Search Results (141)

Background and Objectives: Postoperative pulmonary complications (PPCs) remain an important cause of morbidity after cardiac surgery. Driving pressure (DP), defined as the difference between plateau pressure and positive end-expiratory pressure, has been proposed as a bedside marker of respiratory system mechanics during lung-protective ventilation. However, its relationship with PPCs in patients undergoing cardiac surgery with cardiopulmonary bypass (CPB) remains uncertain. This study aimed to evaluate the association between intraoperative DP and PPCs following CPB-supported cardiac surgery. Materials and Methods: This single-center prospective observational study included 99 adult patients undergoing elective cardiac surgery with CPB. All patients were ventilated using a standardized lung-protective strategy with a tidal volume of 6 mL/kg predicted body weight and a fixed PEEP of 5 cmH₂O. Patients were categorized according to intraoperative DP as Group I (DP < 13 cmH₂O, n = 66) and Group II (DP ≥ 13 cmH₂O, n = 33). The primary outcome was a composite PPC endpoint, defined as the occurrence of at least one EPCO-defined pulmonary complication during the postoperative hospital stay. Multivariable logistic regression was performed to assess whether pre-CPB DP was independently associated with PPCs after adjustment for body mass index, CPB time, and age. Results: Patients with DP ≥13 cmH₂O had higher post-CPB and ICU-admission lactate concentrations. Pneumothorax, pleural effusion, atelectasis, CPAP requirement, and prolonged mechanical ventilation were more frequent in the elevated-DP group. Mechanical ventilation duration, ICU stay, and hospital stay were also longer in this group. Composite PPCs occurred in 41 patients (41.4%). Although higher pre-CPB DP showed a non-significant trend toward increased PPC risk in univariable analysis (OR 1.121, 95% CI 0.988–1.273; p = 0.077), it was not independently associated with the composite PPC endpoint after adjustment (adjusted OR 1.091, 95% CI 0.952–1.251; p = 0.212). In contrast, higher pre-CPB DP was significantly associated with prolonged postoperative ventilation and longer mechanical ventilation, ICU, and hospital stay durations. Conclusions: Elevated intraoperative DP was associated with a higher unadjusted burden of PPCs and delayed postoperative recovery after CPB-supported cardiac surgery. However, pre-CPB DP was not an independent predictor of the composite PPC endpoint after adjustment for relevant confounders. These findings suggest that DP may serve as a clinically useful marker of impaired respiratory mechanics and postoperative vulnerability rather than as an independent causal determinant of PPCs. Full article

Background: Obesity increases the risk of postoperative pulmonary complications (PPCs), and active smoking may further amplify this risk. Whether smoking status identifies a subgroup of obese surgical patients with differential PPC risk or a different response to intraoperative Positive End-Expiratory Pressure (PEEP) strategy remains unclear. We evaluated whether smoking status influences PPCs and modifies the effect of intraoperative PEEP strategy in obese patients undergoing surgery. Methods: In this single-center randomized trial, 95 obese surgical patients were assigned to either a low-PEEP strategy (4 cmH₂O without recruitment maneuvers) or a high-PEEP strategy (12 cmH₂O with recruitment maneuvers). The primary endpoint was PPC incidence within 5 postoperative days in the overall randomized population. Smoking status was recorded at baseline, and pre-specified exploratory subgroup analyses assessed PPC incidence according to smoking status and the smoking-by-PEEP interaction. Results: The overall incidence of postoperative pulmonary complications (PPCs) was 8.9% in the low-PEEP group and 8.0% in the high-PEEP group (p > 0.05). Among smokers, complications occurred in 18.2% in the low-PEEP group and 11.8% in the high-PEEP group. For non-smokers, rates were 5.9% and 6.1%, respectively. No statistically significant differences were observed. Conclusions: Active smoking was associated with a numerically higher incidence of PPCs in obese patients; however, this finding was not statistically significant. The high-PEEP strategy with recruitment maneuvers did not reduce PPC incidence compared with the low-PEEP strategy. Trial Registration: Approval number 003208/2016. Full article

