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      Day and Night Control of COPD and Role of Pharmacotherapy: A Review

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          Abstract

          The topic of 24-hour management of COPD is related to day-to-night symptoms management, specific follow-up and patients’ adherence to therapy. COPD symptoms strongly vary during day and night, being worse in the night and early morning. This variability is not always adequately considered in the trials. Night-time symptoms are predictive of higher mortality and more frequent exacerbations; therefore, they should be a target of therapy. During night-time, in COPD patients the supine position is responsible for a different thoracic physiology; moreover, during some sleep phases the vagal stimulation determines increased bronchial secretions, increased blood flow in the bronchial circulation (enhancing inflammation) and increased airway resistance (broncho-motor tone). Moreover, in COPD patients the circadian rhythm may be impaired. The role of pharmacotherapy in this regard is still poorly investigated. Symptoms can be grossly differentiated according to the different phenotypes of the disease: wheezing recalls asthma, while dyspnea is strongly related to emphysema (dynamic hyperinflation) or obstructive bronchiolitis (secretions). Those symptoms may be different targets of therapy. In this regard, GOLD recommendations for the first time introduced the concept of phenotype distinction suggesting the use of inhaled corticosteroids (ICS) particularly when an asthmatic pattern or eosiophilic inflammations are present, and hypothesized different approaches to target symptoms (ie, dyspnea) or exacerbations. Pharmacotherapy should be evaluated and possibly directed on the basis of circadian variations, for instance, supporting the use of twice-daily rapid-action bronchodilators and evening dose of ICS. Recommendations on day and night symptoms monitoring strategies and choice of the specific drug according to patient’s profile are still not systematically investigated or established. This review is the summary of an advisory board on the topic “24-hour control of COPD and role of pharmacotherapy”, held by five pulmonologists, experts in respiratory pathophysiology, pharmacology and sleep medicine.

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          Most cited references 96

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          Acetylcholine beyond neurons: the non-neuronal cholinergic system in humans.

          Animal life is controlled by neurons and in this setting cholinergic neurons play an important role. Cholinergic neurons release ACh, which via nicotinic and muscarinic receptors (n- and mAChRs) mediate chemical neurotransmission, a highly integrative process. Thus, the organism responds to external and internal stimuli to maintain and optimize survival and mood. Blockade of cholinergic neurotransmission is followed by immediate death. However, cholinergic communication has been established from the beginning of life in primitive organisms such as bacteria, algae, protozoa, sponge and primitive plants and fungi, irrespective of neurons. Tubocurarine- and atropine-sensitive effects are observed in plants indicating functional significance. All components of the cholinergic system (ChAT, ACh, n- and mAChRs, high-affinity choline uptake, esterase) have been demonstrated in mammalian non-neuronal cells, including those of humans. Embryonic stem cells (mice), epithelial, endothelial and immune cells synthesize ACh, which via differently expressed patterns of n- and mAChRs modulates cell activities to respond to internal or external stimuli. This helps to maintain and optimize cell function, such as proliferation, differentiation, formation of a physical barrier, migration, and ion and water movements. Blockade of n- and mACHRs on non-innervated cells causes cellular dysfunction and/or cell death. Thus, cholinergic signalling in non-neuronal cells is comparable to cholinergic neurotransmission. Dysfunction of the non-neuronal cholinergic system is involved in the pathogenesis of diseases. Alterations have been detected in inflammatory processes and a pathobiologic role of non-neuronal ACh in different diseases is discussed. The present article reviews recent findings about the non-neuronal cholinergic system in humans.
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            Dual bronchodilation with QVA149 versus single bronchodilator therapy: the SHINE study

