Anthony Sochet

Surgical Site Infection After Pediatric Cardiothoracic Surgery.

Background: Surgical site infection (SSI) occurs in 0.25% to 6% of children after cardiothoracic surgery (CTS). There are no published data regarding the financial impact of SSI after pediatric CTS. We sought to determine the attributable hospital cost and length of stay associated with SSI in children after CTS. Methods: We performed a retrospective, matched cohort study in a 26-bed cardiac intensive care unit (CICU) from January 2010 through December 2013. Cases with SSI were identified retrospectively and individually matched to controls 2:1 by age, gender, Risk Adjustment for Congenital Heart Surgery score, Society of Thoracic Surgeons–European Association for Cardiothoracic Surgery category, and primary cardiac diagnosis and procedure. Results: Of the 981 cases performed during the study period, 12 with SSI were identified. There were no differences in demographics, clinical characteristics, or intraoperative data. Median total hospital costs were higher in participants with SSI as compared to controls (US

Fluid Overload and Cumulative Thoracostomy Output Are Associated With Surgical Site Infection After Pediatric Cardiothoracic Surgery

219,573 vs US

Cardiopulmonary Bypass Reduces Early Thrombosis of Systemic-to-Pulmonary Artery Shunts

82,623, P < .01). Children with SSI had longer median CICU length of stay (9 vs 3 days, P < .01), hospital length of stay (18 vs 8.5 days, P < .01), and duration of mechanical ventilation (2 vs 1 day, P < .01) and vasoactive administration (4.5 vs 1 day, P < .01). Conclusions: Children with SSI after CTS have an associated increase in hospital costs of US

Use of the pediatric intensive care unit for post-procedural monitoring in young children following microlaryngobronchoscopy: Impact on resource utilization and hospital cost

136,950/case and hospital length of stay of 9.5 days/case. The economic burden posed by SSI stress the importance of infection control surveillance, exhaustive preventative measures, and identification of modifiable risk factors.

Standardization of Postoperative Transitions of Care to the Pediatric Intensive Care Unit Enhances Efficiency and Handover Comprehensiveness

Objectives: To determine the impact of cumulative, postoperative thoracostomy output, amount of bolus IV fluids and peak fluid overload on the incidence and odds of developing a deep surgical site infection following pediatric cardiothoracic surgery. Design: A single-center, nested, retrospective, matched case-control study. Setting: A 26-bed cardiac ICU in a 303-bed tertiary care pediatric hospital. Patients: Cases with deep surgical site infection following cardiothoracic surgery were identified retrospectively from January 2010 through December 2013 and individually matched to controls at a ratio of 1:2 by age, gender, Risk Adjustment for Congenital Heart Surgery score, Society of Thoracic Surgeons—European Association for Cardiothoracic Surgery category, primary cardiac diagnosis, and procedure. Interventions: None. Measurements and Main Results: Twelve cases with deep surgical site infection were identified and matched to 24 controls without detectable differences in perioperative clinical characteristics. Deep surgical site infection cases had larger thoracostomy output and bolus IV fluid volumes at 6, 24, and 48 hours postoperatively compared with controls. For every 1 mL/kg of thoracostomy output, the odds of developing a deep surgical site infection increase by 13%. By receiver operative characteristic curve analysis, a cutoff of 49 mL/kg of thoracostomy output at 48 hours best discriminates the development of deep surgical site infection (sensitivity 83%, specificity 83%). Peak fluid overload was greater in cases than matched controls (12.5% vs 6%; p < 0.01). On receiver operative characteristic curve analysis, a threshold value of 10% peak fluid overload was observed to identify deep surgical site infection (sensitivity 67%, specificity 79%). Conditional logistic regression of peak fluid overload greater than 10% on the development of deep surgical site infection yielded an odds ratio of 9.4 (95% CI, 2–46.2). Conclusions: Increased postoperative peak fluid overload and cumulative thoracostomy output were associated with deep surgical site infection after pediatric cardiothoracic surgery. We suspect the observed increased thoracostomy output, fluid overload, and IV fluid boluses may have altered antimicrobial prophylaxis. Although analysis of additional pharmacokinetic data is warranted, providers may consider modification of antimicrobial prophylaxis dosing or alterations in fluid management and diuresis in response to assessment of peak fluid overload and fluid volume shifts in the immediate postoperative period.

