Blood Transfusion is Associated With Adverse Outcomes in Pediatric Solid Tumor Oncology Patients Following Tumor Resection.

BACKGROUND: Packed red blood cell (PRBC) transfusion is a lifesaving intervention that also has proinflammatory and immunosuppressive effects. Adults with a malignancy who receive PRBC transfusion have increased rates of infection, tumor recurrence, and decreased survival. The effect of PRBC transfusion among children with solid tumors is unknown. METHODS: We performed a retrospective review of all children who underwent operative resection of a solid tumor malignancy. Data collected included demographic information, location of operation, nadir hemoglobin, and any PRBC transfusion within 30 days of tumor resection. RESULTS: Three hundred sixty children underwent tumor resection at our institution between 2002 and 2013; 194 (54%) received a perioperative blood transfusion. After adjusting for stage at diagnosis, tumor location, preoperative chemotherapy and nadir hemoglobin, blood transfusion was associated with a higher rate of postoperative infectious complications, shorter disease-free interval, and a higher rate of tumor recurrence. Each additional transfused unit increased the risk of postoperative infection (odds ratio 3.83; 95% confidence interval 1.21, 14.22, P =0.031). CONCLUSIONS: Among children with solid tumor malignancies, PRBC transfusion within 30 days of operation is associated with higher rates of postoperative infection. If transfusion becomes necessary, single unit increments should be transfused. LEVEL OF EVIDENCE: Level III.

Comparison of Pediatric Trauma Scoring Tools That Incorporate Neurological Status for Trauma Team Activation.

BACKGROUND: Two novel pediatric trauma scoring tools, SIPAB+ (defined as elevated SIPA with Glasgow Coma Scale ≤8) and rSIG (reverse Shock Index multiplied by Glasgow Coma Scale and defined as abnormal using cutoffs for early outcomes), which combine neurological status with Pediatric Age-Adjusted Shock Index (SIPA), have been shown to predict early trauma outcomes better than SIPA alone. We sought to determine if one more accurately identifies children in need of trauma team activation. METHODS: Patients 1 to 18 years old from the 2014-2018 Pediatric Trauma Quality Improvement Program database were included. Sensitivity and specificity for SIPAB+ and rSIG were calculated for components of pediatric trauma team activation, based on criteria standard definitions. RESULTS: There were 11,426 patients (1.9%) classified as SIPAB+ and 235,672 (39.0%) as having an abnormal rSIG. SIPAB+ was consistently more specific, with specificities exceeding 98%, but its sensitivity was poor (<30%) for all outcomes. In comparison, rSIG was a more sensitive tool, with sensitivities exceeding 60%, and specificity values exceeded 60% for all outcomes. CONCLUSIONS: Trauma systems must determine their priorities to decide how best to incorporate SIPAB+ and rSIG into practice, although rSIG may be preferred as it balances both sensitivity and specificity. LEVEL OF EVIDENCE: Level III.

Discreet Values of Shock Index Pediatric Age-Adjusted (SIPA) to Predict Intervention in Children With Blunt Organ Injuries.

INTRODUCTION: Elevated shock index pediatric age-adjusted (SIPA) has been shown to be associated with the need for both blood transfusion and intervention in pediatric patients with blunt liver and spleen injuries (BLSI). SIPA has traditionally been used as a binary value, which can be classified as elevated or normal, and this study aimed to assess if discreet values above SIPA cutoffs are associated with an increased probability of blood transfusion and failure of nonoperative management (NOM) in bluntly injured children. MATERIALS AND METHODS: Children aged 1-18 y with any BLSI admitted to a Level-1 pediatric trauma center between 2009 and 2020 were analyzed. Blood transfusion was defined as any transfusion within 24 h of arrival, and failure of NOM was defined as any abdominal operation or angioembolization procedure for hemorrhage control. The probabilities of receiving a blood transfusion or failure of NOM were calculated at different increments of 0.1. RESULTS: There were 493 patients included in the analysis. The odds of requiring blood transfusion increased by 1.67 (95% CI 1.49, 1.90) for each 0.1 unit increase of SIPA (P < 0.001). A similar trend was seen initially for the probability of failure of nonoperative management, but beyond a threshold, increasing values were not associated with failure of NOM. On subanalysis excluding patients with a head injury, increased 0.1 increments were associated with increased odds for both interventions. CONCLUSIONS: Discreet values above age-related SIPA cutoffs are correlated with higher probabilities of blood transfusion in pediatric patients with BLSI and failure of NOM in those without head injury. The use of discreet values may provide clinicians with more granular information about which patients require increased resources upon presentation.

