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Abstract Rationale Poor adherence is common in difficult-to-control asthma. Distinguishing patients with difficult-to-control asthma who respond to inhaled corticosteroids (ICS) from refractory asthma is an important clinical challenge. Objectives Suppression of fractional exhaled nitric oxide (FeNO) with directly observed ICS therapy over 7 days can identify nonadherence to ICS treatment in difficult-to-control asthma. We examined the feasibility and utility of FeNO suppression testing in routine clinical care within UK severe asthma centers using remote monitoring technologies. Methods A web-based interface with integrated remote monitoring technology was developed to deliver FeNO suppression testing. We examined the utility of FeNO suppression testing to demonstrate ICS responsiveness and clinical benefit on electronically monitored treatment with standard high-dose ICS and long-acting β2-agonist treatment. Measurements and Main Results Clinical response was assessed using the Asthma Control Questionnaire-5, spirometry, and biomarker measurements (FeNO and peripheral blood eosinophil count). Of 250 subjects, 201 completed the test with 130 positive suppression tests. Compared with a negative suppression test, a positive test identified a FeNO-low population when adherent with ICS/long-acting β2-agonist (median, 26 ppb [interquartile range, 16–36 ppb] vs. 43 ppb [interquartile range, 38–73 ppb]) with significantly greater FEV1% (mean, 88.2 ± 16.4 vs. 74.1 ± 20.9; P < 0.01). Asthma Control Questionnaire-5 improved significantly in both groups (positive test: mean difference, −1.2; 95% confidence interval, −0.9 to −1.5; negative test: mean difference, −0.9; 95% confidence interval, −0.4 to −1.3). Conclusions Remote FeNO suppression testing is an effective means of identifying nonadherence to ICS in subjects with difficult-to-control asthma and the substantial population of subjects who derive important clinical benefits from optimized ICS/long-acting β2-agonist treatment.

Asthma exacerbations are characterized by increased symptoms of cough and chest tightness, diminished expiratory airflow, and increased numbers of inflammatory cells in the sputum. In these two small “proof of concept” trials involving patients with eosinophilic asthma and a history of exacerbations, patients treated with an antibody directed against interleukin-5 had fewer exacerbations than did those given placebo. Asthma exacerbations are characterized by increased symptoms of cough and chest tightness, diminished expiratory airflow, and increased numbers of inflammatory cells in the sputum. In these two small “proof of concept” trials involving patients with eosinophilic asthma and a history of exacerbations, patients treated with an antibody directed against interleukin-5 had fewer exacerbations than did those given placebo. Asthma is a complex chronic inflammatory disorder of the bronchial tree. Persons with asthma present with variable symptoms of cough, breathlessness, and wheezing; these episodes may be punctuated by periods of more severe and sustained deterioration in control of symptoms — termed exacerbations — that necessitate emergency treatment. Exacerbations are associated with substantial morbidity and mortality and with considerable health care costs. 1 Exacerbations differ from day-to-day symptoms in that they respond poorly to usual inhaled therapy and are more closely linked to increased airway inflammation. 2 The link to eosinophilic airway inflammation may be particularly important, since infiltration of the airway . . .

Idiopathic pulmonary fibrosis (IPF) is a progressive interstitial lung disease with limited therapeutic options. K Ca 3.1 ion channels play a critical role in TGFβ1-dependent pro-fibrotic responses in human lung myofibroblasts. We aimed to develop a human lung parenchymal model of fibrogenesis and test the efficacy of the selective K Ca 3.1 blocker senicapoc. 2 mm 3 pieces of human lung parenchyma were cultured for 7 days in DMEM ± TGFβ1 (10 ng/ml) and pro-fibrotic pathways examined by RT-PCR, immunohistochemistry and collagen secretion. Following 7 days of culture with TGFβ1, 41 IPF- and fibrosis-associated genes were significantly upregulated. Immunohistochemical staining demonstrated increased expression of ECM proteins and fibroblast-specific protein after TGFβ1-stimulation. Collagen secretion was significantly increased following TGFβ1-stimulation. These pro-fibrotic responses were attenuated by senicapoc, but not by dexamethasone. This 7 day ex vivo model of human lung fibrogenesis recapitulates pro-fibrotic events evident in IPF and is sensitive to K Ca 3.1 channel inhibition. By maintaining the complex cell-cell and cell-matrix interactions of human tissue, and removing cross-species heterogeneity, this model may better predict drug efficacy in clinical trials and accelerate drug development in IPF. K Ca 3.1 channels are a promising target for the treatment of IPF.

