双芳基喹啉类抗结核药片SIRTURO(BEDAQUILINE FUMARATE)TABLET ORAL在欧洲获得批准上市，本品已成为几十年来获欧洲的新类型结核病 (TB) 最有效的治疗药物
批准日期：2012年12月28日；公司：Janssen Research
一般描述
SIRTURO (bedaquiline)为口服给药可得到为100mg强度片。每片含120.89mg的富马酸bedaquiline药物物质，等同于100mg的bedaquiline。Bedaquiline是一种diarylquinoline抗分枝杆菌药。富马酸Bedaquiline是白色至几乎白色粉和几乎不溶于水介质。富马酸bedaquiline化学名为(1R，2S)-1-(6-bromo-2methoxy-3-quinolinyl)-4-(dimethylamino)-2-(1-naphthalenyl)-1-phenyl-2-butanol compound with fumaric acid (1:1)。其分子式为C32H31BrN2O2•C4H4O4和分子量671.58 (555.50 + 116.07)。其结构式为：

SIRTURO 100 mg tablets
1. Name of the medicinal product
SIRTURO 100 mg tablets
2. Qualitative and quantitative composition
Each tablet contains bedaquiline fumarate equivalent to 100 mg of bedaquiline.
Excipient with known effect: Each tablet contains 145 mg of lactose (as monohydrate).
For the full list of excipients, see section 6.1.
3. Pharmaceutical form
Tablet.
Uncoated, white to almost white round biconvex tablet, 11 mm in diameter, with debossing of "T" over "207" on one side and "100" on the other side.
4. Clinical particulars
4.1 Therapeutic indications
SIRTURO is indicated for use as part of an appropriate combination regimen for pulmonary multidrug-resistant tuberculosis (MDR-TB) in adult patients when an effective treatment regimen cannot otherwise be composed for reasons of resistance or tolerability. See sections 4.2, 4.4 and 5.1.
Consideration should be given to official guidance on the appropriate use of antibacterial agents.
4.2 Posology and method of administration
 Treatment with SIRTURO should be initiated and monitored by a physician experienced in the management of multi-drug resistant Mycobacterium tuberculosis.
SIRTURO should be used in combination with at least three medicinal products to which the patient's isolate has been shown to be susceptible in vitro. Treatment with the other agents in the regimen should continue after completion of treatment with SIRTURO. If in vitro testing results are unavailable, treatment may be initiated with SIRTURO in combination with at least four medicinal products to which the patient's isolate is likely to be susceptible.
It is recommended that SIRTURO is administered by directly observed therapy (DOT).
Posology
The recommended dosage is:
• Weeks 1-2: 400 mg (4 tablets of 100 mg) once daily
• Weeks 3-24: 200 mg (2 tablets of 100 mg) three times per week (with at least 48 hours between doses).
The total duration of treatment with SIRTURO is 24 weeks. Data on longer treatment duration is very limited. In patients with extensive drug resistance, where SIRTURO is considered necessary beyond 24 weeks to obtain a curative treatment, a longer duration of therapy may be considered only on a case by case basis and under close safety surveillance (see sections 4.4 and 4.8).
Missed doses
Patients should be advised to take SIRTURO exactly as prescribed and to complete the full course of therapy.
If a dose is missed during the first two weeks of treatment, patients should not make up the missed dose, but should continue the usual dosing schedule.
If a dose is missed from week three onwards, patients should take the missed dose of 200 mg as soon as possible and then resume the three times a week regimen.
Elderly population (≥ 65 years of age)
There is limited clinical data (n = 2) on the use of SIRTURO in elderly patients.
Hepatic impairment
No dose adjustment is necessary for SIRTURO in patients with mild or moderate hepatic impairment (see section 5.2). SIRTURO should be used with caution in patients with moderate hepatic impairment (see section 5.2). SIRTURO has not been studied in patients with severe hepatic impairment and is not recommended in this population.
Renal impairment
No dose adjustment is required in patients with mild or moderate renal impairment. In patients with severe renal impairment (creatinine clearance < 30 ml/min) or end-stage renal disease requiring haemodialysis or peritoneal dialysis, SIRTURO should be used with caution (see section 5.2).
Paediatric population
The safety and efficacy of SIRTURO in children aged < 18 years have not yet been established.
No data are available.
Method of administration
SIRTURO should be taken orally with food, as administration with food increases oral bioavailability by about 2-fold (see section 5.2). SIRTURO tablets should be swallowed whole with water.
4.3 Contraindications
 Hypersensitivity to the active substance or to any of the excipients listed in section 6.1.
4.4 Special warnings and precautions for use
 There are no data on treatment with SIRTURO longer than 24 weeks within the clinical studies C208 and C209 (see section 5.1).
There are no clinical data on the use of SIRTURO to treat:
• extra-pulmonary tuberculosis (e.g. central nervous system, bone)
• infections due to mycobacterial species other than Mycobacterium tuberculosis
• latent infection with Mycobacterium tuberculosis
There are no clinical data on the use of SIRTURO as part of combination regimens used to treat drug-susceptible Mycobacterium tuberculosis.