Survival after emergency department thoracotomy in the pediatric trauma population: a review of published data.

BACKGROUND/PURPOSE: The utility of EDT in the adult trauma population, using well-defined guidelines, is well established, especially for penetrating injuries. Since the introduction of these guidelines, reports on the use of EDT for pediatric trauma have been published, and these series reveal a dismal, almost universally fatal, outcome for EDT following blunt trauma in the child. This report reviews the clinical outcomes of EDT in the pediatric population. MATERIALS/METHODS: We performed a review of EDT in the pediatric population using the published data from 1980 to 2017. Variables extracted included mechanism of injury and mortality. To minimize bias, single case reports were not included in the review. RESULTS: Upon review of four decades of published literature on the use of emergency department thoracotomy (EDT) in the pediatric population, mortality rates are comparable between adults and pediatric patients for penetrating thoracic trauma. In contrast, in pediatric patients sustaining blunt trauma, no patient under the age of 15 has survived. CONCLUSION: In patients between 0 and 14 years of age presenting with no signs of life following blunt trauma, withholding EDT should be considered. Patients between the ages of 15 and 18 should be treated in accordance with adult ATLS principles for the management of thoracic trauma. LEVEL OF EVIDENCE: Level IV.

Goal-directed Hemostatic Resuscitation of Trauma-induced Coagulopathy: A Pragmatic Randomized Clinical Trial Comparing a Viscoelastic Assay to Conventional Coagulation Assays.

BACKGROUND: Massive transfusion protocols (MTPs) have become standard of care in the management of bleeding injured patients, yet strategies to guide them vary widely. We conducted a pragmatic, randomized clinical trial (RCT) to test the hypothesis that an MTP goal directed by the viscoelastic assay thrombelastography (TEG) improves survival compared with an MTP guided by conventional coagulation assays (CCA). METHODS: This RCT enrolled injured patients from an academic level-1 trauma center meeting criteria for MTP activation. Upon MTP activation, patients were randomized to be managed either by an MTP goal directed by TEG or by CCA (ie, international normalized ratio, fibrinogen, platelet count). Primary outcome was 28-day survival. RESULTS: One hundred eleven patients were included in an intent-to-treat analysis (TEG = 56, CCA = 55). Survival in the TEG group was significantly higher than the CCA group (log-rank P = 0.032, Wilcoxon P = 0.027); 20 deaths in the CCA group (36.4%) compared with 11 in the TEG group (19.6%) (P = 0.049). Most deaths occurred within the first 6 hours from arrival (21.8% CCA group vs 7.1% TEG group) (P = 0.032). CCA patients required similar number of red blood cell units as the TEG patients [CCA: 5.0 (2-11), TEG: 4.5 (2-8)] (P = 0.317), but more plasma units [CCA: 2.0 (0-4), TEG: 0.0 (0-3)] (P = 0.022), and more platelets units [CCA: 0.0 (0-1), TEG: 0.0 (0-0)] (P = 0.041) in the first 2 hours of resuscitation. CONCLUSIONS: Utilization of a goal-directed, TEG-guided MTP to resuscitate severely injured patients improves survival compared with an MTP guided by CCA and utilizes less plasma and platelet transfusions during the early phase of resuscitation.

A pediatric specific shock index in combination with GMS identifies children with life threatening or severe traumatic brain injury.