Although asthma is a chronic inflammatory disease of the airways, exactly which components of inflammation relate to the expression of the asthma phenotype is not known. In this study, the number of mast cells in the airway smooth muscle was determined by biopsy of the airways of normal subjects, subjects with asthma, and subjects with eosinophilic bronchitis. There were significantly more mast cells in the airway smooth muscle of the subjects with asthma than in that of either normal subjects or subjects with eosinophilic bronchitis, a condition that is similar to asthma and therefore provides an appropriate control. Asthma is characterized physiologically by variable airflow obstruction and airway hyperresponsiveness. Pathologically, asthma is characterized by the accumulation of eosinophils and CD4+ lymphocytes in the submucosa, mucous-gland hyperplasia, thickening of the subepithelial collagen layer, submucosal matrix deposition, mast-cell degranulation, and hypertrophy and hyperplasia of the airway smooth muscle. 1 The extent to which airway inflammation and airway hyperresponsiveness in patients with asthma are related to one another remains controversial. 2 However, there is a clear dissociation between airway inflammation and airway hyperresponsiveness in patients with eosinophilic bronchitis 3 , 4 — a condition characterized by cough that is responsive to corticosteroids and eosinophilia detectable . . .

Background Severe asthma is characterised by a variety of symptoms, which include chronic cough, however the mechanisms responsible for cough reflex hypersensitivity in asthma remain poorly elucidated. Current asthma patient-related outcome instruments such as the six-point Juniper Asthma Control Score (ACQ-6) and Asthma Quality of Life Questionnaire (AQLQ) were not primarily designed to capture cough and its related morbidity in asthma. The Leicester Cough Questionnaire (LCQ) is a patient-related outcome instrument designed to capture the health-related quality of life associated with cough. To date the LCQ has not been evaluated in a severe asthma population. Methods We evaluated 262 extensively characterised adult patients with severe asthma attending the Leicester Severe Asthma Service. All patients had a clinician diagnosis of asthma and objective physiological evidence and met the ATS/ERS criterion for servere asthma. In all patients we evaluated a) the LCQ distribution and b) the relationships between the LCQ and ACQ-6, AQLQ, airway inflammation in sputum. Results The LCQ demonstrated the following properties; mean: 15.0, standard deviation: 4.54, median: 15.48, and range: 11.6–19.2. We found a moderate correlation between LCQ and ACQ-6 ( r  = − 0.605, p  < 0.0001) and a LCQ and AQLQ ( r  = 0.710, p  < 0.0001). There was no relationship between LCQ and log 10 sputum percentage eosinophils (%). Conclusion A proportion of patients with severe asthma have a significant degree of cough-related morbidity that appears independent of eosinophilic airway inflammation and is not captured fully by existing asthma patient-reported outcome instruments. Our preliminary findings suggest that further research is now required to validate the LCQ and its responsiveness in severe asthma populations to capture cough-related morbidity and response to specific interventions.

Idiopathic pulmonary fibrosis (IPF) is a common, progressive and invariably lethal interstitial lung disease with no effective therapy. We hypothesised that K(Ca)3.1 K(+) channel-dependent cell processes contribute to IPF pathophysiology. K(Ca)3.1 expression in primary human lung myofibroblasts was examined using RT-PCR, western blot, immunofluorescence and patch-clamp electrophysiology. The role of K(Ca)3.1 channels in myofibroblast proliferation, wound healing, collagen secretion and contraction was examined using two specific and distinct K(Ca)3.1 blockers (TRAM-34 and ICA-17043 [Senicapoc]). Both healthy non fibrotic control and IPF-derived human lung myofibroblasts expressed K(Ca)3.1 channel mRNA and protein. K(Ca)3.1 ion currents were elicited more frequently and were larger in IPF-derived myofibroblasts compared to controls. K(Ca)3.1 currents were increased in myofibroblasts by TGFβ1 and basic FGF. K(Ca)3.1 was expressed strongly in IPF tissue. K(Ca)3.1 pharmacological blockade attenuated human myofibroblast proliferation, wound healing, collagen secretion and contractility in vitro, and this was associated with inhibition of TGFβ1-dependent increases in intracellular free Ca(2+). K(Ca)3.1 activity promotes pro-fibrotic human lung myofibroblast function. Blocking K(Ca)3.1 may offer a novel approach to treating IPF with the potential for rapid translation to the clinic.

Abstract Mast cell microlocalization within the airway smooth muscle bundle is an important determinant of the asthmatic phenotype. We hypothesized that mast cells migrate toward airway smooth muscle in response to smooth muscle–derived chemokines. In this study, we investigated (1) chemokine receptor expression by mast cells in the airway smooth muscle bundle in bronchial biopsies from subjects with asthma using immunohistology, (2) the concentration of chemokines in supernatants from stimulated ex vivo airway smooth muscle cells from subjects with and without asthma measured by enzyme-linked immunosorbent assay, and (3) mast cell migration toward these supernatants using chemotaxis assays. We found that CXCR3 was the most abundantly expressed chemokine receptor on human lung mast cells in the airway smooth muscle in asthma and was expressed by 100% of these mast cells compared with 47% of mast cells in the submucosa. Human lung mast cell migration was induced by airway smooth muscle cultures predominantly through activation of CXCR3. Most importantly, CXCL10 was expressed preferentially by asthmatic airway smooth muscle in bronchial biopsies and ex vivo cells compared with those from healthy control subjects. These results suggest that inhibition of the CXCL10/CXCR3 axis offers a novel target for the treatment of asthma.