Mortality
In the 120-week C208 trial where SIRTURO was administered for 24 weeks in combination with a background regimen, more deaths occurred in the SIRTURO treatment group than in the placebo group (see section 4.8). The imbalance in deaths is unexplained; no evidence has been found for a causal relationship with SIRTURO treatment.
Cardiovascular safety
Bedaquiline prolongs the QTc interval. An electrocardiogram should be obtained before initiation of treatment and at least monthly after starting treatment with bedaquiline. Serum potassium, calcium, and magnesium should be obtained at baseline and corrected if abnormal. Follow-up monitoring of electrolytes should be performed if QT prolongation is detected (see sections 4.5 and 4.8).
When bedaquiline is co-administered with other medicinal products that prolong the QTc interval, an additive or synergistic effect on QT prolongation cannot be excluded (see section 4.5). Caution is recommended when prescribing bedaquiline concomitantly with medicinal products with a known risk of QT prolongation. In the event that co-administration of such medicinal products with bedaquiline is necessary, clinical monitoring including frequent electrocardiogram assessment is recommended.
In the event that co-administration of clofazimine with bedaquiline is necessary, clinical monitoring including frequent electrocardiogram assessment is recommended (see section 4.5).
SIRTURO treatment initiation is not recommended in patients with the following, unless the benefits of bedaquiline are considered to outweigh the potential risks:
• Heart failure;
• QT interval as corrected by the Fridericia method (QTcF) > 450 ms (confirmed by repeat electrocardiogram);
• A personal or family history of congenital QT prolongation;
• A history of or ongoing hypothyroidism;
• A history of or ongoing bradyarrhythmia;
• A history of Torsade de Pointes;
• Concomitant administration of fluoroquinolone antibiotics that have a potential for significant QT prolongation (i.e., gatifloxacin, moxifloxacin and sparfloxacin).
• Hypokalemia
SIRTURO treatment must be discontinued if the patient develops:
• Clinically significant ventricular arrhythmia
• A QTcF interval of > 500 ms (confirmed by repeat electrocardiogram).
If syncope occurs, an electrocardiogram should be obtained to detect any QT prolongation.
Hepatic safety
Increases in transaminases were seen in clinical trials during administration of SIRTURO with the background regimen (see section 4.8). Patients should be monitored throughout the treatment course, since the increases in liver enzymes were slow to appear and increased gradually during the 24 weeks. Monitor symptoms and laboratory tests (ALT, AST, alkaline phosphatase, and bilirubin) at baseline, monthly while on treatment, and as needed. If AST or ALT exceeds 5 times the upper limit of normal then the regimen should be reviewed and SIRTURO and/or any hepatotoxic background medicinal product should be discontinued.
Other hepatotoxic medicinal products and alcohol should be avoided while on SIRTURO, especially in patients with diminished hepatic reserve.
Interactions with other medicinal products
CYP3A4 inducers
Bedaquiline is metabolised by CYP3A4. Co-administration of bedaquiline and medicinal products that induce CYP3A4 may decrease bedaquiline plasma concentrations and reduce its therapeutic effect. Co-administration of bedaquiline and moderate or potent CYP3A4 inducers used systemically should, therefore, be avoided (see section 4.5).
CYP3A4 inhibitors
Co-administration of bedaquiline and moderate or strong CYP3A4 inhibitors may increase the systemic exposure to bedaquiline, which could potentially increase the risk of adverse reactions (see section 4.5). Therefore, the combination of bedaquiline and moderate or strong CYP3A4 inhibitors used systemically for more than 14 consecutive days should be avoided. If co-administration is required, more frequent electrocardiogram monitoring and monitoring of transaminases is recommended.
Patients infected with human immunodeficiency virus (HIV)
There are no clinical data on the safety and efficacy of bedaquiline when co-administered with antiretroviral agents.
There are only limited clinical data on the efficacy of bedaquiline in HIV-infected patients not receiving antiretroviral (ARV) therapy. Those patients studied all had CD4+ cell counts greater than 250 x 106 cells/l (N = 22; see section 4.5).
Lactose intolerance and lactase deficiency
SIRTURO contains lactose. Patients with rare hereditary problems of galactose intolerance, the Lapp lactase deficiency or glucose-galactose malabsorption should not take this medicine.
4.5 Interaction with other medicinal products and other forms of interaction
The elimination of bedaquiline has not been fully characterised in vivo. CYP3A4 is the major CYP isoenzyme involved in vitro in the metabolism of bedaquiline and the formation of the N-monodesmethyl metabolite (M2). Urinary excretion of bedaquiline is negligible. Bedaquiline and M2 are not substrates or inhibitors of P-glycoprotein.
CYP3A4 inducers
Bedaquiline exposure may be reduced during co-administration with inducers of CYP3A4.