PURPOSE: We have previously demonstrated that a shock index, pediatric age adjusted (SIPA) accurately identifies severely blunt injured children. We aimed to determine if SIPA could more accurately identify children with severe traumatic brain injury (TBI) than hypotension alone. METHODS: We performed subset analysis of those children with TBI among a cohort of children age 4-16 years with blunt trauma and injury severity score ≥15 from 1/07 to 6/13. We evaluated the ability of four markers to identify the most severely brain injured children. Markers included hypotension, elevated SIPA, abnormal GCS motor score (GMS), and elevated SIPA or abnormal GMS. We aimed to determine which of these four markers had the highest sensitivity in identifying severely injured children. RESULTS: Three hundred and ninety-two (392) children were included. Hypotension was present in 24 patients (6%); elevated SIPA in 106 (27 %), abnormal GMS in 172 (44%), and elevated SIPA or abnormal GMS in 206 (53%). All markers were able to accurately identify severely injured children with TBI. Elevated SIPA or abnormal GMS identified a greater percentage of patients with each of seven complications with higher sensitivity than each of the three other markers. CONCLUSION: Among blunt injured children with TBI, elevated SIPA or abnormal GMS identifies severely brain injured children.

Head injury pattern in children can help differentiate accidental from non-accidental trauma.

OBJECTIVES: Our aim was to define the radiographic findings that help differentiate abusive head trauma (AHT) from accidental head injury. METHODS: Our trauma registry was queried for all children ≤5 years of age presenting with traumatic brain injury (TBI) from 1996-2011. RESULTS: Of 2,015 children with TBI, 71% had accidental injury and 29% had AHT. Children with AHT were more severely injured (ISS 22.1 vs 14.4; p < 0.0001) and had a higher mortality rate (15 vs 5%; p < 0.0001). Patients with AHT had higher rates of diffuse axonal injury (14 vs 8%; p < 0.0001) and subdural hemorrhage (76 vs 23%; p < 0.0001). Children with accidental injury had higher rates of skull fractures (52 vs 21%; p < 0.0001) and epidural hemorrhages (11 vs 3%). CONCLUSIONS: AHT occurred in 29% of children and resulted in increased mortality rates. These children had higher rates of subdural hemorrhages and diffuse axonal injury. Physicians initially evaluating injured children must maintain a high index of suspicion for abuse in those who present with subdural hematoma or diffuse axonal injury.

Chest computed tomography imaging for blunt pediatric trauma: not worth the radiation risk.

INTRODUCTION: A child's risk of developing cancer from radiation exposure associated with computed tomography (CT) imaging is estimated to be as high as 1/500. Chest CT (CCT), often as part of a "pan-scan," is increasingly performed after blunt trauma in children. We hypothesized that routine CCT for the initial evaluation of blunt injured children does not add clinically useful information beyond chest radiograph (CXR) and rarely changes management. METHODS: Pediatric (<15 y) trauma team evaluations over 6 y at an academic Level I trauma center were reviewed. Demographic data, injuries, imaging, and management were identified for all patients undergoing CT. Effective radiation dose in milliSieverts (mSv) was calculated using age-adjusted scales. RESULTS: Fifty-seven of 174 children (33%) undergoing CT imaging had a CCT; 55 (97%) of these had a CXR. Pathology was identified in significantly fewer CXRs compared with CCTs (51% versus 83%, P < 0.001). All 7/57 (12%) emergent or urgent chest interventions were based on information from CXR. In 53 children (93%), the CCT was ordered as part of a pan-scan, resulting in a radiation dose of 37.69 ± 7.80 mSv from initial CT scans. Radiation dose was significantly greater from CCT than from CXR (8.7 ± 1.1 mSv versus 0.017 ± 0.002 mSv, P < 0.001). CONCLUSIONS: Clinically useful information found on CCT had good correlation to information obtained from CXR and did not change patient management, however, did add significantly to the radiation exposure of initial imaging. We recommend selective use of CCT, particularly in the presence of an abnormal mediastinal silhouette on CXR after a significant deceleration injury.

Use of reverse shock index times Glasgow coma scale (rSIG) to determine need for transfer of pediatric trauma patients to higher levels of care.

