When clearance fails: the role of efferocytosis in COPD

The past decade has witnessed great progress in chronic obstructive pulmonary disease (COPD) research.New drugs have been developed and tested, indications for lung volume reduction surgery (LVRS) have been determined, and a growing base of scientific evidence now documents the efficacy of various therapies for symptoms and exacerbations.This advance in knowledge shatters the old conception of COPD as a hopelessly untreatable condition (1-4).It is clear that many patients with COPD can benefit from aggressive management, with a decrease in the frequency of hospitalizations and improvements in quality of life and survival.In addition, basic and clinical scientists have now identified cells, mechanisms, and molecules that appear to play key roles in disease pathogenesis.Additional novel treatments are on the horizon.The good news about COPD is getting out as many organizations are working effectively to increase awareness of the disease (5).Despite advances in care, the COPD epidemic persists, causing more than 120,000 deaths per year in the United States alone.COPD's position as the fourth leading cause of death in the United States is ominous and the probability of the number of cases rising even further is disturbing.Population-based surveys show that as many as 24 million people in the United States have airflow limitation consistent with COPD and that half or more of these cases have not yet been diagnosed (6).Despite the availability of effective treatments for COPD, no existing therapy halts or reverses the progressive and accelerated decline in lung function that is characteristic of this condition.We are far from having a cure for COPD, and in fact, the most basic questions about this disease remain unanswered:d Why do only a minority of smokers develop clinically significant COPD?d Why is there great heterogeneity in the presentation of COPD?d Which pathogenetic pathways are critical, and how can they be modulated therapeutically?d Why does the disease continue to progress even after smoking cessation?d How can the lung injury that characterizes COPD be reversed?

COPD—more than just tobacco smoke

Background: About half of the population in developing countries are exposed to indoor pollution such as combustion fuels at present. Chronic obstructive pulmonary disease (COPD) is one of the leading causes of mortality globally and the primary cause of COPD in women is indoor air pollution exposure, while tobacco smoking is the leading cause in men. The aim of this systematic review and meta-analysis is to evaluate the correlation between the indoor air pollution and deaths related to COPD and COPD prevalence in South Asia. Methods: A systematic search on studies with sufficient statistical power has been conducted from 1985 until 30 June 2020, in English electronic databases following Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines in MEDLINE and PubMed databases with the terms Chronic Obstructive Pulmonary disease COPD or Chronic Bronchitis or Emphysema or COPD Deaths or Chronic Obstructive Lung Disease or Airflow Obstruction or Chronic Airflow Obstruction or Airflow Obstruction, Chronic or Bronchitis, Chronic and Mortality or Death or Deceased was conducted. Studies were eligible if they were Prospective controlled or non-controlled trials conducted in Southern Asia/ Asia and Retrospective studies conducted in Southern Asia/ Asia. Results: The results have concluded that long term exposure to indoor pollution had a significant effect on COPD deaths as well as its symptoms. Odd’s ratio was in a range of 1.05 (Randomized controlled trials) to 7.87 (Cross sectional studies) for all the studies mentioned. Meta-analysis observed a significantly higher Odds Ratio of 2.13 for COPD mortality and 2.08 for COPD prevalence on exposure to indoor air pollution. Conclusion: Exposure to solid fuel smoke is consistently and significantly correlated with COPD mortality and COPD prevalence in South Asian countries, in spite of heterogeneity observed in the studies included. For performing domestic tasks, initiatives are to be taken to reduce dependency on solid fuel by using cleaner alternatives or comparatively cleaner technology.

Maintenance pharmacotherapy of mild and moderate COPD: What is the Evidence?