In an interaction study of single-dose bedaquiline and once daily rifampicin (potent inducer) in healthy subjects, the exposure (AUC) to bedaquiline was reduced by 52% [90% CI (-57; -46)]. Due to the possibility of a reduction of the therapeutic effect of bedaquiline due to a decrease in systemic exposure, co-administration of bedaquiline and moderate or potent CYP3A4 inducers (e.g. efavirenz, etravirine, rifamycins including rifampicin, rifapentine and rifabutin, carbamazepine, phenytoin, St. John's wort (Hypericum perforatum)) used systemically should be avoided.
CYP3A4 inhibitors
Bedaquiline exposure may be increased during co-administration with inhibitors of CYP3A4.
The short-term co-administration of bedaquiline and ketoconazole (potent CYP3A inhibitor) in healthy subjects increased the exposure (AUC) to bedaquiline by 22% [90% CI (12; 32)]. A more pronounced effect on bedaquiline may be observed during prolonged co-administration of ketoconazole or other inhibitors of CYP3A.
There are no safety data from bedaquiline multiple dose trials which utilised a dose higher than the indicated dose. Due to the potential risk of adverse reactions due to an increase in systemic exposure, prolonged co-administration of bedaquiline and moderate or strong CYP3A4 inhibitors (e.g. ciprofloxacin, erythromycin, fluconazole, clarithromycin, ketoconazole, ritonavir) used systemically for more than 14 consecutive days should be avoided. If co-administration is required, more frequent electrocardiogram monitoring and monitoring of transaminases is recommended (see section 4.4).
Other antituberculosis medicinal products
The short-term co-administration of bedaquiline with isoniazid/pyrazinamide in healthy subjects did not result in clinically relevant changes in the exposure (AUC) to bedaquiline, isoniazid or pyrazinamide. No dose-adjustment of isoniazid or pyrazinamide is required during co-administration with bedaquiline.
In a placebo-controlled clinical study in patients with multi-drug resistant Mycobacterium tuberculosis, no major impact of co-administration of bedaquiline on the pharmacokinetics of ethambutol, kanamycin, pyrazinamide, ofloxacin or cycloserine was observed.
Antiretroviral medicinal products
In an interaction study of single-dose bedaquiline and multiple-dose lopinavir/ritonavir, exposure (AUC) to bedaquiline was increased by 22% [90% CI (11; 34)]. A more pronounced effect on bedaquiline plasma exposures may be observed during prolonged co-administration with lopinavir/ritonavir. This increase is likely due to ritonavir. Increases in plasma exposure to bedaquiline would be expected when it is co-administered with other ritonavir-boosted HIV protease inhibitors.
Co-administration of single-dose bedaquiline and multiple-dose nevirapine did not result in clinically relevant changes in the exposure to bedaquiline. Clinical data on co-administration of bedaquiline and antiretroviral agents in patients co-infected with human immunodeficiency virus and multi-drug resistant Mycobacterium tuberculosis are not available (see section 4.4). Efavirenz is a moderate inducer of CYP3A activity and co-administration with bedaquiline may result in reduced bedaquiline exposure and loss of activity, and is, therefore, not recommended.
QT interval prolonging medicinal products
There is limited information available on the potential for a pharmacodynamic interaction between bedaquiline and medicinal products that prolong the QT interval. In an interaction study of bedaquiline and ketoconazole, a greater effect on QTc was observed after repeated dosing with bedaquiline and ketoconazole in combination than after repeated dosing with the individual medicinal products. An additive or synergistic effect on QT prolongation of bedaquiline when co-administered with other medicinal products that prolong the QT interval cannot be excluded and frequent monitoring is recommended (see section 4.4).
QT interval and concomitant clofazimine use
In an open label Phase IIb trial, mean increases in QTcF were larger in the 17 subjects who were using concomitant clofazimine at week 24 (mean change from reference of 31.9 ms) than in subjects who were not using concomitant clofazimine at week 24 (mean change from reference of 12.3 ms) (see section 4.4).
Paediatric population
Interaction studies have only been performed in adults.
4.6 Fertility, pregnancy and lactation
Pregnancy
There are limited data on the use of SIRTURO in pregnant women. At clinically relevant exposures, animal studies do not indicate direct or indirect harmful effects with respect to reproductive toxicity (see section 5.3).
As a precautionary measure, it is recommended to avoid the use of SIRTURO during pregnancy unless the benefit of therapy is considered to outweigh the risks.
Breastfeeding
It is not known whether bedaquiline or its metabolites are excreted in human milk.
In rats, concentrations of bedaquiline in milk were 6- to 12-fold higher than the maximum concentration observed in maternal plasma. Body weight decreases in pups were noted in high dose groups during the lactation period (see section 5.3).
Because of the potential for adverse reactions in breastfed infants, a decision must be made whether to discontinue breast-feeding or to discontinue/abstain from SIRTURO therapy taking into account the benefit of breast-feeding for the infant and the benefit of therapy for the mother.
Fertility
No human data on the effect of bedaquiline on fertility are available. In female rats, there was no effect on mating or fertility with bedaquiline treatment, however some effects were observed in male rats (see section 5.3).