1673: AN UNUSUAL CASE OF TYPE B LACTIC ACIDOSIS IN THE INDUSTRIALIZED WORLD

Background: Shunt thrombosis is a significant cause of morbidity and mortality after systemic-to-pulmonary artery shunt (SPS) placement. Concurrent procedures with placement of SPS may require cardiopulmonary bypass (CPB). Cardiopulmonary bypass is known to cause bleeding and platelet dysfunction in infants, which may protect from early shunt thrombosis. We hypothesized that infants undergoing SPS placement on CPB have a lower incidence of early shunt thrombosis. Methods: Retrospective cohort study of infants undergoing SPS placement from January 2008 to December 2014 was performed. Patients with and without early shunt thrombosis and on or off CPB were compared using the Mann-Whitney U test or Fisher exact test. Multivariable regression analysis was performed to identify independent predictors of early shunt thrombosis and to assess effect of CPB independent of other factors. Results: Seventy-five infants underwent SPS placement during the study period (on CPB, n = 25; off CPB, n = 50). Operative mortality was 11% (8/75). Nine (12%) patients developed early shunt thrombosis, all of whom had shunt placement off CPB. Independent risk factors for early shunt thrombosis were identified to be SPS placement off CPB (P = .011), prematurity (P = .034), and competitive antegrade pulmonary blood flow (P = .038). Conclusion: Prematurity, competitive antegrade pulmonary blood flow, and shunt placement off CPB lead to higher risk of early shunt thrombosis. We speculate that the protection offered by use of CPB may be accounted for by the associated complex coagulopathy and platelet dysfunction associated with CPB.

132: FGF-2, VEGF-A AS BIOMARKERS FOR BLEEDING AND FLUID OVERLOAD AFTER PEDIATRIC CARDIOPULMONARY BYPASS.

OBJECTIVE To assess the frequency of post-procedural complications, medical interventions, and hospital costs associated with microlaryngobronchoscopy (MLB) in children prophylactically admitted for pediatric intensive care unit (PICU) monitoring for age ≤ 2 years. METHODS We performed a single-center, retrospective, descriptive study within a 44-bed PICU in a stand-alone, tertiary, pediatric referral center. Inclusion criteria were age ≤2 years and pre-procedural selection of prophylactic PICU monitoring after MLB between January 2010 and December 2015. Children were excluded for existing tracheostomy, if undergoing concurrent non-otolaryngeal procedures, or if intubated at the time of PICU admission. Primary outcomes were the development of major and minor procedural complications and medical rescue interventions. Secondary outcomes were hospital cost and length of stay (LOS). RESULTS One hundred and eight subjects met inclusion criteria with a median age of 5.3 (IQR: 2.6-10.9) months. A majority (86%) underwent therapeutic instrumentation in addition to diagnostic MLB. There were no observed major complications or rescue interventions. Minor complications were noted within 5 h of monitoring and included isolated stridor (24%), desaturation <90% (10%), and nausea/emesis (8%). Minor interventions included supplemental oxygen via regular nasal cannula (39%), single-dose inhaled racemic epinephrine (19%), single-dose systemic corticosteroids (19%), or high flow nasal cannula (HFNC) therapy (4%). Save for two cases of HFNC, interventions were completed or discontinued within 5 h. Median PICU LOS was 1.1 days and median cost was

Short-Term Peripheral Vasoactive Infusions in Pediatrics: Where Is the Harm?

9650 (IQR:

1146: DON’T PASS THIS UP

8235-

1516: SEVERE COMPLICATIONS AND ICU INTERVENTIONS ARE RARE IN YOUNG CHILDREN AFTER MICROLARYNGOBRONCHOSCOPY

14,861) per encounter. Estimated cost of same day observation in our post anesthesia care unit (PACU) following MLB without PICU admission is