Ofev

Nintedanib.

One soft capsule contains 100 mg or 150 mg nintedanib (as esilate).
Excipient with known effect: Each 100 mg and 150 mg soft capsule contains 1.2 mg and 1.8 mg of lecithin, respectively.
Excipients/Inactive Ingredients: Capsule content: Medium-chain triglycerides, hard fat, lecithin (E322).
Capsule shell: Gelatin, glycerol (85%), titanium dioxide (E171), iron oxide red (E172), iron oxide yellow (E172).
Printing ink: Shellac glaze, iron oxide black (E172), propylene glycol (E1520).

Pharmacotherapeutic group: Antineoplastic agents, protein kinase inhibitors. ATC code: L01EX09.
Pharmacology: Mechanism of action: Nintedanib is a small molecule tyrosine kinase inhibitor including the receptors platelet-derived growth factor receptor (PDGFR) α and β, fibroblast growth factor receptor (FGFR) 1-3, and VEGFR 1-3. In addition, nintedanib inhibits Lck (lymphocyte-specific tyrosine-protein kinase), Lyn (tyrosine-protein kinase lyn), Src (proto-oncogene tyrosine-protein kinase src), and CSF1R (colony stimulating factor 1 receptor) kinases. Nintedanib binds competitively to the adenosine triphosphate (ATP) binding pocket of these kinases and blocks the intracellular signalling cascades, which have been demonstrated to be involved in the pathogenesis of fibrotic tissue remodelling in interstitial lung diseases.
Pharmacodynamics: In in vitro studies using human cells nintedanib has been shown to inhibit processes assumed to be involved in the initiation of the fibrotic pathogenesis, the release of pro-fibrotic mediators from peripheral blood monocytic cells and macrophage polarisation to alternatively activated macrophages. Nintedanib has been demonstrated to inhibit fundamental processes in organ fibrosis, proliferation and migration of fibroblasts and transformation to the active myofibroblast phenotype and secretion of extracellular matrix. In animal studies in multiple models of IPF, SSc/SSc-ILD, rheumatoid arthritis-associated-(RA-)ILD and other organ fibrosis, nintedanib has shown anti-inflammatory effects and anti-fibrotic effects in the lung, skin, heart, kidney, and liver. Nintedanib also exerted vascular activity. It reduced dermal microvascular endothelial cell apoptosis and attenuated pulmonary vascular remodelling by reducing the proliferation of vascular smooth muscle cells, the thickness of pulmonary vessel walls and percentage of occluded pulmonary vessels.
Clinical efficacy and safety: Idiopathic pulmonary fibrosis (IPF): The clinical efficacy of nintedanib has been studied in patients with IPF in two phase III, randomised, double-blind, placebo-controlled studies with identical design (INPULSIS-1 (1199.32) and INPULSIS-2 (1199.34)). Patients with FVC baseline < 50% predicted or carbon monoxide diffusing capacity (DLCO, corrected for haemoglobin) < 30% predicted at baseline were excluded from the trials. Patients were randomized in a 3:2 ratio to treatment with Ofev 150 mg or placebo twice daily for 52 weeks.
The primary endpoint was the annual rate of decline in forced vital capacity (FVC). The key secondary endpoints were change from baseline in Saint George's Respiratory Questionnaire (SGRQ) total score at 52 weeks and time to first acute IPF exacerbation.
Annual rate of decline in FVC: The annual rate of decline of FVC (in mL) was significantly reduced in patients receiving nintedanib compared to patients receiving placebo. The treatment effect was consistent in both trials. See Table 1 for individual and pooled study results. (See Table 1.)

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In a sensitivity analysis which assumed that in patients with missing data at week 52 the FVC decline after the last observed value would be the same as in all placebo patients, the adjusted difference in the annual rate of decline between nintedanib and placebo was 113.9 mL/year (95% CI 69.2, 158.5) in INPULSIS-1 and 83.3 mL/year (95% CI 37.6, 129.0) in INPULSIS-2.
See Figure 1 for the evolution of change from baseline over time in both treatment groups, based on the pooled analysis of studies INPULSIS-1 and INPULSIS-2. (See Figure 1.)

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FVC responder analysis: In both INPULSIS trials, the proportion of FVC responders, defined as patients with an absolute decline in FVC % predicted no greater than 5% (a threshold indicative of the increasing risk of mortality in IPF), was significantly higher in the nintedanib group as compared to placebo. Similar results were observed in analyses using a conservative threshold of 10%. See Table 2 for individual and pooled study results. (See Table 2.)

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Time to progression (≥ 10% absolute decline of FVC % predicted or death): In both INPULSIS trials, the risk of progression was statistically significantly reduced for patients treated with nintedanib compared with placebo. In the pooled analysis, the HR was 0.60 indicating a 40% reduction in the risk of progression for patients treated with nintedanib compared with placebo. (See Table 3.)

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Change from baseline in SGRQ total score at week 52: In the pooled analysis of the INPULSIS trials, the baseline SGRQ scores were 39.51 in the nintedanib group and 39.58 in the placebo group. The estimated mean change from baseline to week 52 in SGRQ total score was smaller in the nintedanib group (3.53) than in the placebo group (4.96), with a difference between the treatment groups of -1.43 (95% CI: -3.09, 0.23; p=0.0923). Overall, the effect of nintedanib on health-related quality of life as measured by the SGRQ total score is modest, indicating less worsening compared to placebo.
Time to first acute IPF exacerbation: In the pooled analysis of the INPULSIS trials, a numerically lower risk of first acute exacerbation was observed in patients receiving nintedanib compared to placebo. See Table 4 for individual and pooled study results. (See Table 4.)

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In a pre-specified sensitivity analysis, the frequency of patients with at least 1 adjudicated exacerbation occurring within 52 weeks was lower in the nintedanib group (1.9% of patients) than in the placebo group (5.7% of patients). Time to event analysis of the adjudicated exacerbation events using pooled data yielded a hazard ratio (HR) of 0.32 (95% CI 0.16, 0.65; p=0.0010).
Survival analysis: In the pre-specified pooled analysis of survival data of the INPULSIS trials, overall mortality over 52 weeks was lower in the nintedanib group (5.5%) compared with the placebo group (7.8%). The analysis of time to death resulted in a HR of 0.70 (95% CI 0.43, 1.12; p=0.1399). The results of all survival endpoints (such as on-treatment mortality and respiratory mortality) showed a consistent numerical difference in favour of nintedanib. (See Table 5.)

