The field of the present invention relates to the use of the known antibiotic colistin for the clinical treatment of bronchiectasis accompanied by bacterial infections.
Non-cystic fibrosis bronchiectasis (NCFB) is a severe chronic illness characterized by irreversible dilation of airways and thickening of bronchial walls, chronic inflammation, repeated infections, and progressive obstruction of the airways. In contrast to cystic fibrosis bronchiectasis (CFB), which is a well-defined genetic disorder, NCFB is a terminal pathologic condition from a number of causes.
Non-cystic fibrosis bronchiectasis (NCFB) is an important health issue that is increasingly common and related to a considerably high mortality. It has higher incidence in older patients and females. Furthermore, the incidence of NCFB during the last decades is increasing due to early diagnosis with the use of high-resolution computed tomography (HRCT).
The main causes of NCFB include infections, and non-infectious conditions such as immune deficiencies, mucociliary clearance defects, bronchial obstruction, chronic obstructive pulmonary disease (COPD), idiopathic inflammatory disorders, and autoimmune diseases. The most common cause in the literature is post-infectious, although no underlying cause is identified.
There is frequent, and often underestimated, coexistence of NCFB with COPD. Other co-morbidities are more frequent in NCFB patients as compared to CFB ones.
Inhaled antibiotics are effective for CFB patients with P. aeruginosa infection, but their efficacy in NCFB has not been demonstrated. In fact, a number of pathogens are involved in the colonization of patients with bronchiectasis. The main pathogens are Gram-negative bacteria including: Haemophilus influenza, Moraxella catarrhalis, and Pseudomonas aeruginosa. The latter is associated with increased morbidity and mortality. Gram-positive bacteria (Streptococcus pneumoniae and Staphylococcus aureus) are rare. In addition, in NCFB, P. aeruginosa strains are frequently more resistant than those in CFB.
At present, there are no approved inhaled antibiotic therapies for NCFB patients. Treatment with inhaled ciprofloxacin has been under investigation in the last few years, with contradictory results. Specifically, ORBIT-4 and RESPIRE-1 trials showed clinical benefit (prolongation of the time of the first exacerbation and reduced rate of exacerbations in the treatment group compared to the placebo group), whereas the ORBIT-3 and RESPIRE-2 failed to achieve their primary endpoints.
Also tobramycin has been proposed for treating NCFB. A review of most of the clinical trials for NCFB has been published in (Amorim A., Rev. Port. Pneumol., 2013, 19 (6): 266-275).
Notwithstanding the several clinical evidences gained in these last years, a conclusive result is still lacking. Guidelines for the treatment of bronchiectasis have been published by the European Respiratory Society. Their recommendations (Polverino E, Goeminne P C, McDonnell M J, et al. European Respiratory Society guidelines for the management of adult bronchiectasis. Eur Respir J 2017; 50:1700629 [https://doi.org/10.1183/13993003.00629-2017].) disclose a complex analysis of the clinical symptoms associated with bronchiectasis. Treatments of bronchiectasis with nebulized colistin 1 MU delivered twice daily through the I-neb, is reviewed but is said not to be associated with a statistically significant improvement in time to first exacerbation compared to placebo.
A recent review summarizes the results of the latest clinical trial (Grimwood, K.; Chang, A. B., A new dawn: inhaled antibiotics for patients with bronchiectasis, The Lancet Respiratory Medicine, published online Jan. 15, 2019 http://dx.doi.org/10.1016/S2213-2600 (18) 30456-9.
However, to date, no therapies have been shown to cure or reverse the progression of the disease, even though in 2010, the British Thoracic Society published guidelines for the management of patients with NCFB Pasteur M C et al., British Thoracic Society Bronchiectasis non-CF Guideline Group. British Thoracic Society guideline for non-CF bronchiectasis. Thorax. 2010; 65 (Suppl. 1): 11-58 . . . . The guidance recommends treating patients with NCFB, who are infected with P. aeruginosa, with chronic inhaled anti-pseudomonal antibiotics, namely gentamicin, tobramycin or colistimethate sodium.
Colistin is a polymixin antibiotic produced by certain strains of Bacillus polymixa. It consists of a cationic cyclic heptapeptide with a tripeptide side chain acylated at the N-terminus by a fatty acid through an α-amide linkage (Reviews of Anti-Infective Agents CID 2005; 40:1033-41).
Two different forms of colistin are available for clinical use: colistin sulfate which is administered orally for bowel decontamination and topically as a powder for the treatment of bacterial skin infections, and colistimethate sodium (CMS) (also called colistin methanesulfate, pentasodium colistimethanesulfate, and colistin sulfonyl methate) for parenteral (intravenous, intramuscular, aerosolized and intrathecal/intraventricular) therapy.
Colistimethate sodium (CMS) represents the sulfomethylated form of colistin. CMS is readily hydrolyzed to form sulfomethylated derivatives, as well as colistin sulfate, the active form of the drug. Thus, CMS is considered to be a pro-drug of colistin, whereby “colistin” it is typically intended a mix of polymyxin E1 and polymyxin E2. Chemical abstracts have assigned the number 1066-17-7 for colistin. According to the European Pharmacopoeia, colistin should comprise more than 77% of Polymyxin E1, E2, E3, E1i and E1-7MOA, but less than 10% of each of the minor components Polymyxin E3, E1-i and E1-MOA. In some occurrences the term “Polymyxin E” is also used interchangeably with “colistin”.
Colistin has recently gained a crucial role for the treatment of various types of infections (e.g. pneumonia, bacteremia, urinary tract infections) caused by Gram-negative pathogens expressing a multidrug resistance phenotype (e.g. non-fermenting Gram-negative pathogens, and carbapenem-resistant enterobacteria).
Colistimethate sodium is active against gram negative bacteria including Pseudomonas aeruginosa, Acinetobacter baumannii and Klebsiella pneumoniae.