Background: Respiratory muscle strength (RMS) is a critical factor influencing athletic performance, particularly in high-intensity or prolonged activities. RMS encompasses inspiratory (IMs) and expiratory muscles (EMs), which differ in anatomical structure, fiber composition, and responsiveness to training. Methods: This pilot interventional within-subject study investigated the effects of two resistive respiratory muscle training (RMT) protocols on RMS and small airway function in eight physically active adults (two females, six males). Maximal inspiratory (MIP) and expiratory pressures (MEP), along with pulmonary function tests (PFTs), were measured using the Airofit PRO™ device and spirometry before and after two consecutive 7-day training protocols, with a 2-day break between interventions. The workload was progressively increased by lengthening the duration of forced inhalation and exhalation, while keeping the air resistance constant. Results: Results demonstrated significant improvements in MEP across both protocols and after a 10-day washout period (p < 0.001–0.03), whereas MIP showed no significant changes (p = 0.19–0.66). Moderate transient improvements were observed in small airway flow (MEF25%) following the first protocol (ES = 0.62), which regressed after the second. Conclusions: These outcomes suggest differential responsiveness of respiratory muscles to RMT; EMs, characterized by a higher proportion of fast-twitch type II fibers and a predominantly passive role in normal breathing, respond rapidly to short-duration, high-intensity forced expiration training through neuromuscular adaptations. Conversely, IMs, dominated by slow-twitch type I fibers, require longer-duration, higher-load training to elicit meaningful adaptations, explaining the limited changes in MIP. Small airway function appeared minimally trainable due to structural and physiological constraints, with short-term improvements likely reflecting effort-dependent factors rather than lasting adaptations. Finally, RMT can selectively enhance EM performance through appropriately designed short-duration, high-intensity interventions, while IMs may necessitate prolonged or higher-load stimuli. The findings highlight the importance of targeted training strategies, individualized to muscle fiber composition and functional demands, to optimize respiratory performance. Future research should investigate longer interventions, larger diverse cohorts, and precise measurement methods to further elucidate RMT’s effects on both respiratory muscles and small airway function. Full article

Background/Objectives: Mechanical ventilation (MV) is a crucial intervention in managing severe respiratory failure due to COVID-19. However, its use may be complicated by pulmonary barotrauma, a serious event associated with increased morbidity and mortality. Understanding its incidence and associated risk factors is essential for optimising ventilatory strategies and improving patient outcomes. The aim of this study was to determine the incidence and risk factors associated with the development of pulmonary barotrauma in mechanically ventilated patients with COVID-19. Methods: All mechanically ventilated patients aged 18 years and above who were admitted to the COVID-19 Intensive Care Unit (ICU) from January 2021 to June 2022 were included. Patients who developed pulmonary barotrauma prior to or within 24 h of ICU admission, had iatrogenic pneumothorax, were readmitted to the ICU, or were ventilated for causes other than COVID-19-related respiratory failure were excluded. Data on patient demographics, vaccination status, ventilator parameters, laboratory findings, and the use of steroid or immunomodulatory therapies were collected and analysed. Univariate and multivariate logistic regression analyses were performed to identify the potential risk factors and clinical outcomes associated with pulmonary barotrauma. Results: The medical records of 204 patients were included. The incidence of pulmonary barotrauma was 22.5%. Lower C-reactive protein (CRP) levels at ICU admission, lower FiO₂ requirements during the first week of MV, a higher positive end-expiratory pressure (PEEP) during the second week, and a prolonged mechanical ventilation duration were significantly associated with pulmonary barotrauma (p = 0.039, 0.049, 0.021, and 0.036, respectively). Patients who developed pulmonary barotrauma experienced longer ICU stays (p = 0.006) and higher all-cause ICU mortality (p = 0.009). Conclusions: Lower CRP levels and a lower FiO₂ requirements, a higher PEEP use, and longer ventilator days were the independent risk factors for pulmonary barotrauma in our study population, leading to a longer ICU stay and higher all-cause ICU mortality. Full article

Background: Thoracentesis is pivotal in managing pleural effusion (PE), particularly in invasive mechanical ventilation (IMV), with documented improvements in respiratory mechanics, oxygenation, and hemodynamic parameters. However, its efficacy may vary based on effusion type and drained volume. Methods: A retrospective longitudinal study was conducted at a high-complexity care center in Cali, Colombia (2019–2024), including 93 (IMV) patients who underwent therapeutic thoracentesis (TT). Respiratory and hemodynamic parameters were assessed before and up to 24 h post-procedure. Stratified analysis was performed by drained volume, fluid type, and left ventricular ejection fraction (LVEF). Results: TT yielded significant improvements in fraction of inspired oxygen (FiO₂) (−4%), positive end expiratory pressure (PEEP) (−0.5 cmH₂O), and Oxygen arterial Pressure Index/Inspired Oxygen Fraction (PaO₂/FiO₂-ratio) (+27.1), with greater impact for volumes ≥500 mL and transudative PE. Patients with LVEF ≤ 40% showed increased mean arterial pressure (MAP) and PaO₂. Complication rates were low (<4%). Conclusions: TT is safe and effective in critically ill IMV patients, particularly for transudative PE and drained volumes ≥500 mL, as well as in subjects with LVEF ≤ 40%. Its positive impact on oxygenation and ventilation supports its therapeutic utility in critical care. Full article