Asthma and chronic obstructive pulmonary disease (COPD) continue to have considerable impact on disease burden and mortality worldwide. Early diagnosis still remains a challenge, with low uptake of spirometry in many countries. Implementing best practice management for airways disease is a critical goal for health-care systems—the management now includes pharmacological and non-pharmacological approaches to the lung disease, as well as recognition and treatment of comorbidities. Finally, the pathogenesis of airways disease continues to be fertile field of investigation, in order to better prevent disease, slow progression and identify relevant biomarkers. A large number of studies published in Respirology in 2012 have addressed all of these important clinical and scientific issues, and made major contributions to advance this field and hopefully improve outcomes for patients with asthma and COPD. Despite years of research, the origins of asthma remain obscure. Although there is clearly a genetic disposition to developing asthma, gene-association studies have so far failed to reveal clear insights into the development of asthma (reviewed in Respirology in 20111), indicating that asthma is likely to result from a complex interaction between genes and environment. Moreover, marked changes in the prevalence of asthma in recent decades indicate that changing environmental exposures must be to blame. Air pollution is known to exacerbate asthma symptoms and has been one of the factors suspected of causing the disease in the first place. Gowers et al. reviewed the association between air pollution and asthma for the Department of Health in the United Kingdom.2 In fact, they found little evidence for an association between pollution and asthma prevalence. If anything, time trends indicated a negative rather than positive association, but there is some evidence for an increased incidence of asthma in people living very close to roads carrying heavy traffic. The overall impact of this traffic pollution on asthma incidence is not likely to be large. Air pollution of different kind was studied by Havstad et al. who studied the impact of early-life exposure to environmental tobacco smoke on the development of atopy by 2–3 years in a cohort of children.3 Using propensity score matching, they found that tobacco smoke exposure increased the risk of positive skin prick or specific immunoglobulin E (IgE) tests in children whose mothers were not atopic, but paradoxically decreased the risk in those with a positive history of maternal atopy. This interaction between maternal atopy and the effect of environmental tobacco smoke on children's risk for atopy may help to explain some of the conflicting data from previous studies. An accompanying editorial emphasizes that exposing children to tobacco smoke should of course be avoided because of the many other adverse effects,4 but the paper, like that of Gowers et al.,2 demonstrates the need to better understand how genes and environment interact to cause atopy. Other changes in lifestyle and exposures may also help to explain increases in asthma prevalence. The well-recognized association between asthma and obesity was reviewed in Respirology and the mechanism for the association continues to elude researchers.5 Changing dietary exposures could be part of the explanation. A novel association between soft drink consumption, tobacco smoking and airway disease was reported by Shi et al.6 In a large cross-sectional telephone survey of Australian adults, consumption of more than half a litre a day of soft drinks was associated with both asthma and COPD. The association was only apparent among smokers in whom soft drinks and smoking appeared to have additive effects. If these findings are confirmed in other studies, they suggest a lifestyle intervention to prevent airways disease. One of the problems in identifying the origins of asthma is that clinical asthma comprises a number of distinct phenotypes. It has recently been proposed that these phenotypes represent truly different diseases with different causes (also called ‘endotypes’) rather than simply being different and variable expressions of the same underlying pathology.7 Defining asthma phenotypes on the basis of the cellular profile of induced sputum has become increasingly important as studies indicate that eosinophilic airway inflammation responds better to corticosteroid treatment than neutrophilic inflammation.8 Phenotypes are increasingly used to target novel asthma treatments, such as the anti-interleukin (IL)-5 monoclonal antibody targeted to eosinophilic asthma.9 Specific treatments for non-eosinophilic asthma have not been established however. Choi et al. studied sputum inflammatory profiles in patients with refractory asthma requiring high-dose corticosteroid therapy selected from a large asthma cohort.10 Those with persistent airway obstruction had a longer duration of asthma and had predominantly neutrophilic inflammation, whereas refractory asthma without persistent