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Long-term treatment with Ofev in patients with IPF (INPULSIS-ON): An open-label extension trial of Ofev included 734 patients with IPF. Patients who completed the 52-week treatment period in an INPULSIS trial received open-label Ofev treatment in the extension trial INPULSIS-ON. Median exposure time for patients treated with Ofev in both the INPULSIS and INPULSIS-ON trials was 44.7 months (range 11.9 - 68.3). The exploratory efficacy endpoints included the annual rate of decline in FVC over 192 weeks which was -135.1 (5.8) mL/year in all patients treated and were consistent with the annual rate of FVC decline in patients treated with Ofev in the INPULSIS phase III trials (-113.6 mL per year). The adverse event profile of Ofev in INPULSIS-ON was consistent to that in the INPULSIS phase III trials.
IPF patients with advanced lung function impairment (INSTAGE): INSTAGE was a multicentre, multinational, prospective, randomised, double-blind, parallel-group clinical trial in IPF patients with advanced lung function impairment (DLCO ≤ 35% predicted) for 24 weeks. 136 patients were treated with Ofev monotherapy. Primary endpoint result showed a reduction of St Georges Respiratory Questionnaire (SGRQ) total score by -0.77 units at week W12, based on adjusted mean change from baseline. A post hoc comparison demonstrated that the decline in FVC in these patients was consistent with the decline in FVC in patients with less advanced disease and treated with Ofev in the INPULSIS phase III trials.
The safety and tolerability profile of Ofev in IPF patients with advanced lung function impairment was consistent with that seen in the INPULSIS phase III trials.
Additional data from the phase IV INJOURNEY trial with Ofev 150 mg twice daily and add-on pirfenidone: Concomitant treatment with nintedanib and pirfenidone has been investigated in an exploratory open-label, randomised trial of nintedanib 150 mg twice daily with add-on pirfenidone (titrated to 801 mg three times a day) compared to nintedanib 150 mg twice daily alone in 105 randomised patients for 12 weeks. The primary endpoint was the percentage of patients with gastrointestinal adverse events from baseline to week 12. Gastrointestinal adverse events were frequent and in line with the established safety profile of each component. Diarrhoea, nausea and vomiting were the most frequent adverse events reported in patients, treated with pirfenidone added to nintedanib versus nintedanib alone, respectively.
Mean (SE) absolute changes from baseline in FVC at week 12 were -13.3 (17.4) mL in patients treated with nintedanib with add-on pirfenidone (n=48) compared to -40.9 (31.4) mL in patients treated with nintedanib alone (n=44).
Other chronic fibrosing interstitial lung diseases (ILDs) with a progressive phenotype: The clinical efficacy of Ofev has been studied in patients with other chronic fibrosing ILDs with a progressive phenotype in a double-blind, randomised, placebo-controlled phase III trial (INBUILD). Patients with IPF were excluded. Patients with a clinical diagnosis of a chronic fibrosing ILD were selected if they had relevant fibrosis (greater than 10% fibrotic features) on HRCT and presented with clinical signs of progression (defined as FVC decline ≥10%, FVC decline ≥ 5% and <10% with worsening symptoms or imaging, or worsening symptoms and worsening imaging all in the 24 months prior to screening). Patients were required to have an FVC greater than or equal to 45% of predicted and a DLCO 30% to less than 80% of predicted. Patients were required to have progressed despite management deemed appropriate in clinical practice for the patient's relevant ILD.
A total of 663 patients were randomised in a 1:1 ratio to receive either Ofev 150 mg bid or matching placebo for at least 52 weeks. The median Ofev exposure over the whole trial was 17.4 months and the mean Ofev exposure over the whole trial was 15.6 months. Randomisation was stratified based on HRCT fibrotic pattern as assessed by central readers. 412 patients with HRCT with usual interstitial pneumonia (UIP)-like fibrotic pattern and 251 patients with other HRCT fibrotic patterns were randomised. There were 2 co-primary populations defined for the analyses in this trial: all patients (the overall population) and patients with HRCT with UIP-like fibrotic pattern. Patients with other HRCT fibrotic patterns represented the 'complementary' population.
The primary endpoint was the annual rate of decline in forced vital capacity (FVC) (in mL) over 52 weeks. Main secondary endpoints were absolute change from baseline in King's Brief Interstitial Lung Disease Questionnaire (K-BILD) total score at week 52, time to first acute ILD exacerbation or death over 52 weeks, and time to death over 52 weeks.
Patients had a mean (standard deviation [SD, Min-Max]) age of 65.8 (9.8, 27-87) years and a mean FVC percent predicted of 69.0% (15.6, 42-137). The underlying clinical ILD diagnoses in groups represented in the trial were hypersensitivity pneumonitis (26.1%), autoimmune ILDs (25.6%), idiopathic nonspecific interstitial pneumonia (18.9%), unclassifiable idiopathic interstitial pneumonia (17.2%), and other ILDs (12.2%).
The INBUILD trial was not designed or powered to provide evidence for a benefit of nintedanib in specific diagnostic subgroups. Consistent effects were demonstrated in subgroups based on the ILD diagnoses. The experience with nintedanib in very rare progressive fibrosing ILDs is limited.
Annual rate of decline in FVC: The annual rate of decline in FVC (in mL) over 52 weeks was significantly reduced by 107.0 mL in patients receiving Ofev compared to patients receiving placebo (Table 6) corresponding to a relative treatment effect of 57.0%. (See Table 6.)

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Similar results were observed in the co-primary population of patients with HRCT with UIP-like fibrotic pattern. The treatment effect was consistent in the complementary population of patients with other HRCT fibrotic patterns (interaction p-value 0.2268) (see Figure 2).

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The results of the effect of Ofev in reducing the annual rate of decline in FVC were confirmed by all pre-specified sensitivity analyses and consistent results were observed in the pre-specified efficacy subgroups: gender, age group, race, predicted baseline FVC %, and original underlying clinical ILD diagnosis in groups.
Figure 3 shows the evolution of change in FVC from baseline over time in the treatment groups. (See Figure 3.)

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In addition, favourable effects of Ofev were observed on the adjusted mean absolute change from baseline in FVC % predicted at week 52. The adjusted mean absolute change from baseline to week 52 in FVC % predicted was lower in the nintedanib group (-2.62%) than in the placebo group (-5.86%). The adjusted mean difference between the treatment groups was 3.24 (95% CI: 2.09, 4.40, nominal p<0.0001).
FVC responder analysis: The proportion of FVC responders, defined as patients with a relative decline in FVC % predicted no greater than 5%, was higher in the Ofev group as compared to placebo. Similar results were observed in analyses using a threshold of 10% (see Table 7).