Inhaled colistimethate sodium is licensed for managing pulmonary infections caused by P. aeruginosa in people with cystic fibrosis (CF). The authorization was granted based on a bibliographic submission. Acute pulmonary exacerbations occur frequently in CF and are associated with progressive morbidity and mortality. Approximately 25% of CF patients will not regain their lung function after a pulmonary exacerbation, pointing to the necessity for the optimal and aggressive treatment of these events.
The following colistimethate preparations are available:
However, there are currently no licensed colistimethate products for the treatment of non-cystic fibrosis bronchiectasis (NICE Advice 2014, “Non-cystic fibrosis bronchiectasis: colistimethate sodium”, Evidence summary, 6 Jan. 2014). Furthermore, according to the summaries of product characteristics, colistimethate sodium is very commonly associated with adverse respiratory effects (affecting at least 1 in 10 people), including cough, dyspnoea, bronchospasm and sore throat. The summary of product characteristics for Promixin® states that there have been reports of P. aeruginosa acquiring resistance to colistimethate sodium during clinical use.
A phase II clinical trial published in 2014 (ref. Haworth, C. et al. Am. J. Respir. Crit. Care Med., 2014, 189 (8), 975-982) disclosed the use of nebulized colistimethate in NCFB (PPCTP/001).
The PPCTP/001 trial enrolled bronchiectasis patients with two or more positive respiratory tract cultures for P. aeruginosa in the preceding 12 months and who were within three weeks of completing a course of antipseudomonal antibiotics for the treatment of an exacerbation. P. aeruginosa also had to be cultured from a sputum sample taken at the screening visit. Participants were randomised to receive colistimethate sodium (1 MIU [33 mg CBA]; n=73) or placebo (0.45% saline; n=71) via the I-neb nebulizer twice a day, for up to 6 months. The primary endpoint was time to exacerbation. Secondary endpoints included time to exacerbation based on adherence recorded by the I-neb, P. aeruginosa bacterial density, quality of life, and safety parameters.
In this trial, however, the median time to first exacerbation after treatment was not statistically different from the placebo group.
Other clinical studies have been carried out in the last decades to assess the efficacy of inhaled colistin in NCFB. None of these studies, with the exception of Haworth, C. et al. (cited above) appears to be a randomized study. Thus, the conclusions achieved seem not to be supported by an appropriate power analysis.
Blanco-Aparicio et al. 2019,_Chron. Resp. Dis_16: 1-9, in a 12-months prospective clinical study, discuss the results of a trial where patients (67) underwent inhaled colistin treatment after a systemic antibiotic eradication treatment.
Lopez Gil Otero et al. in Rev. Esp. Quimioter. 2019, 32 (3): 217-223 is an observational study on 44 patients, treated for 6 or 12 months with CMS. The authors report reduced admissions to emergency and days of hospitalization after colistin treatment compared with the period preceding this treatment.
Dhar R. et al. Thorax 2010, 65:553 has reported a retrospective study in which colomycin was inhaled through a standard “jet nebulizer” at a dose of 1-2 megaunits twice daily for a mean duration on treatment of 21.2 months and was found to reduce the exacerbation frequency with respect to the precolomycin period in a sample of 19 patients.
Therefore, is highly felt in the field of NCFB therapy, a clinical study able to provide results endowed with a suitable statistical power.
A desirable treatment for NCFB would require not only alleviating the clinical symptoms of bronchiectasis such as the frequency of pulmonary exacerbations and their severity, but also minimizing adverse side effects and reducing the systemic toxicity.
The present invention relates to colistimethate sodium (CMS), administered at a dose of at least 20 mg Colistin Base Activity (CBA) per day, to reduce the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) with P. aeruginosa infections, wherein said exacerbation is defined as the presence concurrently of at least 3 of the following 8 symptoms or signs, for at least 24 hours:
The amount of CMS is comprised of from 20 mg to 60 mg CBA per day, even more preferably 10-30 mg CBA twice a day wherein said pulmonary exacerbations is defined above.
A further object of the present invention is a composition for inhalation, nebulization or aerosol spray comprising colistimethate sodium (CMS) in an amount of from at least 30-35 mg CBA/mL to 60-70 mg CBA/mL of sterile aqueous solution suitable for inhalation, for use in reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections.
A further embodiment of the present invention relates to a kit for use in reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infection comprising:
The kit is preferably further provided with a suitable nebulizer system.
The invention also relates to a method of reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections, said method comprising:
The present invention will be better understood with the accompanying drawings, wherein:
The term “colistin” as used herein comprises colistin sulfate (typically administered orally for bowel decontamination and topically as a powder for the treatment of bacterial skin infections) and colistimethate sodium (CMS).
As used herein, the term colistimethate sodium comprises: colistin methanesulfate, pentasodium colistimethanesulfate, and colistin sulfonyl methate. CMS represents the sulfomethylated form of colistin. In order to become an effective antimicrobial agent, the sulfomethyl groups of CMS need to be hydrolysed thereby liberating free amino-groups to colistin sulfate, the active form of the drug. Thus, CMS is considered to be a pro-drug of colistin.
The active ingredient of “colistin” is represented chemically by a mix of polymyxin E1 and polymyxin E2. Chemical abstracts have assigned the number 1066-17-7 for colistin. According to the European Pharmacopoeia, colistin should comprise more than 77% of Polymyxin E1, E2, E3, E1i and E1-7MOA, but less than 10% of each of the minor components Polymyxin E3, E1-i and E1-MOA.
According to the EMA (European Medicines Agency) doses of this antibiotic should always be expressed in IU (International Unit) of colistimethate sodium. However, where a different dosage indication is used, the following conversion table (Table 1) should be used (ref. “European Medicines Agency completes review of polymyxin-based medicines”, Dec. 16, 2014):
1Nominal potency of the drug substance = 12.500 IU/mg
CMS is authorized for parenteral (intravenous, intramuscular, inhalation, aerosolized and intrathecal/intraventricular) use, in the management of adult and paediatric chronic pulmonary infections due to Pseudomonas.
CMS can be found under the following commercial names:
As used herein, the term “about” is intended to refer to a range when a point value is given, the range comprising at least a 2%+/− of the given value.