Background: Cardiovascular diseases are the main cause of mortality and morbidity in Portugal, with coronary artery bypass grafting (CABG) being one of the most performed surgeries in cardiothoracic centers. After cardiac surgery, patients often experience a decrease in physical capacity, which results in an increased risk of mortality or hospitalization expenditures. The objective of this systematic review was to characterize changes in respiratory function in patients undergoing CABG. Methods: This systematic review followed the Preferred Reporting Items for Systematic Reviews and Meta-Analysis. Web of Science, Pubmed, SCOPUS, and Sport Discus were searched using a predefined research strategy to identify relevant original studies published until August 2025. To be included, studies must have assessed adult patients submitted to CABG who evaluated the respiratory function before and after cardiac surgery. Studies that reported other types of cardiac surgery were excluded. The Risk of Bias in Non-randomized Studies-of-Exposure and the Cochrane risk-of-bias tool for randomized trials were used to analyze the risk of bias of the selected studies. Results: After screening 1184 potential articles, six studies met the inclusion criteria. The studies included participants who underwent CABG (n = 324), with a mean age ranging from 54.05 ± 13.6 to 67 ± 10 years. Conclusions: All included studies reported significant postoperative reductions in respiratory function following CABG, including forced vital capacity, forced expiratory volume in one second, maximal inspiratory pressure, and maximal expiratory pressure. Although these findings consistently indicate a decline in pulmonary function, the limited number of available studies limits the strength of the conclusions. This systematic review suggests that monitoring respiratory impairments after CABG may be clinically relevant to improve health-related quality of life. Full article

Background: Joubert syndrome (JS) is a rare ciliopathy characterized by cerebellar and brainstem malformations and the molar tooth sign on magnetic resonance imaging. Motor impairment is primarily driven by axial hypotonia, impaired postural control, and disrupted respiratory-postural integration. Longitudinal reports describing structured neurorehabilitation with standardized functional outcomes remain limited. Case presentation: We report a female child with prenatally suspected vermian hypoplasia and postnatally MRI-confirmed Joubert syndrome. Subsequent molecular testing performed at the age of 3 years and 11 months identified heterozygous variants in the B9D2 gene associated with Joubert syndrome. Early development was marked by axial hypotonia, global motor delay, impaired trunk stabilization, sleep-disordered breathing, and early hip migration. At 2.5 years of age, following motor plateau under conventional therapy, a structured 12-month rehabilitation programme was introduced, combining Vojta-based reflex locomotion, respiratory therapy targeting thoraco-diaphragmatic synchronization, daily home-based practice, and supported standing. Results: After 12 months, gross motor function improved substantially, with GMFM-88 increasing from 12% to 52% (+40 percentage points). PEDI scaled scores improved across all domains, with mobility increasing from 8 to 40, self-care from 15 to 45, and social function from 25 to 50. Ataxia severity decreased from 22 to 15 on the modified Brief Ataxia Rating Scale, consistent with improved trunk stability and coordination. Postural and respiratory organization improved, reflected by a reduction in the subcostal angle from 137° to 90°, an increase in sacral slope from 5° to 10°, and increased expiratory pressure from 10 to 25 mmHg. Caregiver-reported assessment combined with structured clinical observation indicated improved functional visual performance, including enhanced visual attention, visuomotor coordination, and environmental visual interaction. Conclusions: Structured neurorehabilitation was associated with substantial functional improvement across motor, postural, and respiratory domains. These findings support the clinical relevance of mechanism-oriented neurorehabilitation and standardized longitudinal outcome assessment in Joubert syndrome. Full article

