Efficacy of Mepolizumab in Severe Asthmatics on a Long Term (MESILICO) — MESILICO  

Severe Asthma Clinical Trial

Official title: Efficacy of Mepolizumab in Patients With Late-onset Severe Eosinophilic Asthma and Fixed Obstruction

Status Active, not recruiting

Clinical Trial Summary

Interleukin (IL)-5 is the main cytokine responsible for the activation of eosinophils, hence therapeutic strategies have been investigated and developed for clinical use. Biologics targeting IL-5 and its receptor (first mepolizumab and subsequently, reslizumab and benralizumab), have been recently approved and used as add-on therapy for severe eosinophilic asthma resulting in a reduction in the circulating eosinophil count, improvement in lung function and exacerbation reduction in patients with severe asthma. Response to biologic therapies in severe asthma is variable, with patients being either non-responders, responders or super-responders. There is currently no explanation for this broad variation in response. It is important to examine whether these patients have distinct characteristics that could help the treating physician in making the correct diagnosis in clinical practice. Aim of this clinical study is to evaluate the efficacy of mepolizumab, a humanized IL-5 antagonist monoclonal antibody in patients with late-onset severe eosinophilic asthma with fixed obstruction and to identify the characteristics of non-responders and super-responders under mepolizumab treatment. This study is considered as non-interventional and every procedure included is happening in a clinical routine for the diagnosis and phenotyping of the asthmatic patients. Hypothesis includes the efficacy of mepolizumab treatment in late-onset severe eosinophilic asthmatic patients with fixed obstruction and relation to clinical and inflammatory biomarkers. Patients will be collected from the outpatient clinics of bronchial asthma from each site included (8 in number) which cover the whole population of Greece. Overall, this is a prospective multicenter study including eight Pulmonary Clinics. Five Pulmonary University Clinics, two of National Health System and one Army General Hospital in Thessaloniki. The study will include a screening period of up to 2 weeks to assess eligibility and obtain written informed consent, a mepolizumab treatment period of 52 weeks, once every 4 weeks, including follow up visits every 3 months during treatment. The study population will consist of 45 patients with late-onset severe eosinophilic asthma and fixed obstruction receiving mepolizumab, aged 20 and above.

Clinical Trial Description

Scientific rationale Interleukin (IL)-5 is the main cytokine responsible for the activation of eosinophils, hence therapeutic strategies have been investigated and developed for clinical use. Biologics targeting IL-5 and its receptor (first mepolizumab and subsequently, reslizumab and benralizumab), have been recently approved and used as add-on therapy for severe eosinophilic asthma resulting in a reduction in the circulating eosinophil count, improvement in lung function and exacerbation reduction in patients with severe asthma. Response to biologic therapies in severe asthma is variable, with patients being either non-responders, responders or super-responders. There is currently no explanation for this broad variation in response. It is important to examine whether these patients have distinct characteristics that could help the treating physician in making the correct diagnosis in clinical practice. Aim of this clinical study is to evaluate the efficacy of mepolizumab, a humanized IL-5 antagonist monoclonal antibody in patients with late-onset severe eosinophilic asthma with fixed obstruction and to identify the characteristics of non-responders and super-responders under mepolizumab treatment. This study is considered as non-interventional and every procedure included is happening in a clinical routine for the diagnosis and phenotyping of the asthmatic patients. Several methods are used to investigate airway inflammation: direct measurements (like bronchial biopsies or bronchoalveolar lavages) and indirect methods (like symptom assessment, blood sample analysis and lung function tests). The direct techniques have the advantage of reliably assessing the airway inflammation, but they are invasive and not feasible at large scale because of patient discomfort and the risk incurred. As for the indirect methods, they poorly correlate with the direct assessment of airway inflammation. In this study, among patients' clinical characteristics spirometry, biomarkers of inflammation (blood eosinophils, FeNO, IgE levels), impulse oscillometry (IOS) and the thickening of basement membrane via bronchoscopy will be evaluated. It is suggested that late-onset severe eosinophilic asthmatic patients with fixed obstruction who do not respond to the usual treatment (ICS/LABA/LAMA) appear with