As used herein the term “pulmonary exacerbation” in a patient refers to the presence concurrently of at least 3 of the following 8 symptoms/signs for at least 24 hours:
A “severe” pulmonary exacerbation is herein defined a pulmonary exacerbation requiring intravenous antibiotics and/or hospitalisation.
As used herein the term “inhalation” refers to the administration of a substance in the form of a nebulized liquid, gas, aerosol, or fine powder via the respiratory tract, usually by oral or nasal inhalation, for local and/or systemic effect.
As used herein the term suitable “inhalation devices” refer to devices such as: Respironics I-Neb® AAD with 0.3 mL or 0.5 mL medication chamber, Pari eFlow® rapid and Pari LC Sprint with Pari Boy® SX compressor. By AAD is meant Adaptive Aerosol Delivery system, designed to continuously adapt to changes in the patient's breathing pattern, and to pulse aerosol only during the inspiratory part of the breathing cycle. This eliminates waste of aerosol during exhalation, and allows precise aerosol (dose) delivery.
These devices are characterized by the features summarized in
Modified Intention to Treat (mITT). The mITT population comprises all subjects who provided informed consent, who were randomised and who received at least 1 dose or partial dose of the IMP.
By “clinically stable patient” is meant a patient who has not required a change in pulmonary treatment for NCFB within at least 30 days prior to the beginning of the inhaled CMS therapy according to the present invention.
By macrolides the Applicant intends to refer to any one of the following antibiotics: azythromycin, erythromycin, clarithromycin.
According to a main aspect, the invention refers to colistimethate sodium (CMS), administered by inhalation at a dose of at least 20 mg Colistin Base Activity (CBA) per day for use in reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections. Said administration is preferably a “long term” administration, wherein by “long-term” is intended an administration of CBA for at least 12 months.
Preferably, inhaled colistin is provided by an Adaptive Aerosol Delivery system. Some of the distinctive features of the I-neb AAD System are its ability to provide: (1) precise dosing, (2) feedback to the patient, (3) ability to log information about device use and performance, and (4) data for transmission over the Internet to remotely monitor patient's adherence to the drug regimen and device performance. Furthermore, as known, the AAD system allows the drug to be inhaled only during the inspiration phase.
The use of CMS for reducing the frequency of exacerbation in NCFB has not been demonstrated until the present Clinical Phase III study (Promis I). In fact, the Phase II study failed to achieve its primary endpoint, which was set as the increase of days from the beginning of CMS treatment and the first exacerbation (Haworth, C. et al. Am. J. Respir. Crit. Care Med., 2014, 189 (8), 975-982) disclosed the use of nebulized colistimethate in NCFB (PPCTP/001).
Non-cystic fibrosis bronchiectasis (NCFB) is a severe chronic illness characterized by irreversible dilation of airways and thickening of bronchial walls, chronic inflammation, repeated infections, and progressive obstruction of the airways. In contrast to cystic fibrosis bronchiectasis (CFB), which is a well-defined genetic disorder, NCFB is a heterogeneous disease caused by many different medical conditions.
Of note, medical treatments that demonstrate a clinical benefit in CFB do not necessarily show the same benefits in NCFB (Barker et al., “Aztreonam for inhalation solution in patients with non-cystic fibrosis bronchiectasis (AIR-BX1 and AIR-BX2): two randomised double blind, placebo-controlled phase 3 trials.”. Lancet Respir Med, 2014, 2:738-749) hence, direct correlation between the treatment of CFB and NCFB is not appropriate.
CMS is approved in adult and pediatric CFB patients for the management of chronic pulmonary infections due to Pseudomonas aeruginosa.
In view of the former clinical study on NCFB summarized above, however, it was not expected that colistin would reduce the frequency of exacerbations in NCFB patients.
Non-cystic fibrosis bronchiectasis (NCFB) is an important health issue that is increasingly common and related to a considerably high mortality. It has higher incidence in older patients and females and its incidence is increasing during the last decades due to improved diagnostic means.
The main causes of NCFB are several and include infections, bronchial obstruction, allergic bronchopulmonary aspergillosis, immunodeficiency states, connective tissue disorders, idiopathic inflammatory disorders, and autoimmune diseases. The most common cause in the literature is post-infectious due to an exaggerated and uncontrolled inflammation that progressively leads to obstruction of the small airways, bronchial wall damage and destruction, and hence to bronchiectasis, although no unique underlying cause has ever been identified.
As a matter of fact, repeated respiratory infections (bacterial, viral, fungal) in susceptible individuals may lead to chronic airway inflammation, progressive obstruction of the small airways and bronchial wall destruction, which typifies non-cystic fibrosis bronchiectasis (NCFB). Once established, the airways of patients with NCFB commonly become chronically infected with bacteria often leading to recurrent exacerbations. This explanation has led to the established “vicious circle” hypothesis proposed by Cole (Cole P J, “Inflammation: a two-edged sword—the model of bronchiectasis.”, European Journal of Respiratory diseases. Supplement, 1986, 147:6-15 1986). This hypothesis consists of the following circle of events: impaired lung defences permit bacterial infection of the airway mucosa, which stimulates a neutrophilic inflammatory response that becomes chronic when it fails to eradicate the bacteria; the host inflammatory response causes tissue damage, e.g. via proteinase enzymes and reactive oxygen species which overwhelm the body's ability to neutralize them; tissue damage further impairs the lung defences, allowing bacteria to persist; and so the circle continues and disease may progress.
Other co-morbidities are more frequent in NCFB patients as compared to CFB ones. In fact, COPD (41.4%), asthma (32.8%) and gastroesophageal reflux (18.3%) are the most frequent predisposing conditions to NCFB.
Inhaled antibiotics are effective for CFB patients with P. aeruginosa infection, but their efficacy in NCFB has not been clearly demonstrated, yet. In fact, a number of pathogens are involved in the colonization of patients with bronchiectasis. The main Gram negative pathogens are: Haemophilus influenza, Moraxella catarrhalis, and Pseudomonas aeruginosa. The latter is associated with increased morbidity and mortality. Furthermore, in NCFB patients, P. aeruginosa strains may develop antibiotic resistance more frequently than in CFB patients.
