline) with a minimum of 3 000 ABL transcripts as assessed by the central laboratory.

Key secondary endpoints included complete cytogenetic response (CCyR) by 12 months, duration of CCyR, duration of MMR, event‑free survival (EFS), and overall survival (OS). CCyR by Month 12, was defined as the absence of Ph+ metaphases in chromosome banding analysis of ≥ 20 metaphases derived from bone marrow aspirate or MMR if an adequate cytogenetic assessment was unavailable. The p‑values for endpoints other than MMR at 12 months and CCyR by 12 months have not been adjusted for multiple comparisons.

Baseline characteristics for the mITT population were well balanced between the 2 treatment groups with respect to age (median age was 52 years for the bosutinib group and 53 years for the imatinib group with 19.5% and 17.4% of patients 65 years of age or older, respectively); gender (women 42.3% and 44.0%, respectively); race (Caucasian 78.0% and 77.6%, Asian 12.2% and 12.4%, Black or African American 4.1% and 4.1%, and Other 5.7% and 5.4%, respectively, and 1 unknown in the imatinib group); and Sokal risk score (low risk 35.0% and 39.4%, intermediate risk 43.5% and 38.2%, high risk 21.5% and 22.4%, respectively).

After 60 months of follow-up in the mITT population, 60.2% of patients treated with bosutinib (N=246) and 59.8% of patients treated with imatinib (N=239) were still receiving first-line treatment.

After 60 months of follow‑up in the mITT population, discontinuations due to disease progression to AP or BP CML for bosutinib‑treated patients were 0.8% compared to 1.7% for imatinib‑treated patients. Six (2.4%) bosutinib patients and 7 (2.9%) imatinib patients transformed to AP CML or BP CML. Discontinuations due to suboptimal response or treatment failure as assessed by the investigator occurred for 5.3% of patients in the bosutinib‑treated group compared to 15.5% of patients in the imatinib‑treated group. Twelve (4.9%) patients on bosutinib and 14 (5.8%) patients on imatinib died while on study. No additional transformations occurred in the ITT population, there were 2 additional deaths in the bosutinib arm in the ITT population.

The efficacy results of MMR and CCyR are summarised in Table 5.

Table 5 - Summary of MMR at Months 12 and 18 and CCyR by Month 12, by treatment group in the mITT population

Note: MMR was defined as ≤ 0.1% BCR-ABL/ABL ratio by international scale (corresponding to ≥ 3 log reduction from standardised baseline) with a minimum of 3 000 ABL transcripts assessed by the central laboratory. Complete cytogenetic response was defined as the absence of Ph+ metaphases in chromosome banding analysis of ≥ 20 metaphases derived from bone marrow aspirate or MMR if an adequate cytogenetic assessment was unavailable.

Abbreviations: BCR-ABL=breakpoint cluster region‑Abelson; CI=confidence interval; CMH=Cochran‑Mantel‑Haenszel; CCyR=complete cytogenetic response; mITT=modified intent‑to‑treat; MMR=major molecular response; N/n=number of patients; Ph+=Philadelphia chromosome-positive.

^a Adjusted for geographical region and Sokal score at randomisation.

^b Statistically significant comparison at the pre-specified significance level; based on CMH test stratified by geographical region and Sokal score at randomisation.

^c Based on CMH test stratified by geographical region and Sokal score at randomisation.

At Month 12, the MR⁴ rate (defined as ≤ 0.01% BCR‑ABL [corresponding to ≥ 4 log reduction from standardised baseline] with a minimum of 9,800 ABL transcripts) was higher in the bosutinib treatment group compared to the imatinib treatment group in the mITT population (20.7% [95% CI: 15.7%, 25.8%] versus 12.0% [95% CI: 7.9%, 16.1%], respectively, odds ratio (OR) 1.88 [95% CI: 1.15, 3.08], 1‑sided p‑value=0.0052).

At Months 3, 6, and 9, the proportion of patients with MMR was higher in the bosutinib treatment group compared to the imatinib treatment group (Table 6).

Table 6 - Comparison of MMR at Months 3, 6, and 9 by treatment in the mITT population

By Month 60 in the mITT population, the proportion of patients with MMR, MR⁴ and MR^4.5 was higher in the bosutinib group compared to the imatinib group (Table 7). MMR rates by Month 60 across Sokal risk subgroups are summarised in Table 8.