            Introduction Bronchodilators are the cornerstone of symptomatic management of chronic obstructive pulmonary disease (COPD) [1]. Current guidelines recommend treatment with one or more long-acting bronchodilators for patients with moderate-to-very-severe COPD [1]. The use of two bronchodilators with different mechanisms of action has been shown to provide additional benefits compared with either given alone, without significantly increasing side-effects [2, 3]. Both indacaterol, a long-acting β2-agonist (LABA), and tiotropium, a long-acting muscarinic antagonist (LAMA), are effective as monotherapies and have acceptable safety profiles [4, 5]. In addition, their concurrent use has been shown to provide superior bronchodilation and improvement in air trapping compared with tiotropium alone [6]. Glycopyrronium (NVA237) is a recently approved once-daily LAMA for the treatment of moderate-to-severe COPD, and has been shown to provide rapid and sustained improvements in lung function, dyspnoea, health status, exercise endurance and exacerbation risk, with improvements similar to tiotropium and a safety profile similar to placebo [7–9]. QVA149 is a novel once-daily dual bronchodilator containing a fixed dose of the LABA indacaterol with the LAMA glycopyrronium. In patients with COPD, QVA149 has demonstrated rapid and sustained bronchodilation, which is significantly superior to that observed with indacaterol alone or placebo, and it is well tolerated, with an adverse event profile similar to placebo [10, 11]. In the current SHINE study, we sought to confirm the “rule of combination” [12] that dual bronchodilation with QVA149 will provide additional therapeutic benefits compared to the monocomponents indacaterol and glycopyrronium, as well as compared to tiotropium, the current gold standard of care, and placebo in patients with moderate-to-severe COPD. Methods Study design The study was a multicentre, randomised, double-blind, parallel-group, placebo- and active-controlled 26-week trial, and comprised a washout, run-in and the 26-week treatment period, with 30 days of follow-up after the last visit (fig. 1). The first patient’s first visit was September 21, 2010, and the last patient’s last visit was February 10, 2012. Patients receiving fixed-dose combinations of LABA/inhaled corticosteroid (ICS) were switched to an equivalent dose of ICS monotherapy. After screening, eligible patients were randomised in a 2:2:2:2:1 ratio (via interactive response technology) to treatment with double-blind QVA149 (indacaterol 110 μg/glycopyrronium 50 μg), indacaterol 150 μg, glycopyrronium 50 μg, open-label tiotropium 18 μg or placebo. All medications were administered once daily in the morning via the Breezhaler® (Novartis Pharma AG, Stein, Switzerland) device except for tiotropium, which was administered via the HandiHaler® (Boehringer Ingelheim, Ingelheim, Germany) device. A salbutamol/albuterol pressurised metered-dose inhaler was provided as rescue medication. Additional details of the study design and randomisation/blinding procedures are included in the online supplementary material. Figure 1– The SHINE study design. Patients Participants were aged ≥40 years, had moderate-to-severe stable COPD (stage II or III according to Global Initiative for Chronic Obstructive Lung Disease (GOLD) 2008 criteria [13]) and a smoking history of ≥10 pack-years. At screening, they were required to have a post-bronchodilator forced expiratory volume in 1 s (FEV1) ≥30% and 100 mL or >200 mL in trough FEV1 at week 26). Figure 3– Trough forced expiratory volume in 1 s (FEV1) a) at week 26 and b) over the entire 26-week treatment period. a) Data are presented as least squares mean±se. One-sided adjusted p-values are presented for comparisons in the statistical gatekeeping procedure and two-sided p-values are presented for all other comparisons. b) QVA149 was superior to all active treatments and placebo at all timepoints (all p 30 days after the last dose of study drug but before the end of the follow-up visit (indacaterol (n = 1): pneumonia and glycopyrronium (n = 1): colon cancer). None of the deaths were considered by the investigator to be related to the study drug. Discussion Combining two bronchodilators with different mechanisms of action has the potential to enhance efficacy compared with single agents without increasing adverse effects [2, 3]. In the SHINE study, dual bronchodilation with QVA149, administered once-daily, provided superior improvements in lung function compared with its monocomponents indacaterol and glycopyrronium given alone, as well as tiotropium and placebo. Improvement in the primary end-point, trough FEV1 was both statistically and clinically significant (considered to be ≥100 mL in COPD) over placebo, and versus active comparators it approached clinical significance. Furthermore, lung function improvements with QVA149 were superior at their peak and, in a subset of patients monitored over 24 h, throughout the day. Similar trends to the overall population were observed in subgroup analyses. Improvements in lung function versus placebo were greater in patients with moderate versus severe COPD; however, statistically and clinically significant improvements in trough FEV1 were seen for both moderate and severe patient subgroups. Improvements in lung function were not influenced by patient age, sex or concurrent use of ICS. Furthermore, they were maintained throughout the 26-week treatment period, and the onset of action of QVA149 was confirmed to be rapid, similar to that of a short-acting β2-agonist. These beneficial effects of QVA149 on lung function were paralleled by statistically significant improvements in other clinically important end-points: dyspnoea, health status and patient symptoms and reduced rescue medication use. QVA149 was significantly superior to placebo and tiotropium for both the TDI and SGRQ total score at week 26; no other active treatment achieved a significant improvement in SGRQ versus placebo. Furthermore, a significantly higher proportion of patients on QVA149 achieved a clinically meaningful improvement in TDI (≥1 unit) and SGRQ (≥4 units) versus placebo and tiotropium. QVA149 was well tolerated over the 26-week study with an adverse event profile similar to that of placebo. In addition, no actual or potential safety signals were observed with the combination compared with the single bronchodilators. Despite previous concerns that LABAs and LAMAs may present a risk of cardiovascular events [14–17], the CCV safety profile of this LABA/LAMA combination