An effective treatment according to the present invention comprises delivering a CMS amount of from at least 20 mg CBA to 60 CBA (2 MIU to 6 MIU) a day by inhalation. More preferably, CMS is administered at a dose corresponding to 10-30 mg CBA, twice a day. Even more preferably, the CMS amount is provided by inhalation at a dose of at least 10 mg CBA, corresponding to about 0.3 mL of a CMS solution comprising 30-35 mg CBA/mL, twice a day.
Preferably, NCFB patients suitable for the treatment according to the present invention are clinically stable for NCFB, i.e. are patients who have not required a change in pulmonary treatment for NCFB within at least 30 days prior to the beginning of the inhaled CMS therapy.
Inhalation by the respiratory tract, preferably inhalation by the oral route is achieved through an Adaptive Aerosol Delivery system inhalation device, such as the I-neb AAD device, which is activated by a disc provided with the I-neb and is used after appropriate training (including written instructions) which instruct also on the CMS preparation for I-neb. When a subject self-administer the Investigational medicinal product, specifically CMS, via the I-neb device, the time of day, length of nebulisation and amount of drug administered are stored in the device, thus providing a complete and faithful record of the treatment.
Other suitable devices for CMS nebulization and/or inhalation are represented, for example, in
The preferred length of CMS treatment according to the present invention is at least 12 months.
As said above, CMS dosage may be expressed differently. A conversion table (Table 1) has been provided by the European Medicines Agency to define International Units and amounts of colistimethate and colistin activity. According to this table, 1 MIU corresponds to about 80 mg colistimethate sodium (mass) and about 34 mg colistin-base activity (CBA). In the present invention we will refer to colistin-base activity (CBA).
A further embodiment according to the present invention relates to a sterile saline composition comprising colistimethate sodium (CMS), suitable for administration of an amount of CMS corresponding to at least 20 mg CBA/day by inhalation, nebulization or aerosol spray, for use in reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections.
Preferably the composition for inhalation is prepared at the moment of use from a suitable dose of CMS in powder. Suitable compositions comprise CMS in an amount of from at least 30-35 mg CBA/mL to 60-70 mg CBA/mL and are administered twice a day. According to a preferred embodiment, CMS is prepared in a concentration of at least 30-35 mg CBA, in 1 mL solution suitable for inhalation and about one third (0.3 mL) is delivered by inhalation, though a suitable inhalation device, delivering about 10 mg CBA each inhalation.
The sterile saline aqueous solution typically used for dispersing the colistimethate sodium in powder, preferably comprises sodium chloride (NaCl) in concentration of from 0.4% to 0.9% w/v in sterile water for injection (WFI) or a suitable physiological sterile buffered solution. The preferred final NaCl concentration in the solution for inhalation comprising CMS for use in the treatment according to the present invention, is comprised from 0.4% to 0.5% w/V, even more preferably is 0.45% w/V.
As said above, CMS compositions are preferably prepared extemporaneously, i.e. at the moment of use, or prepared and used within 24 hours, if stored at 2 to 8° C.
According to a preferred embodiment patients undergoing inhaled CMS therapy with success had a form of NCFB characterized by at least two NCFB pulmonary exacerbations requiring oral or inhaled antibiotics or one NCFB pulmonary exacerbations requiring intravenous antibiotics in the 12 months preceding the inhaled CMS treatment.
Even more preferably the patients are at least 80% adherent to the treatment.
The present invention also refers to a kit for the reduction of the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections comprising a vial with colistimethate sodium (CMS) in powder in an amount corresponding to at least 30-35 mg CBA, an aqueous sterile solution and a leaflet with instruction for the treatment of NCFB by inhalation and stating that the powder has to be resuspended in about 1 mL saline and transferred to the nebulizer chamber, delivering about 0.3 mL prepared CMS composition for a long-term treatment, wherein long-term means at least 12 months.
The kit may further comprise a suitable nebulizer system, as described above.
The kit according to the present invention comprises an aqueous sterile saline solution wherein sodium chloride is in concentration of from 0.4% to 0.9% w/v, more preferably sodium chloride is in a concentration comprised from 0.4% to 0.5% w/V and even more preferably sodium chloride is present at a concentration of about 0.45% w/V.
The leaflet with instruction would recommend the use of CMS by inhalation in an amount of from at least 20 mg CBA per day, preferably an amount of CMS comprised from 20 to 60 mg CBA a day, or even more preferably at least 10 mg CBA, twice a day for at least 12 months, for reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections.
The reduction of the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections is accompanied by an increase of the time from the beginning of treatment to the first pulmonary exacerbation of at least 180 days, more preferably 185 days, even more preferably 190, 200, 205, 206, 207 or 208 days, comprising all the intermediate values.
As said above, by pulmonary exacerbation the Applicant refers to the presence concurrently of at least 3 of the following 8 symptoms/signs for at least 24 hours:
A sensitivity analysis was conducted using an alternative definition of NCFB pulmonary exacerbation for the mITT Population, based on that published by the ERS in 2017 (Hill A T, Haworth C S, Aliberti S, et al. Pulmonary exacerbation in adults with bronchiectasis: a consensus definition for clinical research. Eur Respir J. 2017; 49 (6): 1700051. doi: 10.1183/13993003.00051-2017.).
This alternative definition is the ERS definition but because of limitations in data collection, the actual definition used in the analysis was modified based on a) the presence of 3 or more specific solicited symptoms (regardless of their deterioration), b) the use of antibiotics (and not any change in NCFB therapy), c) a duration of at least two days (rather than a duration of at least 48 hours). Of note, the result of the sensitivity analysis support that of the primary analysis by the above mentioned criteria.
A new pulmonary exacerbation is only considered to occur if there are at least 14 days between the end of the course of systemic antibiotics and the onset of new qualifying symptoms. (Note: A pulmonary exacerbation is reported as an Adverse Event or serious AE (SAE).