INTRODUCTION: Most children in the US live more than one hour from a Level 1 PTC. The Need For Trauma Intervention (NFTI) score was developed to assess trauma triage criteria and is dependent on whether someone requires one of six urgent interventions (NFTI+). We sought to determine if a novel scoring tool, rSIG, could predict NFTI and facilitate the transfer decision making process. METHODS: Children 1-18 years old transferred to our level 1 PTC from 2010 - 2020 with complete vital signs and Glasgow Coma Scale (GCS) score at the transferring facility were included. rSIG was calculated as previously described [(SBP/HR) x GCS], and the following cutoffs were used for each age group: ≤13.1, ≤16.5, and ≤20.1 for 1-6, 7-12, and 13-18 years, respectively. Clinical outcomes upon arrival to the PTC were collected to determine if patients met any NTFI criteria. RESULTS: A total of 456 patients met inclusion criteria. The proportion of patients with an abnormal rSIG was 60.1% (274) and 37.0% (169) were NFTI+. Patients with an abnormal rSIG had an odds ratio of 6.18 (95% CI: 3.90, 10.07), p < 0.001 of being NFTI+ compared to those with a normal rSIG. CONCLUSION: Children with an abnormal rSIG are more likely to be NFTI+ and require higher levels of care, indicating this scoring tool can identify pediatric trauma patients who may benefit from expedited transfer. Incorporating rSIG into initial evaluation and triage of traumatically injured children may expedite the transfer decision making process and limit delays in transport to a PTC. TYPE OF STUDY: Retrospective Comparative Study LEVEL OF EVIDENCE: III.

Use of prehospital reverse shock index times Glasgow Coma Scale to identify children who require the most immediate trauma care.

BACKGROUND: Appropriate prehospital trauma triage ensures transport of children to facilities that provide specialized trauma care. There are currently no objective and generalizable scoring tool for emergency medical services to facilitate such decisions. An abnormal reverse shock index times Glasgow Coma Scale (rSIG), which is calculated using readily available parameters, has been shown to be associated with severely injured children. This study sought to determine if rSIG could be used in the prehospital setting to identify injured children who require the highest levels of care. METHODS: Patients (1-18 years old) transferred from the scene to a level 1 pediatric trauma center from 2010 to 2020 with complete prehospital and emergency department vital signs, and Glasgow Coma Scale (GCS) scores were included. Reverse shock index times GCS was calculated as previously described ((systolic blood pressure/heart rate) × GCS), and the following cutoffs were used: ≤13.1, ≤16.5, and ≤20.1 for 1- to 6-, 7- to 12-, and 13- to 18-year-old patients, respectively. Trauma activation level and clinical outcomes upon arrival to the pediatric trauma center were collected. RESULTS: There were 247 patients included in the analysis; 66.0% (163) had an abnormal prehospital rSIG. Patients with an abnormal rSIG had a higher rate of highest-level trauma activation compared with those with a normal rSIG (38.7% vs. 20.2%, p = 0.013). Patients with an abnormal prehospital rSIG also had higher rates of intubation (28.8% vs. 9.52%, p < 0.001), intracranial pressure monitor (9.20 vs. 1.19%, p = 0.032), need for blood (19.6% vs. 8.33%, p = 0.034), laparotomy (7.98% vs. 1.19%, p = 0.039), and intensive care unit admission (54.6% vs. 40.5%, p = 0.049). CONCLUSION: Reverse shock index times GCS may assist emergency medical service providers in early identification and triage of severely injured children. An abnormal rSIG in the emergency department is associated with higher rates of intubation, need for blood transfusion, intracranial pressure monitoring, laparotomy, and intensive care unit admission. Use of this metric may help to speed the identification, care, and treatment of any injured child. LEVEL OF EVIDENCE: Prognostic and Epidemiological; Level IV.

Establishing a core outcome set for blunt cerebrovascular injury: an EAST modified Delphi method consensus study.

