Search Results (255)

Asthma, the most common chronic respiratory condition in children, involves airway inflammation, hyper-responsiveness, and frequent exacerbation that worsen the airflow and inflammation. Exosomes, extracellular vesicles carrying microRNAs (miRNAs), play a key role in cell communication alongside other types of communication and are promising markers of asthma severity. This study compares exosomal miRNA and long non-coding RNA (lncRNA) profiles in boys with asthma, focusing on differences between those with normal lung functions and those with severe airflow obstruction. This study enrolled 20 boys aged 9–18 years with asthma, split into two groups based on their lung function. Ten had normal lung function (NLF; FEV1/FVC > 0.84, FEF75% > 69% predicted), while ten had severe airflow obstruction (SAO; FEV1/FVC < 0.70, FEF75 < 50% predicted). Saliva and blood samples were collected. Exosomes were isolated, quantified, and analyzed via small RNA sequencing to identify differentially expressed (DE) miRNA and lncRNA profiles. Bioinformatic tools were then used to explore potential miRNA biomarkers linked to asthma severity. SAO subjects were more likely to exhibit allergen sensitization, higher IgE levels, and more eosinophils. We identified 27 DE miRNAs in plasma and 40 DE miRNAs in saliva. Additionally, five key miRNAs were identified in both saliva and plasma which underline important pathways such as neurotrophins, T-cell receptor, and B-cell receptor signaling. We further outlined key features and functions of miRNAs and long non-coding RNAS (lncRNAs) and their interactions in children with asthma. This study identified DE miRNAs and lncRNAs in children with SAO when compared to those with NLF. Exosomal miRNAs show strong potential as non-invasive biomarkers for personalized asthma diagnosis, treatment, and monitoring. These RNA markers may also aid in tracking disease progression and response to therapy, thereby supporting the need for future studies aimed at applications in precision medicine. Full article

The use of implants in the trachea is increasing in respiratory diseases as an alternative to address pathological problems with airway obstruction. This article presents the design and development of a three-way cannula and its evaluation in a testbed capable of emulating the human breathing cycle. The new tracheal cannula allows airflow through a third duct (vertical one) towards the vocal folds, enabling phonation. The testbed assesses Total Lung Capacity (TLC) and endotracheal pressure by considering the cannula inside a replica of a trachea. The flow is generated by a mechanism composed of electronic elements, and the implementation of instruments for measuring pressure and lung capacity enables the visual and continuous collection of data. The three-way cannula offers improvements in airway capacity, with an average of up to 1.766 L of airflow and a pressure of 17.083 mbar. The airflow at the upper branch allows for improvement, enabling the patient to phonate even with the implant in place, while preserving patency due to the biocompatibility and elasticity of platinum silicone. Full article

Background: Chronic obstructive pulmonary disease (COPD) is a heterogeneous lung condition marked by persistent airflow limitation and is currently the fourth leading cause of death worldwide, accounting for 3.5 million deaths in 2021. While its physical manifestations such as dyspnea, chronic cough, and sputum production are well known, its psychological impact, particularly the high prevalence of depression among patients, remains under-recognized. Objectives: This narrative review aims to summarize the existing data on the association between COPD and depression, analyze their pathophysiological connections, explore treatment possibilities, and highlight the interrelationships between these conditions. Methods: A non-systematic literature search was conducted using PubMed, Scopus, and Google Scholar. Studies, reviews, and key publications addressing the relationship between COPD and depression were selected based on clinical relevance. Findings were synthesized thematically to provide a comprehensive and critical overview. Results: Depression in patients with COPD is linked to worse quality of life, increased functional impairment, higher suicide risk, and poorer adherence to treatment. Contributing mechanisms include chronic systemic inflammation, hypoxemia, oxidative stress, and psychosocial risk factors such as low educational level, socioeconomic disadvantage, and comorbidities. Despite evidence of this strong association, treatment strategies remain limited and underutilized, and no unified approach has yet been established. Conclusions: Depression represents a major comorbidity in COPD that exacerbates both disease burden and patient suffering. Further research is essential to clarify the underlying mechanisms and to develop integrated therapeutic approaches. Enhancing our understanding and management of this comorbidity holds promise for significantly improving patient outcomes and overall quality of life. Full article