Table 7 - Summary of molecular response by Month 60 in the mITT population

Note: MMR/MR⁴/MR^4.5 were defined as ≤ 0.1/0.01/0.0032% BCR-ABL/ABL ratio on international scale (corresponding to ≥ 3/4/4.5 log reduction from standardised baseline) with a minimum of 3 000/9 800/30 990 ABL transcripts assessed by the central laboratory.

Abbreviations: BCR-ABL=breakpoint cluster region‑Abelson; CI=confidence interval; mITT=modified intent‑to‑treat; MMR=major molecular response; MR=molecular response; N/n=number of patients.

^a Adjusted for geographical region and Sokal score at randomisation.

Table 8 - Summary of MMR by Month 60 by Sokal risk score in the mITT population

Note: Percentages were based on number of patients in each treatment group. MMR was defined as ≤ 0.1% BCR‑ABL/ABL ratio on international scale (corresponding to ≥ 3 log reduction from standardised baseline) with a minimum of 3 000 ABL transcripts assessed by the central laboratory.

Abbreviations: BCR‑ABL=breakpoint cluster region‑Abelson; CI=confidence interval; mITT=modified intent‑to‑treat; MMR=major molecular response; N/n=number of patients.

The cumulative incidence of CCyR adjusted for the competing risk of treatment discontinuation without CCyR was higher in the bosutinib treatment group compared to the imatinib treatment group in the mITT population (83.3% [95% CI: 78.1%, 87.4%] versus 76.8% [95% CI: 70.9%, 81.6%] at Month 60; hazard ratio [HR] from a stratified proportional sub distributional hazards model: 1.35, [95% CI: 1.11, 1.64]). The median time to CCyR (responders only) was 24.0 weeks (range: 11.4 to 120.7) in the bosutinib group compared to the 24.3 weeks (range: 11.4 to 96.6) in the imatinib group.

The median time to MMR, MR⁴ and MR^4.5 (responders only) was 36.1 weeks (range: 11.9 to 241.9), 83.7 weeks (range: 12.4 to 244.3), and 108.0 weeks (range: 24.1 to 242.1), respectively, for the bosutinib treatment group versus 47.7 weeks (range: 12.1 to 216.1), 84.4 weeks (range: 23.6 to 241.9), and 120.4 weeks (range: 24.6 to 240.7), respectively, for the imatinib treatment group in the mITT population.

The cumulative incidence of MMR, MR⁴ and MR^4.5 adjusted for the competing risk of treatment discontinuation without the event was higher with bosutinib compared to imatinib as shown in Figures 1 to 3.

Figure 1 - Cumulative incidence of MMR (mITT population)

Figure 2 - Cumulative incidence of MR⁴ (mITT population)

Figure 3 - Cumulative incidence of MR^4.5 (mITT population)

In the mITT population, among patients who achieved CCyR, the Kaplan-Meier estimate of maintaining a response at Year 4 was 97.4% (95% CI: 93.9%, 98.9%) and 93.7% (95% CI: 88.9%, 96.5%) in the bosutinib and imatinib groups (HR 0.39 [95% CI: 0.14, 1.13]), respectively. Among patients who achieved MMR, the Kaplan-Meier estimate of maintaining a response at Year 4 was 92.2% (95% CI: 86.8%, 95.4%) and 92.0% (95% CI: 85.9%, 95.5%) in the bosutinib and imatinib groups (HR 1.09 [95% CI: 0.49, 2.44]), respectively.

By Month 60, 43.9% (95% CI: 37.7%, 50.1%) and 38.6% (95% CI: 32.4%, 44.7%) of bosutinib- and imatinib-treated patients (OR 1.24 [95% CI: 0.87, 1.78]) in the mITT population, respectively, had sustained MR⁴ defined by the following criteria: treatment for at least 3 years with at least MR⁴ at all assessments during a 1‑year period.

The cumulative incidence of on-treatment EFS events at Month 60 in the mITT population was 6.9% (95% CI: 4.2%, 10.5%) in the bosutinib arm and 10.4% (95% CI: 6.9%, 14.6%) in the imatinib arm (HR 0.64, 95% CI: 0.35, 1.17).