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Time to first acute ILD exacerbation or death: Over the whole trial, the proportion of patients with at least one event of first acute ILD exacerbation or death was 13.9% in the Ofev group and 19.6% in the placebo group. The HR was 0.67 (95% CI: 0.46, 0.98; nominal p=0.0387), indicating a 33% reduction in the risk of first acute ILD exacerbation or death in patients receiving Ofev compared to placebo (see Figure 4).

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Survival analysis: The risk of death was lower in the Ofev group compared to the placebo group. The HR was 0.78 (95% CI: 0.50, 1.21; nominal p=0.2594), indicating a 22% reduction in the risk of death in patients receiving Ofev compared to placebo.
Time to progression (≥ 10% absolute decline of FVC % predicted) or death: In the INBUILD trial, the risk of progression (≥ 10% absolute decline of FVC % predicted) or death was reduced for patients treated with Ofev. The proportion of patients with an event was 40.4% in the Ofev group and 54.7% in the placebo group. The HR was 0.66 (95% CI: 0.53, 0.83; p=0.0003), indicating a 34% reduction of the risk of progression (≥ 10% absolute decline of FVC % predicted) or death in patients receiving Ofev compared to placebo.
Quality of life: The adjusted mean change from baseline in K-BILD total score at week 52 was -0.79 units in the placebo group and 0.55 in the Ofev group. The difference between the treatment groups was 1.34 (95% CI: -0.31, 2.98; nominal p=0.1115).
The adjusted mean absolute change from baseline in Living with Pulmonary Fibrosis (L-PF) symptoms dyspnoea domain score at week 52 was 4.28 in the Ofev group compared with 7.81 in the placebo group. The adjusted mean difference between the groups in favour of Ofev was -3.53 (95% CI: -6.14, -0.92; nominal p=0.0081). The adjusted mean absolute change from baseline in L-PF Symptoms cough domain score at week 52 was -1.84 in the Ofev group compared with 4.25 in the placebo group. The adjusted mean difference between the groups in favour of Ofev was -6.09 (95% CI: -9.65, -2.53; nominal p=0.0008).
Systemic sclerosis associated interstitial lung disease (SSc-ILD): The clinical efficacy of Ofev has been studied in patients with SSc-ILD in a double-blind, randomised, placebo-controlled phase III trial (SENSCIS). Patients were diagnosed with SSc-ILD based upon the 2013 American College of Rheumatology / European League Against Rheumatism classification criteria for SSc and a chest high resolution computed tomography (HRCT) scan conducted within the previous 12 months. A total of 580 patients were randomised in a 1:1 ratio to receive either Ofev 150 mg bid or matching placebo for at least 52 weeks, of which 576 patients were treated. Randomisation was stratified by antitopoisomerase antibody status (ATA). Individual patients stayed on blinded trial treatment for up to 100 weeks (median Ofev exposure 15.4 months; mean Ofev exposure 14.5 months).
The primary endpoint was the annual rate of decline in FVC over 52 weeks. Key secondary endpoints were absolute change from baseline in the modified Rodnan Skin Score (mRSS) at week 52 and absolute change from baseline in the Saint George's Respiratory Questionnaire (SGRQ) total score at week 52.
In the overall population, 75.2% of the patients were female. The mean (standard deviation [SD, Min-Max]) age was 54.0 (12.2, 20-79) years. Overall, 51.9% of patients had diffuse cutaneous systemic sclerosis (SSc) and 48.1% had limited cutaneous SSc. The mean (SD) time since first onset of a non-Raynaud symptom was 3.49 (1.7) years. 49.0% of patients were on stable therapy with mycophenolate at baseline (46.5% mycophenolate mofetil, 1.9% mycophenolate sodium, 0.5% mycophenolic acid). The safety profile in patients with or without mycophenolate at baseline was comparable.
Annual rate of decline in FVC: The annual rate of decline of FVC (mL) over 52 weeks was significantly reduced by 41.0 mL in patients receiving Ofev compared to patients receiving placebo (Table 8) corresponding to a relative treatment effect of 43.8%. (See Table 8.)

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The effect of Ofev in reducing the annual rate of decline in FVC was similar across pre-specified sensitivity analyses and no heterogeneity was detected in pre-specified subgroups (e.g. by age, gender, and mycophenolate use).
In addition, similar effects were observed on other lung function endpoints, e.g absolute change from baseline in FVC in mL at week 52 (Figure 5 and Table 9) and rate of decline in FVC in % predicted over 52 weeks (Table 10) providing further substantiation of the effects of Ofev on slowing progression of SSc-ILD. Furthermore, fewer patients in the Ofev group had an absolute FVC decline > 5% predicted (20.6% in the Ofev group vs. 28.5% in the placebo group, OR=0.65, p=0.0287). The relative FVC decline in mL > 10% was comparable between both groups (16.7% in the Ofev group vs. 18.1% in the placebo group, OR=0.91, p=0.6842). In these analyses, missing FVC values at week 52 were imputed with the patient's worst value on treatment.
An exploratory analysis of data up to 100 weeks (maximum treatment duration in SENSCIS) suggested that the on treatment effect of Ofev on slowing progression of SSc-ILD persisted beyond 52 weeks. (See Figure 5 and Tables 9 and 10.)

