On-site CAD templates reduce surgery time for complex craniostenosis repair in infants: a new method.

INTRODUCTION: The surgical correction of craniostenosis in children is a time-consuming and taxing procedure. To facilitate this procedure, especially in infants with complex craniostenosis, we refined the computer-aided design and manufacturing technique (CAD/CAM) based on computed tomography (CT)-generated DICOM data. We used cutting guides and molding templates, which allowed the surgeon to reshape and fixate the supraorbital bar extracorporeally on a side table and to control the intracorporal fit without removing the template. METHOD AND PATIENTS: To compare our traditional concept with the possibility of preoperative virtual planning (PVP) technique, the surgical treatment and courses of 16 infants with complex craniostenosis following fronto-orbital advancement (FOA) (age range 8-15 months) were analyzed in two groups (group 1: traditional, control group n = 8, group 2: CAD/CAM planned, n = 8). RESULTS: While in both groups, the head accurately reshaped postoperatively during the follow-up; the CAD group 2 showed a significantly shorter operating time with a mean of 4 h 25 min compared with group 1 with a mean of 5 h 37 min (p = 0.038). Additionally, the CAD group 2 had a significantly lower volume of blood loss (380 ml vs. 575 ml mean, p = 0.047), lower blood transfusion volume (285 ml vs. 400 ml mean, p = 0.108), lower fresh frozen plasma (FFP) volume (140 ml vs. 275 ml mean, p = 0.019), shorter stay in the pediatric intensive care unit (PICU) (3 vs. 5 days mean (p = 0.002), and shorter total length of hospital stay (6 days vs. 8 days mean, p = 0.002). CONCLUSION: CAD/CAM cutting guides and templates offer optimizing operative efficiency, precision, and accuracy in craniostenosis surgery in infants. As shown in this single-center observational study, the use of on-site templates significantly accelerates the reconstruction of the bandeau. The virtual 3D planning technique increases surgical precision without discernible detrimental effects.

[Reduction of treatment time for children in the trauma room care : Impact of implementation of an interdisciplinary trauma room concept (iTRAPS)]. / Verkürzung der Versorgungszeit im Trauma-Schockraum für Kinder : Auswirkungen der Einführung eines interdisziplinären Schockraumkonzepts (iTRAPS).

INTRODUCTION: In addition to infrastructural and conceptual planning, smooth interdisciplinary cooperation is crucial for trauma room care of severely injured children based on time-saving management and a clear set of priorities. The time to computed tomography (CT) is a well-accepted marker for the efficacy of trauma management. Up to now there are no guidelines in the literature for an adapted approach in pediatric trauma room care. METHODS: A step-by-step algorithm for pediatric trauma room care (Interdisciplinary Trauma Room Algorithm in Pediatric Surgery, iTRAPS) was developed within the framework of an interdisciplinary team: pediatric surgeons, pediatric anaethesiologists, pediatric intensivists and pediatric radiologists. In two groups of patients from January 2014 to April 2015 (group 1) and from July 2015 to January 2017 (group 2) process quality was monitored by the time required for trauma room treatment until the CT scan was performed and used as a surrogate marker. Inclusion criteria were patients aged 0-16 years, who were evaluated in a level 1 pediatric trauma room with an injury severity score (ISS) ≥8 and the necessity for a CT scan. RESULTS: Before (group 1) and after (group 2) implementation of iTRAPS 16 patients were included in each group. There were no significant differences between the age and the ISS in the two groups of patients. The required time for trauma room treatment was significantly reduced from an average of 33.6 min before to 15.2 min after implementation of iTRAPS (p < 0.01). DISCUSSION: The required time for the trauma care room treatment could be significantly reduced by more than half after the implementation of iTRAPS. The reasons were the interdisciplinary organization of the trauma room leadership, reorganization of patient transfer and improved briefing by emergency doctors. CONCLUSION: Besides a well-organized trauma team, it is essential that the trauma room workflow is adapted to the specific structure of the hospital. Despite the limitations of the study the data demonstrate that the trauma room workflow enables an efficient management. By the interdisciplinary reorganization of the pediatric trauma room treatment with improved structures and standardized processes, patient care was more effective with a significant reduction in the time required for trauma room treatment. The suggested iTRAPS concept could be used as a framework to establish individualized workflows for pediatric trauma room treatment in other hospitals. This algorithm should be supplemented by standardized operating procedures (SOPs) for the differentiated radiological diagnostic procedures in areas of traumatic brain injury (TBI), thoracic and abdominal trauma in children.

