Ventilation In Children Research Articles

Point-of-Care Lung Ultrasound to Evaluate Lung Isolation During One-Lung Ventilation in Children: A Blinded Observational Feasibility Study.

Minimally invasive thoracic surgical techniques require effective lung isolation using one-lung ventilation (OLV). Verification of lung isolation may be confirmed by auscultation, visual confirmation using fiberoptic bronchoscopy (FOB), or more recently, point-of-care ultrasound (POCUS). The aim of this study was to prospectively compare lung ultrasound with clinical auscultation to confirm OLV before thoracic surgery in pediatric patients. This prospectively blinded feasibility study included 40 patients ranging in age from 0 to 20 years. After confirmation of lung separation by the primary anesthesia team using FOB, the sonographer and the auscultator, both blinded to the laterality of surgery and lung separation, entered the operating room. The sonographer evaluated for pleural lung sliding and the auscultator listened for breath sounds. Successful lung separation was definitively confirmed by direct visualization of lung collapse during the operation. In confirming effective single-lung ventilation, lung ultrasound had a diagnostic accuracy of 95% (95% confidence interval [CI], 82.7%-98.5%). In contrast, auscultation could only reliably confirm lung isolation with 68% accuracy (95% CI, 51.5%-80.4%). The McNemar test showed a statistically significant difference between the use of lung ultrasound and auscultation (P < .001). The median time to perform ultrasonography was 67 seconds (interquartile range [IQR], 46-142) and the median time to perform auscultation was 21 seconds (IQR, 10-32). Based on the initial results of our feasibility trial, lung ultrasound proved to be a fast and reliable method to verify single-lung ventilation in pediatric patients presenting for thoracic surgery with a high degree of diagnostic accuracy.

Lung Ultrasound Score, Severity of Acute Lung Disease and Prolonged Mechanical Ventilation in Children.

Lung ultrasound may be useful for prognostication of acute lung disease. To assess whether the lung ultrasound score is associated with the severity of lung disease and may predict prolonged invasive mechanical ventilation in critically ill children. Prospective observational multicenter study in children aged 1 month to 18 years who required respiratory support in the intensive care unit. Children with chronic parenchymal lung disease were excluded. The lung ultrasound score was obtained at 12 hours and 48-72 hours from admission. Prolonged invasive mechanical ventilation was defined as >7 consecutive days. Correlation of the lung ultrasound score with oxygenation as well as its prognostic accuracy for prolonged invasive mechanical ventilation were investigated. 538 children were included and 62 (11.5%) required prolonged mechanical ventilation. In these subjects, the lung ultrasound score was higher at 12 [24 (19-26) vs. 8 (3-14); p<0.001] and 48-72 hours [16 (10.5-22.5) vs. 6 (3-11) vs; p<0.001]. At 12 hours the lung ultrasound score correlated with oxygenation index [R2= 0.435 (95% CI: 0.293-0.566), rho coefficient -0.705, p<0.001] and oxygen saturation index [R2 0.499 (95% CI: 0.370-0.613), rho coefficient 0.651, p<0.001p<0.001]. To predict prolonged invasive mechanical ventilation, the lung ultrasound score at 12 hours had a good accuracy [AUROC=0.87 (95% CI: 0.81-0.93)] while its use in a multivariable model had an excellent accuracy both in derivation [AUROC=0.92 (95% CI: 0.89-0.95)] and internal validation [AUROC=0.91 (95% CI: 0.90-0.92)]. In critically ill children, the lung ultrasound score early after admission may predict prolonged invasive mechanical ventilation.

Phenotypes based on respiratory drive and effort to identify the risk factors when P0.1 fails to estimate ∆PES in ventilated children.