airway obstruction was more likely to be eosinophilic. The authors suggest that this provides a rationale for developing new medications for individualized treatment in these patients. However, two studies in Respirology show that eosinophilic airway inflammation varies over time even in the absence of corticosteroid treatment. Hancox et al. found that the eosinophilic/non-eosinophilic classification was not stable over time in two clinical asthma treatment trails: even though the sputum phenotype was determined at a time when the patients were not taking any steroid treatment, nearly all patients with ‘non-eosinophilic asthma’ had raised sputum eosinophils at some point.11 Similarly, the study of Bacci et al. (discussed in the Airway Biology section) provided evidence that inflammatory phenotypes based on sputum cell analysis are not stable over time.12 Another report last year found that sputum phenotypes are not stable in children either.13 Hence, characterization of asthma and long-term treatment decisions should not be based on a single sputum specimen.14 Induced sputum analysis remains valuable for assessing patients with difficult asthma, but the resources required to obtain and analyse frequent sample will inhibit its widespread use. Although not yet established in the management of asthma, measuring of exhaled nitric oxide (eNO) offers a more practical way to monitor airway inflammation than monitoring of induced sputum.15 Affordable handheld electrochemical nitric oxide analysers are now available, making this a realistic possibility for many services. Kim et al. compared eNO measurements using the handheld Niox Mino (Aerocrine AB, Solna, Sweden) electrochemical analyser with a Sievers (GE Analytical Instruments, Boulder, CO, USA) chemiluminesence analyser.16 Correlation between the two machines was good (r = 0.88), but agreement in absolute values was only moderate: the Mino tended to give about 15% lower readings. The handheld machines are convenient but differences between machines need to be taken into account when interpreting eNO values. Although measuring airway inflammation is appealing, more simple clinical assessments remain the mainstay of asthma management. Ko et al. found that a single measurement of the Asthma Control Test—a score based on a simple 5-item questionnaire—correlated with asthma control assessments by physicians and predicted exacerbations and emergency health-care use over the following 6 months in a cohort of patients attending tertiary care in Hong Kong.17 The baseline Asthma Control Test score was better at predicting exacerbations than lung function, peak flow or eNO measurements. Simple management of asthma was also supported by a large randomized control trial comparing adjustment of inhaled steroid doses using eNO, clinical physician guidance and patient symptom-based adjustment using inhaled corticosteroids (ICS) each time they required β-agonist. No difference was found between the strategies, with the trends favouring patient symptom-led adjustment.9 Improvements in computed tomography (CT) scanning technology and lower radiation doses have enabled the use of high-resolution scans to study airway structure and differentiate between diseases, sites of inflammation and treatment response without the need for tissue biopsies.18 Kurashima et al. found that airway lumens were smaller in the 3rd- to 6th-generation bronchi in asthma but not COPD, whereas both diseases demonstrated airway wall thickening.19 These small airway diameters correlated with lung function in asthma not COPD. Hoshino and Ohtawa used high-resolution CT scans to assess changes in large airway remodelling before and after 24 weeks treatment with combination long-acting β-agonist (LABA) and ICS or ICS alone in a double-blind randomized controlled trial.20 Combination therapy reduced airway wall thickness and increased the airway luminal area to a greater extent than ICS alone. The improvements in airway wall thickness in the combination group correlated with reductions in sputum eosinophils and improvements in forced expiratory volume in 1 s (FEV1). The mechanisms for this positive interaction between ICS and LABA are not known, but the findings offer hope that airway remodelling can effectively treated and/or prevented by combination therapy. An accompanying editorial by King and Farah emphasizes the need for confirmatory and long-term studies as well as investigations of the effects on smaller airways that remain beyond the resolution of the scans.21 The findings of Hoshino and Ohtawa of a positive interaction between LABA and ICS on remodelling is relevant to the current concerns over the safety of LABA in asthma.20 Among the most controversial issues this year is the American Food and Drug Administration requirement that the manufacturers of LABA undertake large safety studies of the combination on LABA with ICS. It is accepted that using LABA without ICS is not acceptable in asthma, but it has been suggested that these large safety studies of