The Kaplan-Meier estimates of OS at Month 60 for bosutinib and imatinib patients in the mITT population were 94.9% (95% CI: 91.1%, 97.0%) and 94.0% (95% CI: 90.1%, 96.4%), respectively (HR 0.80, 95% CI: 0.37, 1.73).

In a retrospective analysis, among evaluable patients in the ITT population, more patients in the bosutinib arm 200/248 (80.6%) achieved early molecular response (BCR-ABL transcripts ≤ 10% at 3 months) compared to patients in the imatinib arm 153/253 (60.5%), OR 2.72 (95% CI: 1.82, 4.08). MMR and EFS at Month 60 in bosutinib patients with and without early molecular response are summarised in Table 9.

Table 9 - Outcomes at Month 60 in bosutinib patients with BCR-ABL ≤ 10% vs > 10% at Month 3 in the ITT population

Abbreviations: BCR-ABL=breakpoint cluster region‑Abelson; CI=confidence interval; ITT=intent‑to‑treat; MMR=major molecular response; EFS=event free survival; N=number of patients with ≥ 3 000 ABL copies at Month 3.

^a Adjusted for geographical region and Sokal score at randomisation.

Fewer patients in the bosutinib arm [6 (2.4%) bosutinib and 12 (5.0%) imatinib] had newly detectable mutations at 60 months in the mITT population.

Phase 1/2 Clinical study in imatinib-resistant or intolerant CML in CP, AP, and BP

A single-arm, Phase 1/2 open‑label, multicentre trial was conducted to evaluate the efficacy and safety of bosutinib 500 mg once daily in patients with imatinib‑resistant or ‑intolerant CML with separate cohorts for chronic, accelerated, and blast phase disease previously treated with 1 prior TKI (imatinib) or more than 1 TKI (imatinib followed by dasatinib and/or nilotinib).

There were 570 patients treated with bosutinib in this trial including CP CML patients previously treated with only 1 prior TKI (imatinib), CP CML patients previously treated with imatinib and at least 1 additional TKI (dasatinib and/or nilotinib), CML patients in accelerated or blast phase previously treated with at least 1 TKI (imatinib) and patients with Ph+ ALL previously treated with at least 1 TKI (imatinib).

The primary efficacy endpoint of the study was the major cytogenetic response (MCyR) rate at Week 24 in patients with imatinib‑resistant CP CML previously treated with only 1 prior TKI (imatinib). Other efficacy endpoints include the cumulative cytogenetic and molecular response rates, time to and duration of cytogenetic and molecular responses, response in baseline mutations, transformation to AP/BP, progression free survival and OS for all cohorts.

Patients who were still receiving bosutinib at the end of the Phase 1/2 study and were benefiting from bosutinib treatment as judged by the investigator, as well as those patients who had already discontinued bosutinib as part of the Phase 1/2 study and were in long-term follow-up for survival or had completed the Phase 1/2 study, were eligible for enrollment into the extension study. Each patient remained in the extension study, either on bosutinib treatment or in long‑term survival follow‑up, until the last patient reached 10 years of follow‑up, as calculated from the date of his/her first dose of bosutinib administered in the Phase 1/2 study.

Extension study efficacy endpoints included duration of cytogenetic and molecular responses, transformation to AP/BP, progression free survival, and OS.

The efficacy analyses included data from this completed extension study.

CP CML patients

The efficacy results for Ph+ CP CML patients previously treated with imatinib and at least 1 additional TKI (minimum follow-up 120 months, median treatment duration of 9 months (range: 0.23 to 164.28 months) and 20.2% and 7.6% still on‑treatment at 60 and 120 months, respectively) and the results for Ph+ CP CML patients previously treated with only imatinib (minimum follow‑up 120 months, median treatment duration of 26 months (range: 0.16 to 170.49 months) and 40.5% and 19.4% still on‑treatment at 60 and 120 months, respectively) are presented in Table 9.

AP and BP CML patients

The efficacy results for AP (minimum follow‑up 120 months, median treatment duration of 10 months (range: 0.10 to 156.15 months) and 12.7% and 7.6% still on‑treatment at 60 and 120 months, respectively) and BP (minimum follow‑up 120 months, median treatment duration of 2.8 months (range: 0.03 to 71.38 months) and 3.1% and 0% still on‑treatment at 60 and 120 months, respectively) Ph+ CML patients are present in Table 10.