Objectives: Our understanding of blunt cerebrovascular injury (BCVI) has changed significantly in recent decades, resulting in a heterogeneous description of diagnosis, treatment, and outcomes in the literature which is not suitable for data pooling. Therefore, we endeavored to develop a core outcome set (COS) to help guide future BCVI research and overcome the challenge of heterogeneous outcomes reporting. Methods: After a review of landmark BCVI publications, content experts were invited to participate in a modified Delphi study. For round 1, participants submitted a list of proposed core outcomes. In subsequent rounds, panelists used a 9-point Likert scale to score the proposed outcomes for importance. Core outcomes consensus was defined as >70% of scores receiving 7 to 9 and <15% of scores receiving 1 to 3. Feedback and aggregate data were shared between rounds, and four rounds of deliberation were performed to re-evaluate the variables not achieving predefined consensus criteria. Results: From an initial panel of 15 experts, 12 (80%) completed all rounds. A total of 22 items were considered, with 9 items achieving consensus for inclusion as core outcomes: incidence of postadmission symptom onset, overall stroke incidence, stroke incidence stratified by type and by treatment category, stroke incidence prior to treatment initiation, time to stroke, overall mortality, bleeding complications, and injury progression on radiographic follow-up. The panel further identified four non-outcome items of high importance for reporting: time to BCVI diagnosis, use of standardized screening tool, duration of treatment, and type of therapy used. Conclusion: Through a well-accepted iterative survey consensus process, content experts have defined a COS to guide future research on BCVI. This COS will be a valuable tool for researchers seeking to perform new BCVI research and will allow future projects to generate data suitable for pooled statistical analysis with enhanced statistical power. Level of evidence: Level IV.

Effect of damage control surgery on major abdominal vascular trauma.

BACKGROUND: In 1982, we reported our experience with abdominal vascular trauma, highlighting the critical role of hypothermia, acidosis, and coagulopathy. Damage control surgery was subsequently introduced to address this "lethal triad." The purpose of the present study was to evaluate the outcomes from our most recent 6-year experience compared with a cohort from 30 years ago. METHODS: Patients with major abdominal vascular injuries were examined, and the most recent 6-year period was compared with archived data from a similar 6-year period three decades ago. RESULTS: The number of patients with major abdominal vascular injuries decreased from 123 patients in 1975 to 1980 to 64 patients in 2004 to 2009. The mean initial pH decreased from 7.21 to 6.96 (1975 to 1980 versus 2004 to 2009) for patients with overt coagulopathy. Despite increasingly protracted acidosis, mortality attributable to refractory coagulopathy decreased from 46% to 19% (1975 to 1980 versus 2004 to 2009, chi-square = 4.36, P = 0.04). No significant difference was found in mortality from exsanguinating injuries (43% versus 62%, 1975 to 1980 versus 2004 to 2009, chi-square = 1.96, P = 0.16). The prehospital transport times were unchanged (22 versus 20 min, 1975 to 1980 versus 2004 to 2009). Despite the administration of additional clotting factors and the advent of damage control surgery, the overall mortality remained largely unchanged (37% versus 33%, 1975 to 1980 versus 2004 to 2009, chi-square = 0.385, P = 0.53). CONCLUSIONS: The adoption of damage control surgery, including the implementation of a massive transfusion protocol, was associated with a reduction in mortality for abdominal vascular injuries due to coagulopathy; however, patients have continued to die of exsanguination.

Adolescent blunt solid organ injury: Differences in management strategies and outcomes between pediatric and adult trauma centers.