Monitoring respiratory effort and drive during mechanical ventilation is needed to deliver lung and diaphragm protection. Esophageal pressure (∆PES) is the gold standard measure of respiratory effort but is not routinely available. Airway occlusion pressure in the first 100ms of the breath (P0.1) is a readily available surrogate for both respiratory effort and drive but is only modestly correlated with ∆PES in children. We sought to identify risk factors for P0.1 over or underestimating ∆PES in ventilated children. Secondary analysis of physiological data from children and young adults enrolled in a randomized controlled trial testing lung and diaphragm protective ventilation in pediatric acute respiratory distress syndrome (PARDS) (NCT03266016). ∆PES (∆PES-REAL), P0.1 and predicted ∆PES (∆PES-PRED = 5.91*P0.1) were measured daily to identify phenotypes based upon the level of respiratory effort and drive: one passive (no spontaneous breathing), three where ∆PES-REAL and ∆PES-PRED were aligned (low, normal, and high effort and drive), two where ∆PES-REAL and ∆PES-PRED were mismatched (high underestimated effort, and overestimated effort). Logistic regression models were used to identify factors associated with each mismatch phenotype (High underestimated effort, or overestimated effort) as compared to all other spontaneous breathing phenotypes. We analyzed 953 patient days (222 patients). ∆PES-REAL and ∆PES-PRED were aligned in 536 (77%) of the active patient days. High underestimated effort (n = 119 (12%)) was associated with higher airway resistance (adjusted OR 5.62 (95%CI 2.58, 12.26) per log unit increase, p < 0.001), higher tidal volume (adjusted OR 1.53 (95%CI 1.04, 2.24) per cubic unit increase, p = 0.03), higher opioid use (adjusted OR 2.4 (95%CI 1.12, 5.13, p = 0.024), and lower set ventilator rate (adjusted OR 0.96 (95%CI 0.93, 0.99), p = 0.005). Overestimated effort was rare (n = 37 (4%)) and associated with higher alveolar dead space (adjusted OR 1.05 (95%CI 1.01, 1.09), p = 0.007) and lower respiratory resistance (adjusted OR 0.32 (95%CI 0.13, 0.81), p = 0.017). In patients with PARDS, P0.1 commonly underestimated high respiratory effort particularly with high airway resistance, high tidal volume, and high doses of opioids. Future studies are needed to investigate the impact of measures of respiratory effort, drive, and the presence of a mismatch phenotype on clinical outcome. NCT03266016; August 23, 2017.

Same-Day Repeatability and 28-Day Reproducibility of Xenon MRI Ventilation in Children With Cystic Fibrosis in a Multi-Site Trial.

MRI with xenon-129 gas (Xe MRI) can assess airflow obstruction and heterogeneity in lung diseases. Specifically, Xe MRI may represent a sensitive modality for future therapeutic trials of cystic fibrosis (CF) therapies. The reproducibility of Xe MRI has not yet been assessed in the context of a multi-site study. To determine the same-day repeatability and 28-day reproducibility of Xe MRI in children with CF. Four-center prospective, longitudinal. Thirty-eight children (18 females, 47%), median interquartile range (IQR) age 12 (9-14) years old, with mild CF (forced expiratory volume in 1 second (FEV1) ≥85% predicted). 3-T, two-dimensional (2D) gradient-echo (GRE) sequence. Xe MRI, FEV1, and nitrogen multiple-breath wash-out for lung-clearance index (LCI2.5) were performed. To assess same-day reproducibility, Xe MRI was performed twice within the first visit, and procedures were repeated at 28 days. Xe hypoventilation was quantified using ventilation-defect percentage (VDP) and reader-defect volume (RDV). For VDP, hypoventilated voxels from segmented images were identified using a threshold of <60% mean whole-lung signal and expressed as a percentage of the lung volume. For RDV, hypoventilation was identified by two trained readers and expressed as a percentage. Inter-site comparisons were conducted using Kruskal-Wallis nonparametric tests with Dunn's multiple-comparisons tests. Differences for individuals were assessed using Wilcoxon matched-pairs tests. Bland-Altman tests were used to evaluate same-day repeatability, 28-day reproducibility, and inter-reader agreement. A P-value ≤0.05 was considered significant. Median FEV1 %-predicted was 96.8% (86%-106%), and median LCI2.5 was 6.6 (6.3-7.4). Xe MRI had high same-day reproducibility (mean VDP difference 0.12%, 95% limits of agreement [-3.2, 3.4]; mean RDV difference 0.42% [-2.5, 3.3]). At 28 days, 26/31 participants (84%) fell within the same-day 95% limits of agreement. Xe MRI may offer excellent same-day and short-term reproducibility. 2 TECHNICAL EFFICACY: Stage 2.

Assessment of the Impact of Technical Incidents in Critical Situations Using High-Fidelity Simulation Techniques in Pediatric Intensive Care.