Table 10 - Efficacy results in previously treated patients with chronic and advanced phase CML*

The Overall Survival in the CP, AP and BP cohorts is displayed graphically in Figure 4.

Figure 4 - Kaplan-Meier Estimate of Overall Survival (OS) in CP2L, CP3L, AP, and BP

Based on the limited clinical information from the Phase 1/2 study, some evidence of clinical activity was observed in patients with BCR‑ABL mutations (see Table 11).

Table 11 - Response by baseline BCR‑ABL mutation status in CP CML evaluable population: prior imatinib and dasatinib and/or nilotinib (third‑line)

One patient with the E255V mutation previously treated with nilotinib achieved CHR as best response.

In vitro testing indicated that bosutinib had limited activity against the T315I or the V299L mutation. Therefore, clinical activity in patients with these mutations is not expected.

Phase 4 Clinical study in Ph+ CML previously treated with 1 or more TKI(s)

A single‑arm, Phase 4 open‑label, non‑randomised, multi‑centre study was conducted to evaluate the efficacy and safety of bosutinib 500 mg once daily in patients with TKI‑resistant or TKI‑intolerant CML with separate cohorts for CP, AP or BP disease previously treated with 1 or more prior TKIs.

There were 163 patients treated with bosutinib in this trial including 46 patients with CP Ph+ CML and treated previously with 1 prior TKI (imatinib or dasatinib or nilotinib), 61 CP Ph+ CML patients previously treated with 2 prior TKIs (imatinib and/or dasatinib and/or nilotinib), 49 CP Ph+ CML patients treated with 3 prior TKIs (imatinib and dasatinib and nilotinib), 4 patients with AP Ph+ CML previously treated with at least 1 TKI (2 patients treated with 2 prior TKIs and 2 patients treated with 3 prior TKIs) and 3 patients with Ph- CML treated with at least 1 prior TKI.

The primary efficacy endpoint was cumulative confirmed MCyR by 1 year (Week 52) in patients with CP Ph+ CML previously treated with 1 or 2 prior TKIs and patients with CP Ph+ CML previously treated with 3 prior TKIs. For patients with AP and BP Ph+ CML with any prior TKI therapy, the primary efficacy endpoint was cumulative confirmed overall haematological response (OHR) by 1 year (Week 52). Other efficacy endpoints in Ph+ CP CML patients include cumulative cytogenetic and molecular response, the duration of cytogenetic and molecular responses, response in baseline mutations, transformation to AP/BP, PFS, and OS. Additional endpoints in the Ph+ AP/BP cohort include cumulative cytogenetic and molecular responses rates, PFS and OS.

CP CML patients

The primary endpoint of cumulative confirmed MCyR (95% CI) rate by 1 year (52 weeks) was 76.5% (66.9, 84.5) in patients treated with 1 or 2 prior TKIs and 62.2% (46.5, 76.2) in patients treated with 3 prior TKIs.

Additional efficacy results at study closure, after a minimum follow-up of 3 years, in Ph+ CP CML patients treated with 1 (median treatment duration 47.5 months (range: 0.9 to 50.1 months) and 60.9% still on‑treatment), 2 (median treatment duration 41.9 months (range: 0.4 to 48.9 months) and 45.9% still on‑treatment) and 3 (median treatment duration 20.0 months (range: 0.2 to 48.9 months) and 38.8% still on‑treatment) prior TKIs are presented in Table 12.

Table 12 – Efficacy results in previously treated patients with chronic phase Ph+ CML

The cumulative incidence of MMR, MR⁴ and MR^4.5 adjusted for the competing risk of treatment discontinuation without the event are shown in Figure 5.

Figure 5 - Cumulative Incidence of Molecular Response (CP Evaluable Population)

Achieved molecular responses by line of treatment are shown in Table 13.

Table 13 – Achieved molecular responses

In CP patients, there were no on-treatment progressions to AP or BP CML.