Asthma is a complex and heterogeneous disease characterized by chronic airway inflammation, bronchial hyperresponsiveness, and reversible airflow obstruction. Despite extensive research, its underlying molecular mechanisms remain incompletely understood. Among the key immune cells involved, eosinophils play a central role in asthma pathophysiology through their contributions to Type 2 inflammation, tissue remodeling, and immune regulation. Recent studies have shown that non-coding RNAs (ncRNAs) play a crucial role in regulating eosinophil biology and contribute to the molecular mechanisms underlying asthma progression. This review consolidates the current understanding of ncRNAs in the development of eosinophils, their involvement in asthma pathogenesis, and the mechanisms underlying this process. Full article

Chronic obstructive pulmonary disease (COPD) is an escalating global health burden, with a disproportionate impact on low- and middle-income countries (LMICs). Although tobacco smoking is a well-established risk factor, emerging evidence highlights the significant role of non-smoking exposure in driving the prevalence of COPD in these regions. This narrative review synthesizes current data on key non-smoking contributors, including household air pollution, ambient urban pollution, occupational exposure, early-life respiratory insults, chronic infections, and socioeconomic adversity. These risk factors are associated with distinct COPD phenotypes, often marked by increased airway inflammation, reduced emphysema, and variable airflow limitation. Such presentations are particularly common among women and younger populations in LMICs. However, diagnostic and therapeutic challenges persist, owing to limited disease awareness, under-resourced health systems, restricted access to essential medications, and financial constraints impacting adherence. Despite the proven effectiveness of non-pharmacological measures and public health interventions, their implementation remains inadequate because of infrastructural and funding limitations. Bridging these gaps requires region-specific clinical guidelines, improved diagnostic infrastructure, expanded access to affordable treatment, and culturally sensitive interventions. Future priorities include identifying robust biomarkers, refining disease definitions to accommodate non-smoking phenotypes, and advancing implementation science to improve interventions. A coordinated, context-aware global response is essential to reduce the growing burden of COPD in LMICs and to ensure equitable respiratory health outcomes. Full article

Ammonia is emerging as a promising zero-carbon marine fuel due to its high hydrogen density, low storage pressure, and long-term stability, making it well-suited for supporting sustainable maritime energy systems. However, its adoption introduces serious safety challenges, as its toxic, flammable, and corrosive properties pose greater risks than many other alternative fuels, necessitating rigorous risk assessment and safety management. This study presents a comprehensive investigation of potential ammonia leakage scenarios that may arise during the fuel gas supply process within confined compartments of marine vessels, such as the fuel preparation room and engine room. The simulations were conducted using FLACS-CFD V22.2, a validated computational fluid dynamics tool specialized for flammable gas dispersion and explosion risk analysis in complex geometries. The model enables detailed assessment of gas concentration evolution, toxic exposure zones, and overpressure development under various leakage conditions, providing valuable insights for emergency planning, ventilation design, and structural safety reinforcement in ammonia-fueled ship systems. Prolonged ammonia exposure is driven by three key factors: leakage occurring opposite the main ventilation flow, equipment layout obstructing airflow and causing gas accumulation, and delayed sensor response due to recirculating flow patterns. Simulation results revealed that within 1.675 s of ammonia leakage and ignition, critical impact zones capable of causing fatal injuries or severe structural damage were largely contained within a 10 m radius of the explosion source. However, lower overpressure zones extended much further, with slight damage reaching up to 14.51 m and minor injury risks encompassing the entire fuel preparation room, highlighting a wider threat to crew safety beyond the immediate blast zone. Overall, the study highlights the importance of targeted emergency planning and structural reinforcement to mitigate explosion risks in ammonia-fueled environments. Full article

Bronchial asthma is a respiratory chronic disorder frequently affecting youth. It is characterized by a huge personal, familial, and societal impact. Biological and cellular studies in recent decades define asthma as a chronic inflammatory disease of the airways. Inflammation represents the major pathogenetic factor underlying the airflow obstruction and bronchial hyperactivity that peculiarly characterize asthma. When bronchial asthma is diagnosed after too long a delay and treated too late or inadequately, structural remodeling of the whole bronchial wall can occur and lead to persistent limitations in lung function and quality of life. Although adult asthma and asthma in youth may be recognized by some common pathogenetic mechanisms, there are some important differences that justify a peculiar approach to asthma in young individuals, worth particular attention. Anatomical, physiological, social, and emotional aspects that differentiate asthma in children and adolescence are briefly revised and highlighted in the present review. Full article