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Change from baseline in Modified Rodnan Skin Score (mRSS) at week 52: The adjusted mean absolute change from baseline in mRSS at week 52 was comparable between the Ofev group (-2.17 (95% CI -2.69, -1.65)) and the placebo group (-1.96 (95% CI -2.48, -1.45)). The adjusted mean difference between the treatment groups was -0.21 (95% CI -0.94, 0.53; p = 0.5785).
Change from baseline in St. George's Respiratory Questionnaire (SGRQ) total score at week 52: The adjusted mean absolute change from baseline in SGRQ total score at week 52 was comparable between the Ofev group (0.81 (95% CI -0.92, 2.55)) and the placebo group (-0.88 (95% CI -2.58, 0.82)). The adjusted mean difference between the treatment groups was 1.69 (95% CI -0.73, 4.12; p = 0.1711).
Survival analysis: Mortality over the whole trial was comparable between the Ofev group (N = 10; 3.5%) and the placebo group (N = 9; 3.1%). The analysis of time to death over the whole trial resulted in a HR of 1.16 (95% CI 0.47, 2.84; p = 0.7535).
QT interval: In a dedicated study in renal cell cancer patients, QT/QTc measurements were recorded and showed that a single oral dose of 200 mg nintedanib as well as multiple oral doses of 200 mg nintedanib administered twice daily for 15 days did not prolong the QTcF interval.
Paediatric population: The European Medicines Agency has waived the obligation to submit the results of studies with Ofev in all subsets of the paediatric population in IPF (see Dosage & Administration for information on paediatric use).
Pharmacokinetics: Absorption: Nintedanib reached maximum plasma concentrations approximately 2 - 4 h after oral administration as soft gelatine capsule under fed conditions (range 0.5 - 8 h). The absolute bioavailability of a 100 mg dose was 4.69% (90% CI: 3.615 - 6.078) in healthy volunteers. Absorption and bioavailability are decreased by transporter effects and substantial first-pass metabolism. Dose proportionality was shown by increase of nintedanib exposure (dose range 50 - 450 mg once daily and 150 - 300 mg twice daily). Steady state plasma concentrations were achieved within one week of dosing at the latest.
After food intake, nintedanib exposure increased by approximately 20% compared to administration under fasted conditions (CI: 95.3 - 152.5%) and absorption was delayed (median t_max fasted: 2.00 h; fed: 3.98 h).
Distribution: Nintedanib follows at least bi-phasic disposition kinetics. After intravenous infusion, a high volume of distribution (Vss: 1,050 L, 45.0% gCV) was observed.
The in vitro protein binding of nintedanib in human plasma was high, with a bound fraction of 97.8%. Serum albumin is considered to be the major binding protein. Nintedanib is preferentially distributed in plasma with a blood to plasma ratio of 0.869.
Biotransformation: The prevalent metabolic reaction for nintedanib is hydrolytic cleavage by esterases resulting in the free acid moiety BIBF 1202. BIBF 1202 is subsequently glucuronidated by uridine 5'-diphospho-glucuronosyltransferase (UGT) enzymes, namely UGT 1A1, UGT 1A7, UGT 1A8, and UGT 1A10 to BIBF 1202 glucuronide.
Only a minor extent of the biotransformation of nintedanib consisted of CYP pathways, with CYP 3A4 being the predominant enzyme involved. The major CYP-dependent metabolite could not be detected in plasma in the human ADME study. In vitro, CYP-dependent metabolism accounted for about 5% compared to about 25% ester cleavage. Nintedanib, BIBF 1202, and BIBF 1202 glucuronide did not inhibit or induce CYP enzymes in preclinical studies, either. Drug-drug interactions between nintedanib and CYP substrates, CYP inhibitors, or CYP inducers are therefore not expected.
Elimination: Total plasma clearance after intravenous infusion was high (CL: 1,390 mL/min, 28.8% gCV). Urinary excretion of the unchanged active substance within 48 h was about 0.05% of the dose (31.5% gCV) after oral and about 1.4% of the dose (24.2% gCV) after intravenous administration; the renal clearance was 20 mL/min (32.6% gCV). The major route of elimination of drug related radioactivity after oral administration of [¹⁴C] nintedanib was via faecal/biliary excretion (93.4% of dose, 2.61% gCV). The contribution of renal excretion to the total clearance was low (0.649% of dose, 26.3% gCV). The overall recovery was considered complete (above 90%) within 4 days after dosing. The terminal half-life of nintedanib was between 10 and 15 h (gCV % approximately 50%).
Linearity/non-linearity: The pharmacokinetics (PK) of nintedanib can be considered linear with respect to time (i.e. single-dose data can be extrapolated to multiple-dose data). Accumulation upon multiple administrations was 1.04-fold for C_max and 1.38-fold for AUC_τ. Nintedanib trough concentrations remained stable for more than one year.
Transport: Nintedanib is a substrate of P-gp. For the interaction potential of nintedanib with this transporter, see Interactions. Nintedanib was shown to be not a substrate or inhibitor of OATP-1B1, OATP-1B3, OATP-2B1, OCT-2 or MRP-2 in vitro. Nintedanib was also not a substrate of BCRP. Only a weak inhibitory potential on OCT-1, BCRP, and P-gp was observed in vitro which is considered to be of low clinical relevance. The same applies for nintedanib being a substrate of OCT-1.
Population pharmacokinetic analysis in special populations: The PK properties of nintedanib were similar in healthy volunteers, patients with IPF, patients with other chronic fibrosing ILDs with a progressive phenotype, patients with SSc-ILD, and cancer patients. Based on results of a population PK (PopPK) analysis in patients with IPF and non-small cell lung cancer (NSCLC) (N=1,191) and descriptive investigations, exposure to nintedanib was not influenced by sex (body weight corrected), mild and moderate renal impairment (estimated by creatinine clearance), alcohol consumption, or P-gp genotype.
PopPK analyses indicated moderate effects on exposure to nintedanib depending on age, body weight, and race (see as follows). Based on the high inter-individual variability of exposure observed moderate effects are considered not clinically relevant (see Precautions).
Age: Exposure to nintedanib increased linearly with age. AUC_τ,ss decreased by 16% for a 45-year old patient and increased by 13% for a 76-year old patient relative to a patient with the median age of 62 years. The age range covered by the analysis was 29 to 85 years; approximately 5% of the population were older than 75 years. Based on a PopPK model, an increase in nintedanib exposure of approximately 20 - 25% was observed in patients ≥ 75 years compared with patients under 65 years.
Studies in paediatric populations have not been performed.
Body weight: An inverse correlation between body weight and exposure to nintedanib was observed. AUC_τ,ss increased by 25% for a 50 kg patient (5^th percentile) and decreased by 19% for a 100 kg patient (95^th percentile) relative to a patient with the median weight of 71.5 kg.
Race: The population mean exposure to nintedanib was 33 - 50% higher in Chinese, Taiwanese, and Indian patients and 16% higher in Japanese patients while it was 16 - 22% lower in Koreans compared to Caucasians (body weight corrected). Data from Black individuals were very limited but in the same range as for Caucasians.
Hepatic impairment: In a dedicated single dose phase I study and compared to healthy subjects, exposure to nintedanib based on C_max and AUC was 2.2-fold higher in volunteers with mild hepatic impairment (Child Pugh A; 90% CI 1.3 - 3.7 for C_max and 1.2 - 3.8 for AUC, respectively). In volunteers with moderate hepatic impairment (Child Pugh B), exposure was 7.6-fold higher based on C_max (90% CI 4.4 - 13.2) and 8.7-fold higher (90% CI 5.7 - 13.1) based on AUC, respectively, compared to healthy volunteers. Subjects with severe hepatic impairment (Child Pugh C) have not been studied.
Concomitant treatment with pirfenidone: In a dedicated pharmacokinetic study, concomitant treatment of nintedanib with pirfenidone was investigated in patients with IPF. Group 1 received a single dose of 150 mg nintedanib before and after uptitration to 801 mg pirfenidone three times a day at steady state (N=20 patients treated). Group 2 received steady state treatment of 801 mg pirfenidone three times a day and had a PK profiling before and after at least 7 days of co-treatment with 150 mg nintedanib twice daily (N=17 patients treated). In group 1, the adjusted geometric mean ratios (90% confidence interval (CI)) were 93% (57% - 151%) and 96% (70% - 131%) for C_max and AUC_0-tz of nintedanib, respectively (n=12 for intraindividual comparison). In group 2, the adjusted geometric mean ratios (90% CI) were 97% (86% - 110%) and 95% (86% - 106%) for C_max,ss and AUC_τ,ss of pirfenidone, respectively (n=12 for intraindividual comparison).
Based on these results, there is no evidence of a relevant pharmacokinetic drug-drug interaction between nintedanib and pirfenidone when administered in combination (see Precautions).
Concomitant treatment with bosentan: In a dedicated pharmacokinetic study, concomitant treatment of Ofev with bosentan was investigated in healthy volunteers. Subjects received a single dose of 150 mg Ofev before and after multiple dosing of 125 mg bosentan twice daily at steady state. The adjusted geometric mean ratios (90% confidence interval (CI)) were 103% (86% - 124%) and 99% (91% - 107%) for C_max and AUC_0-tz of nintedanib, respectively (n=13), indicating that co-administration of nintedanib with bosentan did not alter the pharmacokinetics of nintedanib.
Concomitant treatment with oral hormonal contraceptives: In a dedicated pharmacokinetic study, female patients with SSc-ILD received a single dose of a combination of 30 μg ethinylestradiol and 150 μg levonorgestrel before and after twice daily dosing of 150 mg nintedanib for at least 10 days. The adjusted geometric mean ratios (90% confidence interval (CI)) were 117% (108% - 127%; C_max) and 101% (93% - 111%; AUC_0–tz) for ethinylestradiol and 101% (90% - 113%; C_max) and 96% (91% - 102%; AUC_0–tz) for levonorgestrel, respectively (n=15), indicating that co-administration of nintedanib has no relevant effect on the plasma exposure of ethinylestradiol and levonorgestrel.
Exposure-response relationship: Exposure-response analyses of patients with IPF and other chronic fibrosing ILDs with a progressive phenotype, indicated a weak relationship between nintedanib plasma exposure and ALT and/or AST elevations. Actual administered dose might be the better predictor for the risk of developing diarrhoea of any intensity, even if plasma exposure as risk determining factor could not be ruled out (see Precautions).
Toxicology: Preclinical safety data: General toxicology: Single dose toxicity studies in rats and mice indicated a low acute toxic potential of nintedanib. In repeat dose toxicology studies in rats, adverse effects (e.g. thickening of epiphyseal plates, lesions of the incisors) were mostly related to the mechanism of action (i.e. VEGFR-2 inhibition) of nintedanib. These changes are known from other VEGFR-2 inhibitors and can be considered class effects.
Diarrhoea and vomiting accompanied by reduced food consumption and loss of body weight were observed in toxicity studies in non-rodents.
There was no evidence of liver enzyme increases in rats, dogs, and cynomolgus monkeys. Mild liver enzyme increases which were not due to serious adverse effects such as diarrhea were only observed in rhesus monkeys.
Reproduction toxicity: In rats, embryo-foetal lethality and teratogenic effects were observed at exposure levels below human exposure at the MRHD of 150 mg twice daily. Effects on the development of the axial skeleton and on the development of the great arteries were also noted at subtherapeutic exposure levels.
In rabbits, embryo-foetal lethality and teratogenic effects were observed at an exposure approximately 3 times higher than at the MRHD but equivocal effects on the embryo-foetal development of the axial skeleton and the heart were noted already at an exposure below that at the MRHD of 150 mg twice daily.
In a pre- and postnatal development study in rats, effects on pre- and post-natal development were seen at an exposure below the MRHD.
A study of male fertility and early embryonic development up to implantation in rats did not reveal effects on the male reproductive tract and male fertility.
In rats, small amounts of radiolabelled nintedanib and/or its metabolites were excreted into the milk (≤ 0.5% of the administered dose).
From the 2-year carcinogenicity studies in mice and rats, there was no evidence for a carcinogenic potential of nintedanib.
Genotoxicity studies indicated no mutagenic potential for nintedanib.