AP CML patients

In patients with Ph+ AP CML, the median duration of treatment was 22.1 months (range: 1.6 to 50.1 months), the cumulative confirmed OHR by 1 year (52 weeks) was 75.0% (95% CI: 19.4, 99.4), as was the cumulative CCyR rate, all 3 patients maintained their CCyR on-treatment.

Response by BCR-ABL Mutations at baseline

Ten patients in the CP cohort had mutations at baseline (A365V, E453K, E255K, E255V, Q252H, L298V [n=1 each], Y253F and G250E [n=2 each]). One patient in the CP cohort had a F359I mutation identified on study day 8. One patient in the AP cohort had 2 mutations (F311L and L387F) at baseline. In the CP cohort, among patients with mutations, molecular responses were observed in 4/11 (36.4%) patients, 1 patient with a E255V mutation achieved MMR and 3 patients with F359I, Y253F and A365V respectively achieved MR^4.5. The patient with mutations in the AP cohort did not achieve any response.

Paediatric population

The efficacy of Bosulif in paediatric patients was evaluated in the BCHILD trial “A Phase I/II study of bosutinib in paediatric patients with newly-diagnosed chronic phase or resistant/intolerant Ph+ CML”.

The BCHILD trial is a Phase I/II, multicentre, international, single-arm, open-label study conducted to identify a recommended dose of bosutinib administered orally once daily in paediatric patients (aged 1 to < 18 years) with newly‑diagnosed chronic phase Ph+ CML (ND CML) or Ph+ CML who have received at least one prior TKI therapy (R/I CML) and to assess preliminary estimate the safety tolerability and efficacy, and to evaluate the Pharmacokinetics of bosutinib in this patient population.

Paediatric patients with newly-diagnosed CP Ph+ CML

The efficacy of Bosulif in paediatric patients with newly-diagnosed CP Ph+ CML (CP1L) was evaluated as part of the BCHILD trial. In the Phase II dose expansion portion 30 patients with ND CML received bosutinib at a dose of 300 mg/m² once daily. The median duration of follow-up for overall survival in the total cohort (N=30) was 21.91 (1.08, 45.11) months in ND CML patients, and the median treatment duration was 13.68 (0.20, 43,70). A summary of cumulative cytogenetic and molecular responses at any time in patients with ND CML is shown in Table 15. Among responders, one patient lost CCyR and MCyR.

Among evaluable ND patients (ABL copies ≥10 000), 81.08% (95% CI: 64.2, 97.7) had a BCR-ABL ratio ≤ 10% at 3 months, and 62.5% (95% CI: 38.8, 86.2) had a BCR-ABL ratio ≤ 1% at 6 months.

There were no deaths in the ND cohort and no progressions to AP or BP.

Paediatric patients with imatinib-resistant or intolerant Ph+ CP, CML

The efficacy of Bosulif in paediatric patients with resistant or intolerant Ph+ CML was evaluated as part of the BCHILD trial.

In the Phase I dose escalation portion, 28 patients with R/I CML received bosutinib at doses ranging from 300 to 400 mg/m² once daily. 6 patients were enrolled in the Phase II portion (400 mg/m²).

Table 14 – Demographic characteristics of CML patients

The median duration of follow-up for overall survival in the total phase 1 portion (N=28) was 29.27 months (15.21, 85.88) and in the phase 2 portion (N=6) was 9.66 (2.00, 15.54). The median treatment duration in the phase 1 portion was 17.26 months (range 0.30 to 60.85) and 9.64 months (1.97, 15.54) in the phase 2 portion.

A summary of cumulative cytogenetic and molecular responses at any time in patients with CML is shown in Table 15. In Phase I, among responders, three patients lost CCyR and 2 patients lost MCyR. In the phase 1 portion, the probability of maintaining MMR at 18 months was 92.3% (95% CI: 56.6, 98.8).

There were no progressions to AP or BP.

Table 15 - Efficacy results in paediatric patients with resistant or intolerant Ph+ CML

Bosutinib pharmacokinetics were assessed following oral dosing with food in adult patients with CML and were presented as geometric mean (CV%), unless otherwise specified.