increased smooth muscle mass. However, the precise effects of increased airway smooth muscle mass on airway narrowing are not known and may vary with disease severity. In addition, biomarkers of inflammation will also be evaluated before and after 52-week mepolizumab treatment in biological fluids (serum, sputum, sputum supernatant and bronchial samples). Biomarkers of inflammation are very important to identify responders to non-responders. More specific, IOS has been introduced as an alternative technique to assess lung function with particular application to asthma. This technique is noninvasive, easily performed during tidal breathing and requires only minimal patient cooperation. Sputum collection is another way to sample cells from the airways and allows the direct assessment of airway inflammation. Furthermore, examples with sputum supernatant include the analysis of mediators and the assessment of the chemotactic activity of the sample for eosinophils. The sputum cells can also be analyzed by flow cytometry which allows, among others, immunophenotyping and sorting cells. Furthermore, sputum cells can be cultured, and their mediator production can be measured in vitro. It is worth noting that in this case, the mediator content is different from what can be found in sputum supernatant. Indeed, mediators in sputum supernatant may be influenced by secretions from airway resident cells and by plasma exudation, contrary to the sputum cell culture model. Finally, immunocytochemistry and in situ hybridization can also be performed using sputum cells. Although phenotypes, blood eosinophils, and serum IgE levels have been proposed for use as a reference, there is a dissociation between the blood immune-cell level and the airway epithelium immune reaction, as confirmed in previous studies. Airway epithelium immunohistochemistry staining for targeted immune cells has been used to determine various types of airway inflammation; however, this technique is rarely used in a clinical setting. Previous studies have revealed the relative safety of performing bronchoscopy biopsies for patients with severe asthma. Among the sampling techniques used for tissue diagnosis, including nasal biopsies, nasal or bronchial brushing, and bronchoalveolar lavage, bronchoscopy-guided bronchial epithelium sampling provides more accurate information about the epithelial and inflammatory cells in the tissue context. It is thus a powerful tool for selecting the most suitable biologics in difficult clinical conditions. Besides, asthmatic disease is characterized by a chronic mucosal inflammatory process, which results in irreversible changes of the bronchial wall, known today as "bronchial remodeling". Glandular and smooth muscle fibers hyperplasia and/or hypertrophy, goblet cells hyperplasia, and variable thickening of basement membrane (BM) present under the respiratory epithelium are part of these morphological changes. the changes generated at the epithelium-connective interface account for an "adaptive response" to inflammatory stress and sporadic bronchoconstriction. However, current data on BM reactivity in asthmatic patient are still incomplete for an accurate assessment of its involvement in pathogenesis and specifically in bronchial wall remodeling, mainly as collagen deposits in lamina reticularis are not correlated to the degree of disease severity. Moreover, it is increasingly evident that severe asthma is not a single disease, as evidenced by the variety of clinical presentations, physiologic characteristics, and outcomes seen in patients with asthma. To better understand this heterogeneity, the concept of asthma phenotyping and endotyping has emerged. Phenotyping integrates both biological and clinical features, from molecular, cellular, morphologic, and functional to patient-oriented characteristics with the goal to improve therapy. Ultimately, these phenotypes evolve into asthma "endotypes," which combine clinical characteristics with identifiable mechanistic pathways. Biomarkers, defined as characteristics that can be objectively measured and serve as an indicator of underlying biological processes or pathogenesis, are crucial in defining phenotypes and endotypes. In asthma, genetic polymorphisms, measures of airway physiology, and levels of inflammatory mediators in urine, blood, sputum, tissue, exhaled gas, and breath condensate have all been studied as potential markers to improve and objectify asthma diagnosis and management. Developing such tools will allow us to phenotype and endotype the various clinical patterns described in asthma, with the ultimate goal of tailoring therapy based on a specific biomarker profile. Biomarkers can then be used to help better understand the pharmacologic response to an intervention and adjust therapy accordingly. Biomarkers have been critical for studies of disease pathogenesis and the development of new therapies in severe