Ofev is indicated in adults for the treatment of idiopathic pulmonary fibrosis (IPF).
Ofev is also indicated in adults for the treatment of other chronic fibrosing interstitial lung diseases (ILDs) with a progressive phenotype (see Pharmacology: Pharmacodynamics under Actions).
Ofev is indicated in adults for the treatment of systemic sclerosis associated interstitial lung disease (SSc-ILD).

Treatment should be initiated by physicians experienced in the management of diseases for which Ofev is approved.
Posology: The recommended dose is 150 mg nintedanib twice daily administered approximately 12 hours apart. The 100 mg twice daily dose is only recommended to be used in patients who do not tolerate the 150 mg twice daily dose.
If a dose is missed, administration should resume at the next scheduled time at the recommended dose. If a dose is missed the patient should not take an additional dose. The recommended maximum daily dose of 300 mg should not be exceeded.
Dose adjustments: In addition to symptomatic treatment if applicable, the management of adverse reactions to Ofev (see Precautions and Adverse Reactions) could include dose reduction and temporary interruption until the specific adverse reaction has resolved to levels that allow continuation of therapy. Ofev treatment may be resumed at the full dose (150 mg twice daily) or a reduced dose (100 mg twice daily). If a patient does not tolerate 100 mg twice daily, treatment with Ofev should be discontinued.
If diarrhoea, nausea and/or vomiting persist despite appropriate supportive care (including anti-emetic therapy), dose reduction or treatment interruption may be required. The treatment may be resumed at a reduced dose (100 mg twice daily) or at the full dose (150 mg twice daily). In case of persisting severe diarrhoea, nausea and/or vomiting despite symptomatic treatment, therapy with Ofev should be discontinued (see Precautions).
In case of interruptions due to aspartate aminotransferase (AST) or alanine aminotransferase (ALT) elevations > 3x upper limit of normal (ULN), once transaminases have returned to baseline values, treatment with Ofev may be reintroduced at a reduced dose (100 mg twice daily) which subsequently may be increased to the full dose (150 mg twice daily) (see Precautions and Adverse Reactions).
Special populations: Elderly patients (≥ 65 years): No overall differences in safety and efficacy were observed for elderly patients. No a-priori dose adjustment is required on the basis of a patient's age. Patients ≥75 years may be more likely to require dose reduction to manage adverse effects (see Pharmacology: Pharmacokinetics under Actions).
Renal impairment: Adjustment of the starting dose in patients with mild to moderate renal impairment is not required. The safety, efficacy, and pharmacokinetics of nintedanib have not been studied in patients with severe renal impairment (<30 ml/min creatinine clearance).
Hepatic impairment: In patients with mild hepatic impairment (Child Pugh A), the recommended dose of Ofev is 100 mg twice daily approximately 12 hours apart. In patients with mild hepatic impairment (Child Pugh A), treatment interruption or discontinuation for management of adverse reactions should be considered. The safety and efficacy of nintedanib have not been investigated in patients with hepatic impairment classified as Child Pugh B and C. Treatment of patients with moderate (Child Pugh B) and severe (Child Pugh C) hepatic impairment with Ofev is not recommended (see Pharmacology: Pharmacokinetics under Actions).
Paediatric population: The safety and efficacy of Ofev in children aged 0-18 years have not been established. No data are available.
Method of administration: Ofev is for oral use. The capsules should be taken with food, swallowed whole with water, and should not be chewed. The capsule should not be opened or crushed (see Special precautions for disposal and other handling under Cautions for Usage).