combination therapy are futile because they will not be powered to address the question of whether they cause a small excess of asthma deaths.22 In the meantime, a recent meta-analysis demonstrates that withdrawing LABA once asthma control has been achieved, as currently recommended by the Food and Drug Administration, leads to a deterioration in control.23 Cough-variant asthma is another well-recognized but poorly understood phenotype. Ohkura et al. compared coughing during methacholine-induced bronchoconstriction in patients with cough-variant asthma (but normal cough sensitivity to capsaicin challenge) and normal controls.24 Patients with cough-variant asthma had increased cough during even mild methacholine-induced bronchoconstriction. After treatment with inhaled steroids, the number of coughs diminished to be similar to normal controls, indicating that increased cough sensitivity to bronchoconstriction is a feature of this disease variant, but that it responds to anti-inflammatory treatment. For non-asthmatic refractory chronic cough, an exciting discovery this year was that gabapentin is an effective treatment in a double-blind randomized controlled trial.25 Gabapentin is an anticonvulsant that is also used to treat neuropathic pain, suggesting that its effect on chronic cough may be due to suppression of central cough reflexes. The paradigm of Th1- versus Th2-mediated inflammation would suggest that asthma (predominantly a Th2 disease) would be less uncommon in sarcoidosis—regarded as a Th1 disorder. However, Wilsher et al. found that the prevalence of positive specific IgE tests for common aeroallergens (34%) and a history of asthma (21.5%) were similar in patients with sarcoidosis to that reported in the general population.26 In another study from the same group, Young et al. found that 44% of patients with sarcoidosis had airway hyperresponsiveness to histamine (a direct airway challenge), whereas only 11% were hyperresponsive to an indirect challenge using hypertonic saline.27 Hyperresponsiveness to histamine was more common in those with lower baseline FEV1 values and those with fibrotic and reticular patterns on lung CT. The findings suggest that the high prevalence of histamine responsiveness in patients with sarcoidosis is likely to be distinct from asthma (because of the low prevalence of hypertonic saline responsiveness) and is more likely to be due to airway remodelling caused by granulomatous airway inflammation. The development of COPD is related to both genetic and environmental factors. For genetic factors, a recent study by Guan et al. from China found that D2S388-5 microsatellite polymorphism located upstream of the surface lung surfactant protein B gene on chromosome 2 may be associated with susceptibility to COPD in Xinjiang Kazakhs.28 Another genetic factor, nucleotide-binding and oligomerization domain (NOD) 2 genes polymorphism, has also been found to have some potential association with COPD in a study from Japan. The distribution of NOD2 rs1077861 genotypes differed between COPD patients and non-COPD smokers and was associated with a lower FEV1 % predicted value in the TT when compared with the TA/AA genotypes.29 For environmental factors, exposure to noxious particles or gases is associated with the development of COPD.30 A study from Johannessen et al. found that exposure to environmental tobacco smoking during childhood was associated with COPD and respiratory symptoms in adulthood mainly in women in a cross-sectional study in Norway. In men, the most important risk factor is still acting smoking.31 The relationship of air pollution and COPD is reviewed by Ko and Hui.32 Outdoor air pollution (such as ambient air pollution) and indoor pollution (such as second-hand smoking and biomass fuel combustion exposure) are associated with the development of COPD and outdoor air pollution is a significant environmental trigger for acute exacerbation of COPD. Zeng et al. reviewed the aetiology of COPD in non-smoking subjects and risk factors may include genetic factors, long-standing asthma, outdoor air pollution, environmental smoke exposure, biomass smoke, occupational exposure, diet, recurrent respiratory infection in early childhood and tuberculosis.33 Interestingly, statins34 and even soft drink consumption6 have been found to have association with COPD. A cross-sectional study from Japan found that the prevalence of airflow limitation among patients who used statins was approximately five times lower than that among patients who did not use statins. However, statin use was not significantly associated with a lower prevalence of airflow limitation in multivariate analysis.34 Statins thus cannot be advocated for prevention of airflow obstruction at this stage. A study from South Australia assessed the relationship between soft drink consumption and presence of asthma/COPD in over 16 000 subjects.6 and noted the odds ratio for having COPD was 1.79 (95% confidence interval: 1.32–2.43) in multivariate analysis by comparing those who