“Severe” pulmonary exacerbations, are herein defined as those requiring intravenous antibiotics and/or hospitalisation;
After the study, the results on Pseudomonas aeruginosa density confirms that P. aeruginosa density falls rapidly and remains suppressed in the patients on colistimethate sodium, with no data suggestive of development of colistimethate resistance for active vs placebo groups.
According to a further embodiment, the present invention relates to a therapeutic method of reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections, said method comprising:
Preferably, the therapeutic method is based on the administration of a CMS dose comprised from 20 to 60 mg CBA a day.
Even more preferably the method according to the invention provides a dose of CMS corresponding to an amount of from about 10 mg CBA to about 30 mg CBA, twice a day.
In a more preferred embodiment, the dose of CMS given to a patient by inhalation is at least 10 mg CBA twice a day.
The method of reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections, comprises administering by inhalation, nebulization or aerosol spray to said patients a composition comprising at least 1 MIU/mL a day, of colistimethate sodium (CMS) (corresponding to about 33-34 mg CBA/mL and 80 mg/mL colistimethate sodium; delivering to said patients an amount of about 0.3 mL of said composition, and reducing said frequency of said pulmonary exacerbations in said patients. Preferably, said CMS is in a physiological or saline solution, wherein said saline solution is a sterile aqueous solution comprising from 0.4% to 0.9% w/v of sodium chloride. Even more preferably, said sterile saline solution comprises from 0.4% to 0.5% w/V NaCl, even more preferably 0.45% w/v of sodium chloride.
Even more preferably, said CMS is a powder to be dissolved before use in a sterile aqueous solution suitable for inhalation, wherein said powder corresponds to the amount of CMS for each inhalation and is comprised of from about 30-35 mg CBA to about 60-70 mg CBA for each dose, that is preferably resuspended in 1 mL sterile aqueous solution. Even more preferably the amount of CMS corresponds to at least 30-35 mg CBA, preferably 33-34 mg CBA, dissolved in 1 mL sterile aqueous solution suitable for inhalation, of which about 0.3 mL are inhaled, corresponding to about 10 mg CBA delivered during each inhalation, preferably twice a day.
Preferably the sterile aqueous solution is a saline solution, comprising from 0.4 to 0.9% w/v of sodium chloride, possibly diluted with Water for Injections.
Preferably, NCFB patients undergoing the treatment according to the present invention have not received an antibiotic treatment with oral macrolides and/or colistin within at least 30 days before the beginning of the treatment with CSM.
Preferably, administration of CMS in the above mentioned preferred amounts, is long-term and continued for at least 12 months.
According to a preferred embodiment, the method of the invention comprises administration by inhalation of from about 10 mg CBA twice a day, wherein about 30-35 mg CBA, preferably about 33-34 mg CBA (corresponding to about 1 MIU), are preferably dissolved in 1 mL sterile aqueous saline solution and about 0.3 mL are delivered by I-neb, twice a day.
According to the data, better detailed in the Experimental Part, the treatment according to the invention reduces the annual rate of exacerbations which is lower in patients receiving CMS I-neb vs placebo (0.58 per patient per year vs 0.95, rate ratio (RR) 0.61 95% CI 0.46-0.82, p=0.00101).
CMS treatment demonstrated a 39% reduction in the annual rate of pulmonary exacerbations relative to placebo which is clinically and highly statistically relevant. These data are supported by the results achieved from other pre-planned analysis of the primary endpoint, such as the sensitivity analysis using the alternative definition of pulmonary exacerbation (by Hill A T, Haworth C S, Aliberti S, et al. Pulmonary exacerbation in adults with bronchiectasis: a consensus definition for clinical research. Eur Respir J. 2017; 49 (6): 1700051. doi: 10.1183/13993003.00051-2017), and the analysis on adherent subject (adherence>80%) where a highly statistically significantly (p=0.00080) lower mean annual exacerbation rate was shown in the CMS group (LS Mean 0.494) compared to the placebo group (LS Mean 0.873) at the 5% level.
Other achievements (secondary efficacy variables) by the present Clinical Study are described in the following:
There was a prolonged time to first exacerbation in the CMS I-neb group (HR 0.59, 95% CI 0.43-0.81, p=0.00074; HR=Hazard Ratio).
Time to First NCFB Pulmonary Exacerbation from the First Dose of IMP was statistically significantly longer in the CMS group than in the placebo group. The median time to first NCFB pulmonary exacerbation was 208 days in the placebo group and the median was not reached in the CMS group because less than half of the subjects (n=68, 38.6%) experienced a pulmonary exacerbation during the study.
The survival distributions were compared between the two treatment groups using a log rank test and assessed as statistically significant (p=0.00074). A supportive analysis was conducted using the Cox proportional hazard regression model for the mITT (modified Intention to Treat) Population.
The time to first NCFB pulmonary exacerbation was statistically significantly longer in the CMS group than in the placebo group (see
The risk of a first exacerbation was significantly lower in the CMS group compared to placebo (hazard ratio 0.590; 95% CI, 0.432, 0.806). This showed a 41% reduction in the risk of the first exacerbation event for the CMS group compared to placebo.
CMS inhaled through the I-neb demonstrated superiority compared to placebo in terms of reducing the severe NCFB pulmonary exacerbation annual rate (p=0.003). The LS Mean severe NCFB pulmonary exacerbation annual rate was 0.116 in the CMS group and 0.283 in the placebo group. The LS Mean rate ratio of CMS relative to placebo was 0.409 (95% CI, 0.227, 0.738, p=0.003), representing a statistically significant 59% reduction in the rate of severe pulmonary exacerbations in subjects treated with CMS compared to placebo.
Severe NCFB pulmonary exacerbations were observed in 19/176 subjects (10.8%) in the CMS group, which is lower than in the placebo group, 36/197 subjects (18.3%). The median time to first severe NCFB pulmonary exacerbation, 25th percentile, and 75th percentile were not reached in either group. The survival distributions were compared between the two treatment groups and the difference was assessed as statistically significant (p=0.03318).