There is no specific antidote or treatment for Ofev overdose. Two patients in the oncology programme had an overdose of maximum 600 mg twice daily up to eight days. Observed adverse reactions were consistent with the known safety profile of nintedanib, i.e. increased liver enzymes and gastrointestinal symptoms. Both patients recovered from these adverse reactions. In the INPULSIS trials, one patient was inadvertently exposed to a dose of 600 mg daily for a total of 21 days. A non-serious adverse event (nasopharyngitis) occurred and resolved during the period of incorrect dosing, with no onset of other reported events. In case of overdose, treatment should be interrupted and general supportive measures initiated as appropriate.

Pregnancy (see Use in Pregnancy & Lactation).
Hypersensitivity to nintedanib, to peanut or soya, or to any of the excipients listed in Description.

Gastrointestinal disorders: Diarrhoea: In the clinical trials (see Pharmacology: Pharmacodynamics under Actions), diarrhoea was the most frequent gastro-intestinal adverse reaction reported (see Adverse Reactions). In most patients, the adverse reaction was of mild to moderate intensity and occurred within the first 3 months of treatment.
Serious cases of diarrhoea leading to dehydration and electrolyte disturbances have been reported in the post-marketing. Patients should be treated at first signs with adequate hydration and anti-diarrhoeal medicinal products, e.g. loperamide, and may require dose reduction or treatment interruption. Ofev treatment may be resumed at a reduced dose (100 mg twice daily) or at the full dose (150 mg twice daily). In case of persisting severe diarrhoea despite symptomatic treatment, therapy with Ofev should be discontinued.
Nausea and vomiting: Nausea and vomiting were frequently reported gastrointestinal adverse reactions (see Adverse Reactions). In most patients with nausea and vomiting, the event was of mild to moderate intensity. In clinical trials, nausea led to discontinuation of Ofev in up to 2.1% of patients and vomiting led to discontinuation of Ofev in up to 1.4% of patients.
If symptoms persist despite appropriate supportive care (including anti-emetic therapy), dose reduction or treatment interruption may be required. The treatment may be resumed at a reduced dose (100 mg twice daily) or at the full dose (150 mg twice daily). In case of persisting severe symptoms therapy with Ofev should be discontinued.
Hepatic function: The safety and efficacy of Ofev has not been studied in patients with moderate (Child Pugh B) or severe (Child Pugh C) hepatic impairment. Therefore, treatment with Ofev is not recommended in such patients (see Dosage & Administration). Based on increased exposure, the risk for adverse reactions may be increased in patients with mild hepatic impairment (Child Pugh A). Patients with mild hepatic impairment (Child Pugh A) should be treated with a reduced dose of Ofev (see Dosage & Administration and Pharmacology: Pharmacokinetics under Actions).
Cases of drug-induced liver injury have been observed with nintedanib treatment, including severe liver injury with fatal outcome. The majority of hepatic events occur within the first three months of treatment. Therefore, hepatic transaminase and bilirubin levels should be investigated before treatment initiation and during the first month of treatment with Ofev. Patients should then be monitored at regular intervals during the subsequent two months of treatment and periodically thereafter, e.g. at each patient visit or as clinically indicated.
Elevations of liver enzymes (ALT, AST, blood alkaline phosphatase (ALKP), gamma-glutamyl-transferase (GGT), see Adverse Reactions) and bilirubin were reversible upon dose reduction or interruption in the majority of cases. If transaminase (AST or ALT) elevations > 3x ULN are measured, dose reduction or interruption of the therapy with Ofev is recommended and the patient should be monitored closely. Once transaminases have returned to baseline values, treatment with Ofev may be resumed at the full dose (150 mg twice daily) or reintroduced at a reduced dose (100 mg twice daily) which subsequently may be increased to the full dose (see Dosage & Administration). If any liver test elevations are associated with clinical signs or symptoms of liver injury, e.g. jaundice, treatment with Ofev should be permanently discontinued. Alternative causes of the liver enzyme elevations should be investigated.
Patients with low body weight (< 65 kg), Asian and female patients have a higher risk of elevations of liver enzymes. Nintedanib exposure increased linearly with patient age, which may also result in a higher risk of developing liver enzyme elevations (see Pharmacology: Pharmacokinetics under Actions). Close monitoring is recommended in patients with these risk factors.
Renal function: Cases of renal impairment/failure, in some cases with fatal outcome, have been reported with nintedanib use (see Adverse Reactions).
Patients should be monitored during nintedanib therapy, with particular attention to those patients exhibiting risk factors for renal impairment/failure. In case of renal impairment/failure, therapy adjustment should be considered (see Dose adjustments under Dosage & Administration).
Haemorrhage: Vascular endothelial growth factor receptor (VEGFR) inhibition might be associated with an increased risk of bleeding.
Patients at known risk for bleeding including patients with inherited predisposition to bleeding or patients receiving a full dose of anticoagulative treatment were not included in the clinical trials. Non-serious and serious bleeding events, some of which were fatal, have been reported in the post-marketing period (including patients with or without anticoagulant therapy or other medicinal products that could cause bleeding). Therefore, these patients should only be treated with Ofev if the anticipated benefit outweighs the potential risk.
Arterial thromboembolic events: Patients with a recent history of myocardial infarction or stroke were excluded from the clinical trials. In the clinical trials, arterial thromboembolic events were infrequently reported (Ofev 2.5% versus placebo 0.7% for INPULSIS; Ofev 0.9% versus placebo 0.9% for INBUILD; Ofev 0.7% versus placebo 0.7% for SENSCIS). In the INPULSIS trials, a higher percentage of patients experienced myocardial infarctions in the Ofev group (1.6%) compared to the placebo group (0.5%), while adverse events reflecting ischaemic heart disease were balanced between the Ofev and placebo groups. In the INBUILD trial, myocardial infarction was observed with low frequency: Ofev 0.9% versus placebo 0.9%. In the SENSCIS trial, myocardial infarction was observed with low frequency in the placebo group (0.7%) and not observed in the Ofev group. Caution should be used when treating patients at higher cardiovascular risk including known coronary artery disease. Treatment interruption should be considered in patients who develop signs or symptoms of acute myocardial ischemia.