Background/Objective: Post-COVID survivors present significant respiratory deficiency that has been associated with ongoing shortness of breath and impaired lung function. Inspiratory muscle training (IMT) is increasingly used in survivors of COVID-19 rehabilitational programs as a means to facilitate recovery of the respiratory system. Yet, its home-based effectiveness across clinically relevant outcomes remains unclear. This systematic review aimed to present current evidence on home- or tele-delivered IMT in the post-COVID-19 population. Methods: PubMed, Scopus, Cochrane library and Science Direct were systematically searched for studies evaluating home-based (or telerehabilitation) IMT, alone or as part of a respiratory muscle training program, in adults with post-COVID-19 symptoms. The primary outcome was inspiratory muscle strength. Secondary outcomes included dyspnea, pulmonary function, exercise capacity and health-related quality of life. The methodological quality of the included studies was assessed via the PEDro scale. Owing to clinical and methodological heterogeneity, we performed only a qualitative synthesis. Results: Eight studies met the inclusion criteria. Two included both inspiratory and expiratory muscles training and three included physical training as well. The methodological quality was found to be good. IMT consistently increased inspiratory muscle strength across trials. Respiratory muscle training (RMT) programs that combined inspiratory and expiratory training also improved maximal expiratory pressure. IMT reduced dyspnea versus control/sham or baseline and several studies reported improvements in exercise capacity and physical function. Spirometry/DLCO changes were small or null in most cohorts. HRQoL gains were domain-specific in anxiety and depression. Adherence was generally good. No serious adverse events attributable to IMT were reported. Conclusions: Home-based IMT for adults with post-COVID-19 conditions is safe and seems to improve inspiratory muscle strength and dyspnea, with signs of benefit for exercise capacity, physical function, and selected HRQoL domains. Effects on ventilatory efficiency and conventional lung function appear limited. Future multicenter, sham-controlled RCTs should further explore the characteristics of IMT, employ core outcome sets, include longer follow-up, and predefine phenotype-based subgroups. Full article

Background: The aim of this prospective longitudinal observational study was to assess respiratory muscle function after surgical correction of scoliosis in individuals with spinal muscular atrophy (SMA). Material: The study included 20 patients (aged 7–19) with scoliosis in the course of neuromuscular disease, eligible for surgical treatment with diagnosed SMA Type 2 or 3. Methods: Measurements were taken of the maximal inspiratory pressure (MIP) [cmH₂O] and the maximal expiratory pressure (MEP) [cmH₂O] in all patients immediately before surgical correction of scoliosis (measurement I), 7 days after surgery (measurement II) and 3 months after surgery (measurement III). Results: The mean Cobb angle of spinal curvature measured before surgery in the entire group was 102.57 ± 17.96. The mean MEP values in the entire group of patients were 40.48 ± 11.76 cmH₂O before surgery, 36.74 ± 17.17 cmH₂O after 7 days, and 39.17 ± 16.18 cmH₂O 3 months after surgery. The MIP values for the entire group were 64.35 ± 28.40 cmH₂O before surgery, 53.96 ± 28.66 cmH₂O after 7 days, and 67.00 ± 31.27 cmH₂O after 3 months. Conclusions: Surgical correction of spinal curvature creates conditions for maintaining respiratory muscle strength in patients with SMA over a period of several months of observation. As a result of the surgical intervention, respiratory muscle strength did not deteriorate, but even slightly increased. Full article

Patients with chronic obstructive pulmonary disease (COPD) commonly experience impaired lung function, reduced exercise tolerance, and respiratory muscle weakness. Owing to the unique properties of the aquatic environment, water-based exercise may provide rehabilitation benefits that differ from those of traditional land-based exercise. Objective: This systematic review and meta-analysis aimed to compare the effects of water-based versus land-based exercise on lung function, exercise capacity, and respiratory muscle function in patients with COPD, thereby providing evidence to inform the optimization of pulmonary rehabilitation exercise modalities. Methods: PubMed, Web of Science, CNKI, and other databases were systematically searched to identify randomized controlled trials comparing water-based and land-based exercise interventions in adults with COPD. Primary outcomes included lung function (FEV₁% predicted and FEV₁/FVC), exercise capacity (six-minute walk distance, 6MWD), respiratory muscle strength (maximal inspiratory pressure (MIP]) and maximal expiratory pressure (MEP). Meta-analyses were performed using Stata 17.0. Results: A total of 14 RCTs were included. Meta-analysis showed that, compared with land-based exercise, water-based exercise significantly improved FEV₁% predicted (WMD = 3.33, 95% CI: 0.02–6.64) and FEV₁/FVC (WMD = 4.00, 95% CI: 1.27–6.73). Regarding exercise capacity, water-based exercise significantly increased 6MWD (WMD = 47.81 m, 95% CI: 20.19–75.44), with more pronounced improvements observed in short-term interventions (≤8 weeks). Respiratory muscle function analyses demonstrated significant improvements in MIP (WMD = 14.22 cmH₂O, 95% CI: 7.75–20.69) and MEP (WMD = 14.40 cmH₂O, 95% CI: 4.92–23.89). Conclusions: Compared with land-based exercise, water-based exercise demonstrates consistent advantages in improving exercise capacity and respiratory muscle function in patients with COPD and shows additional benefits for lung function indices. Therefore, water-based exercise may serve as a valuable adjunct to land-based training within pulmonary rehabilitation programs. Full article