was similar to that of placebo. The results of this study are consistent with those of several published studies that have investigated the efficacy and safety of free combinations of LABAs and LAMAs in patients with COPD [6, 18–20], but this is the first to demonstrate the additive benefit of the two classes of long-acting bronchodilator in a combination device. Previous studies have been limited by different durations of actions of the LAMA and LABA components (i.e. formoterol or salmeterol having to be administered twice daily). Our study confirms that the additive benefit of indacaterol and glycopyrronium persists over 24 h, without tachyphylaxis, providing further support for the use of dual bronchodilators. The present study supports the GOLD 2013 strategy alternative choice recommendation that the addition of a second bronchodilator in patients with moderate-to-severe COPD (groups B–D) may optimise symptom benefit [1]. In “low-risk” patients who remain symptomatic on a single bronchodilator (group B), the combination of indacaterol plus glycopyrronium in a single inhaler may lead to significantly improved outcomes compared with LABA or LAMA monotherapy. In “high-risk” patients with severe or very severe COPD (high symptom level and historical exacerbation frequency; groups C and D in the GOLD management strategy [1]) a LABA plus a LAMA is recommended as an alternative to a LABA/ICS combination (group C) or ICS plus LABA and/or LAMA (group D). In comparing LABA plus LAMA and LABA/ICS combination, improvements in lung function achieved with two bronchodilators are expected to be numerically superior to the single bronchodilator in LABA/ICS combinations. In the TORCH (Towards a Revolution in COPD Health) study, combination therapy achieved 50 mL and 44 mL improvement in FEV1 versus salmeterol and fluticasone propionate alone, respectively; however, the LABA/ICS combination is selected for its demonstrated effect on COPD exacerbations [21]. A real-world analysis has indicated that a high proportion of patients at low risk for exacerbations (groups A or B) may be receiving ICS inappropriately [22]. Some patients currently receiving combined LABA/ICS may do better on a LABA/LAMA combination [23]. This would provide dual bronchodilation without the need for ICS treatment, and therefore without the inherent risks of ICS [24], as recommended by the GOLD 2013 strategy [1]. The 26-week ILLUMINATE study supports the use of QVA149 versus LABA/ICS in this population [25]. QVA149 once daily was associated with significant improvements in lung function and dyspnoea versus twice-daily salmeterol/fluticasone. Furthermore, the current SHINE study provides evidence for the additive benefit and safety of a LABA/LAMA combination, demonstrating that QVA149 is superior for most end-points over tiotropium, which is currently recommended as an alternative to LABA/ICS combination, alone or in combination with a LABA. Features of QVA149 that may help to reduce nonadherence to treatment, which remains high in COPD [26], are the convenience of once-daily dosing [27] which is generally preferred by patients [26, 28, 29] and the need for only a single inhaler. Furthermore, the rapid onset of action may be evident to patients as they wake at the nadir of their daily lung function cycle when symptoms are most prominent [30]. However, these advantages of a LABA/LAMA combination and QVA149 are speculative and need to be tested in further prospective studies. We acknowledge several limitations in our study. Firstly, with regards to the study population, we did not intend to include the full range of COPD severities that might benefit from dual long-acting bronchodilators. Since our main objective was to assess the incremental benefit of two bronchodilators in combination (versus one), we elected to recruit only patients with moderate-to-severe COPD. As in our study, results of studies involving LABA/ICS combinations (e.g. the TORCH study [21]) and tiotropium (e.g. the UPLIFT study [31]), have confirmed that patients with moderate disease showed the greatest improvements in lung function. The apparent high reversibility of FEV1 (20%) is attributable to the fact that both salbutamol and ipratropium were administered during this test, and reversibility of this magnitude is not unusual in moderate COPD. We went to lengths to exclude patients with asthma (inclusion criteria: age of onset of symptoms >40 years, absence of rhinitis and blood eosinophil count of <600 cells·mm−3 (see the online supplementary material)). Finally, unlike most COPD studies, which enrich for patients with exacerbations, in our study we excluded patients with a recent COPD exacerbation (in the previous 6 weeks) to reduce the impact of withdrawal due to exacerbations on the primary spirometric end-point. For this reason, along with the fact that patients had milder disease and the study was relatively short (6 months), the present study does not provide useful information on the effect of QVA149 on COPD exacerbations, which has been examined in studies of appropriate design (SPARK study [32]). A further limitation of our study is the difficulty in evaluating the clinical significance of spirometric and other clinical end-points (TDI and SGRQ) versus active (monocomponent) treatments. Although statistically superior to all monocomponents, QVA149 attained the MCID for only some comparisons (fig. 3 and online supplementary table S3). However, it should be noted that the MCID for a trough FEV1 of 100 mL is generally used for comparisons versus placebo, and that the mean improvements of 70, 80 and 90 mL versus indacaterol, glycopyrronium and tiotropium, respectively, approach this threshold value; comparative data for TDI and SGRQ also support this trend. In conclusion, once-daily QVA149 demonstrated superior efficacy compared with placebo, its monocomponents indacaterol and glycopyrronium, and the current standard of care (tiotropium) in patients with moderate-to-severe COPD. QVA149 was also associated with an adverse event profile that was similar to placebo with no additional safety signal compared with monotherapies. This is the first study to demonstrate the advantage of dual bronchodilation with a fixed-dose LABA/LAMA combination, compared with a single bronchodilator in patients with moderate-to-severe COPD.
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              Device selection and outcomes of aerosol therapy: Evidence-based guidelines: American College of Chest Physicians/American College of Asthma, Allergy, and Immunology.