consumed more than half a litre of soft drink per day with those who did not consume soft drinks. The reason behind these associations is unclear and a causative relationship cannot be drawn from these studies. Comorbidities are common in COPD patients and the latest Global Initiative for Chronic Obstructive Lung Disease (GOLD) guideline has also emphasized that comorbid illness in COPD patients should be managed appropriately.30 The link between COPD and coronary artery disease is strong and complex. Coronary artery disease has a strong effect on the severity and prognosis of COPD and vice versa, including acute exacerbations.35 Ito and colleagues found that depression and sleep disorders were both common in patients with COPD.36 McSharry et al. found that sleep quality is poor in severe COPD patients with reduced sleep efficiency and reduced percentage of rapid eye movement sleep. There was a significant association between daytime hypoxaemia and sleep efficiency.37 However, depression, but not sleep disorder, is an independent risk factor for exacerbations and hospitalizations among COPD patients.36 The economic burden of COPD is huge and a recent study from Singapore showed that in 2009, COPD admissions represented 3.4% of all hospital discharges. Hospitalization was found to be the major cost driver, accounting for 73% of the total COPD burden, Between 2005 and 2009, attendances at primary care clinics, emergency departments and specialist clinics accounted for 3%, 5% and 17% of overall COPD costs, respectively.38 There are some new developments in the assessment of COPD using tools like CT and exercise tests. Degree of hyperinflation39 and airway dimensions18, 19 in COPD patients can be measured using CT parameters. Tanabe and colleagues applied a novel CT index to assess lung volume. This DLV% index measures the ratio of lung volume region adjacent to the diaphragm dome (D) to total lung volume (LV). Using this index, it was found that a reduced lung volume around the diaphragm correlated with lung hyperinflation and health-related quality of life, independent of emphysema severity.39 A recent study by Galban et al. adapted the parametric response map, a voxel-wise image analysis technique, for assessing COPD phenotype. In their study, whole-lung CT scans acquired at inspiration and expiration of COPD patients were analysed. Parametric response map identified the extent of functional small airways disease and emphysema as well as provided CT-based evidence that supports the concept that functional small airways disease precedes emphysema with increasing COPD severity.40 Phenotyping COPD by image biomarkers is currently under investigation and offers potential development of personalized therapy for COPD patients. There are also different field and laboratory tests for measuring exercise capacity in COPD patients. Hill and colleagues compared the 6-min walk test, incremental shuttle walk test and endurance shuttle walk test with a ramp cycle ergometer test in a group of patients with moderate COPD and found that these tests all elicited a similar peak rate of oxygen uptake and heart rate response. This suggested that that both self- and externally paced field tests can progress to high intensities.41 Field tests can probably offer a reasonable alternative for the evaluation of patients with moderate COPD.42 The revised was published in were indicated as the or in the treatment of all of patients with COPD. A new of and long-acting have as the most effective for control in patients with COPD. et al. reported the of one such when compared with in patients from 6 for found that provided significant and improvements in and in COPD with that reported in other from clinical indicate that may prevent acute exacerbations of However, the underlying mechanism for this effect is et al. showed that treatment in patients with COPD the and of both and by and This a effect of the in by the of and by the airway The long-term safety of this and its in to other treatment need evaluation before it a acute exacerbation of it is difficult for physicians to differentiate COPD from heart common and comorbidities. and colleagues the of for the diagnosis of in patients with severe acute exacerbations of COPD and in 2 care found that the was more in patients with normal function sensitivity and than those in and required adjustment of the to a et al. in a trial of patients with acute COPD and from heart compared treatment with versus reported more rapid in with the combination treatment but difference in This is a to the and treatment of heart during apparent COPD and sleep disorders are common and important in severe Ito et al. in a study of COPD patients and normal that only depression but not sleep disorders is associated with the increased risk of exacerbations and The management of and depression was the of a by and colleagues in they treatment with the of clinical on this important of COPD with sputum to exacerbations and poor quality of in patients with COPD. In a et