asthma. In particular, biomarkers of type 2 inflammation have proven valuable for endotyping and targeting new biological agents. Because of these successes in understanding and marking type 2 inflammation, lack of knowledge regarding non-type 2 inflammatory mechanisms in asthma will soon be the major obstacle to the development of new treatments and management strategies in severe asthma. Other potential biomarkers include innate lymphoid cells, IL-33 or thymic stromal lymphopoietin. Recent publications confirmed crucial regulatory role of miRNAs in the pathomechanism of asthma. Some single miRNAs or their sets hold the promise for their use as asthma biomarkers facilitating diagnosis or prediction of treatment outcomes. They are also possible target of future therapies. The studies in this field are lacking though. Recently it has been shown that most of the involved miRNAs increase secretion of Th2 cytokines, decrease secretion of Th1 cytokines, promote differentiation of T cells towards Th2 or play a role in hyperplasia and hypertrophy of bronchial smooth muscle cells. The profiles of miRNAs correlate with clinical characteristics, including lung function, phenotype and severity of asthma. Most industry sponsored biologic clinical trials have effectively used the above approach by selecting study subjects that resemble the severe asthma clinical phenotypes of SARP (high-intensity controller medication regimens, frequent exacerbations, and low lung function), but then require an elevated biomarker (in blood, exhaled gas, or sputum) that should identify patients most likely to be responders to a specific immunomodulator within those clinical phenotypes. The biologics in recently published clinical trials target type 2 inflammatory pathways and restrict participation to subjects with elevated type 2 biomarkers (blood or sputum eosinophils or FeNO). Post hoc responder analyses to "group" biomarkers to better understand which patients have the greatest benefit from a biologic immunomodulator will lead to an understanding that concurrent elevations in more than 1 type 2 inflammatory biomarker may further identify "high responder" patients. Hypothesis includes the efficacy of mepolizumab treatment in late-onset severe eosinophilic asthmatic patients with fixed obstruction and relation to clinical and inflammatory biomarkers. Research questions Is there any improvement in exacerbation rate in late-onset severe eosinophilic asthmatic patients under mepolizumab treatment during their 1st year of treatment and what are the characteristics of non-responders and super-responders? Is there any improvement in smooth muscle cells remodeling? Are there any biomarkers to predict response to mepolizumab treatment in late-onset severe eosinophilic asthmatic patients? Is there any improvement in respiratory parameters? Is there any improvement in asthma control and patients' quality of life? Objectives The primary objectives of this study are: 1. To demonstrate the effect of mepolizumab treatment in exacerbation rate in late-onset severe eosinophilic asthmatic patients with fixed obstruction. 2. To identify characteristics of non-responders and super-responders. 3. Stydy's extension to identify any improvement in airway remodeling after 156 months of treatment The key secondary objectives of this study are: 1. Any improvement in remodeling (thickening of bronchial smooth muscle cells). 2. Any possible biomarkers of response. 3. Any improvement in respiratory parameters in asthma control and in patients' quality of life during mepolizumab treatment in late-onset severe eosinophilic asthmatic patients with fixed obstruction. Study design and Methods Patients will be collected from the outpatient clinics of bronchial asthma from each site (8 in number) which cover the population of Greece. All these Clinics are included to reinforce the recruitment as well as to include bronchoscopist experts with international impact. Due to the current situation concerning Covid-19 pandemic, the investigators assume that this clinical study does not interfere with the workload in our Clinics. Overall, this is a prospective multicenter study including eight Pulmonary Clinics. Five Pulmonary University Clinics, two of National Health System and one Army General Hospital. The study will include a screening period of up to 2 weeks to assess eligibility and obtain written informed consent, a mepolizumab treatment period of 52 weeks, once every 4 weeks, including follow up visits every 3 months during treatment. The extension of the protocol includes a treatment period of 156 weeks of treatment. The study population will consist of 45 patients with late-onset severe eosinophilic asthma and fixed obstruction receiving mepolizumab aged 20 and above. Study participation, assessment and follow up: Screening: Investigators will screen selected subjects to the participated clinics (Severe Asthma outpatient