              The proliferation of inhaler devices has resulted in a confusing number of choices for clinicians who are selecting a delivery device for aerosol therapy. There are advantages and disadvantages associated with each device category. Evidence-based guidelines for the selection of the appropriate aerosol delivery device in specific clinical settings are needed. (1) To compare the efficacy and adverse effects of treatment using nebulizers vs pressurized metered-dose inhalers (MDIs) with or without a spacer/holding chamber vs dry powder inhalers (DPIs) as delivery systems for beta-agonists, anticholinergic agents, and corticosteroids for several commonly encountered clinical settings and patient populations, and (2) to provide recommendations to clinicians to aid them in selecting a particular aerosol delivery device for their patients. A systematic review of pertinent randomized, controlled clinical trials (RCTs) was undertaken using MEDLINE, EmBase, and the Cochrane Library databases. A broad search strategy was chosen, combining terms related to aerosol devices or drugs with the diseases of interest in various patient groups and clinical settings. Only RCTs in which the same drug was administered with different devices were included. RCTs (394 trials) assessing inhaled corticosteroid, beta2-agonist, and anticholinergic agents delivered by an MDI, an MDI with a spacer/holding chamber, a nebulizer, or a DPI were identified for the years 1982 to 2001. A total of 254 outcomes were tabulated. Of the 131 studies that met the eligibility criteria, only 59 (primarily those that tested beta2-agonists) proved to have useable data. None of the pooled metaanalyses showed a significant difference between devices in any efficacy outcome in any patient group for each of the clinical settings that was investigated. The adverse effects that were reported were minimal and were related to the increased drug dose that was delivered. Each of the delivery devices provided similar outcomes in patients using the correct technique for inhalation. Devices used for the delivery of bronchodilators and steroids can be equally efficacious. When selecting an aerosol delivery device for patients with asthma and COPD, the following should be considered: device/drug availability; clinical setting; patient age and the ability to use the selected device correctly; device use with multiple medications; cost and reimbursement; drug administration time; convenience in both outpatient and inpatient settings; and physician and patient preference.
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                Author and article information