BACKGROUND: Adolescents with blunt solid organ injuries (BSOI) are cared for at both pediatric trauma centers (PTC) and adult trauma centers (ATC). Over the past decade, treatment strategies have shifted towards non-operative management with reported favorable outcomes. The aim of this study was to compare management strategies and outcomes between PTC and ATC. METHODS: We queried the 2016-2018 Trauma Quality Improvement Program (TQIP) datasets to identify adolescents between the ages of 16 and 19 with BSOI. Characteristics were stratified by center type (pediatric or adult) for comparative analyses. Separate logistic regressions were used to assess the association of hospital type, location of injury, age, gender, weight, Glascow Coma Score (GCS), Injury Severity Score (ISS), and intensive care unit (ICU) admissions for outcomes of interest. RESULTS: Among the 3,011,310 patients enrolled in the 2016-2018 TQIP datasets, 106,892 (3.5%) had a BSOI ICD9/10 code. Of those, 9,193 (8.6%) were between 16 and 19 years of age and included in this analysis. Within this cohort, 6,073 (66.1%) were managed at an ATC and 3,120 (33.9%) were managed at a PTC. While statistically different, there were no clinically relevant differences for age, weight, and sex between groups. A significantly higher ISS and lower GCS score were observed among those admitted to ATC compared to PTC. ICU admissions were more frequent at ATC. Number of blood transfusions by 4 h after presentation were also higher among those admitted to an ATC. Despite a lower ISS and higher GCS at presentation, mortality was higher among those treated at a PTC with an odds ratio (95% confidence interval) of 2.42 (1.31-4.53). After excluding adolescents with a traumatic brain injury, a common cause of mortality among adolescent trauma patients, these differences in outcomes persisted. CONCLUSIONS: Our data suggest that adolescents with BSOI managed at a PTC are less likely to receive blood transfusions by 4 h of admission or be admitted to the ICU than those managed at an ATC. However, this more conservative approach may come at the expense of higher overall mortality. Further work is needed to understand these differences and determine if PTC need to be more aggressive in managing BSOI.

Pediatric cardiac and great vessel injuries: Recent experience at two pediatric trauma centers.

BACKGROUND: Cardiac injuries are rare in pediatric trauma patients and data regarding this type of injury is limited. There is even less data on traumatic great vessel injuries. This study sought to examine and summarize our recent experience at two pediatric trauma centers, which serve a major metropolitan area and large geographic region. METHODS: This is a retrospective review of pediatric (<18 years) patients who sustained cardiac or great vessel injuries and were managed at a Level 1 or Level 2 pediatric trauma center between January 1, 2010 and June 30, 2020. Demographic and clinical characteristics were compared using two-sample t-tests, Wilcoxon Rank-Sum tests, Fisher's exact tests and chi-squared tests for continuous, non-normally distributed continuous, and categorical variables, respectively. RESULTS: A total of 53 patients sustained cardiac and/or great vessel injuries. Of these, 37 (70%) sustained cardiac, 9 (17%) sustained great vessel, and 7 (13%) sustained both types of injuries. The median age was 14.9 years and 74% (n = 39) were male. The median injury severity score (ISS) was 36.0 and the injury mechanism was blunt in 31 (58%) patients. The most common cardiac and great vessel injury locations were left ventricle (n = 9) and thoracic aorta (n = 11), respectively. The overall mortality rate was 53% (n = 28). Mortality was highest among those who sustained great vessel injuries (89%). CONCLUSIONS: There is substantial heterogeneity in cardiac and great vessel injuries. Regardless, they are highly morbid and lethal, despite aggressive surgical and catheter-based interventions.

Improved identification of severely injured pediatric trauma patients using reverse shock index multiplied by Glasgow Coma Scale.

BACKGROUND: The shock index pediatric age-adjusted (SIPA) predicts the need for increased resources and mortality among pediatric trauma patients without incorporating neurological status. A new scoring tool, rSIG, which is the reverse shock index (rSI) multiplied by the Glasgow Coma Scale (GCS), has been proven superior at predicting outcomes in adult trauma patients and mortality in pediatric patients compared with traditional scoring systems. We sought to compare the accuracy of rSIG to Shock Index (SI) and SIPA in predicting the need for early interventions in civilian pediatric trauma patients. METHODS: Patients (aged 1-18 years) in the 2014 to 2018 Pediatric Trauma Quality Improvement Program database with complete heart rate, systolic blood pressure, and total GCS were included. Optimal cut points of rSIG were calculated for predicting blood transfusion within 4 hours, intubation, intracranial pressure monitoring, and intensive care unit admission. From the optimal thresholds, sensitivity, specificity, and area under the curve were calculated from receiver operating characteristics analyses to predict each outcome and compared with SI and SIPA. RESULTS: A total of 604,931 patients with a mean age of 11.1 years old were included. A minority of patients had a penetrating injury mechanism (5.6%) and the mean Injury Severity Score was 7.6. The mean SI and rSIG scores were 0.85 and 18.6, respectively. Reverse shock index multiplied by Glasgow Coma Scale performed better than SI and SIPA at predicting early trauma outcomes for the overall population, regardless of age. CONCLUSION: Reverse shock index multiplied by Glasgow Coma Scale outperformed SI and SIPA in the early identification of traumatically injured children at risk for early interventions, such as blood transfusion within 4 hours, intubation, intracranial pressure monitoring, and intensive care unit admission. Reverse shock index multiplied by Glasgow Coma Scale adds neurological status in initial patient assessment and may be used as a bedside triage tool to rapidly identify pediatric patients who will likely require early intervention and higher levels of care. LEVEL OF EVIDENCE: Prognostic, level III.