Lymphangioleiomyomatosis (LAM) is a rare progressive disease that affects women of reproductive age and is characterized by cystic lung destruction, airflow obstruction, and lymphatic dysfunction. Current diagnostic methods are costly or lack sufficient specificity, highlighting the need for novel non-invasive approaches. Exhaled breath analysis using real-time proton mass spectrometry (PTR-MS) presents a promising strategy for identifying disease-specific volatile organic compounds (VOCs). This cross-sectional study analyzed exhaled breath samples from 51 LAM patients and 51 age- and sex-matched healthy controls. PTR-time-of-flight mass spectrometry (PTR-TOF-MS) was employed to identify VOC signatures associated with LAM. Data preprocessing, feature selection, and statistical analyses were performed using machine learning models, including gradient boosting classifiers (XGBoost), to identify predictive biomarkers of LAM and its complications. We identified several VOCs as potential biomarkers of LAM, including m/z = 90.06 (lactic acid) and m/z = 113.13. VOCs predictive of disease complications included m/z = 49.00 (methanethiol), m/z = 48.04 (O-methylhydroxylamine), and m/z = 129.07, which correlated with pneumothorax, obstructive ventilation disorders, and radiological findings of lung cysts and bronchial narrowing. The classifier incorporating these biomarkers demonstrated high diagnostic accuracy (AUC = 0.922). This study provides the first evidence that exhaled breath VOC profiling can serve as a non-invasive additional tool for diagnosing LAM and predicting its complications. These findings warrant further validation in larger cohorts to refine biomarker specificity and explore their clinical applications in disease monitoring and personalized treatment strategies. Full article

Background: Lithium is an essential commodity; however, its mining and processing can expose miners to airborne contaminants such as inhalable dust, respirable dust and respirable crystalline silica. These exposures may adversely affect respiratory health. To protect the health of miners, exposure assessment and control activities are required, followed by respiratory health monitoring to assess the effect of exposure on respiratory health. This study aimed to investigate the relationship between workgroup exposure to airborne contaminants and respiratory health. To determine group exposure levels, exposure data was collected at the group level, which limits individual-level inference, followed by health monitoring. Methods: Industry health monitoring data were collected from miners in three surface lithium mines in Western Australia for the period between October 2023 and October 2024. Miners from Management Administration & Technical, Crusher/Dry/Wet Plant, and Laboratory Operations participated in a pulmonary function test, completed a health and exposure questionnaire and underwent a low dose high-resolution computed tomography. Multivariable linear and logistic regression models were fitted to identify factors associated with lung function and respiratory symptoms. Results: Older age, smoking and pre-existing respiratory conditions were correlated with poor respiratory airflow. The odds of having a respiratory obstruction or restriction were significantly higher by 3.942 and 2.165 times respectively, for miners who were 40 years old or above, and those who had existing diagnosed respiratory medical conditions. The risk of coughing among current smokers was more than four times higher compared to non-smokers. In addition, working in Crushing and Processing was significantly associated with the risk of experiencing respiratory symptoms compared to working in Management Administration & Technical and Laboratory Operations. Conclusions: The study demonstrated that respiratory health was influenced by non-work-related risk factors. Based on these results, it is recommended that health promotion programs be developed and implemented to empower miners to cease smoking and to manage non-work-related respiratory conditions. Full article

Asthma is a chronic inflammatory disease characterized by airway hyperresponsiveness, variable airflow obstruction, and persistent inflammation. While its pathophysiology is well established, growing evidence highlights significant sex-based differences in its prevalence, severity, and treatment response. Epidemiological studies indicate that asthma is more common in prepubertal boys but shifts toward a female predominance after puberty, with adult women experiencing higher morbidity and greater healthcare utilization. These disparities suggest a crucial role for sex hormones, genetic predisposition, and epigenetic regulation in asthma pathogenesis. Sex hormones modulate immune responses, contributing to disease progression. Estrogen enhances type 2 inflammation, increases eosinophilic infiltration, and upregulates IL-4 and IL-13 expression, leading to greater airway hyperreactivity in women. Additionally, progesterone fluctuations correlate with perimenstrual asthma exacerbations, while testosterone appears to exert a protective effect by dampening Th2-driven inflammation and airway remodeling. These hormonal influences contribute to sex-specific asthma phenotypes and treatment responses. Genetic and epigenetic factors further shape sex-related differences in asthma. The X chromosome harbors immune-regulatory genes, including TLR7 and TLR8, which amplify inflammatory responses in females. The sex-dependent expression of IL13 and ORMDL3 influences eosinophilic inflammation and airway remodeling. Epigenetic modifications, such as DNA methylation and microRNA regulation, further impact immune activation and corticosteroid responsiveness. For instance, Let-7 miRNAs modulate IL-13 expression, contributing to sex-specific inflammatory profiles. Environmental factors, including air pollution, obesity, and diet, interact with hormonal and genetic influences, exacerbating sex disparities in asthma severity. Obesity-related metabolic dysfunction promotes systemic inflammation, airway remodeling, and steroid resistance, disproportionately affecting women. Given these complex interactions, sex-specific approaches to asthma management are essential. Personalized treatment strategies targeting hormonal pathways, immune regulation, and metabolic health may improve outcomes for both men and women with asthma. Future research should focus on sex-based therapeutic interventions to optimize disease control and mitigate healthcare disparities. Full article

