Halo-gravity traction in the treatment of complex spinal deformities in children with respiratory dysfunctions

HGT is a safe technique as the world literature describes complications in the form of loosening of the pins or superficial infections of the skin around the pins, which are not significant and do not pose a threat to the patient’s life. Purpose – to improve the results of the ventilation function of the lungs in patients with complex spinal deformities through the preliminary use of halo gravity traction and to introduce an effective and safe method for the treatment of complex spinal deformities in children with respiratory dysfunctions. Materials and methods. 64 children with complex spinal deformities (>100°) were treated in the orthopedic and traumatology department of the Okhmatdet NSPU using halo gravity traction during the period from 2003 until 2018. Of these, 38 are boys and 26 are girls. The average age of the patients was 11.6 years. The average Risser score was 3.8 (P>0.01). Results. According to the data of spirography performed, 46% of patients had moderate ventilation disorders and 54% – severe ventilation disorders (FVC<60% – grade 3 and 4 of ventilation failure). Mixed type disorders were recorded in 83% of patients, and restrictive type disorders in 17% (8/48) of children. After HGT, there was an improvement in pulmonary function indicators: an increase in FVC from 63.19% to 71.77% and FEV1 from 54.71% to 65.46%, Tiffeneau-Pinelli index – from 74.59% to 85.33%. Compared with the initial level of indicators, the improvement in FVC was 13.6% after HGT and 14.6% in dynamics during the year, and FEV1 – 19.6% and 21.6%, respectively. The results obtained indicate a significant improvement in the ventilation function of the lungs, especially due to the degree of FEV1 increase, which correlates with the degree of improvement in performance, mortality and life prognosis. Conclusions. The use of HGT makes it possible to improve the results of the final correction of spinal deformity, which in turn significantly improves the ventilation function of the lungs, which in turn helps to reduce the risks of mortality due to pulmonary insufficiency in adulthood. The choice of the appropriate methods of surgical correction for complex deformity of the spine is a prerequisite for successful treatment and the achievement of three-dimensional correction of the spine to maximally approximate its parameters to the physiological norm. The indication for halo gravity traction is a rigid scoliotic deformity of the spine with a deformity angle (>100°). This study was conducted in accordance with the principles of the Helsinki Declaration. The research protocol was approved by the Local Ethics Committee of the institutions mentioned in the work. Informed parental agreement was obtained for the research. No conflict of interests was declared by the authors. Key words: spinal deformity, respiratory dysfunctions, halo-gravity traction.

Potential for the Lung Recruitment and the Risk of Lung Overdistension During 21 Days of Mechanical Ventilation in Patients With COVID-19 After Noninvasive Ventilation Failure: the COVID-VENT Observational Trial

Background: Data on the lung respiratory mechanics and gas exchange in the time course of COVID-19-associated respiratory failure is limited. This study aimed to explore respiratory mechanics and gas exchange, the lung recruitability and risk of overdistension during the time course of mechanical ventilation. Methods: This was a prospective observational study in critically ill mechanically ventilated patients (n=116) with COVID-19 admitted into Intensive Care Units of Sechenov University. The primary endpoints were: «optimum» positive end-expiratory pressure (PEEP) level balanced between the lowest driving pressure and the highest SpO2 and number of patients with recruitable lung on Days 1 and 7 of mechanical ventilation. We measured driving pressure at different levels of PEEP (14, 12, 10 and 8 cmH2O) with preset tidal volume, and with the increase of tidal volume by 100 ml and 200 ml at preset PEEP level, and calculated static respiratory system compliance (CRS), PaO2/FiO2, alveolar dead space and ventilatory ratio on Days 1, 3, 5, 7, 10, 14 and 21.Results: The «optimum» PEEP levels on Day 1 were 11.0 (10.0-12.8) cmH2O and 10.0 (9.0-12.0) cmH2O on Day 7. Positive response to recruitment was observed on Day 1 in 27.6% and on Day 7 in 9.2% of patients. PEEP increase from 10 to 14 cmH2O and VT increase by 100 and 200 ml led to a significant decrease in CRS from Day 1 to Day 14 (p<0.05). Ventilatory ratio was 2.2 (1.7-2,7) in non-survivors and in 1.9 (1.6-2.6) survivors on Day 1 and decreased on Day 7 in survivors only (p<0.01). PaO2/FiO2 was 105.5 (76.2-141.7) mmHg in non-survivors on Day 1 and 136.6 (106.7-160.8) in survivors (p=0.002). In survivors, PaO2/FiO2 rose on Day 3 (p=0.008) and then between Days 7 and 10 (p=0.046). Conclusion: Lung recruitability was low in COVID-19 and decreased during the course of the disease, but lung overdistension occurred at «intermediate» PEEP and VT levels. In survivors gas exchange improvements after Day 7 mismatched CRS.Trial registration: ClinicalTrials.gov, NCT04445961. Registered 24 June 2020 - Retrospectively registered, http://https://clinicaltrials.gov/ct2/show/NCT04445961?cond=COVID-19&cntry=RU&city=Moscow&draw=3&rank=23