Use of ultrasound measurements to direct laparoscopic pyloromyotomy in infants.

BACKGROUND: Laparoscopic pyloromyotomy is associated with an increased risk of incomplete myotomy compared with open myotomy. We hypothesized that utilizing ultrasound measured length to direct laparoscopic pyloromyotomy would reduce the risk of incomplete pyloromyotomy without a concomitant increase in the risk of mucosal perforation. METHODS: Infants (n=43) with hypertrophic pyloric stenosis diagnosed by ultrasound and subsequent laparoscopic pyloromyotomy over a 2-year period (December 2006 through December 2008) were studied. Pyloromyotomy length was guided by preoperative ultrasound measurements. Pyloromyotomy was considered complete if the measured length was ≥ the ultrasound measurement. Infants were followed prospectively for time to full feeding, time to discharge, and complications. RESULTS: The cohort included 38 male and 5 female infants (age, 37±13 days; range, 17 to 72 days) who underwent ultrasound (length 1.9±0.2cm; thickness 4.4±0.9mm) and laparoscopic pyloromyotomy. Infants achieved full feeding 28±16 hours postoperatively and were discharged 34±18 hours postoperatively. No infant required reoperation for incomplete myotomy. One infant sustained mucosal perforation (2%). No patient suffered other complications. CONCLUSION: Preoperative ultrasound measurement of pyloric length to determine the length of laparoscopic pyloromyotomy, rather than visual cues alone, appears to minimize the risk of incomplete pyloromyotomy.

The benefits of limiting scheduled blood draws in children with a blunt liver or spleen injury.

BACKGROUND: Nonoperative management protocols of blunt liver and spleen injury in children usually call for serial monitoring of the child's hemoglobin and hematocrit (H/H) at scheduled intervals. We previously demonstrated that the need for emergent intervention is triggered by changes in vital signs, not the findings of scheduled blood draws and changed our protocol accordingly. The current aim is to evaluate the safety of this change. METHODS: We performed a retrospective review of all children admitted following blunt liver or spleen injury during two periods; the historic cohort 1/09-12/13 and the protocol cohort 8/15-7/17. Data evaluated included the need for intervention, number of H/H checks, and outcomes. RESULTS: 330 children were included (216 historic; 114 protocol). Groups did not differ in percentage of male patients, injury severity score, or GCS. Median age in the historic cohort was younger than the protocol cohort (9 vs 12 years; p = 0.02). More children in the protocol group had a grade 5 injury (1% vs 9%; p < 0.0001). Groups did not differ in the number who required intervention or discharge disposition (including mortality). The protocol group had fewer H/H checks (median 5 vs 4, p < 0.0001); the two groups did not differ in their nadir H/H. The historic group had a longer median hospital length of stay (3 days vs 2, p = 0.0007). CONCLUSIONS: Decreasing the number of scheduled blood draws following a blunt liver or spleen injury in children is safe. Additional benefits include a decrease in the number of blood draws and a decrease in length of hospital stay. STUDY TYPE: Cost-effectiveness. LEVEL OF EVIDENCE: Level III.

Early discharge following laparoscopic appendectomy in children utilizing an evidence-based clinical pathway.