Introduction In certain fields such as anesthesia and critical care, technical incidents are rare events; however, when they occur, they disrupt workflow, optimal patient care, and survival, with human factors often implicated. In pediatric resuscitation, the impact of these incidents on patient care has not yet been thoroughly explored through simulation. Consequently, we investigated how healthcare teams integrate technical incidents in critical situations and whether this interferes with the adequate management of patients. Materials & methods In a single-blind randomized study utilizing high-fidelity simulation, we incorporated a pediatric scenario involving hypoxemia in an intubated and ventilated infant where the endotracheal tube (ETT) was obstructed. A technical incident (disconnected oxygen supply) was either present (TI+) or absent (TI-) in the scenario. We compared reaction times for "removal of the obstructed ETT" between the two groups (TI+ and TI-). Additionally, we recorded and analyzed reaction times for "bagventilation" and "repair of the technical incident" in the TI+ group. To assess the scenario's credibility, we conducted an analysis comparing the medians of evaluation forms that were anonymously completed by participants at the end of the sessions. Results In total, 10 simulation sessions were conducted, five TI+ and five TI-. The time required for removal of the obstructed ETT in the presence of a technical incident was significantly prolonged compared to controls (Mann-Whitney test, p=0.03). Furthermore, bagventilation precedes tube removal in the TI+ group, a contrast to the TI- group, which quickly removes the obstructed ETT before stabilizing the patient with bag-mask ventilation. Conclusion Technical incidents in simulated pediatric scenario adversely affect urgent care in ventilated children. Developing and validating a procedural response to these situations through further simulation is imperative.

Home Mechanical Ventilation in Children: Complications and Benefits—A Two-Year Experience at a Referral Children's Hospital

Background: The rising prevalence of chronic respiratory failure in pediatric patients necessitates a detailed evaluation of home mechanical ventilation (HMV). Objectives: This study assesses the advantages of HMV devices, focusing on cases from Imam Hussein Children's Hospital. Methods: This research involved 20 children who required long-term ventilation and were admitted to both general and intensive care units at Imam Hussein Children's Hospital in Isfahan. Before discharge, a team of HMV experts trained the parents on the proper use of the ventilation devices. Post-discharge, the educational needs of the parents were assessed continuously, with regular home visits conducted by a nurse and a representative from the ventilator supplier. Results: Approximately 73% of the children demonstrated therapeutic effectiveness following HMV implementation. About 35% of parents observed no adverse effects in their children. The average cost savings from reduced ICU rehospitalizations was significant at 347.59%, and there was a 65.09% reduction in the costs associated with general ward hospitalizations. Conclusions: The adoption of HMV has led to improved health outcomes, substantial reductions in medical expenses, and shorter hospital stays. It is advisable to plan for broader implementation of HMV in children who require long-term ventilation.

Two months outcomes following delirium in the pediatric intensive care unit.

The lasting consequences of delirium in children are not well characterized. This study aimed to compare the two-month outcomes in pediatric intensive care unit (PICU) survivors according to the presence of delirium. Post-hoc analysis of a single-center prospective study of mechanically ventilated (invasive ventilation or non-invasive ventilation) children followed at the CHU Sainte-Justine PICU follow-up clinic two months after PICU discharge, between October 2018 and August 2022. Delirium was defined as one or more Cornell Assessment of Pediatric Delirium (CAPD) scores ≥ 9. Primary outcome was survivors' quality of life and secondary outcomes were sleep and posttraumatic stress and anxiety and depression in parents. Multivariable linear and logistic regression models assessed the independent associations between delirium and outcomes while adjusting for age, sex, comorbidity, diagnosis, severity of illness, PICU length of stay, and invasive mechanical ventilation. Of the 179 children included over a 47 month-period, 117 (65.4%) had delirium. Children with delirium were more commonly intubated (91.5% vs. 30.7%, p < 0.001) and had higher PELOD-2 scores (10 vs. 4, p < 0.001). On multivariable analysis, delirium was associated with a decreased quality of life at 2.3 months post discharge (p = 0.03). The severity of the delirium episode (higher scores of CAPD) was associated with a higher likelihood of sleep disturbances (OR 1.13, p = 0.01) and parental anxiety (OR 1.16, p = 0.01), in addition to lower quality of life (p = 0.03).Conclusions: Two months following their PICU stay, children with delirium had a lower quality of life, suggesting a lasting effect of delirium on children and their families.