Absorption

Following administration of a single dose of bosutinib (500 mg) with food in healthy subjects, the absolute bioavailability was 34%. Absorption was relatively slow, with a median time-to-peak concentration (t_max) reached after 6 hours. Bosutinib exhibits dose-proportional increases of AUC over the dose range of 100 to 600 mg. The bosutinib PK parameters for adults were derived from a population PK analysis using pooled data across studies. Bosutinib steady state C_max was 127 ng/mL (31%), C_trough was 68 ng/mL (39%) and AUC was 2 370 ng•h/mL (34%) following multiple oral doses of Bosulif 400 mg; Bosutinib steady state C_max was 171 ng/mL (38%), C_trough was 91 ng/mL (42%) and AUC was 3 150 ng•h/mL (38%) following multiple oral doses of Bosulif 500 mg.

No clinically significant differences in the pharmacokinetics of bosutinib were observed following administration of either the tablet or intact hard capsule dosage forms of bosutinib at the same dose, under fed conditions. Bosutinib hard capsule contents mixed with applesauce or yogurt exhibited comparable PK to the bosutinib intact hard capsule under fed condition in healthy adult participants.

The solubility of bosutinib is pH‑dependent and absorption is reduced when gastric pH is increased (see section 4.5).

Effect of food

Bosutinib C_max increased 1.8-fold and AUC increased 1.7-fold when bosutinib tablets were given with a high-fat meal to healthy subjects compared to administration under fasted condition. In a separate study, bosutinib hard capsule administration under the fed condition resulted in exposures approximately 1.5 – 1.6-fold higher than administration under fasted conditions.

Distribution

Following administration of a single intravenous dose of 120 mg bosutinib to healthy subjects, bosutinib had a mean (% coefficient of variation [CV]) volume of distribution of 2,331 (32) L, suggesting that bosutinib is extensively distributed to extra vascular tissue.

Bosutinib was highly bound to human plasma proteins in vitro (94%) and ex vivo in healthy subjects (96%), and binding was not concentration‑dependent.

Biotransformation

In vitro and in vivo studies indicated that bosutinib (parent compound) undergoes predominantly hepatic metabolism in humans. Following administration of single or multiple doses of bosutinib (400 or 500 mg) to humans, the major circulating metabolites appeared to be oxydechlorinated (M2) and N‑desmethylated (M5) bosutinib, with bosutinib N‑oxide (M6) as a minor circulating metabolite. The systemic exposure of N‑desmethylated metabolite was 25% of the parent compound, while the oxydechlorinated metabolite was 19% of the parent compound. All 3 metabolites exhibited activity that was ≤ 5% that of bosutinib in a Src‑transformed fibroblast anchorage‑independent proliferation assay. In faeces, bosutinib and N‑desmethyl bosutinib were the major drug-related components. In vitro studies with human liver microsomes indicated that the major cytochrome P450 isozyme involved in the metabolism of bosutinib is CYP3A4 and drug interaction studies have shown that ketoconazole and rifampicin had marked effect on the pharmacokinetics of bosutinib (see section 4.5). No metabolism of bosutinib was observed with CYPs 1A2, 2A6, 2B6, 2C8, 2C9, 2C19, 2D6, 2E1, or 3A5.

Elimination

In healthy subjects given a single intravenous dose of 120 mg bosutinib, the mean (%CV) terminal elimination half‑life was 35.5 (24) hours, and the mean (%CV) clearance was 61.9 (26) L/h. In a mass‑balance study with oral bosutinib, an average of 94.6% of the total dose was recovered in 9 days; faeces (91.3%) was the major route of excretion, with 3.29% of the dose recovered in urine. Seventy‑five percent of the dose was recovered within 96 hours. Excretion of unchanged bosutinib in urine was low with approximately 1% of the dose in both healthy subjects and those with advanced malignant solid tumours.

Special populations

Hepatic impairment

A 200 mg dose of bosutinib administered with food was evaluated in a cohort of 18 hepatically impaired subjects (Child‑Pugh classes A, B, and C) and 9 matched healthy subjects. C_max of bosutinib in plasma increased 2.4‑fold, 2‑fold, and 1.5‑fold, respectively, in Child‑Pugh classes A, B, and C; and bosutinib AUC in plasma increased 2.3‑fold, 2‑fold, and 1.9‑fold, respectively. The t_½ of bosutinib increased in hepatic impaired patients as compared to the healthy subjects.