Idiopathic pulmonary fibrosis (IPF) is a chronic, progressive disease of increasing prevalence marked by poor prognosis and limited treatment options. Ca2+-activated KCa3.1 potassium channels have been shown to play a key role in the aberrant activation and responses to injury in both epithelial cells and fibroblasts, both considered key drivers in the fibrotic process of IPF. Pharmacological inhibition of IPF-derived fibroblasts is able to somewhat prevent TGF-β– and basic fibroblast growth factor-dependent profibrotic responses. In the current study, we investigated whether blockade of the KCa3.1 ion channel in vivo with a selective inhibitor, Senicapoc, was able to attenuate both histological and physiological outcomes of early fibrosis in our large animal (sheep) model for pulmonary fibrosis. We also determined whether treatment was targeting the profibrotic activity of sheep lung fibroblasts. Senicapoc was administered in established fibrosis, at 2 weeks after bleomycin instillation, and drug efficacy was assessed 4 weeks after treatment. Treatment with Senicapoc improved pre-established bleomycin-induced changes compared with vehicle control, leading to improved lung compliance, reduced extracellular matrix and collagen deposition, and a reduction in both α-smooth muscle actin expression and proliferating cells, both in vivo and in vitro. These studies show that inhibiting the KCa3.1 ion channel is able to attenuate the early fibrogenic phase of bleomycin-dependent fibrosis and inhibits profibrotic behavior of primary sheep lung fibroblasts. This supports the previous research conducted in human IPF-derived fibroblasts and suggests that inhibiting KCa3.1 signaling may provide a novel therapeutic approach for IPF.

KCa3.1 encodes the intermediate-conductance calcium-activated potassium channel KCa3.1, a regulator of membrane potential and calcium-dependent signalling in cardiovascular and immune cells. Increasing evidence indicates that KCa3.1 is a shared driver of vascular remodelling, inflammation, fibrosis, and electrical instability across multiple cardiovascular diseases. In ischaemic heart disease (IHD), KCa3.1 is upregulated in endothelial cells, vascular smooth muscle cells, macrophages, and T lymphocytes, where it promotes smooth muscle proliferation, neointimal formation, and chronic vascular inflammation. Genetic deletion or pharmacological blockade of KCa3.1 reduces atherosclerotic plaque burden and restenosis in animal models. In atrial fibrillation (AF), KCa3.1 contributes to electrical remodelling by shortening atrial action potential duration and to structural remodelling by driving fibroblast activation and collagen deposition. KCa3.1 also regulates macrophage polarisation and pro-inflammatory cytokine release in atrial tissue, linking immune activation to arrhythmogenic substrate formation. Inhibition of KCa3.1 prolongs atrial refractoriness, attenuates atrial fibrosis, and reduces AF inducibility in multiple preclinical models. Emerging data in valvular heart disease suggest that KCa3.1 is upregulated in valvular interstitial cells and regions of active calcification, where it supports myofibroblast differentiation, osteogenic signalling, and inflammatory crosstalk, implicating the channel in fibrocalcific valve degeneration. Collectively, these findings position KCa3.1 as a central molecular integrator of electrical, fibrotic, and inflammatory pathways in cardiovascular disease. The availability of selective KCa3.1 inhibitors with established human safety profiles supports the feasibility of therapeutic translation. Targeting KCa3.1 may enable disease-modifying strategies that extend beyond symptom control to suppress maladaptive cardiovascular remodelling.

The KCa3.1 K+ channel has been proposed as a novel target for pulmonary diseases such as asthma and pulmonary fibrosis. It is expressed in epithelia but its expression and function in primary human bronchial epithelial cells (HBECs) has not been described. Due to its proposed roles in the regulation of cell proliferation, migration, and epithelial fluid secretion, inhibiting this channel might have either beneficial or adverse effects on HBEC function. The aim of this study was to assess whether primary HBECs express the KCa3.1 channel and its role in HBEC function. Primary HBECs from the airways of healthy and asthmatic subjects, SV-transformed BEAS-2B cells and the neoplastic H292 epithelial cell line were studied. Primary HBECs, BEAS-2B and H292 cells expressed KCa3.1 mRNA and protein, and robust KCa3.1 ion currents. KCa3.1 protein expression was increased in asthmatic compared to healthy airway epithelium in situ, and KCa3.1 currents were larger in asthmatic compared to healthy HBECs cultured in vitro. Selective KCa3.1 blockers (TRAM-34, ICA-17043) had no effect on epithelial cell proliferation, wound closure, ciliary beat frequency, or mucus secretion. However, several features of TGFβ1-dependent epithelial-mesenchymal transition (EMT) were inhibited by KCa3.1 blockade. Treatment with KCa3.1 blockers is likely to be safe with respect to airway epithelial biology, and may potentially inhibit airway remodelling through the inhibition of EMT.