clinics). Subjects will come in to sign consent. Clinical assessment and procedures and structural interviews will be performed during screening. Subjects that are eligible/able to complete the screening Visit may do so, on the same day, and if necessary, they will complete their baseline assessment within 2 weeks. Subjects with an ongoing asthma exacerbation should have their screening and treatment initiation visit delayed until the investigator considers the subject has returned to their baseline asthma status. If the 2-week screening period has elapsed then the subject should be considered a screening failure. Subjects will remain on their current maintenance therapy throughout screening periods. Eligibility of the patients will be based on the criteria listed in the next sections. Asthma exacerbation history for the last 12 months will be reported at screening visit. Also, exacerbations will be evaluated at each visit as reported. Vital signs will be performed at screening visit, at baseline and every 3 months. Measurements will include systolic and diastolic blood pressure, pulse rate and body temperature. Height in centimeters (cm) and body weight in kilograms (kg) will be measured at screening visits. Body Mass Index (BMI) will be calculated as the weight in kg divided by the height in meters squared Laboratory evaluation (Hematology, Blood chemistry, Urinalysis): Venous blood and urine will be collected at baseline. Hematology: Hemoglobin, hematocrit, red blood cell count, white blood cell count with differential, and platelet will be measured in the laboratory of each site's hospital. Basic clinical chemistry and urinalysis will be evaluated. Collection of urine for female subjects will also evaluate pregnancy. IgE levels will be evaluated at screening visit using immunoCAP tests and will be reported as IU/mL. The following Questionnaires will be administered: 1) the Asthma Control Questionnaire (ACQ-5) and Asthma Control Test (ACT) to assess current asthma control; 2) the Asthma Quality of Life Questionnaire (AQLQ+12) to assess quality of life and psychological morbidity. To further asses sleeping quality 1) Athens Insomnia Scale (AIS), 2) Epworth Sleepiness Scale (ESS), 3) St. George's Respiratory Questionnaire (SGRQ) and 4) WHO (Five) Well-Being Index (WHO-5), 5) Fatigue Severity Scale (FSS). Exhaled nitric oxide (NO) will be measured at baseline and every 3 months according to the American Thoracic Society Guidelines and as specified by the manufacturer. FeNO levels will be reported as parts per billion. Measurements will be made before spirometry is performed. Venous blood samples will be retrieved between 8 to 10 am, at baseline and every 3 months during the 52-week period with mepolizumab treatment. Absolute blood eosinophil count will be reported as cells/μl. Spirometry: Spirometry A will be conducted, using the site's own equipment at the visits (baseline and every 3 months). All clinic visits must occur in the morning. During the treatment period the spirometry will meet the current ATS/ERS guidelines and the spirometer must produce a printout of all data generated, which should be stored in the subject's notes. The spirometer will be calibrated in accordance with the manufacturer's instructions. Spirometry must be performed at the same time (±1 hour) of the Visit 0 spirometry. Subjects should try to withhold short-acting beta-2-agonists (SABAs) for ≥4 hours and LABAs for ≥15 hours prior to clinic visit, if possible (GINA 2019). Assessments to be recorded will include FEV1, FVC, FEV1/FVC%, PEF and FEF25-75. Post-bronchodilator measurements will be taken at every visit, using 200-400mcg albuterol or equivalent. Spirometry B will be conducted, using the site's own equipment at the visits (baseline, after 6 months and after treatment at 52 weeks timepoint). Spirometry B includes diffusion, pulmonary volumes and capacities. Impulse oscillometry (optional): Impulse Osillometry (IOS) will be conducted at baseline and after 52 weeks of treatment. IOS includes resistance at 5 Hz-resistance at 20 Hz (R5-R20), a measure reflecting respiratory resistance of small to midsized conductive and peripheral airways, AX, a measure reflecting distensibility of the peripheral lungs (namely the parenchyma and small peripheral airways), and the respiratory system reactance (X5), a measure reflecting inertance and elasticity or capacitance (including small peripheral airways). Therapy with biologics: Upon completion of the screening visits the participant may initiate treatment with biologic therapy (mepolizumab) within a month. During therapy subjects will be under the care of the pulmonologist who had referred them to the research group for taking part into the study. These pulmonologists will be termed as 'associate pulmonologists. Treatment will be provided as per product manufacturer instructions. Associate pulmonologists providing biologic treatment