Background: Impaired postural balance is a common feature in individuals with chronic obstructive pulmonary disease (COPD), increasing their risk of falls. This study aimed to evaluate the test–retest reliability of force platform parameters used to assess postural balance in individuals with COPD. Methods: A test–retest reliability study was conducted with participants diagnosed with moderate to severe COPD. Each participant completed two standardized balance assessments on a force platform, separated by a seven-day interval. Center of pressure (COP) parameters—including sway area, mean velocity, and path length—were analyzed under eyes-open and eyes-closed conditions. Reliability was determined using intraclass correlation coefficients (ICC), standard error of measurement (SEM), and coefficient of variation (CV). Correlations were performed between force platform parameters, the Timed Up and Go (TUG) test, and the Downton Fall Risk Scale. Results: Twenty individuals with COPD (mean age: 67.8 ± 6.1 years; forced expiratory value in the first second: 54 ± 12% predicted) were evaluated. The COP parameters demonstrated good to excellent test–retest reliability (ICC = 0.82–0.95) across all conditions, with low measurement error (SEM < 10%). Moderate correlations were found between force platform parameters and both TUG performance (r = 0.52–0.67) and Downton scores (r = 0.48–0.61). Conclusions: Force platform measurements show high reliability for assessing postural balance in individuals with COPD. These findings support the use of objective balance assessment tools in pulmonary rehabilitation and for monitoring fall risk in this population. Full article

Background: Amateur runners may benefit from combining respiratory muscle training (RMT) with resistance or aerobic modalities, but direct comparisons are scarce. This study compared different RMT-based combinations on pulmonary function, respiratory muscle strength, and whole-body exercise capacity. Methods: In this randomized four-arm trial, 48 amateur runners were allocated equally to stand-alone RMT, RMT plus upper-limb resistance (RMT + ULRT), RMT plus lower-limb resistance (RMT + LLRT), or RMT plus aerobic exercise (RMT + AET). All groups completed supervised sessions three times per week for six weeks. Pulmonary function (forced vital capacity [FVC], forced expiratory volume in one second [FEV₁], FEV₁/FVC), respiratory muscle strength (maximal inspiratory and expiratory pressures, MIP and MEP), and cardiopulmonary exercise test indices (peak oxygen uptake [VO₂peak], VE/VCO₂ slope) were assessed before and after training using standardized spirometry, mouth-pressure measurements, and treadmill cardiopulmonary exercise testing (CPET). Pre–post changes within groups and the overall between-group differences were evaluated using standard parametric methods. Results: All four interventions were associated with improvements in at least one respiratory or cardiopulmonary domain. FVC and FEV₁ tended to improve more in the resistance-combination groups, whereas the FEV₁/FVC ratio increased with RMT alone and when combined with resistance. MIP increased in the RMT, RMT + ULRT, and RMT + LLRT groups, and MEP increased across all groups. VO₂peak rose in every group, while the VE/VCO₂ slope improved only when RMT was combined with upper- or lower-limb resistance or aerobic exercise. Between-group differences in change scores were not statistically significant and did not clearly favor any single regimen. Conclusions: In amateur runners, six weeks of RMT-based programs are feasible and associated with domain-specific improvements in lung function, respiratory muscle strength, and exercise capacity. Because between-group differences in change scores were not statistically significant and the sample size was modest, these findings should be considered exploratory and may inform hypothesis generation regarding the use of different RMT combinations in future, larger trials. Full article