                Journal
                Int J Chron Obstruct Pulmon Dis
                Int J Chron Obstruct Pulmon Dis
                COPD
                copd
                International Journal of Chronic Obstructive Pulmonary Disease
                Dove
                1176-9106
                1178-2005
                04 June 2020
                2020
                : 15
                : 1269-1285
                Affiliations
                [1 ]Department of Pulmonary Rehabilitation, Sleep Laboratory, Istituti Clinici Scientifici Maugeri, IRCCS , Veruno, NO, Italy
                [2 ]Department of Internal Medicine, Respiratory Diseases and Allergy Clinic, University of Genoa, Azienda Policlinico IRCCS San Martino , Genoa, Italy
                [3 ]Respiratory Area, Medical Affairs Chiesi Italia , Parma, Italy
                [4 ]Respiratory Unit, Department of Experimental Medicine, University of Rome “Tor Vergata” , Rome, Italy
                [5 ]Pierachille Santus, Department of Biomedical and Clinical Sciences (DIBIC), University of Milan , Milan, Italy
                [6 ]Department of Biomedicine and Internal and Specialistic Medicine (DIBIMIS), University of Palermo , Palermo, Italy
                Author notes
                Correspondence: Fulvio Braido Department of Internal Medicine, IRCCS San Martino Genoa University Hospital , Genoa, Italy Email Fulvio.braido@unige.it
                Article
                240033
                10.2147/COPD.S240033
                7283230
                © 2020 Braghiroli et al.

                This work is published and licensed by Dove Medical Press Limited. The full terms of this license are available at https://www.dovepress.com/terms.php and incorporate the Creative Commons Attribution – Non Commercial (unported, v3.0) License ( http://creativecommons.org/licenses/by-nc/3.0/). By accessing the work you hereby accept the Terms. Non-commercial uses of the work are permitted without any further permission from Dove Medical Press Limited, provided the work is properly attributed. For permission for commercial use of this work, please see paragraphs 4.2 and 5 of our Terms ( https://www.dovepress.com/terms.php).

                Page count
                Figures: 2, Tables: 2, References: 129, Pages: 17
                Categories
                Review

                Respiratory medicine

                ics, copd, laba, circadian lama, adherence, follow-up, sleep, night, dyspnea, symptoms

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