BACKGROUND: The utility of laparoscopic appendectomy (LA) in children remains controversial. The determination of the efficacy of LA in children is complicated by variable postoperative management, duration of antibiotics,and criteria for discharge. The aim of this study was to examine the results of a commitment to LA and the concurrent implementation of an evidence-based clinical pathway (CP) for management appendicitis in a children's hospital. METHODS: With institutional review board approval, all children presenting with appendicitis (n = 72; age =10.6 +/- 0.1 years) were offered LA and management directed by CP. Data were accrued prospectively for 12 consecutive months (May 2006 to April 2007) and analysis performed at 15 months. Data are reported as the mean +/- standard error of the mean. RESULTS: Children were stratified based on the operative findings: group one - acute 41; group two-suppurative=11; and group 3-gangrenous or perforated 20. Duration of hospital stay differed between the groups:group one= 26 +/- 0.3 hours; group 2 =48 +/- 3 hours; group 3= 127 +/- 6 hours (P <0.05). No patients in groups one or two suffered a complication or were readmitted following discharge. Two patients in group 3 (10%)were readmitted and treated with antibiotic therapy alone. Overall, 66% of the children with acute appendicitis(27/41) and 27% with suppurative appendicitis (3/11) were discharged within 24 hours of admission. Discharge by 24 hours in groups 1 and 2 was not influenced by age, gender, or time of operation (before or after 7 PM). CONCLUSIONS: The commitment to LA and use of CP resulted in discharge within 24 hours in 2 of 3 of children with acute appendicitis without readmission or complications being observed. Early discharge was not influenced by age, gender, or time of admission. For advanced appendicitis, length of hospital stay, determined by clinical parameters, resulted in a low rate of complication or readmission.

Central venous lines in critically ill children: Thrombosis but not infection is site dependent.

BACKGROUND: Central venous catheters (CVC) are vital to the management of critically ill children. Despite efforts to minimize complications, central line associated bloodstream infection (CLABSI) and venous thromboembolisms (VTE) still occur. METHODS: We performed a retrospective review of a prospectively collected database for children admitted to the pediatric intensive care unit (PICU) between November 2013 and December 2016. RESULTS: In total, 2714 CVC were in place, 979 of which were percutaneous CVC. During the study period, 21 CLABSI (1.6/1000 line days) were identified, of which, nearly half (n = 9, 42.9%) were associated with percutaneous CVC (2.6/1000 line days). Poisson regression analysis did not identify a single risk factor for CLABSI when adjusting for line type, anatomic location and laterality of placement, geographic location of placement, length of PICU admission, presence of gastrostomy tube, concurrent mechanical ventilation, age, weight, and height. Forty clinically significant VTE (2.9/1000 line days) were identified, with percutaneous CVC having the highest incidence (7.5/1000 line days, p < 0.001). Of percutaneous CVC, clinically significant VTE were more often associated with femoral vein cannulation (14.8/1000 line days) compared to internal jugular and subclavian vein (2.5 and 2.4/1000 line days, respectively, p < 0.001). CONCLUSION: This data suggests that the femoral site may be an important risk factor that should be considered in prevention strategies for catheter-associated VTE in children. LEVEL OF EVIDENCE: III.

Mapping pediatric injuries to target prevention, education, and outreach.

BACKGROUND: Initiatives exist to prevent pediatric injuries, but targeting these interventions to specific populations is challenging. We hypothesized that mapping pediatric injuries by zip code could be used to identify regions requiring more interventions and resources. METHODS: We queried the trauma registries of two level I trauma centers for children 0-17years of age injured between 2009 and 2013 with home zip codes in our state. Maps were created to identify outlier zip codes. Multivariate linear regression analysis identified predictors within these zip codes. RESULTS: There were 5380 children who resided in the state and were admitted for traumatic injuries during the study period, with hospital costs totaling more than 200 million dollars. Choropleth mapping of patient addresses identified outlier zip codes in our metro area with higher incidences of specific mechanisms of injury and greater hospital charges. Multivariate analysis identified demographic features associated with higher rates of pediatric injuries and hospital charges, to further target interventions. CONCLUSIONS: We identified outlier zip codes in our metro area with higher frequencies of pediatric injuries and higher costs for treatment. These data have helped obtain funding for prevention and education efforts. Techniques such as those presented here are becoming more important as evidence based public health initiatives expand. LEVEL OF EVIDENCE: Type of Study: Cost Effectiveness, II.