Outcomes associated with ventilator-associated events (VAE), respiratory infections (VARI), pneumonia (VAP) and tracheobronchitis (VAT) in ventilated pediatric ICU patients: A multicentre prospective cohort study

ObjectivesAn objective categorization of respiratory infections based on outcomes is an unmet clinical need. Ventilator-associated pneumonia and tracheobronchitis remain used in clinical practice, whereas ventilator-associated events (VAE) are limited to surveillance purposes. Research methodology/designThis was a secondary analysis from a multicentre observational prospective cohort study. VAE were defined as a sustained increase in minimum Oxygen inspired fraction (FiO2) and/or Positive end-expiratory pressures (PEEP) of ≥ 0.2/2 cm H2O respectively, or an increase of 0.15 FiO2 + 1 cm H20 positive end-expiratory pressures for ≥ 1 calendar-day. Setting15 Paediatric Intensive Care Units. Main outcome measuresMechanical ventilation duration, intensive care and hospital length of stay; (LOS) and mortality. ResultsA cohort of 391 ventilated children with an age (median, [Interquartile Ranges]) of 1 year[0.2–5.3] and 7 days[5–10] of mechanical ventilation were included. Intensive care and hospital stays were 11 [7–19] and 21 [14–39] days, respectively. Mortality was 5.9 %. Fifty-eight ventilator-associated respiratory infections were documented among 57 patients: Seventeen (29.3 %) qualified as ventilator-associated pneumonia (VAP) and 41 (70.7 %) as ventilator-associated tracheobronchitis (VAT). Eight pneumonias and 16 tracheobronchitis (47 % vs 39 %,P = 0.571) required positive end-expiratory pressure or oxygen increases consistent with ventilator-associated criteria. Pneumonias did not significantly impact on outcomes when compared to tracheobronchitis. In contrast, infections (pneumonia or tracheobronchitis) following VAEs criteria were associated with > 6, 8 and 15 extra-days of ventilation (16 vs 9.5, P = 0.001), intensive care stay (23.5 vs 15; P = 0.004) and hospital stay (39 vs 24; P = 0.015), respectively. ConclusionWhen assessing ventilated children with respiratory infections, VAE apparently is associated with higher ventilator-dependency and LOS compared with pneumonia or tracheobronchitis. Implications for practiceIncorporating the modification of ventilatory settings for further categorization of the respiratory infections may facilitate therapeutic management among ventilated patients.

Characteristics Leading to Mechanical Ventilation in Children Admitted for First Episode of Anaphylaxis due to Peanuts

Characteristics Leading to Mechanical Ventilation in Children Admitted for First Episode of Anaphylaxis due to Peanuts

Emergency Care Plans for the Management of Emergencies in Children on Home Mechanical Ventilation

In pediatrics chronic respiratory insufficiency is increasingly treated on an outpatient basis with home mechanical ventilation. Nursing and medical teams with different structures take care of the often complex ill children in the outpatient setting. Structured treatment processes, especially emergency plans for the management of respiratory emergencies of home mechanical ventilated children are lacking. This article is a proposal for emergency management of respiratory infections, emergencies of non-invasively ventilated and invasively ventilated, tracheotomized children. In addition to resuscitation measures according to ERC/AHA, the focus is primarily on secretion management, as well as on the handling of ventilators and devices.

Estimation of inspiratory effort using airway occlusion maneuvers in ventilated children: a secondary analysis of an ongoing randomized trial testing a lung and diaphragm protective ventilation strategy

BackgroundMonitoring respiratory effort in ventilated patients is important to balance lung and diaphragm protection. Esophageal manometry remains the gold standard for monitoring respiratory effort but is invasive and requires expertise for its measurement and interpretation. Airway pressures during occlusion maneuvers may provide an alternative, although pediatric data are limited. We sought to determine the correlation between change in esophageal pressure during tidal breathing (∆Pes) and airway pressure measured during three airway occlusion maneuvers: (1) expiratory occlusion pressure (Pocc), (2) airway occlusion pressure (P0.1), and (3) respiratory muscle pressure index (PMI) in children. We also sought to explore pediatric threshold values for these pressures to detect excessive or insufficient respiratory effort.MethodsSecondary analysis of physiologic data from children between 1 month and 18 years of age with acute respiratory distress syndrome enrolled in an ongoing randomized clinical trial testing a lung and diaphragm protective ventilation strategy (REDvent, R01HL124666). ∆Pes, Pocc, P0.1, and PMI were measured. Repeated measure correlations were used to investigate correlation coefficients between ∆Pes and the three measures, and linear regression equations were generated to identify potential therapeutic thresholds.ResultsThere were 653 inspiratory and 713 expiratory holds from 97 patients. Pocc had the strongest correlation with ∆Pes (r = 0.68), followed by PMI (r = 0.60) and P0.1 (r = 0.42). ∆Pes could be reliably estimated using the regression equation ∆Pes = 0.66 times Pocc (R2 = 0.82), with Pocc cut-points having high specificity and moderate sensitivity to detect respective ∆Pes thresholds for high and low respiratory effort. There were minimal differences in the relationship between Pocc and ∆Pes based on age (infant, child, adolescent) or mode of ventilation (SIMV versus Pressure Support), although these differences were more apparent with P0.1 and PMI.ConclusionsAirway occlusion maneuvers may be appropriate alternatives to esophageal pressure measurement to estimate the inspiratory effort in children, and Pocc represents the most promising target.Trial registration: NCT03266016; August 23, 2017.