4.7 Effects on ability to drive and use machines
Bedaquiline has minor influence on the ability to drive and use machines. Adverse reactions, such as dizziness, may affect the ability to drive or use machines. Patients should be advised not to drive or operate machinery if they experience dizziness while taking SIRTURO.
4.8 Undesirable effects
Summary of the safety profile
Adverse drug reactions for SIRTURO were identified from pooled Phase IIb clinical trial data (both controlled and uncontrolled) containing 335 patients who received SIRTURO in combination with a background regimen of tuberculosis medicinal products. The basis of assessment of causality between the adverse drug reactions and SIRTURO was not restricted to these trials, but also on review of the pooled Phase I and Phase IIa safety data. The most frequent adverse drug reactions (> 10.0% of patients) during treatment with SIRTURO in the controlled trials were nausea (35.3% in the SIRTURO group vs 25.7% in the placebo group), arthralgia (29.4% vs 20.0%), headache (23.5% vs 11.4%), vomiting (20.6% vs 22.9%) and dizziness (12.7% vs 11.4%).
Tabulated list of adverse reactions
Adverse drug reactions to SIRTURO reported from controlled trials in 102 patients treated with SIRTURO are presented in the table below.
Adverse drug reactions are listed by system organ class (SOC) and frequency. Frequency categories are defined as follows: very common (≥ 1/10), common (≥ 1/100 to < 1/10) and uncommon (≥ 1/1,000 to < 1/100).

 

System Organ Class (SOC)	Frequency Category	ADRs
Nervous system disorders	Very Common	Headache, dizziness
Cardiac disorders	Common	Electrocardiogram QT prolonged
Gastrointestinal disorders	Very Common	Nausea, vomiting
	Common	Diarrhoea
Hepatobiliary disorders	Common	Transaminases increased*
Musculoskeletal and connective tissue disorders	Very Common	Arthralgia
	Common	Myalgia

Terms represented by 'transaminases increased' included AST increased, ALT increased, hepatic enzyme increased, hepatic function abnormal, and transaminases increased (see section below).
Description of selected adverse events
Deaths
In the randomised phase IIb study (C208, stage 2) a higher rate of deaths was seen in the SIRTURO treatment group (10/79) compared to the placebo treatment group (2/81). In the SIRTURO group, all of the five deaths due to tuberculosis occurred in patients whose sputum culture status at last visit was 'not converted'. The causes of death in the remaining SIRTURO subjects were alcohol poisoning, hepatitis/hepatic cirrhosis, septic shock/peritonitis, cerebrovascular accident and motor vehicle accident. One of the ten deaths in the SIRTURO group (due to alcohol poisoning) occurred during the 24-week treatment period. The other nine deaths among those treated with SIRTURO occurred after completion of treatment with this agent (range 86-911 days post-SIRTURO; median 344 days). The observed imbalance in deaths between the two treatment groups is unexplained. No discernible pattern between death and sputum culture conversion, relapse, sensitivity to other medicinal products used to treat tuberculosis, human immunodeficiency virus status, or severity of disease could be observed. During the trial, there was no evidence of antecedent significant QT prolongation or clinically significant dysrhythmia in any of the patients that died.
Description of selected adverse reactions
Cardiovascular
In the controlled Phase IIb study (C208), mean increases from baseline values in QTcF were observed from the first on-treatment assessment onwards (9.9 ms at week 1 for SIRTURO and 3.5 ms for placebo). The largest mean increase from baseline values in QTcF during the 24 weeks of SIRTURO treatment was 15.7 ms (at week 18). After the end of SIRTURO treatment (i.e. after week 24), QTcF increases in the SIRTURO group gradually became less pronounced. The largest mean increase from baseline values in QTcF in the placebo group during the first 24 weeks was 6.2 ms (also at week 18) (see section 4.4).
In the Phase IIb, open label study (C209), where patients with no treatment options received other QT-prolonging medicinal products used to treat tuberculosis, including clofazimine, concurrent use with SIRTURO resulted in additive QT prolongation, proportional to the number of QT prolonging medicinal products in the treatment regimen.
Patients receiving SIRTURO alone with no other QT prolonging medicinal product developed a maximal mean QTcF increase over baseline of 23.7 ms with no QT duration in excess of 480 ms, whereas patients with at least 2 other QT prolonging medicinal products developed a maximal mean QTcF prolongation of 30.7 ms over baseline, resulting in a QTcF duration in excess of 500 ms in one patient.
There were no documented cases of Torsade de Pointes in the safety database (see section 4.4). See section 4.5, QT interval and concomitant clofazimine use, for further information regarding patients using clofazimine concomitantly.
Increased transaminases
In study C208 (stage 1 and 2), aminotransferase elevations of at least 3 x ULN developed more frequently in the SIRTURO treatment group (11/102 [10.8%] versus 6/105 [5.7%]) in the placebo treatment group. In the SIRTURO treatment group, the majority of these increases occurred throughout the 24 weeks of treatment and were reversible. During the investigational phase in Stage 2 of study C208, increased aminotransferases were reported in 7/79 (8.9%) patients in the SIRTURO treatment group compared to 1/81 (1.2%) in the placebo treatment group.