al. that inhaled treatment may improve the quality of in patients with by sputum studies are to the of this is an important goal in patients with COPD.30 It quality of and the of greater and pulmonary is an effective way to in COPD long-term monitoring and of at is to the of any exercise In this et al. found that a value was correlated with severe This may be a practical of patients can and to with are and is a intervention for patients with acute exacerbations of COPD who to to treatment. It may be as the current of care in this clinical Moreover, in patients with COPD on the of and mortality from to However, there is a need to improve the practical assessment of the response to in the acute In this et al. reviewed the of for the of during acute However, they were to positive from randomized The clinical may be that of may not be a of response to and should continue to on parameters. the disease the treatment of COPD become less effective and symptoms become more for such patients need to early to complex with about values and for care including of et in a of the the approaches to care at the of in patients with severe interaction susceptibility to airway diseases such as asthma and COPD. association studies have found associations of specific single with the development of asthma or COPD. in Respirology have also on genetic of airway A meta-analysis of studies of the polymorphism in found increased risk of asthma in or with A genetic association study of COPD patients and non-COPD in Japan single in the genes and recognition that The A of single polymorphism rs1077861 in NOD2 was associated with increased risk of COPD, and NOD2 gene in with studies such as these interaction in inflammation and in the development of airway smoking is the major cause of other causes include air pollution and occupational In the development of childhood asthma, an and respiratory are The link between respiratory and Th2 has been demonstrated in asthma in with respiratory in induced airway inflammation and by and reduced to infection may also to asthma pathogenesis and as by studies of airway in In a of asthma, the as an for to by has been as a risk factor for In the Respirology on obesity and respiratory Farah and potential mechanisms for the effects of obesity in including of from tissue and changes that lung have found increased of tissue in patients with The of asthma is by Th2 IgE and cell with of the airway In non-eosinophilic asthma in some patients. In a study of patients with non-eosinophilic asthma of patients also had sputum during over 6 This was more common when they were treated with the alone without inhaled compared with This in Respirology supports the of LABA for asthma and the potential of airway inflammatory phenotype. The airway inflammation of COPD is by and A number of studies in Respirology have on other of are a of that and function more like but also link to the of were lower in the of patients with stable COPD and decreased during acute is a recognition that A study of lung tissue showed that from COPD patients and smokers had increased protein of compared with smoke exposure in increased of and increased and exposure to the smoke could inflammatory to and other of recognition in the Other have also been in COPD. of was in small airway of COPD patients and compared with in with gene of and from that had high Hence, of in the airways could to susceptibility to in the of COPD patients and Airway remodelling is an important feature of chronic In a study in airway of was increased in patients with severe asthma, compared with mild asthma or and was induced following bronchoconstriction with or has been to be for and is a potential of airway remodelling in The pathogenesis of COPD is by a response to environmental to lung that for inflammation, These have been in a number of studies in Respirology in the of may have effects in specific protein of was measured in the lung tissue of COPD with mainly in and was increased in sputum of COPD correlated with of lung function, and correlated with sputum and In another study, and tissue of were measured in from COPD patients and non-COPD of and as well as tissue of 1 and were increased in COPD, the of COPD is by acute as disease A study of patients with an exacerbation of COPD measured inflammatory biomarkers at and before of and were at the of the correlated with exacerbation severity and were reduced by the time of but not to normal of biomarkers behind clinical and could be in monitoring COPD studies into treatment in airways disease. In an asthma study, single in the region of the gene were associated with in a association study of subjects from clinical Although the function of is as yet in of by in airway increased protein of the suggesting a for in In the Respirology on into recent developments in tissue in to the The large airways have been for tissue with and or or In development of for the small airways has been more because of the and number of of the of lung will help to advance this the hope of for lung