during the study will require to sign an agreement to conduct the study in compliance with the protocol, to acknowledge that he/she is responsible for medical conduct and for study conduct, and to ensure that the associate (and their colleagues and employees) assisting in the conduct of the study are informed about their obligations. Mechanisms will be in place to ensure that associate staff receives the appropriate information and support by the research group throughout the study. Follow up during biologic therapy: At initiation and at every visit for biologic therapy administration collection of information will be performed by the associate pulmonologist, and with support by the research group if requested by the associate pulmonologist e.g., researchers via telephone or face-to-face contact will interview the patient. Furthermore, compliance will be recorded form the physician based on patient's oral confirmation. Date form of drug administration will be recorded at every visit, as well as immediate and delayed adverse effects. Safety monitoring: Recorded adverse events (AEs) will be monitored and collated as required in study reports. An adverse event is the appearance or worsening of any undesirable sign, symptom, or medical condition occurring after starting the study entry. Medical conditions/diseases present before starting study drug are only considered adverse events if they worsen after starting study drug. Abnormal laboratory values or test results constitute adverse events only if they induce clinical signs or symptoms, are considered clinically significant, or require therapy. Also, adverse events related to Covid-19 are included. If a partner pulmonologist or research staff becomes aware of an AE associated with a product, it can be reported to the manufacturer according to their local standard practice for spontaneous AE reporting. A copy of the report should also be sent to the study coordinator. Serious adverse events (SAE) will be reported in the eCRF pages and within 24 hours all the investigators will have the responsibility to inform the Central Committee in Thessaloniki. Then the Central Committee will inform the scientific board and the Greek Medical Agency. Also, medical and scientific judgment will be exercised by the principal investigator of each center with the Central Committee, in deciding whether the subject should stop the treatment or not. Pregnancy report: Initially, female patients at screening will have to do a pregnancy test. During treatment, if a female subject reports a pregnancy to us, she will be asked to withdraw from the study (to prevent bias) Then, she will be asked if she would like to keep getting the treatment outside of this protocol and be monitored at each center's outpatient clinic. Pre-screening and Screening Failures: Subjects will be assigned a study number at the time of signing the consent. Subjects who signed but do not progress to the screening visits assessment will be deemed a pre-screen failure. No data will be captured in the database for these subjects. Subjects that complete at least one of the two screening visits, but do not initiate biologic therapy will be designated as screening failures. Information to be collected for pre-screening and screening failures will be detailed in the database completion. Withdrawal Visit: If a participant decides to withdraw from the study during follow-up (for any reason other than loss to follow up), they may be asked to attend a withdrawal visit (if deemed necessary by investigator and subject to consent). During the visit, the participant may be asked questions about their current conditions as part of clinical information collection such as: asthma and nasal symptoms, exacerbations and the progression of treatment being received. Blood samples' collection and processing: Blood samples will be collected at baseline visit, at 6 months and after treatment completion. After collecting the blood samples, they will be left undisturbed for about half an hour for complete clot formation. The sample will then be centrifuged to separate the serum from the clot. After centrifugation the serum will be stored at -20° C in eppendorf tubes till the analysis was done. Blood phenotyping will also be evaluated by flow cytometry. Induced sputum (optional): Induced sputum will be performed at baseline before treatment initiation and after completion of treatment according to the ERS Task Force report where a detailed expert consensus-based recommendation for induced sputum processing is suggested. At the visits, sputum induction will be performed after the routine spirometric assessments have been completed. The induced sputum will be processed within two hours of the end of the induction procedure at the research site. Sputum cells and cell suspension supernatant will be stored at -80ºC for analysis. After collecting the induced sputum, the supernatant of the