Reporting of suspected adverse reactions
Reporting suspected adverse reactions after authorisation of the medicinal product is important. It allows continued monitoring of the benefit/risk balance of the medicinal product. Healthcare professionals are asked to report any suspected adverse reactions via :
United Kingdom
Yellow Card Scheme
Website: www.mhra.gov.uk/yellowcard
Ireland
IMB Pharmacovigilance
Earlsfort Terrace
IRL - Dublin 2
Tel: +353 1 6764971
Fax: +353 1 6762517
Website: www.imb.ie
e-mail: imbpharmacovigilance@imb.ie
4.9 Overdose
 Cases of intentional or accidental acute overdose with bedaquiline were not reported during clinical trials. In a study in 44 healthy subjects receiving a single 800 mg dose of SIRTURO, adverse reactions were consistent with those observed in clinical studies at the recommended dose (see section 4.8).
There is no experience with the treatment of acute overdose with SIRTURO. General measures to support basic vital functions including monitoring of vital signs and electrocardiogram (QT interval) monitoring should be taken in case of deliberate or accidental overdose. Removal of unabsorbed bedaquiline may be aided by the administration of activated charcoal. Since bedaquiline is highly protein-bound, dialysis is not likely to significantly remove bedaquiline from plasma. Clinical monitoring should be considered.
5. Pharmacological properties
5.1 Pharmacodynamic properties

Pharmacotherapeutic group: Antimycobacterials, drugs for treatment of tuberculosis, ATC code: J04AK05
Mechanism of action
Bedaquiline is a diarylquinoline. Bedaquiline specifically inhibits mycobacterial ATP (adenosine 5'-triphosphate) synthase, an essential enzyme for the generation of energy in Mycobacterium tuberculosis. The inhibition of ATP synthase leads to bactericidal effects for both replicating and non-replicating tubercle bacilli.
Pharmacodynamic effects
Bedaquiline has activity against Mycobacterium tuberculosis with a minimal inhibitory concentration (MIC) for drug-sensitive as well as drug-resistant strains ( multi-drug resistant including pre-extensively drug resistant strains, extensively drug resistant strains) in the range of ≤ 0.008-0.12 µg/ml. The N-monodesmethyl metabolite (M2) is not thought to contribute significantly to clinical efficacy given its lower average exposure (23% to 31%) in humans and lower antimycobacterial activity (3- to 6-fold lower) compared to the parent compound.
The intracellular bactericidal activity of bedaquiline in primary peritoneal macrophages and in a macrophage-like cell line was greater than its extracellular activity. Bedaquiline is also bactericidal against dormant (non-replicating) tubercle bacilli. In the mouse model for TB infection, bedaquiline has demonstrated bactericidal and sterilizing activities.
Bedaquiline is bacteriostatic for many non-tuberculous mycobacterial species. Mycobacterium xenopi, Mycobacterium novocastrense, Mycobacterium shimoidei and non-mycobacterial species are considered inherently resistant to bedaquiline.
Pharmacokinetic/pharmacodynamic relationship
Within the concentration range achieved with the therapeutic dose, no pharmacokinetic/pharmacodynamic relationship was observed in patients.
Mechanisms of resistance
Mycobacterial resistance mechanisms that affect bedaquiline include modification of the atpE target gene. Not all isolates with high MICs have mutations in the atpE gene, suggesting the existence of at least one other mechanism of resistance. Isolates with decreased susceptibility to bedaquiline tend to be less susceptible to clofazimine.
Susceptibility testing breakpoints
When available, the clinical microbiology laboratory should provide the physician with the results of in vitro susceptibility test results for antimicrobial medicinal products used in resident hospitals as periodic reports that describe the susceptibility profile of nosocomial and community-acquired pathogens. These reports should aid the physician in selecting a combination of antibacterial medicinal products for treatment.
Breakpoints
Minimal inhibitory concentration (MIC) breakpoints are as follows:
Epidemiological Cut-Off (ECOFF)
 0.25 mg/l
Clinical Breakpoints
 S ≤ 0.25 mg/l; R > 0.25 mg/l
S = susceptible
R = resistant
Commonly susceptible species
Mycobacterium tuberculosis
Inherently resistant organisms
Mycobacterium xenopi
Mycobacterium novocastrense
Mycobacterium shimoidei
Non-mycobacterial species
Clinical efficacy and safety
The following definitions applies for resistance categories used:
Multi-drug resistant Mycobacterium tuberculosis (MDRH&R-TB): isolate resistant to at least isoniazid and rifampicin, but susceptible to fluoroquinolones and second line injectable agents.
Pre-extensively drug resistant tuberculosis (pre-XDR-TB): isolate resistant to isoniazid, rifampicin, and either any fluoroquinolone or at least one second line injectable agent (but not to both a fluoroquinolone and a second line injectable agent).
Extensively drug resistant tuberculosis (XDR-TB): isolate resistant to isoniazid, rifampicin, any fluoroquinolone, and at least one second line injectable agent.