Cause-specific mortality adjudication in the UPLIFT® COPD trial: Findings and recommendations

UK COPD treatment: failing to progress

Muscle dysfunction is a common complication and an important prognostic factor in chronic obstructive pulmonary disease (COPD). As therapeutic strategies are still needed to treat this complication, gaining more insight into the process that leads to skeletal muscle decline in COPD appears to be an important issue. This review focuses on mitochondrial involvement in limb skeletal muscle alterations (decreased muscle mass, strength, endurance and power and increased fatigue) in COPD. Mitochondria are the main source of energy for the cells; they are involved in production of reactive oxygen species and activate an important pathway that leads to apoptosis. In COPD patients, skeletal muscles are characterized by decreased mitochondrial density and biogenesis, impaired activity and coupling of mitochondrial respiratory chain complexes, increased mitochondrial production of reactive oxygen species and, possibly, increased apoptosis. Of particular interest, a sedentary lifestyle, hypoxia, hypercapnia, tobacco smoking, corticosteroid therapy and, possibly, inflammation participate in this mitochondrial dysfunction, which is accessible to conventional therapies, such as exercise and tobacco cessation, as well as, potentially, to more innovative approaches, such as antioxidant treatment and supplementation with polyunsaturated fatty acids.

Our previous studies have shown that nutritional zinc restriction exacerbates airway inflammation accompanied by an increase in caspase-3 activation and an accumulation of apoptotic epithelial cells in the bronchioles of the mice. Normally, apoptotic cells are rapidly cleared by macrophage efferocytosis, limiting any secondary necrosis and inflammation. We therefore hypothesized that zinc deficiency is not only pro-apoptotic but also impairs macrophage efferocytosis. Impaired efferocytic clearance of apoptotic epithelial cells by alveolar macrophages occurs in chronic obstructive pulmonary disease (COPD), cigarette-smoking and other lung inflammatory diseases. We now show that zinc is a factor in impaired macrophage efferocytosis in COPD. Concentrations of zinc were significantly reduced in the supernatant of bronchoalveolar lavage fluid of patients with COPD who were current smokers, compared to healthy controls, smokers or COPD patients not actively smoking. Lavage zinc was positively correlated with AM efferocytosis and there was decreased efferocytosis in macrophages depleted of Zn in vitro by treatment with the membrane-permeable zinc chelator TPEN. Organ and cell Zn homeostasis are mediated by two families of membrane ZIP and ZnT proteins. Macrophages of mice null for ZIP1 had significantly lower intracellular zinc and efferocytosis capability, suggesting ZIP1 may play an important role. We investigated further using the human THP-1 derived macrophage cell line, with and without zinc chelation by TPEN to mimic zinc deficiency. There was no change in ZIP1 mRNA levels by TPEN but a significant 3-fold increase in expression of another influx transporter ZIP2, consistent with a role for ZIP2 in maintaining macrophage Zn levels. Both ZIP1 and ZIP2 proteins were localized to the plasma membrane and cytoplasm in normal human lung alveolar macrophages. We propose that zinc homeostasis in macrophages involves the coordinated action of ZIP1 and ZIP2 transporters responding differently to zinc deficiency signals and that these play important roles in macrophage efferocytosis.

Year in review 2017: Chronic obstructive pulmonary disease and asthma.