Association of end-tidal and venous carbon dioxide in intubated and ventilated children

Introduction: The end-tidal CO2 pressure (PetCO2) monitoring which is a non-invasive method than PvCO2 (venous pressure of carbon dioxide), could determinate a graph depicting the carbon dioxide concentration in blood. The aim of this study was to investigate the correlation between PetCO2-PvCO2 in ventilated children. Methods: All children intubated in the PICU of Children hospital Tabriz, Iran from 2019 to 2020 using the census method were assessed in terms of initial diagnosis, age, sex, PetCO2, and PvCO2 during a prospective cross-sectional study. Associations between variables were calculated for total patients and patients in the subgroups. Descriptive statistics were used to describe the quantitative analysis of data and the Pearson correlation coefficient and Linear Regression Test were used for the evaluation of the relationship between variables and for assessing the predictive values of PvCO2 using SPSS.26. A P value&lt;0.05 was considered statistically significant. Results: Out of 61 samples, 42 (68.9%) patients were males with a median age of 48 months. The mean of PetCO2 and PvCO2 were 20.3±8.5 and 43±12.3 mm Hg, respectively. The correlation of PetCO2-PvCO2 was significant in total patients (P value=0.003, r=0.379) and group 1 (P value=0.009, r=0.374). Furthermore, the results presented the predictive values of PvCO2 for PetCO2 while for one unit increase in the PvCO2 variable, PetCO2 could increase 0.372 units (P value=0.005, Slope b=0.24, Beta coefficient=0.372). Conclusion: In most intubated children, PetCO2 may estimate the ventilation and change concentrations of CO2. It is necessary that the sample size of future studies will become large due to the weak correlation.

Aerosolized lidocaine to reduce tracheal suction-associated pain after pediatric congenital heart surgery: A randomized, double-blind, placebo-controlled trial

BackgroundIn children undergoing heart surgery for congenital heart disease (CHD), postoperative pain is associated with changes in the respiratory system that can lead to complicated courses and poor outcomes. Respiratory therapy (RT) can restore respiratory function through manual techniques and tracheal suction (TS). However, TS itself can cause pain, leading to hemodynamic and respiratory manifestations, such as tachycardia, hyper- or hypotension, tachypnea, increased work-of-breathing, patient-ventilator asynchrony, among others. ObjectivesThe aim of this study was to investigate whether RT/TS increases pain and whether inhaled lidocaine can attenuate pain increase in infants and children undergoing surgery for CHD. MethodsDouble-blind, randomized, placebo-controlled trial at a pediatric intensive care unit in a Brazilian tertiary-care university hospital. Patients <18 years submitted to open-heart surgery for CHD were included and randomized to receive either aerosolized lidocaine (1 mg/kg) or placebo before RT/TS. Pain was assessed by the Face, Legs, Activity, Cry, Consolability pain scale – revised (FLACC-R), along with hemodynamic and ventilatory parameters, before and 10 min after RT/TS start on postoperative days 1, 3, and 7 given they were on mechanical ventilation. Results119 patients were included. RT/TS induced minor changes in pain, which were not attenuated by lidocaine (confirmed in multivariate analysis). RT/TS also caused minor, clinically not relevant effects in hemodynamic and ventilatory parameters, which were also not modified by lidocaine. ConclusionRespiratory therapy with tracheal suction did not increase postoperative pain in ventilated children after congenital heart surgery until the 7th day, nor did aerosolized lidocaine exhibit any clinically significant effect on pain or other hemodynamic or ventilatory parameters.Registered at REBEC: RBR-10vtd55m.