A Phase IIb, placebo-controlled, double-blind, randomised trial (C208) evaluated the antibacterial activity, safety, and tolerability of SIRTURO in newly diagnosed patients with sputum smear-positive pulmonary MDRH&R- and pre-XDR-TB. Patients received SIRTURO (n = 79) or placebo (n = 81) for 24 weeks, both in combination with a preferred 5-drug background regimen (BR) consisting of ethionamide, kanamycin, pyrazinamide, ofloxacin, and cycloserine/terizidone. After the investigational period, the background regimen was continued to complete 18 to 24 months of total multi-drug resistant Mycobacterium tuberculosis treatment. A final evaluation was conducted at Week 120. Main demographics were as follows: 63.1% were males, median age 34 years, 35% were Black, and 15% were HIV positive. Cavitation in one lung was seen in 58% of patients, and in both lungs in 16%. For patients with full characterisation of resistance status, 76% (84/111) were infected with anMDRH&R-TB strain and 24% (27/111) with a pre-XDR-TB strain.
SIRTURO was administered as 400 mg once daily for the first 2 weeks, and as 200 mg 3 times/week for the following 22 weeks.
The primary outcome parameter was the time to sputum culture conversion (i.e. the interval between the first SIRTURO intake and the first of two consecutive negative liquid cultures from sputum collected at least 25 days apart) during treatment with SIRTURO or placebo (median time to conversion was 83 days for the SIRTURO group, 125 days for the placebo group (hazard ratio, 95% CI: 2.44 [1.57; 3.80]), p < 0.0001).
In the SIRTURO group, no or only minor differences in time to culture conversion and culture conversion rates were observed between patients with pre-XDR-TB and patients with MDRH&R-TB.
Response rates at week 24 and week 120 (i.e. around 6 months after stopping all therapy) are presented in table 1.

Table 1: Culture conversion Status
Culture Conversion Status, n (%)	mITT population
	N	SIRTURO/BR	N	Placebo/BR
Overall responder at Week 24	66	52 (78.8%)	66	38 (57.6%)
Patients with MDRH&R-TB	39	32 (82.1%)	45	28 (62.2%)
Patients infected with a pre-XDR-TB	15	11 (73.3%)	12	4 (33.3%)
Overall non-responder* at Week 24	66	14 (21.2%)	66	28 (42.4%)
Overall responder at Week 120	66	41 (62.1%)	66	29 (43.9%)
Patients with MDRH&R-TB	39#	27 (69.2%)	46# §	20 (43.5%)
Patients infected with pre-XDR-TB	15#	9 (60.0%)	12#	5 (41.7%)
Overall non-responder* at Week 120	66	25 (37.9%)	66	37 (56.1%)
Failure to convert	66	8 (12.1%)	66	15 (22.7%)
Relapse†	66	6 (9.1%)	66	10 (15.2%)
Discontinued but converted	66	11 (16.7%)	66	12 (18.2%)

Patients who died during the trial or discontinued the trial were considered as non-responders.
Relapse was defined in the trial as having a positive sputum culture after or during treatment following prior sputum culture conversion.
Extent of resistance based on central laboratory drug susceptibility testing results was not available for 20 subjects in the mITT population (12 in the SIRTURO group and 8 in the placebo group). These subjects were excluded from the subgroup analysis by extent of resistance of M tuberculosis strain.
§ Central laboratory drug susceptibility testing results became available for one additional placebo subject after the week 24 interim analysis.
Study C209 (ongoing) evaluates the safety, tolerability, and efficacy of 24 weeks treatment with open-label SIRTURO as part of an individualized treatment regimen in 233 patients who were sputum smear positive within 6 months prior to screening. This study included patients of all three resistance categories (MDRH&R-, pre-XDR- and XDR-TB).
The primary efficacy endpoint was the time to sputum culture conversion during treatment with SIRTURO (median 57 days, for 205 patients with sufficient data). At week 24, sputum culture conversion was seen in 163/205 (79.5%) patients. Conversion rates at week 24 were highest (87.1%; 81/93) in patients with MDRH&R-TB, 77.3% (34/44) in pre-XDR-TB patients and lowest (55.6%; 20/36) in XDR-TB patients. Extent of resistance based on central laboratory drug susceptibility testing results was not available for 32 subjects in the mITT population. These subjects were excluded from the subgroup analysis by extent of resistance of Mycobacterium tuberculosis strain. Responder rates were higher for patients on 3 or more potentially active substances in vitro in their background regimen.
Paediatric population
The European Medicines Agency has deferred the obligation to submit the results of studies with SIRTURO in one or more subsets of the paediatric population in the treatment of multi-drug resistant Mycobacterium tuberculosis (see section 4.2 for information on paediatric use).
This medicinal product has been authorised under a so-called 'conditional approval' scheme.
This means that further evidence on this medicinal product is awaited.
The European Medicines Agency will review new information on this medicinal product at least every year and this SmPC will be updated as necessary.
5.2 Pharmacokinetic properties
The pharmacokinetic properties of bedaquiline have been evaluated in adult healthy subjects and in adult multi-drug resistant tuberculosis-infected patients. Exposure to bedaquiline was lower in multi-drug resistant tuberculosis-infected patients than in healthy subjects.