Acute respiratory distress syndrome (ARDS) causes heterogeneous injury, with normal, unstable, and edematous tissue distributed throughout the lung. Although positive pressure ventilation initially reduced ARDS-related mortality, it became clear that the ventilator can be a double-edged sword and, if set improperly, can worsen outcomes. This uneven pathology makes the lung vulnerable to secondary ventilator-induced lung injury (VILI). In 2000, evidence showed that lowering tidal volume (V_T) and airway pressure significantly reduced mortality in patients with ARDS, suggesting that this reduction led to less overdistension of healthy lung tissue. Including respiratory system compliance (C_RS) in the calculation. It was shown that low driving pressure (ΔP = V_T/C_RS) was more strongly associated with survival than low V_T alone. This idea was further extended into measuring the mechanical power delivered to the respiratory system: MP_rs = RR × ΔV²∙[1/2∙EL_rs + RR∙(1 + I:E)/60∙I:E∙R_aw] + ΔV∙PEEP, where EL_rs is elastance, I:E is inspiratory:expiratory ratio, R_aw is airway resistance, and RR is respiratory rate. This measure helps identify when the lung is at risk of VILI. However, a recent study found no direct causal link between MP_RS and mortality; rather, it showed that MP_RS, normalized to C_RS or end-expiratory lung volume (EELV), was independently associated with outcomes. This indicates that lung size and underlying pathophysiology—rather than ΔP or MP_RS alone—are critical determinants of VILI risk. Reopening collapsed lung tissue would increase C_RS and decrease E_RS, thereby lowering ΔP or MP_RS at any given V_T, R_aw, PEEP, I:E, or RR setting. Consequently, the focus should shift from simply adjusting the ventilator to normalize C_RS and EELV that reduce ΔP or MP_RS at higher ventilator settings. Full article

Background: Early reports highlighted unique features of COVID-19-associated ARDS. The combination of prone position (PP) and positive end-expiratory pressure (PEEP)-induced lung recruitment maneuver (LRM) has demonstrated efficacy in enhancing oxygenation and improving outcomes in patients with ARDS, but it remains unknown whether there is a difference between COVID-19 ARDS and non-COVID-19 ARDS. Method: This study is a secondary analysis of a previously conducted randomized controlled trial. Patients with moderate to severe ARDS were consecutively enrolled during the study period (June–December 2023). After initiation of PP, patients received a PEEP-induced LRM followed by 12 h of daily PP. The interventions were repeated at least three times over the subsequent 3 days. Clinical outcomes, respiratory mechanics, and electrical impedance tomography (EIT) results were evaluated. Results: Twenty-eight patients were included in the final analysis, half of whom were infected with COVID-19 (50%). The PEEP-induced LRM led to greater improvement in oxygenation among COVID-19 ARDS than non-COVID-19 ARDS (∆PaO₂/FiO₂ ratio 90.5 mmHg vs. 65.5 mmHg, p < 0.05). Based on EIT measurement, compared with the non-COVID-19 ARDS group, PEEP-induced LRM resulted in a greater increase in ventilation distribution, mainly in the dorsal regions of interest 4 (ROI 4) ventilation distribution (∆ROI4 4.5% vs. 1.0%, p = 0.01) and in dorsal regional ventilation (∆dorsal regional ventilation 10.0% vs. 5.5%, p = 0.04) in the COVID-19 ARDS group. Conclusions: Compared to typical ARDS, PEEP-induced LRM combined with PP may be more effective in enhancing oxygenation in COVID-19-related ARDS. Full article

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease that affects motor neurons; respiratory problems are the leading cause of death and hospital admissions and are secondary to progressive weakness of the respiratory muscles and upper airway. Noninvasive ventilation (NIV) can increase survival, alleviate symptoms, reduce hospital admissions, and improve the quality of life of these patients. The key factor in respiratory management of patients with ALS is achieving effective NIV; ineffective NIV has a negative impact on survival, with a reduction of up to 50% compared to patients with an effective technique. The most common cause of ineffective NIV is air leaks; other causes include upper airway obstruction events, residual hypoventilation, hyperventilation, and upper airway obstruction secondary to an oronasal mask. Regular monitoring of the effectiveness of NIV is essential given its impact on survival; the key tools that detect the main problems are the presence of hypoventilation symptoms, arterial blood gases, nocturnal oximetry and capnography, and built-in ventilator software. Different measures have been proposed to address the ineffectiveness of NIV, such as fitting the mask to reduce air leaks, increasing ventilatory support for residual hypoventilation, decreasing ventilatory support for hyperventilation, or a trial with a nasal mask to address oronasal interface effects. In the case of obstruction, the most common measure is to increase positive expiratory pressure during NIV. These measures enable NIV to be effective in 58% of cases, achieving a survival rate similar to that of patients who have effective NIV from the outset. Full article