Pilot study of an interprofessional pediatric mechanical ventilation educational initiative in two intensive care units

IntroductionInappropriate ventilator settings, non-adherence to a lung-protective ventilation strategy, and inadequate patient monitoring during mechanical ventilation can potentially expose critically ill children to additional risks. We set out to improve team theoretical knowledge and practical skills regarding pediatric mechanical ventilation and to increase compliance with treatment goals.MethodsAn educational initiative was conducted from August 2019 to July 2021 in a neonatal and pediatric intensive care unit of the University Children’s Hospital, Hamburg-Eppendorf, Germany. We tested baseline theoretical knowledge using a multiple choice theory test (TT) and practical skills using a practical skill test (PST), consisting of four sequential Objective Structured Clinical Examinations of physicians and nurses. We then implemented an educational bundle that included video self-training, checklists, pocket cards, and reevaluated team performance. Ventilators and monitor settings were randomly checked in all ventilated patients. We used a process control chart and a mixed-effects model to analyze the primary outcome.ResultsA total of 47 nurses and 20 physicians underwent assessment both before and after the implementation of the initiative using TT. Additionally, 34 nurses and 20 physicians were evaluated using the PST component of the initiative. The findings revealed a significant improvement in staff performance for both TT and PST (TT: 80% [confidence interval (CI): 77.2–82.9] vs. 86% [CI: 83.1–88.0]; PST: 73% [CI: 69.7–75.5] vs. 95% [CI: 93.8–97.1]). Additionally, there was a notable increase in self-confidence among participants, and compliance with mechanical ventilation treatment goals also saw a substantial rise, increasing from 87.8% to 94.5%.DiscussionImplementing a pediatric mechanical ventilation education bundle improved theoretical knowledge and practical skills among interprofessional pediatric intensive care staff and increased treatment goal compliance in ventilated children.

Study on clinical profile of ventilated children in a pediatric intensive care unit of tertiary care centre

Background: Mechanical ventilation constitutes a major therapeutic modality in intensive care, so care of patients requiring ventilatory support is an integral part of the critical care unit. Very less data is available from developing countries regarding use of Mechanical Ventilation, its complication and outcomes which is a challenge for modern day intensivists. Objectives were to study clinical profile of ventilated children in a PICU of tertiary care centre. Methods: Present prospective cross-sectional study was conducted on ventilated children admitted at PICU of Dr. VMGMC hospital, Solapur. The study included demographics, clinical profile, indication for ventilation, length of hospital stays, outcome. Results: Out of 300 children, 170 were males. Most the children were from age group &lt;5 years. Difficulty in breathing was seen in 188 cases, fever in 55%, 100 patients had acute CNS infections, 82 cases had bronchopneumonia, 85 cases respiratory failure was the indication for intubation. The duration of the mechanical ventilation was more in CNS cases, RS cases, sepsis cases. 165 cases got recovered successfully. Conclusions: Mechanical ventilation is one of the major supportive modalities used in critical care all over the world and is also used in many of the sick children in government tertiary care centre. Despite of its life saving advantages, mechanical ventilation is associated with complication. Early use of HHFNC, CPAP/BiPAP and other non-invasive modes of ventilation decrease the need for invasive mechanical ventilation.

Sedation in pediatric intensive care unit and its impact on outcomes of ventilated children: a prospective observational study

BackgroundSedation is an integral part in the management of critical patients in the pediatric intensive care unit (PICU). Optimum sedation is when the child is asleep but easily arousable. The patient should be able to breathe synergistically with the ventilator and should tolerate or be compliant with other therapeutic procedures. Undersedation can make the children hypertensive, tachycardic, and agitated. Conversely, oversedation can cause increased tolerance and prolonged ventilation. Both undersedation and oversedation have negative impacts on patient outcomes such as prolonged mechanical ventilation and ICU stay and increased risk of contracting ventilator-associated pneumonia, thus contributing to significant morbidity and mortality. This study aims to assess sedation levels in ventilated children using RASS in the first 48hrs of ventilation and study their correlation with patient outcomes.ResultsOf the 111 children enrolled in the study, 2 were excluded because the sedation was discontinued before 48 h, and 9 were excluded because they were ventilated for more than 7 days. Majority of the children receiving ventilation in PICU were oversedated (40%). Adequately sedated children were observed to have significantly lesser duration of mechanical ventilation (p-value: 0.022) and PICU stay (p-value: 0.01). Undersedated children were noted to have significantly higher incidence of self extubation (p-value: < 0.001), reintubation (p-value: < 0.001), and higher requirement of restraints (p-value: < 0.001). Oversedated had a higher incidence of VAP and mortality (p-value: < 0.001).ConclusionThe findings of this study highlight the importance of achieving adequate sedation in PICU which is associated with better outcomes with respect to duration of ventilation, PICU stay, hospital stay, and mortality. This study also reflects the impact of absence of sedation protocols and emphasizes the need for monitoring of sedation and having protocols to guide clinical practice in order to improve patient outcome.