Aneurysms and artery dissections: The use of VEGF pathway inhibitors in patients with or without hypertension may promote the formation of aneurysms and/or artery dissections. Before initiating Ofev, this risk should be carefully considered in patients with risk factors such as hypertension or history of aneurysm.
Venous thromboembolism: In the clinical trials, no increased risk of venous thromboembolism was observed in nintedanib treated patients. Due to the mechanism of action of nintedanib patients might have an increased risk of thromboembolic events.
Gastrointestinal perforations and ischaemic colitis: In the clinical trials, the frequency of patients with perforation was up to 0.3% in both treatment groups. Due to the mechanism of action of nintedanib, patients might have an increased risk of gastrointestinal perforations. Cases of gastrointestinal perforations and cases of ischaemic colitis, some of which were fatal, have been reported in the post-marketing period. Particular caution should be exercised when treating patients with previous abdominal surgery, previous history of peptic ulceration, diverticular disease or receiving concomitant corticosteroids or NSAIDs. Ofev should only be initiated at least 4 weeks after abdominal surgery. Therapy with Ofev should be permanently discontinued in patients who develop gastrointestinal perforation or ischaemic colitis. Exceptionally, Ofev can be reintroduced after complete resolution of ischaemic colitis and careful assessment of patient's condition and other risk factors.
Nephrotic range proteinuria and thrombotic microangiopathy: Very few cases of nephrotic range proteinuria with or without renal function impairment have been reported post-marketing. Histological findings in individual cases were consistent with glomerular microangiopathy with or without renal thrombi. Reversal of the symptoms has been observed after Ofev was discontinued, with residual proteinuria in some cases.
Treatment interruption should be considered in patients who develop signs or symptoms of nephrotic syndrome.
VEGF pathway inhibitors have been associated with thrombotic microangiopathy (TMA), including very few case reports for nintedanib. If laboratory or clinical findings associated with TMA occur in a patient receiving nintedanib, treatment with nintedanib should be discontinued and thorough evaluation for TMA should be completed.
Hypertension: Administration of Ofev may increase blood pressure. Systemic blood pressure should be measured periodically and as clinically indicated.
Pulmonary hypertension: Data on the use of Ofev in patients with pulmonary hypertension is limited.
Patients with significant pulmonary hypertension (cardiac index ≤ 2 L/min/m², or parenteral epoprostenol/treprostinil, or significant right heart failure) were excluded from the INBUILD and SENSCIS trials.
Ofev should not be used in patients with severe pulmonary hypertension. Close monitoring is recommended in patients with mild to moderate pulmonary hypertension.
Wound healing complication: No increased frequency of impaired wound healing was observed in the clinical trials. Based on the mechanism of action nintedanib may impair wound healing. No dedicated studies investigating the effect of nintedanib on wound healing were performed. Treatment with Ofev should therefore only be initiated or - in case of perioperative interruption - resumed based on clinical judgement of adequate wound healing.
Co-administration with pirfenidone: In a dedicated pharmacokinetic study, concomitant treatment of nintedanib with pirfenidone was investigated in patients with IPF. Based on these results, there is no evidence of a relevant pharmacokinetic drug-drug interaction between nintedanib and pirfenidone when administered in combination (see Pharmacology: Pharmacokinetics under Actions). Given the similarity in safety profiles for both medicinal products, additive adverse reactions, including gastrointestinal and hepatic adverse events, may be expected. The benefit-risk balance of concomitant treatment with pirfenidone has not been established.
Effect on QT interval: No evidence of QT prolongation was observed for nintedanib in the clinical trial programme (see Pharmacology: Pharmacodynamics under Actions). As some other tyrosine kinase inhibitors are known to exert an effect on QT, caution should be exercised when nintedanib is administered in patients who may develop QTc prolongation.
Allergic reaction: Dietary soya products are known to cause allergic reactions including severe anaphylaxis in persons with soya allergy. Patients with known allergy to peanut protein carry an enhanced risk for severe reactions to soya preparations.
Effects on ability to drive and use machines: Ofev has minor influence on the ability to drive and use machines. Patients should be advised to be cautious when driving or using machines during treatment with Ofev.

Women of childbearing potential / Contraception: Nintedanib may cause foetal harm in humans (see Pharmacology: Toxicology: Preclinical safety data under Actions). Women of childbearing potential should be advised to avoid becoming pregnant while receiving treatment with Ofev and to use highly effective contraceptive methods at initiation of, during and at least 3 months after the last dose of Ofev. Nintedanib does not relevantly affect the plasma exposure of ethinylestradiol and levonorgestrel (see Pharmacology: Pharmacokinetics under Actions). The efficacy of oral hormonal contraceptives may be compromised by vomiting and/or diarrhoea or other conditions where the absorption may be affected. Women taking oral hormonal contraceptives experiencing these conditions should be advised to use an alternative highly effective contraceptive measure.
Pregnancy: There is no information on the use of Ofev in pregnant women, but pre-clinical studies in animals have shown reproductive toxicity of this active substance (see Pharmacology: Toxicology: Preclinical safety data under Actions). As nintedanib may cause foetal harm also in humans, it must not be used during pregnancy (see Contraindications) and pregnancy testing must be conducted prior to treatment with Ofev and during treatment as appropriate.
Female patients should be advised to notify their doctor or pharmacist if they become pregnant during therapy with Ofev.
If the patient becomes pregnant while receiving Ofev, treatment must be discontinued and she should be apprised of the potential hazard to the foetus.
Breast-feeding: There is no information on the excretion of nintedanib and its metabolites in human milk. Pre-clinical studies showed that small amounts of nintedanib and its metabolites (≤ 0.5% of the administered dose) were secreted into milk of lactating rats. A risk to the newborns/infants cannot be excluded. Breast-feeding should be discontinued during treatment with Ofev.
Fertility: Based on preclinical investigations there is no evidence for impairment of male fertility (see Pharmacology: Toxicology: Preclinical safety data under Actions). From subchronic and chronic toxicity studies, there is no evidence that female fertility in rats is impaired at a systemic exposure level comparable with that at the maximum recommended human dose (MRHD) of 150 mg twice daily (see Pharmacology: Toxicology: Preclinical safety data under Actions).