The overall treatment difference in SGRQ total score for all time points by LS means was-3.378, p=0.01766, indicating statistically significant improvement in quality of life over the study period. At the end of the CMS treatment, the treatment difference in SGRQ total score by LS means was 4.552, p=0.0055, indicating a clinically meaningful and statistically significant improvement in quality of life at the end of study compared to baseline (see
Changes in P. aeruginosa Density
There was a statistically significant greater reduction of P. aeruginosa density in the CMS group than in the placebo group after 1 month (LS mean difference=−1.620, p<0.00001). After 12 months, there remained a greater reduction of P. aeruginosa density compared to baseline in the CMS group (mean CFB, −0.86) compared to placebo (mean CFB, −0.08) (see
The percentage of patients with adverse events was similar between groups. Bronchospasm was experienced clinically only in 0.6% of the patients on CMS treatment and the development of P. aeruginosa resistance to colistin sulphate was as low as 1%.
Therefore, CMS by I-neb, i.e. provided by an Adaptive Aerosol Delivery system significantly reduces the annual rate of exacerbations and P. aeruginosa infection and it is safe and well tolerated.
The above results have been achieved with statistical analysis providing a statistical power equal to or higher than 80%, to detect a 30% treatment difference.
Baseline stable macrolide use was similar in both CMS (24.4%) and placebo groups (26.9%). Of note, the use of stable concomitant oral macrolides was included as an effect in the model and was not statistically significant (p=0.44506), suggesting that there is no notable difference in the mean NCFB pulmonary exacerbation annual rate between subjects who used stable concomitant oral macrolides and those who did not.
The mean age of subjects was 64.2 years in both the CMS and placebo groups, and two-thirds of subjects were female (123 subjects [69.9%] in the CMS group and 126 subjects [64.0%] in the placebo group).
Most subjects were Caucasian (167 subjects [94.9%] in the CMS group and 189 subjects [95.9%] in the placebo group). The demographic characteristics, including height, weight, and body mass index, were similar in both groups. Over two-thirds of subjects were non-smokers; 124/176 subjects (70.5%) in the CMS group and 142/197 subjects (72.1%) in the placebo group. Only three subjects (0.8%) were current smokers: 0/176 in the CMS group and 3/197 in the placebo group. The remaining 27.9%; 52/176 in the CMS group and 52/197 in the placebo group, were former smokers.
1. A method of reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infections, said method comprising:
2. The method according to the former embodiment, wherein said dose is comprised from 20 mg CBA/day to 60 mg CBA/day.
3. The method according to the former embodiment wherein inhaled colistin is provided by an Adaptive Aerosol Delivery system.
4. The method according to the former embodiments wherein said patients are clinically stable.
5. The method according to the former embodiment wherein said patients had at least two NCFB pulmonary exacerbations requiring oral or inhaled antibiotics or one NCFB pulmonary exacerbations requiring intravenous antibiotics in the 12 months preceding the CMS treatment.
6. The method according to the former embodiments wherein said patients have one or more of the following co-morbidities: COPD, asthma and gastroesophageal reflux.
7. Method according to the former embodiments, wherein said dose is of from 10 mg CBA to 30 mg CBA twice a day.
8. Method according to the former embodiments, wherein said dose is 10 mg CBA twice a day.
9. Method of reducing the frequency of pulmonary exacerbations in patients suffering from Non-Cystic Fibrosis Bronchiectasis (NCFB) and P. aeruginosa infection, said method comprising:
10. Method according to the former embodiments, wherein said composition comprising CMS, is a saline solution.
11. Method according to the former embodiments, wherein said saline solution is a sterile aqueous solution comprising from 0.4% to 0.9% w/v of sodium chloride.
12. Method according to the former embodiments, wherein said sterile aqueous solution comprises 0.45% w/v of sodium chloride.
13. Method according to the former embodiments, wherein CMS is in a form of a powder to be dissolved before use in a sterile aqueous solution suitable for inhalation.
14 Method according to the former embodiments, wherein said powder corresponds to a dose of from 30-35 mg CBA to 60-70 mg CBA.
15. Method according to the former embodiments, wherein the sterile aqueous solution is a saline solution.
16. Method according to the former embodiments wherein said saline solution comprises from 0.4 to 0.9% w/v of sodium chloride.
17. Method according to the former embodiments, wherein said CMS is administered for at least 12 months.
18. Method according to the former embodiments comprising:
The clinical study PROMIS 1 is available at clinicaltrials.gov (https://clinicaltrials.gov/ct2/show/NCT03093974?term=Zambon&cond=Non-cystic+Fibrosis+Bronchiectasis&draw=2&rank=2).
377 Patients were randomized (177 to CMS by I-neb) and 200 to placebo
Subjects were considered eligible if they:
Subjects were considered not eligible if they have/are:
In order to investigate whether the use of inhaled colistimethate sodium reduces the frequency of pulmonary exacerbations compared to placebo in subjects with NCFB chronically infected with P. aeruginosa, the following hypothesis has been tested:
The null hypothesis must be rejected for the efficacy of inhaled colistimethate sodium to be considered demonstrated.
A supportive analysis has been conducted using an alternative definition of NCFB pulmonary exacerbation. The re-classification of exacerbations has been conducted in a blinded fashion (before database lock). The alternative definition of pulmonary exacerbations used will be deterioration in three or more of the following key symptoms for at least 48 hours:
The number of NCFB pulmonary exacerbations during the treatment period has been analysed using a Poisson regression model allowing for over-dispersion including treatment, pooled sites and use of stable concomitant therapy with oral macrolides as fixed effects and log-time on trial as an offset.
The number and the percentage of subjects with NCFB pulmonary exacerbations, the number of pulmonary exacerbations and the total follow-up time in years have been summarised by treatment group. The adjusted yearly mean exacerbation rates in each treatment group and the adjusted rate ratio with their 95% CIs has been estimated by the model.
For the analysis, 2 pulmonary exacerbations have been considered as a single episode in cases where the second exacerbation starts less than 14 days after the end of the antibiotic therapy (oral or intravenous) for the first pulmonary exacerbation.