Absorption
Maximum plasma concentrations (Cmax) are typically achieved at about 5 hours post-dose. Cmax and the area under the plasma concentration-time curve (AUC) increased proportionally up to the highest doses studied (700 mg single-dose and once daily 400 mg multiple doses). Administration of bedaquiline with food increased the relative bioavailability by about 2-fold compared to administration under fasted conditions. Therefore, bedaquiline should be taken with food to enhance its oral bioavailability.
Distribution
The plasma protein binding of bedaquiline is > 99.9% in all species tested, including human. The plasma protein binding of the N-monodesmethyl metabolite (M2) in humans is at least 99.8%. In animals, bedaquiline and its active N-monodesmethyl metabolite (M2) are extensively distributed to most tissues, however, brain uptake was low.
Biotransformation
CYP3A4 was the major CYP isoenzyme involved in vitro in the metabolism of bedaquiline and the formation of the N-monodesmethyl metabolite (M2).
In vitro, bedaquiline does not significantly inhibit the activity of any of the CYP450 enzymes tested (CYP1A2, CYP2A6, CYP2C8/9/10, CYP2C19, CYP2D6, CYP2E1, CYP3A4, CYP3A4/5 and CYP4A) and does not induce CYP1A2, CYP2C9 or CYP2C19 activities.
Elimination
Based on the preclinical studies, the bulk of the administered dose is eliminated in faeces. The urinary excretion of unchanged bedaquiline was < 0.001% of the dose in clinical studies, indicating that renal clearance of unchanged active substance is insignificant. After reaching Cmax, bedaquiline concentrations decline tri-exponentially. The mean terminal elimination half-life of bedaquiline and the active N-monodesmethyl metabolite (M2) is about 5.5 months. This long terminal elimination phase likely reflects slow release of bedaquiline and M2 from peripheral tissues.
Special populations
Hepatic impairment
A single-dose study of SIRTURO in 8 subjects with moderate hepatic impairment (Child-Pugh B) demonstrated exposure to bedaquiline and M2 (AUC672h) was 19% lower compared to healthy subjects. No dose adjustment is deemed necessary in patients with mild or moderate hepatic impairment. Bedaquiline has not been studied in patients with severe hepatic impairment (see section 4.2).
Renal impairment
SIRTURO has mainly been studied in patients with normal renal function. Renal excretion of unchanged bedaquiline is insignificant (< 0.001%).
In a population pharmacokinetic analysis of tuberculosis patients treated with SIRTURO 200 mg three times a week, creatinine clearance (range: 40 to 227 ml/min) was not found to influence the pharmacokinetic parameters of bedaquiline. It is therefore not expected that mild or moderate renal impairment will have a clinically relevant effect on the exposure to bedaquiline. However, in patients with severe renal impairment (creatinine clearance < 30 ml/min) or end-stage renal disease requiring haemodialysis or peritoneal dialysis, bedaquiline concentrations may be increased due to alteration of active substance absorption, distribution, and metabolism secondary to renal dysfunction. As bedaquiline is highly bound to plasma proteins, it is unlikely that it will be significantly removed from plasma by haemodialysis or peritoneal dialysis.
Paediatric patients
The pharmacokinetics of SIRTURO in paediatric patients have not been evaluated.
Elderly patients
There is limited clinical data (n = 2) on the use of SIRTURO in tuberculosis patients aged 65 years and older.
In a population pharmacokinetic analysis of tuberculosis patients (age range 18 years to 68 years) treated with SIRTURO age was not found to influence the pharmacokinetics of bedaquiline.
Race
In a population pharmacokinetic analysis of tuberculosis patients treated with SIRTURO, exposure to bedaquiline was found to be lower in Black patients than in patients from other race categories. This low exposure was not considered to be clinically relevant as no clear relationship between exposure to bedaquiline and response has been observed in clinical trials. Furthermore, response rates in patients that completed the bedaquiline treatment period were comparable between different race categories in the clinical trials.
Gender
In a population pharmacokinetic analysis of tuberculosis patients treated with SIRTURO no clinically relevant difference in exposure between men and women were observed.
5.3 Preclinical safety data
Animal toxicology studies have been conducted with bedaquiline administration up to 3 months in mice, up to 6 months in rats, and up to 9 months in dogs. The plasma bedaquiline exposure (AUC) in rats and dogs was similar to that observed in humans. Bedaquiline was associated with effects in target organs which included monocytic phagocytic system (MPS), skeletal muscle, liver, stomach, pancreas and heart muscle. All of these toxicities except effects on MPS were monitored clinically. In the MPS of all species, pigment-laden and/or foamy macrophages were also seen in various tissues, consistent with phospholipidosis. The significance of phospholipidosis in humans is unknown. Most of the observed changes occurred after prolonged daily dosing and subsequent increases in plasma and tissue concentrations of the active substance. After treatment cessation, all indications of toxicity exhibited at least partial recovery to good recovery.