Renal impairment

In a renal impairment study, a single dose of 200 mg bosutinib was administered with food to 26 subjects with mild, moderate, or severe renal impairment and to 8 matching healthy volunteers. Renal impairment was based on CL_Cr (calculated by the Cockcroft‑Gault formula) of < 30 mL/min (severe renal impairment), 30 ≤ CL_Cr ≤ 50 mL/min (moderate renal impairment), or 50 < CL_Cr ≤ 80 mL/min (mild renal impairment). Subjects with moderate and severe renal impairment had an increase in AUC over healthy volunteers of 35% and 60%, respectively. Maximal exposure C_max increased by 28% and 34% in the moderate and severe groups, respectively. Bosutinib exposure was not increased in subjects with mild renal impairment. The elimination half‑life of bosutinib in subjects with renal impairment was similar to that in healthy subjects.

Dose adjustments for renal impairment were based on the results of this study, and the known linear pharmacokinetics of bosutinib in the dose range of 200 to 600 mg.

Age, gender and race

No formal studies have been performed to assess the effects of these demographic factors. Population pharmacokinetic analyses in patients with Ph+ leukaemia or malignant solid tumour and in healthy subjects indicate that there are no clinically relevant effects of age, gender or body weight. Population pharmacokinetic analyses revealed that Asians had a 18% lower clearance corresponding to an approximately 25% increase in bosutinib exposure (AUC).

Paediatric population

The pharmacokinetics of bosutinib in 41 newly‑diagnosed or resistant/intolerant paediatric patients 1 to < 18 years of age were evaluated over the dose range of 300 mg/m² to 400 mg/m² administered orally once daily with food. In paediatric patients, median T_max occurred at approximately 3 hours post-dose (range 1 to 8 hours post-dose). Exposures increased in a dose proportional manner between 100 – 600 mg. The geometric mean AUC_tau in the 300 mg/m² to 400 mg/m² cohorts was within the range (+/- 20%) of geometric mean AUC_tau for the adult dose level in the respective newly-diagnosed and resistant or intolerant Ph+ CML indications, however C_max and clearance were higher and C_min was lower in paediatric patients than in adults.

Bosutinib has been evaluated in safety pharmacology, repeated dose toxicity, genotoxicity, reproductive toxicity, and phototoxicity studies.

Safety pharmacology

Bosutinib did not have effects on respiratory functions. In a study of the central nervous system (CNS), bosutinib treated rats displayed decreased pupil size and impaired gait. A no observed effect level (NOEL) for pupil size was not established, but the NOEL for impaired gait occurred at exposures approximately 11‑times the human exposure resulting from the clinical dose of 400 mg and 8‑times the human exposure resulting from the clinical dose of 500 mg (based on unbound C_max in the respective species). Bosutinib activity in vitro in hERG assays suggested a potential for prolongation of cardiac ventricular repolarisation (QTc). In an oral study of bosutinib in dogs, bosutinib did not produce changes in blood pressure, abnormal atrial or ventricular arrhythmias, or prolongation of the PR, QRS, or QTc of the ECG at exposures up to 3‑times the human exposure resulting from the clinical dose of 400 mg and 2‑times the human exposure resulting from the clinical dose of 500 mg (based on unbound C_max in the respective species). A delayed increase in heart rate was observed. In an intravenous study in dogs, transient increases in heart rate and decreases in blood pressure and minimal prolongation of the QTc (< 10 msec) were observed at exposures ranging from approximately 6‑times to 20‑times the human exposure resulting from the clinical dose of 400 mg and 4‑times to 15‑times the human exposure resulting from the clinical dose of 500 mg (based on unbound C_max in the respective species). The relationship between the observed effects and medicinal product treatment were inconclusive.

Repeated‑dose toxicity

Repeated-dose toxicity studies in rats of up to 6 months in duration and in dogs up to 9 months in duration revealed the gastrointestinal system to be the primary target organ of toxicity of bosutinib. Clinical signs of toxicity included foecal changes and were associated with decreased food consumption and body weight loss which occasionally led to death or elective euthanasia.