sample will be stored at -20° C in eppendorf tubes till the analysis was done. Following these procedures, laboratory evaluation of the sputum is next according to guidelines. Bronchoscopy, bronchial biopsies and washing samples' collection and processing (optional): At the visits, endoscopy with bronchial biopsies, bronchial washing sample (Visit 0b) will be performed upon patient's written consent. In specific, a separate inform consent will be included to be signed from each patient. Bronchoscopy will be performed at two time-points (baseline before treatment initiation and after the completion of treatment). Flexible bronchoscopy and diagnostic techniques were performed under monitored anesthesia care as recommended by the American Thoracic Society and the British Thoracic Society. Tissue samples will be fixed in inflation or immersion using formaldehyde or glutaraldehyde and embedded in paraffin. Airways will be systematically sampled or obtained during diagnostic dissection at the discretion of the pathologist. Consecutive sections of 0.5, 5 and 30 μm thickness were cut from each block and stained using the Masson's trichrome technique, haematoxylin and eosin, and haematoxylin, respectively. Immunohistochemical staining will be done done with the following mAbs: anti-mast cell tryptase clone AA1 (Dako UK), anti-alpha smooth muscle actin clone 1A4 (Dako UK), anti-eosinophil major basic protein clone BMK-13 (Monosan, Netherlands), anti-neutrophil elastase clone NP57 (Dako UK), and anti-endothelium clone EN4 (Monosan, Netherlands) or appropriate isotype controls were used. The endobronchial biopsies will be assessed by a single observer blinded to the clinical characteristics (ZEN 2012 image analysis software for light microscopy, Carl Zeiss AG, Germany) and will be expressed as the mean of measurements undertaken from a minimum of two sections either from independent biopsies or as non-contiguous tissue sections at least 20μm apart from the same biopsy. Epithelial integrity will be assessed by measuring the lengths of intact and denuded epithelium. These will be expressed as percentage of all the reticular basement membrane (RBM) length. Vascularity will be measured using the Chalkley count, a surrogate of both vessel density and vascular area. A Chalkley eyepiece graticule (NG52 Chalkley Point Array, Pyser-SGI Ltd, UK) will be used at x200 to measure Chalkley counts in four non-overlapping vascular hotspots (6). Airway smooth muscle content will be determined as the proportion of the total area. Inflammatory cells were expressed as the number of nucleated cells/area of lamina propria. Bronchial washing samples will be immediately transported to the laboratory, to be stored at -80 degrees. Examination of bronchial washing fluids will be performed at a later stage to determine several biomarkers. Analysis of biomarkers of inflammation with Flow Cytometry Analysis (FACS) or ELIZA: Biomarkers included before and after treatment with mepolizumab in two or three timepoints, (at baseline, at 6 months treatment and after treatment completion visit): lymphocyte subsets, Th2/Th17 cytokines, chemokines, microRNAs expression to be quantitated by flow cytometry or ELISA) in biological fluids (blood, serum, bronchial washing, sputum and sputum supernatant). Panel kits and appropriate antibodies will be tested by Flow Cytometer Analysis using a BD FACS Calibur system (BD Biosciences, San Jose, CA), according to the manufacturer's recommendations and instructions. ELISA (enzyme-linked immunosorbent assay) is a plate-based assay technique designed for detecting and quantifying substances such as peptides, proteins, antibodies and hormones. ELISA kits will be analyzed using VICTOR X3 spectrophotometer according to the manufacturer's recommendations and instructions. Allergy testing (If applicable) The patients' atopic status will be evaluated (if not available) at screening visit by the skin prick test (SPT) to a standard panel of aeroallergens for detecting total IgE antibodies against various common inhalant allergens. Database An electronic data collection platform will be the method used at baseline every 3 months until 1 year follow up for this database. During treatment visits paper forms/questionnaires will be completed by the associate pulmonologist. Each site will entry specific data in an electronic database. Each patient is uniquely identified by a Subject number which is composed by the site number assigned by the responsible monitoring site and a sequential number assigned by the investigator. Upon signing the informed consent form, the patient is assigned the next sequential number by the investigator. The site must contact the central research personnel and provide the requested identifying information for the patient as registered into the electronic database. The treatment visit forms will also be sent to the central research personnel. The authorized