Background: Over the last 15 years, few echocardiographic studies have examined the biventricular mechanics by speckle tracking echocardiography (STE) in patients affected by chronic obstructive pulmonary disease (COPD) without advanced lung disease. We aimed to summarize the main findings of these studies and quantify the overall effect of COPD on biventricular mechanics in patients without severe airflow obstruction. Methods: Eligible studies assessing cardiac function by conventional transthoracic echocardiography (TTE), implemented with a STE analysis of left ventricular (LV)-global longitudinal strain (GLS) and/or right ventricular (RV)-GLS in COPD patients without severe airflow obstruction vs. healthy controls, were selected from the PubMed, Embase and Scopus databases. The primary endpoint was to quantify the effect of COPD on LV-GLS and RV-GLS in individuals without advanced lung disease. Continuous data [LV-GLS, RV-GLS, left ventricular ejection fraction (LVEF) and tricuspid annular plane systolic excursion (TAPSE)] were pooled as the standardized mean difference (SMD) comparing COPD cohorts with healthy controls. Results: Ten studies were included, totaling 682 COPD patients and 316 healthy controls. Overall, COPD showed a large effect on LV-GLS (SMD −1.296; 95%CI −2.010, −0.582, p < 0.001) and RV-GLS (SMD −1.474; 95% CI −2.142, −0.805, p < 0.001), a medium-to-large effect on TAPSE (SMD −0.783, 95% CI −0.949, −0.618, p < 0.001) and a small effect on LVEF (SMD −0.366, 95% CI −0.659, −0.074, p = 0.014). The I² statistic value for the LV-GLS (91.1%), RV-GLS (88.2%) and LVEF (76.7%) studies suggested a high between-study heterogeneity, while that for the TAPSE (38.1%) studies was compatible with a low-to-moderate between-study heterogeneity. Egger’s test yielded a p-value of 0.16, 0.48, 0.58 and 0.50 for LV-GLS, RV-GLS, LVEF and TAPSE studies, respectively, indicating an absence of publication bias. Meta-regression analyses excluded that the effect of COPD on biventricular mechanics might be influenced by potential confounders (all p > 0.05). Sensitivity analysis confirmed the robustness of the LV-GLS, RV-GLS and TAPSE studies’ results. Conclusions: COPD appears to be independently associated with a mild attenuation of biventricular mechanics in patients with moderate airflow limitations, despite a preserved LVEF and TAPSE on conventional TTE. STE analysis may allow clinicians to identify COPD patients with subclinical myocardial dysfunction and an increased risk of heart failure and cardiovascular complications early. Full article

The burden of chronic obstructive pulmonary disease (COPD) is increasing, especially for women in low-to-middle income countries. Biomarkers provide ever-increasing diagnostic precision for COPD and show promise for primary, secondary, and tertiary disease prevention. This review describes emerging applications for biomarkers in COPD, especially as they align with the Global Initiative for Chronic Obstructive Lung Disease (GOLD) emphasis on prevention, early diagnosis, and response to therapy. These biomarkers include blood eosinophils; IgE; C-reactive protein; fibrinogen; procalcitonin; interleukins 6, 8, and 33; tumor necrosis factor alpha; and soluble receptor for advanced glycated products (sRAGE). They have been used in various ways to identify COPD endotypes, predict exacerbations, predict mortality, and monitor the response to therapy. The fraction of exhaled nitric oxide (FENO) is increasingly studied in eosinophilic COPD endotypes and can be a diagnostic and predictive non-invasive biomarker. Imaging biomarkers, especially the quantitative computerized tomography (QCT) assessment of airway remolding, functional small airway disease, air trapping, lung function, and volume surrogates, all serve as non-invasive biomarkers for screening, early detection, and disease progression. Biomarkers facilitate all the phases of COPD care from detecting early airflow obstruction to predicting exacerbation and mortality. Biomarkers will be increasingly used as precise diagnostic tools to improve the COPD outcomes. The aim of this narrative review is to summarize the recent investigations in COPD biomarkers and their clinical applications. Full article