Histopathologically, luminal dilation, goblet cell hyperplasia, haemorrhage, erosion, and oedema of the intestinal tract, and sinus erythrocytosis and haemorrhage in the mesenteric lymph nodes, were observed. The liver was also identified as a target organ in rats. Toxicities were characterised by an increase in liver weights in correlation with hepatocellular hypertrophy which occurred in the absence of elevated liver enzymes or microscopic signs of hepatocellular cytotoxicity, and is of unknown relevance to humans. The exposure comparison across species indicates that exposures that did not elicit adverse events in the 6‑ and 9‑month toxicity studies in rats and dogs, respectively, were similar to the human exposure resulting from a clinical dose of 400 mg or 500 mg (based on unbound AUC in the respective species).

Genotoxicity

Genotoxicity studies in bacterial in vitro systems and in mammalian in vitro and in vivo systems with and without metabolic activation did not reveal any evidence for a mutagenic potential of bosutinib.

Reproductive toxicity and development toxicity

In a rat fertility study, fertility was slightly decreased in males. Females were observed with increased embryonic resorptions, and decreases in implantations and viable embryos. The dose at which no adverse reproductive effects were observed in males (30 mg/kg/day) and females (3 mg/kg/day) resulted in exposures equal to 0.6‑times and 0.3‑times, respectively, the human exposure resulting from the clinical dose of 400 mg, and 0.5‑times and 0.2‑times, respectively, the human exposure resulting from the clinical dose of 500 mg (based on unbound AUC in the respective species). An effect on male fertility cannot be excluded (see section 4.6).

Foetal exposure to bosutinib-derived radioactivity during pregnancy was demonstrated in a placental transfer study in gravid Sprague-Dawley rats. In a rat pre‑ and postnatal development study, there were reduced number of pups born at ≥ 30 mg/kg/day, and increased incidence of total litter loss and decreased growth of offspring after birth occurred at 70 mg/kg/day. The dose at which no adverse development effects were observed (10 mg/kg/day) resulted in exposures equal to 1.3‑times and 1.0‑times human exposure resulting from the clinical dose of 400 mg and 500 mg, respectively (based on unbound AUC in the respective species). In a rabbit developmental toxicity study at the maternally toxic dose, there were foetal anomalies observed (fused sternebrae, and 2 foetuses had various visceral observations), and a slight decrease in foetal body weight. The exposure at the highest dose tested in rabbits (10 mg/kg/day) that did not result in adverse foetal effects was 0.9‑times and 0.7‑times the human exposure resulting from the clinical dose of 400 mg or 500 mg, respectively (based on unbound AUC in the respective species).

Following a single oral (10 mg/kg) administration of [¹⁴C] radiolabelled bosutinib to lactating Sprague‑Dawley rats, radioactivity was readily excreted into breast milk as early as 0.5 hr after dosing. Concentration of radioactivity in milk was up to 8‑fold higher than in plasma. This allowed measurable concentrations of radioactivity to appear in the plasma of nursing pups.

Carcinogenicity

Bosutinib was not carcinogenic in the 2‑year rat and 6-month rasH2 mouse carcinogenicity studies.

Phototoxicity

Bosutinib has demonstrated the ability to absorb light in the UV‑B and UV‑A range and is distributed into the skin and uveal tract of pigmented rats. However, bosutinib did not demonstrate a potential for phototoxicity of the skin or eyes in pigmented rats exposed to bosutinib in the presence of UV radiation at bosutinib exposures up to 3‑times and 2‑times the human exposure resulting from the clinical dose of 400 or 500 mg, respectively (based on unbound C_max in the respective species).

Bosulif hard capsules

Mannitol (E421)

Microcrystalline cellulose (E460)

Croscarmellose sodium (E468)

Poloxamers 188

Povidone (E1201)

Magnesium stearate (E470b)

Bosulif hard capsule shells

Gelatin

Titanium dioxide (E171)

Yellow iron oxide (E172)

Red iron oxide (E172)

Printing ink hard capsules

Shellac (E904)

Propylene glycol (E1520)

Ammonia solution, concentrated (E527)

Black iron oxide (E172)

Potassium hydroxide (E525)

Not applicable.

3 years.

Do not store above 30 °C. Store in the original package in order to protect from light.

High-density polyethylene (HDPE) bottle and polypropylene (PP) closure with heat induction seal (HIS).

Cartons of one bottle containing 30 hard capsules.

Not all pack sizes may be marketed.

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