Nitrosative stress in patients with asthma−chronic obstructive pulmonary disease overlap

Patients with chronic obstructive pulmonary disease (COPD) have an ongoing systemic inflammation, which can be assessed by measuring serum C-reactive protein (CRP). To determine whether increased serum CRP in individuals with airway obstruction predicts future hospitalization and death from COPD. We performed a cohort study with a median of 8-yr follow-up of 1,302 individuals with airway obstruction selected from the ongoing Copenhagen City Heart Study. We measured serum CRP at baseline, and recorded COPD admissions and deaths as outcomes. During follow-up, 185 (14%) individuals were hospitalized due to COPD and 83 (6%) died of COPD. Incidences of COPD hospitalization and COPD death were increased in individuals with baseline CRP > 3 mg/L versus < or = 3 mg/L (log rank: p < 0.001). After adjusting for sex, age, FEV(1)% predicted, tobacco consumption, and ischemic heart disease, the hazard ratios for hospitalization and death due to COPD were increased at 1.4 (95% confidence interval, 1.0-2.0) and 2.2 (1.2-3.9) in individuals with baseline CRP > 3 mg/L versus < or = 3 mg/L. After close matching for FEV(1)% predicted and adjusting for potential confounders, baseline CRP was, on average, increased by 1.2 mg/L (analysis of variance: p = 0.002) and 4.1 mg/L (p = 0.001) in those who were subsequently hospitalized or died of COPD, respectively. The absolute 10-yr risks for COPD hospitalization and death in individuals with CRP above 3 mg/L were 54 and 57%, respectively, among those older than 70 yr with a tobacco consumption above 15 g/d and an FEV(1)% predicted of less than 50. CRP is a strong and independent predictor of future COPD outcomes in individuals with airway obstruction.

Chronic obstructive pulmonary disease (COPD) is a common disability, largely encountered in the elderly population, in whom it causes significant morbidity and mortality. The general perception of health professionals is that COPD is often a self-inflicted disorder affecting the more socio-economically disadvantaged segment of the population with significant comorbidity. COPD is the least funded in terms of research in relation to illness burden compared with other chronic diseases. However, recently published guidelines of both the British Thoracic Society and the Global Initiative for Chronic Obstructive Lung Disease have highlighted best management strategies both of chronic symptoms and acute exacerbations in this patient group. The chronic management of COPD should, like asthma, involve a stepwise approach with smoking cessation being pivotal for all severities of COPD, regardless of patient age. The mainstay of therapeutic treatment remains regular bronchodilators, both beta(2)-adrenoreceptor agonists and anticholinergic agents. Current evidence suggests that long-acting beta(2)-adrenoreceptor agonists such as salmeterol and the new long-acting anticholinergic agent tiotropium bromide are more efficacious than their shorter acting equivalents such as salbutamol and ipratropium bromide in terms of bronchodilation, improved well-being and a reduction in acute exacerbation rates. Additionally since they are taken once or twice daily compliance should be improved. The role of long-term inhaled corticosteroids in the chronic management of COPD is contentious. Only those patients with COPD who have been shown to respond to a formal corticosteroid trial, preferably with a 2-week course of oral corticosteroid, should receive long-term inhaled corticosteroids. In the management of acute exacerbations in acidotic patients nasal ventilation is the treatment of choice in addition to conventional treatment with bronchodilators and oral corticosteroids. Antibacterials need not be prescribed universally in all exacerbations of COPD. Pulmonary rehabilitation classes either individually or in groups have been shown to be beneficial in the management of patients with COPD and their use in secondary care is to be encouraged. Most treatment modalities do not improve pulmonary function in patients with severe COPD. Therefore, pulmonary function including spirometry should be used to make the diagnosis of COPD but not as a monitor of efficacy of treatment. Assessment of severity of COPD and improvement with treatment modalities is best done with dynamic exercise testing such as 6-minute walk tests and incremental shuttle walk tests or with the administration of disease-specific physical disability and quality-of-life questionnaires. Most COPD research does not specifically target the older COPD patients and these patients may merit special consideration for their optimum assessment and management.

Management of chronic obstructive pulmonary disease: Moving beyond the asthma algorithm

Interactive effects of high temperature and ozone on COPD deaths in Shanghai