If the null hypothesis will be rejected, additional investigation of proportionality of the hazard will be implemented in a secondary analysis. Additional details on the analysis will be provided in the SAP.
A corresponding two-sided p-value of <0.05 has been considered statistically significant.
Summary statistics and analyses of the secondary efficacy/pharmaco-economic endpoints have been conducted for the mITT (main analysis) and the PP, as follows.
The time to the first NCFB pulmonary exacerbation and the time to the first severe NCFB pulmonary exacerbation has been calculated as the time in days from the date of the first dose of IMP to the date at which the first pulmonary exacerbation occurs (i.e. date at which the first pulmonary exacerbation occurs—date of the first dose+1). A log-rank sum test has been used to compare the treatment groups. Subjects completing the trial without NCFB pulmonary exacerbations or who are discontinued prematurely without exacerbations, will be considered as censored at the time of their last follow-up.
The annualised number of exacerbation-free days have been also presented by treatment group. An appropriate non-parametric test has been used that makes allowing for the effect of prognostic covariates possible.
The number and the percentage of subjects with pneumonia and severe pulmonary exacerbations, defined as those requiring intravenous antibiotics and/or hospitalisation (admission to the hospital for longer than 24 hours), the number of pneumonias/severe pulmonary exacerbations and the annual mean pneumonia/severe pulmonary exacerbation rate has been also be presented by treatment group.
The SGRQ total score and domain scores (Symptoms, Activity and Impact scores) has been summarised at each visit by treatment group using descriptive statistics. Changes from baseline (Visit 2) have been also summarised for each post-baseline visit by treatment group. Scores have been computed according to the SGRQ manual [20].
Multiple entries and missing data have been dealt with as described in the same manual.
SGRQ total score has been analysed using a linear mixed model for repeated measures including treatment, visit, treatment-by-visit interaction, use of stable concomitant therapy with oral macrolides and pooled sites as fixed effects and baseline value as covariate. An unstructured covariance matrix has been assumed and the Kenward-Roger adjustment has been used for the degrees of freedom. The least square means in each treatment group, the least square mean differences between treatments, their 95% CIs and associated p-values at each visit will be estimated by the model.
The total score of the QOL-B questionnaire has been summarised and analysed similarly to the SGRQ total score. Algorithm of scoring and methods for handling with multiple imputations and missing data have been performed according to the questionnaire instructions [21, 22].
Pseudomonas aeruginosa Density
The P. aeruginosa density as determined by the mean change in log 10 CFU/g sputum from baseline (Visit 2) to Day 28 (Visit 3), as well as to Visits 5 and 7, has been compared between the treatment groups by an analysis of covariance model including treatment, pooled site and use of stable concomitant therapy with oral macrolides as fixed effects and baseline value as covariate. Least square means in each treatment group, least square mean difference between treatments, their 95% CIs and associated p-values have been estimated.
Sensitivity analyses may be conducted to assess the robustness of conclusions.
Summary statistics of the P. aeruginosa density (log 10 CFU/g sputum) and change from baseline (Visit 2) will be provided by treatment group for each trial visit.
CMS powder 1 MIU (Xellia Pharm. Aps, Copenhagen, DK), approximately equivalent to 80 mg colistimethate sodium/33 mg Colistin Base Activity (CBA) according to table 1 was adminstered by I-neb twice a day.-I-neb is a pulmonary administration device working by an ultrasonic (vibrating mesh) nebulizer system designed to aerosolize liquid medication approved for use with the I-neb AAD System. It is described e.g. in U.S. Pat. No. 6,367,470.
The subjects will administer the IMP via the I-neb AAD device twice daily, activated by a disc provided with the I-neb. Subjects will receive appropriate training on the use of the I-neb device (including written instructions) and on preparation of the IMP to be used in the I-neb. Subjects will perform the first administration of IMP under supervision of the site personnel during Visit 2 and they will be informed that the device will log their IMP usage. When subjects self-administer the IMP via the I-neb device, the time of day, length of nebulisation and amount of IMP administered are stored in the device.
During the trial, adherence will be assessed on-site by the Investigator on an ongoing basis by downloading the data from the I-neb into a data analyser installed in laptops provided by the Sponsor. In addition, drug accountability, assessing the amount of IMP used and not used by a subject (see Section 11.4) will be performed. The data remains on the I-neb so it can be fully analysed at the end of the study.
After the end of treatment, i.e. Visit 7, the device use data from the I-neb will be downloaded to the laptop using instructions provided to the site personnel. The data can then be sent electronically to the CRO or Philips as per instructions. Alternatively, the device can be stored and returned to Almac with returned IMP. Almac will then send the device on to Philips (the I-neb manufacturer) who will download the data and send it on to the CRO. As the I-neb system records all information on the doses of IMP taken, these data will be used to determine overall adherence.
Pseudomonas aeruginosa Analysis
Results of the quantitative analysis for P. aeruginosa density will be presented as colony forming units (CFU) count per gram sputum.
Besides P. aeruginosa density analysis (see Section 9.1.5), the susceptibility of P. aeruginosa to colistin sulphate will be evaluated from the sputum samples collected at each visit. The susceptibility testing will be done using a minimal inhibitory concentration (MIC) method. Testing of susceptibility with other antibacterial panels will also be conducted for samples collected during pulmonary exacerbations.
If resistance to colistin sulphate is detected and/or any isolate shows a significant rise in MIC (i.e. showing greater than a four-fold change in colistimethate sodium MIC) genotyping studies on P. aeruginosa isolates may be conducted to determine if the change in MIC is due to microbiological recurrence or re-infection.
The results have shown that P. aeruginosa density fell rapidly and remained suppressed in those on colistimethate sodium, with no data suggestive of development of colistimethate resistance for active vs placebo groups.
P. aeruginosa density
The primary variable for this trial is the mean annual NCFB pulmonary exacerbation rate (frequency of pulmonary exacerbations) over 12 months.
The mITT has been used to produce summaries of baseline subject characteristics and for the analysis of all primary and secondary efficacy endpoints.