Risk Factors for Noninvasive Ventilation Failure in Children Post-Hematopoietic Cell Transplant

RationaleLittle is known on the use of noninvasive ventilation (NIPPV) in pediatric hematopoietic cell transplant (HCT) patients.ObjectiveWe sought to describe the landscape of NIPPV use and to identify risk factors for failure to inform future investigation or quality improvement.MethodsThis is a multicenter, retrospective observational cohort of 153 consecutive children post-HCT requiring NIPPV from 2010-2016.Results97 (63%) failed NIPPV. Factors associated with failure on univariate analysis included: longer oxygen use prior to NIPPV (p=0.04), vasoactive agent use (p&lt;0.001), and higher respiratory rate at multiple hours of NIPPV use (1hr p=0.02, 2hr p=0.04, 4hr p=0.008, 8hr p=0.002). Using respiratory rate at 4 hours a multivariable model was constructed. This model demonstrated high ability to discriminate NIPPV failure (AUC=0.794) with the following results: respiratory rate &gt;40 at 4 hours [aOR=6.3 9(95% CI: 2.4, 16.4), p&lt;0.001] and vasoactive use [aOR=4.9 (95% CI: 1.9, 13.1), p=0.001]. Of note, 11 patients had a cardiac arrest during intubation (11%) and 3 others arrested prior to intubation. These 14 patients were closer to HCT [14 days (IQR:4, 73) vs 54 (IQR:21,117), p&lt;0.01] and there was a trend toward beginning NIPPV outside of the PICU and arrest during/prior to intubation (p=0.056).ConclusionsIn this cohort respiratory rate at 4 hours and vasoactive use are independent risk factors of NIPPV failure. An objective model to predict which children may benefit from a trial of NIPPV, may also inform the timing of both NIPPV initiation and uncomplicated intubation.

Predictive factors of continuous negative extrathoracic pressure management failure in children with moderate to severe respiratory syncytial virus infection

Continuous negative extrathoracic pressure (CNEP) might be beneficial for children with severe respiratory tract infections. However, there are no available data on the predictors of its failure among individuals with respiratory syncytial virus (RSV) infections. Here, we conducted a retrospective cohort study between October 1, 2015 and October 31, 2018 in hospitalized children with moderate to severe symptoms of respiratory syncytial virus (RSV) infections. We divided 45 children requiring CNEP ventilation with a non-fluctuating negative pressure of − 12 cm H2O into two groups. They were classified based on improvement or deterioration of their respiratory disorder under CNEP ventilation (responder group: n = 27, failure group: n = 18). Based on the univariate analysis, the responder and failure groups significantly differed in terms of median age, days elapsed from RSV onset to the initiation of CNEP, white blood cell count (WBC), titer of venous pCO2, body temperature at admission, and modified Wood-Downes Score (mWDS) 6 h after initiating CNEP. Based on a logistic regression analysis adjusted for age < 1 year upon admission, less than 5 days elapsed from RSV onset to the initiation of CNEP, not high value of WBC and body temperature at admission, and high values of mWDS 6 h after initiating CNEP were found to be significant independent risk factors for CNEP ventilation failure. The former two variables were associated with less failure (odds ratio was approximately 5), and the latter two variables are associated with more failure (odds ratio was approximately 8–9). Thus, CNEP could be a valid option for children with moderate to severe RSV infections, especially in those who were aged > 1 year, and specific clinical and laboratory findings.