Artificial Airway Suctioning: A Systematic Review.

Airway suctioning is routinely performed in the majority of care circumstances, including acute care, subacute care, home-based settings, and long-term care. Using an artificial airway to suction the patient allows for the mobilization and evacuation of secretions. When a patient can't independently remove all of the secretions from their respiratory tract, suction is used. This can occur when the body produces excessive secretion or it is not eliminated quickly enough, causing the respiratory system's upper and lower respiratory secretions to accumulate. Airway blockage and inadequate breathing may result from this. Ultimately, this leads to a shortage of oxygen and carbon dioxide from the air, both of which are necessary for ideal cellular activity. Artificial airway suctioning is one of the most crucial components of airway care and a core competency for medical professionals trying to ensure airway patency. Artificial airway suctioning is a standard treatment carried out every day globally and is frequently done in both outpatient and inpatient patients. Therefore, specialists must know the safest and most efficient ways to perform surgery and any potential side effects. In ventilated infants and children, the removal of obstructive secretions by endotracheal suctioning is frequently done. It is unknown how suctioning affects the mechanics of breathing. This study used a prospective observational clinical design to examine the immediate impact of airway resistance in endotracheal suctioning, tidal volume, and dynamic lung regulation in mechanically ventilated adult patients and mechanically ventilated pediatric patients. The preparation, process, and indications for intraoperative fusion treatment in various circumstances are covered in this systematic review.

Mechanical ventilation during pediatric extracorporeal life support.

To discuss the role of ventilator induced lung injury (VILI) and patient self-inflicted lung injury in ventilated children supported on extracorporeal membrane oxygenation (ECMO). While extracorporeal life support is used routinely used every day around the globe to support neonatal, pediatric, and adult patients with refractory cardiac and/or respiratory failure, the optimal approach to mechanical ventilation, especially for those with acute respiratory distress syndrome (ARDS), remains unknown and controversial. Given the lack of definitive data in this population, one must rely on available evidence in those with ARDS not supported with ECMO and extrapolate adult observations. Ventilatory management should include, as a minimum standard, limiting inspiratory and driving pressures, providing a sufficient level of positive end-expiratory pressure, and setting a low rate to reduce mechanical power. Allowing for spontaneous breathing and use of pulmonary specific ancillary treatment modalities must be individualized, while balancing the risk and benefits. Future studies delineating the best strategies for optimizing MV during pediatric extracorporeal life support are much needed. Future investigations will hopefully provide the needed evidence and better understanding of the overall goal of reducing mechanical ventilation intensity to decrease risk for VILI and promote lung recovery for those supported with ECMO.

Transition of long-term ventilated children to adult medical care

Through advances in long-term ventilation, the number of children with chronic respiratory insufficiency reaching adult age has increased tremendously. Therefore, transition of children from pediatric to adult care has become inevitable. Transition is necessary for medicolegal reasons, to increase autonomy of the young patients and because of change in the disease as a result of increasing age. Transition bears the risks of uncertainty of patients and parents, loss of the medical home or even loss of complete medical care. Good structural conditions, professional preparation of patient and parents, a comprehensive formalized transfer and patient coaching are prerequisites for a successful professional transition. This article discusses issues of transition with focus on long-term ventilated children.

Measuring Expiratory Diaphragm Activity: An Electrifying Tool to Guide Positive End-Expiratory Pressure Strategy in Critically Ill Children?

Measuring Expiratory Diaphragm Activity: An Electrifying Tool to Guide Positive End-Expiratory Pressure Strategy in Critically Ill Children?