The annual rate of exacerbations was lower in patients receiving CMS I-neb vs placebo (0.58 per patient per year vs 0.95, rate ratio (RR=Relative Risk) 0.61 95% CI 0.46-0.82, p=0.00101).
The LS (Least square) Mean rate ratio of CMS relative to placebo was 0.612 (95% CI 0.457, 0.820, p=0.00101), representing a statistically significant 39% reduction in the rate of pulmonary exacerbations in subjects treated with CMS compared to placebo (similar result [LS Mean rate ratio=0.591, 95% CI (0.438-0.796), p=0.0006] was attained in the post-hoc analyses with low-recruiting countries combined). These data were supported by the PP Population analysis, in which the results were similar to those of the primary analysis; LS Mean NCFB pulmonary exacerbation annual rate was 0.491 and 0.842 in the CMS and placebo groups, respectively, and the LS Mean rate ratio of CMS relative to placebo was 0.583 (95% CI, 0.413, 0.822, p=0.00212), a 42% reduction.
Therefore, this study has shown that CMS inhaled through the I-neb AAD nebuliser is superior to placebo in terms of reducing the NCFB pulmonary exacerbation annual rate.
This result is highly statistically relevant.
The result of the sensitivity analysis using the alternative definition of pulmonary exacerbation (by Hill A T, Haworth C S, Aliberti S, et al. Pulmonary exacerbation in adults with bronchiectasis: a consensus definition for clinical research. Eur Respir J. 2017; 49 (6): 1700051. doi: 10.1183/13993003.00051-2017) support that of the primary analysis: LS mean NCFB pulmonary exacerbation annual rate was 0.538 in the CMS group and 0.838 in the placebo group, LS mean rate ratio of CMS relative to placebo was 0.642 (95% CI, 0.470, 0.877), equating to a reduction of 36% which is statistically significantly lower in the CMS group compared to the placebo group (p=0.00540).
Other secondary efficacy variables are described in the following paragraphs.
There was a prolonged time to first exacerbation in the CMS I-neb group (HR 0.59, 95% CI 0.43-0.81, p=0.00074; HR=Hazard Ratio) (see
Time to First NCFB Pulmonary Exacerbation from the First Dose of IMP was statistically significantly longer in the CMS group than in the placebo group. The median time to first NCFB pulmonary exacerbation was 208 days in the placebo group and the median was not reached in the CMS group because less than half of the subjects (n=68, 38.6%) experienced a pulmonary exacerbation during the study.
The survival distributions were compared between the two treatment groups using a log rank test and assessed as statistically significant (p=0.00074). A supportive analysis was conducted using the Cox proportional hazard regression model for the mITT (modified Intention to Treat) Population.
The risk of a first exacerbation was significantly lower in the CMS group compared to placebo (hazard ratio 0.590; 95% CI, 0.432, 0.806). This showed a 41% reduction in the risk of the first exacerbation event for the CMS group compared to placebo.
CMS inhaled through the I-neb demonstrated superiority compared to placebo in terms of reducing the severe NCFB pulmonary exacerbation annual rate (p=0.003). The LS Mean severe NCFB pulmonary exacerbation annual rate was 0.116 in the CMS group and 0.283 in the placebo group. The LS Mean rate ratio of CMS relative to placebo was 0.409 (95% CI, 0.227, 0.738, p=0.003), representing a statistically significant 59% reduction in the rate of severe pulmonary exacerbations in subjects treated with CMS compared to placebo.
Severe NCFB pulmonary exacerbations were observed in 19/176 subjects (10.8%) in the CMS group, which is lower than in the placebo group, 36/197 subjects (18.3%). The median time to first severe NCFB pulmonary exacerbation, 25th percentile, and 75th percentile were not reached in either group. The survival distributions were compared between the two treatment groups and the difference was assessed as statistically significant (p=0.03318).
The overall treatment difference in SGRQ total score for all time points by LS means was-3.378, p=0.01766, indicating statistically significant improvement in quality of life over the study period (see
Changes in P. aeruginosa Density
There was a statistically significant greater reduction of P. aeruginosa density in the CMS group than in the placebo group after 1 month (LS mean difference=−1.620, p<0.00001). After 12 months, there remained a greater reduction of P. aeruginosa density compared to baseline in the CMS group (mean CFB, −0.86) compared to placebo (mean CFB, −0.08) (see
The percentage of patients with adverse events was similar between groups. Bronchospasm and antibiotic resistance were infrequently observed (2.8% and 1% respectively). In particular, bronchospasm was experienced clinically only in 0.6% of the patients on CMS treatment and the development of P. aeruginosa resistance to colistin sulphate was as low as 1%.
According to the above results, CMS by I-neb significantly reduced the annual rate of exacerbations and severe exacerbations in patients with bronchiectasis and P. aeruginosa. The treatment was safe and well tolerated.
Baseline stable macrolide use was similar in both CMS (24.4%) and placebo groups (26.9%). Of note, the use of stable concomitant oral macrolides was included as an effect in the model and was not statistically significant (p=0.44506), suggesting that there is no notable difference in the mean NCFB pulmonary exacerbation annual rate between subjects who used stable concomitant oral macrolides and those who did not.
The above results have been achieved with statistical analysis providing a statistical power equal to or higher than 80%, to detect a 30% treatment difference.
The mean age of subjects was 64.2 years in both the CMS and placebo groups, and two-thirds of subjects were female (123 subjects [69.9%] in the CMS group and 126 subjects [64.0%] in the placebo group).
Most subjects were Caucasian (167 subjects [94.9%] in the CMS group and 189 subjects [95.9%] in the placebo group). The demographic characteristics, including height, weight, and body mass index, were similar in both groups. Over two-thirds of subjects were non-smokers; 124/176 subjects (70.5%) in the CMS group and 142/197 subjects (72.1%) in the placebo group. Only three subjects (0.8%) were current smokers: 0/176 in the CMS group and 3/197 in the placebo group. The remaining 27.9%; 52/176 in the CMS group and 52/197 in the placebo group, were former smokers.
Number | Date | Country | Kind |
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21189819.2 | Aug 2021 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/071960 | 8/4/2022 | WO |