Osteoclastic craniectomy for scaphocephaly in infants results in physiological head shapes.

INTRODUCTION: Sagittal synostosis leading to scaphocephaly is the most common type of craniostenosis being operated. Different treatment options are known, but the optimal treatment method is still controversial. Head growth indicated by measurements of the head´s circumference and cephalic index (CI) are valid surrogate parameters for normal head shapes in children. The aim of the study was to analyze if osteoclastic craniectomy (OC) in scaphocephaly children at four to ten months of age results in normal head shapes. PATIENTS AND METHODS: Twenty-seven patients with scaphocephaly underwent OC between 2003 and 2011. The mean patient age at the time of surgery was 6.75 months. The body weight was between 6.1 and 9.3 kg, mean 8.0 kg. The average duration of surgery was 108 minutes. The mean blood loss during the procedure was 168 ml and the mean amount of erythrocyte transfusion was 152 ml. The mean time spent on the ICU was 1.48 days and the mean of total hospital stay was 5.81 days. The operative method is described. During the mean follow-up time of 6.3 years (min 3.8, max 10.4, median 7.1) focus was set on the patient´s head growth and cephalic index (CI) following OC. For statistical reason the follow up period was divided into three groups: follow up 2-4 years, 5-7 years and 8-10 years. RESULTS: For all cases the total head growth was 9.5cm (mean) during the follow up period of 6.3 years. Analyzing the mean head growth by bootstrapping analysis, the three observational groups showed a significant increase of the head circumference in all cases being analyzed: group 1 p=0.003, group 2 p=0.005 and group 3 p=0.028 Evaluation of the CI showed a statistically significant change from a pathologic value of 0.67 (mean) preoperatively to a normal value of 0.78 (mean) postoperatively during the follow up analyzing all patients. To precise these findings, the bootstrapping analysis showed in the first period an increase of the mean CI not reaching statistical significance (p=0.351). Analyzing the second and third period the CI significantly increased in both groups (p=0.016 and p=0.037). All patients showed a nearly complete re-ossification during the follow up period. No secondary operation was necessary in any patient of this cohort. CONCLUSION: As shown in this single-center observational study, the surgical intervention significantly improved the cephalic index and resulted in a symmetric head shape with excellent aesthetic appearance. The results were not dependent on postoperative helmet therapy, and compliance of caregivers. Re-ossification reached 100% within the observation period. According to these data, we recommend osteoclastic craniectomy as the method of choice in infants six to twelve months of age.

Closed reduction and immobilization of displaced distal radial fractures. Method of choice for the treatment of children?

PURPOSE: The therapy of distal radial fractures in children is expected to be as non-invasive as possible but also needs to deliver the definite care for gaining optimal reduction and stabilizing the fracture. Therefore, closed reduction and immobilization is competing with routine Kirschner wire fixation. The aim of our study was to investigate if closed reduction and immobilization without osteosynthesis can ensure stabilization of the fracture. METHODS: We chose a retrospective study design and analyzed 393 displaced distal radial fractures in children from 1 to 18 years with open epiphyseal plates studying medical files and X-rays. The Pearson's χ (2) test was applied. Statistical analysis was performed using IBM SPSS Statistics 20.0. Statistical significance was set at an alpha level of P = 0.05. RESULTS: Of these studied fractures 263 cases were treated with closed reduction and immobilization. Only 38 of these needed secondary interventions, 28 of these underwent reduction after redisplacement and ten patients received secondary Kirschner wire fixation. The last follow-up examination after 4-6 weeks revealed that 96.4% of fractures initially treated with closed reduction and immobilization were measured within the limits of remodeling. 104 of the studied fractures were treated with cast immobilization alone when displacement was expected to correct due to remodeling. Here 22.1% of patients needed secondary reduction. Furthermore, primary Kirschner wire fixation was performed in only 25 children with unstable fractures and only one received further treatment. Interestingly, operative reports of primary closed reduction revealed that repeated maneuvers of reduction as well as residual displacement are risk factors for redisplacement. CONCLUSION: For the treatment of displaced distal radial fractures in children closed reduction and immobilization can be considered the method of choice. However, for cases with repeated reduction maneuvers or residual displacement we recommend primary Kirschner wire fixation to avoid redisplacement. LEVEL OF EVIDENCE: Retrospective comparative study, Level III.