Summary of the safety profile: In clinical trials and during the post-marketing experience, the most frequently reported adverse reactions associated with the use of nintedanib included diarrhoea, nausea and vomiting, abdominal pain, decreased appetite, weight decreased and hepatic enzyme increased.
For the management of selected adverse reactions see Precautions.
Tabulated list of adverse reactions: Table 11 provides a summary of the adverse drug reactions (ADRs) by MedDRA System Organ Class (SOC) and frequency category using the following convention: 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). (See Table 11.)

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Description of selected adverse reactions: Diarrhoea: In clinical trials (see Pharmacology: Pharmacodynamics under Actions), diarrhoea was the most frequent gastro-intestinal event reported. In most patients, the event was of mild to moderate intensity. More than two thirds of patients experiencing diarrhoea reported its first onset already during the first three months of treatment. In most patients, the events were managed by anti-diarrhoeal therapy, dose reduction or treatment interruption (see Precautions). An overview of the reported diarrhoea events in the clinical trials is listed in Table 12. (See Table 12.)

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Hepatic enzyme increased: In the INPULSIS trials, liver enzyme elevations (see Precautions) were reported in 13.6% versus 2.6% of patients treated with Ofev and placebo, respectively. In the INBUILD trial, liver enzyme elevations were reported in 22.6% versus 5.7% of patients treated with Ofev and placebo, respectively. In the SENSCIS trial, liver enzyme elevations were reported in 13.2% versus 3.1% of patients treated with Ofev and placebo, respectively. Elevations of liver enzymes were reversible and not associated with clinically manifest liver disease.
For further information about special populations, recommended measures and dosing adjustments in case of diarrhoea and hepatic enzyme increased, refer additionally to Precautions and Dosage & Administration, respectively.
Bleeding: In clinical trials, the frequency of patients who experienced bleeding was slightly higher in patients treated with Ofev or comparable between the treatment arms (Ofev 10.3% versus placebo 7.8% for INPULSIS; Ofev 11.1% versus placebo 12.7% for INBUILD; Ofev 11.1% versus placebo 8.3% for SENSCIS). Non-serious epistaxis was the most frequent bleeding event reported. Serious bleeding events occurred with low frequencies in the 2 treatment groups (Ofev 1.3% versus placebo 1.4% for INPULSIS; Ofev 0.9% versus placebo 1.5% for INBUILD; Ofev 1.4% versus placebo 0.7% for SENSCIS).
Post-marketing bleeding events include but are not limited to gastrointestinal, respiratory and central nervous organ systems, with the most frequent being gastrointestinal (see Precautions).
Proteinuria: In clinical trials, the frequency of patients who experienced proteinuria was low and comparable between the treatment arms (Ofev 0.8% versus placebo 0.5% for INPULSIS; Ofev 1.5% versus placebo 1.8% for INBUILD; Ofev 1.0% versus placebo 0.0% for SENSCIS). Nephrotic syndrome has not been reported in clinical trials. Very few cases of nephrotic range proteinuria with or without renal function impairment have been reported post-marketing. Histological findings in individual cases were consistent with glomerular microangiopathy with or without renal thrombi. Reversal of the symptoms has been observed after Ofev was discontinued, with residual proteinuria in some cases. Treatment interruption should be considered in patients who develop signs or symptoms of nephrotic syndrome (see Precautions).
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.

P-glycoprotein (P-gp): Nintedanib is a substrate of P-gp (see Pharmacology: Pharmacokinetics under Actions). Co-administration with the potent P-gp inhibitor ketoconazole increased exposure to nintedanib 1.61-fold based on AUC and 1.83-fold based on C_max in a dedicated drug-drug interaction study. In a drug-drug interaction study with the potent P-gp inducer rifampicin, exposure to nintedanib decreased to 50.3% based on AUC and to 60.3% based on C_max upon co-administration with rifampicin compared to administration of nintedanib alone. If co-administered with Ofev, potent P-gp inhibitors (e.g. ketoconazole, erythromycin or cyclosporine) may increase exposure to nintedanib. In such cases, patients should be monitored closely for tolerability of nintedanib. Management of adverse reactions may require interruption, dose reduction, or discontinuation of therapy with Ofev (see Dosage & Administration).
Potent P-gp inducers (e.g. rifampicin, carbamazepine, phenytoin, and St. John's Wort) may decrease exposure to nintedanib. Selection of an alternate concomitant medicinal product with no or minimal P-gp induction potential should be considered.
Cytochrome (CYP)-enzymes: Only a minor extent of the biotransformation of nintedanib consisted of CYP pathways. Nintedanib and its metabolites, the free acid moiety BIBF 1202 and its glucuronide BIBF 1202 glucuronide, did not inhibit or induce CYP enzymes in preclinical studies (see Pharmacology: Pharmacokinetics under Actions). The likelihood of drug-drug interactions with nintedanib based on CYP metabolism is therefore considered to be low.
Co-administration with other medicinal products: Co-administration of nintedanib with oral hormonal contraceptives did not alter the pharmacokinetics of oral hormonal contraceptives to a relevant extent (see Pharmacology: Pharmacokinetics under Actions).
Co-administration of nintedanib with bosentan did not alter the pharmacokinetics of nintedanib (see Pharmacology: Pharmacokinetics under Actions).

Incompatibilities: Not applicable.
Special precautions for disposal and other handling: In the event of coming in contact with the content of the capsule, hands should be washed off immediately with plenty of water (see Dosage & Administration).
Any unused medicinal product or waste material should be disposed of in accordance with local requirements.

Do not store above 25°C.
Store in the original package in order to protect from moisture.

Other Drugs Acting on the Respiratory System

L01EX09 - nintedanib ; Belongs to the class of other protein kinase inhibitors. Used in the treatment of cancer.

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