In vitro and in vivo genotoxicity tests indicated that bedaquiline did not have any mutagenic or clastogenic effects. Bedaquiline is currently being evaluated for its carcinogenic potential.
Bedaquiline had no effects on fertility when evaluated in female rats. Three of 24 male rats treated with high bedaquiline doses failed to produce offspring in the fertility study. Normal spermatogenesis and a normal amount of spermatozoa in the epidydimides were noted in these animals. No structural abnormalities in the testes and epididymides were seen after up to 6-months of bedaquiline treatment. No relevant bedaquiline-related effects on developmental toxicity parameters were observed in rats and rabbits. The corresponding plasma exposure (AUC) was 2-fold higher in rats compared to humans. In the rat, no adverse effects were observed in a pre- and post-natal development study at maternal plasma exposure (AUC) similar to humans and exposure in the offspring 3-fold higher than in adult humans. There was no effect of maternal treatment with bedaquiline at any dose level on sexual maturation, behavioural development, mating performance, fertility or reproductive capacity of the F1 generation animals. Body weight decreases in pups were noted in high dose groups during the lactation period after exposure to bedaquiline via milk and were not a consequence of in utero exposure. Concentrations of bedaquiline in milk were 6- to12-fold higher that the maximum concentration observed in maternal plasma.
Environmental Risk Assessment (ERA)
Environmental risk assessment studies have shown that bedaquiline has the potential to be persistent, bioaccumulative and toxic to the environment (see section 6.6).
6. Pharmaceutical particulars
6.1 List of excipients
Lactose monohydrate
Maize starch
Hypromellose
Polysorbate 20
Microcrystalline cellulose
Croscarmellose sodium
Silica, colloidal anhydrous
Magnesium stearate
6.2 Incompatibilities
Not applicable.
6.3 Shelf life
2 years
6.4 Special precautions for storage
This medicinal product does not require any special temperature storage conditions.
Store in the original container in order to protect from light.
6.5 Nature and contents of container
188 tablets packaged in a white high density polyethylene (HDPE) bottle with child-resistant polypropylene (PP) closure with aluminium induction seal liner.
6.6 Special precautions for disposal and other handling
This medicinal product may pose a risk to the environment.
Any unused product or waste material should be disposed of in accordance with local requirements (see section 5.3).
7. Marketing authorisation holder
Janssen-Cilag International NV
Turnhoutseweg 30
B-2340 Beerse
Belgium
8. Marketing authorisation number(s)
EU/1/13/901/001
9. Date of first authorisation/renewal of the authorisation
05 March 2014
10. Date of revision of the text
Detailed information on this medicinal product is available on the website of the European Medicines Agency http://www.ema.europa.eu.
强生结核新药Situro获欧盟有条件批准
强生（JNJ）3月7日宣布，结核病新药Situro（bedaquiline）获欧盟委员会（EC）有条件批准（conditionalapproval），作为组合疗法的一部分，用于因耐药性或耐受性使得一种有效治疗方案不能用于其临床治疗的肺部耐多药结核病（MDR-TB）成人患者的治疗。
此前，Sirturo被指定为孤儿药地位，并于2013年12月获欧盟CHMP建议批准的积极意见。CHMP认为，强生所提供的数据表明，Sirturo的临床利益大于其风险，该药可能有助于应对多耐药结核病在新治疗选择方面远未满足的医疗需求，但这些数据尚不全面，因此，应该就Sirturo的使用开展更多的研究。
在美国，Sirturo于2012年12月通过加速审批程序获FDA批准，该药是近40年来首个具有全新作用机制的TB药物，同时也是有史以来首个明确用于MDR-TB的TB药物。Sirturo具有独特的作用机制，通过靶向ATP合成酶来杀死结核分枝杆菌（M.tb），而ATP合成酶对能量的生成至关重要。
Sirturo的获批，是基于一项II期临床开发项目的24周数据。根据规定，强生将开展一项III期试验，进一步证实Sirturo的利益风险，并确定其最佳使用，包括需要联合用药的药物类型、数量及最佳治疗期。
结核病（tuberculosis）是由结核杆菌（Mycobacteriumtuberculosis）引发的一种传染性疾病，主要影响肺部。在欧盟，结核病是一种罕见病，据2011年预计数据，结核病在欧盟的发病率约为万分之2.3。耐多药结核病是指至少对异烟肼（isoniazid）和利福平（rifampicin）耐药的结核病，这2种药物是用于结核病标准治疗中的2种主要的抗结核药物。据估计，在全球范围内，每年发生约45万例耐多药结核病病例，相当于全球每年结核病的5%。
近年来，由于缺乏新的治疗选择，耐药性结核病所导致的公共健康问题迅速增加。耐多药结核病与高的死亡率相关，已构成了严重的公共健康威胁，因为感染了耐药菌株的患者无法获得充分的治疗，并有可能传播感染。
Sirturo则为那些没有其他治疗选择的患者带来了希望。但是，该药也有一些严重的风险，医生应确保合理应用该药物，只适用于对其他抗结核治疗无效的患者。