study personnel will be responsible for data collection, editing, and also protecting the data being collected at their own site and the database is backed up on a daily basis. Quality review/control will be the joint responsibility of all individuals involved and the central research personnel [data custodian]. Sample size calculation G power analysis Sample size is calculated using the G*Power software (Die Heinrich-Heine-Universität Düsseldorf, Germany). The difference in annual exacerbation rate of the patients with late onset severe eosinophilic asthmatics before and after Mepolizumab treatment with is the primary endpoint of the study. In the DREAM study (one of the only two studies that has reported results similar to our primary endpoint so far) it was reported that the annual exacerbation rate of patients with severe Asthma declined from 3.6 to 1.33 after the initiation of treatment with Mepolizumab. Using this data and a two-sided test, with a power at 0.95 and a level of statistical significance at 0.05, the investigators calculated an effect size of 0.556, which indicated a total sample size of 45 participants. Statistical Plan Analysis Statistical analysis will be performed using the SPSS (version 21.0 IBM SPSS statistical software, Armonk, NY, USA). Categorical variables will be stated as numbers (n) and percentages (%), continuous variables as mean ± SD if normally distributed, or median and interquartile ranges if otherwise. Where necessary variables without a normal distribution will be transformed. P < 0.05 was accepted as statistically significant. Shapiro-Wilk test will be performed in order to separate parametric from non-parametric variables. Paired-Samples T Test for parametric or Wilcoxon Signed Ranks test for non-parametric variables will be used to detect differences in the variables measured before and after Mepolizumab treatment. There is no comparator arm as every patient is control to himself. There are baseline characteristics (clinical and laboratory biomarkers) that are going to be measured at baseline, every 3 months and after 52-week treatment completion. Study endpoints include the analysis of all those biomarkers as the identification of the characteristics of non-responders and super-responders. Also, secondary endpoints include the evaluation of the biomarkers mentioned in the methods as assessments. Statistical analysis will be performed initially with the number of patients that have completed the 52-week period of treatment. Secondly, patients that have not completed the 52-week treatment will be analyzed separately and finally these two groups are going to be compared to each other. More specifically, with univariate analysis (two-sided independent sample tests) the investigators will test for associations/correlations between all baseline outcomes compared with the ones after mepolizumab treatments (every 3 months until 1 year of treatment): biomarkers in sputum and in blood, clinical outcomes. Similarly, univariate associations between outcomes and personal/demographic characteristics will be tested for identifying potential confounders. Significant associations will be then tested with adjusted regression models. Associations/correlations will be evaluated separately at baseline clinical characteristics and every 3 months follow up during treatment as well as at baseline and after 1 year of mepolizumab treatment. Besides, subgrouping analysis will be performed for each biomarker for the identification of biomarker level to treatment response. Paired-Samples T Test for parametric or Wilcoxon Signed Ranks test for non-parametric variables will be used to detect differences in the variables measured before and after Mepolizumab treatment. In specific, levels of biomarkers at baseline will be compared to levels after 1-year of mepolizumab treatment. Overall response to treatment in one year (from baseline to 1-year post treatment initiation) for each outcome will be measured with paired test of dependent samples (parametric and non-parametric paired tests) in each patient. Then response to treatment will be defined as the change (absolute and % change) of the outcome in one year. The investigators will assess predictors influencing response to treatment (change) such as biomarkers by using multiple regression models for each clinicopathological outcome. For outcomes with more than 2 observations per subject during the study period the investigators will use mixed models using the repeated measurements of the outcome. All tests will be 2-sided with a statistical significance level at 5%. ;

Related Conditions & MeSH terms

• Asthma
• Asthma; Eosinophilic
• Late-Onset Asthma
• Pulmonary Eosinophilia
• Severe Asthma

• NCT number: NCT04612556
• Study type: Observational
• Source: Aristotle University Of Thessaloniki
• Status: Active, not recruiting
• Start date: January 22, 2021
• Completion date: March 15, 2025