Background/Objectives: This retrospective study used computer fluid dynamics (CFD) to evaluate the medium-term changes in the upper airways (UA) airflow after rapid maxillary expansion (RME) in three age-matched groups with different degrees of adenoidal obstruction. Methods: The sample included Cone-Beam Computed Tomography (CBCT) of 67 adolescents taken before (T0) and 12 months after RME (T1) and divided into three cohorts: Control Group (CG, <25% obstruction: 24 subjects, mean age = 11.8 ± 1.3), Adenoids Group 1 (AG1, >25% <75% obstruction: = 22 subjects, mean age = 10.9 ± 1.5), Adenoids Group 2 (AG2, >75% obstruction: = 21 subjects, mean age = 11.2 ± 1.6). The airflow pressure, velocity and obstruction were simulated using computer fluid dynamics (CFD). Results: The pressure significantly improved in CG and AG1 groups while the velocity improved in AG1 as well as the prevalence of obstruction improvement. The airflow pressure and velocity changes could be attributed to the reduction of the resistances in the adenotonsillar region, which was remarkably more marked in the AG1. Conclusions: Alterations in the adenotonsillar region likely represent the most substantial factors influencing airflow changes after RME. The integration of anatomical and functional data, along with the identification of baseline patient characteristics, may facilitate the characterization of phenotypes most appropriate for initial management through either Rapid Maxillary Expansion (RME) or otolaryngologic (ENT) interventions. Full article

Background/Objectives: Upper airway patency is a key pathophysiological factor in obstructive sleep apnea (OSA). Research has primarily focused on the role of the genioglossus muscle in maintaining airway patency in OSA. However, hypoglossal nerve stimulation (HNS) therapy, which activates the genioglossus muscle, has been associated with poor outcomes in patients with lateral oropharyngeal collapse. The stylopharyngeus muscle is an upper airway dilator muscle that supports the lateral pharyngeal wall. Its role in maintaining upper airway patency and its effect on normal respiratory airflow is unclear. We hypothesize that bilateral transection of the stylopharyngeus muscles disrupts normal breathing. Currently, no animal model depicting lateral pharyngeal collapse has been reported. This study aims to introduce a novel rodent model with bilateral transection of the stylopharyngeus muscles to examine its effect on respiratory airflow and tracing. Methods: Adult male Sprague Dawley rats were divided into two groups: (1) bilateral stylopharyngeus muscle transection (n = 4) and (2) sham surgery (n = 2). Under anesthesia, the stylopharyngeus muscle was transected bilaterally in the transection group, while only exposure of the muscle was performed in the sham group. Respiratory airflow was measured using whole-body plethysmography before and after surgery, and airflow tracings were analyzed. Results: Significant alterations in respiratory airflow and tracings, particularly a flattening in inspiratory flow and sharp expiratory peaks, were observed on the first post-operative day in the transection group. The flattening of the inspiratory flow persisted over 3 days. No significant changes were noted in the sham group. Conclusions: Bilateral stylopharyngeus muscle transection alters normal airflow in a conscious rodent model, supporting the hypothesis that stylopharyngeus muscle plays a vital role in shaping respiratory airflow. The flattening of the inspiratory airflow is an indication of flow limitations through the upper airway patency due to the loss of stylopharyngeus function. Full article

Background/Objectives: Nasal irrigation with isotonic seawater is a known and oft-used treatment for nasal obstruction in patients with acute and chronic nasal inflammatory disease undergoing therapy with intranasal corticosteroids and antihistamine drugs. Nasal patency in healthy athletes is extremely important; however, to date, the effect of isotonic solutions for nasal irrigation in healthy athletes has not been tested. This randomized controlled trial aimed to investigate the potential synergy of physical exercise and nasal isotonic seawater on airflow and the subjective assessment of nasal patency in healthy, high-level athletes. Methods: The intervention group included 33 healthy athletes who used an isotonic seawater nasal spray daily, with a control group including 31 healthy athletes who did not use any sprays; both groups underwent identical seven-day training periods. The primary outcome measures were subjective NOSE questionnaire scores and secondary peak nasal inspiratory flow (PNIF) measures, while anthropometric and demographic variables were covariates. Results: A significant decrease in subjective nasal resistance scores was observed in the intervention group compared to the control group (binary logistic regression model, p = 0.006, RR 7.695), both in the first and second measurement interval. This effect increased with time (Friedman’s two-way analysis of variance, p < 0.001). Peak nasal inspiratory flow is positively affected by exercise but not by isotonic seawater spray intervention. Conclusions: The effects of nasal isotonic seawater irrigation during intense athletic training are beneficial on subjective nasal patency in the short term, while the effects on objective nasal patency are less clear. Full article