Innovation at a Children's Hospital: Personal Protective Equipment Efforts During the Pandemic.

The COVID-19 pandemic has affected life for everyone, and hospitals, in particular have been hard hit. In this study, we describe our efforts to develop personal protective equipment at a children's hospital early in the pandemic. We convened an innovation working group to organize our efforts and respond to the rapidly changing situation. We describe our work in four areas: (1) plexiglass shields for the emergency department, (2) face shields for clinical providers, (3) breath shields for ophthalmology, and (4) flip-up safety glasses for nurses. The hospital's supply chain is now caught up with addressing many pandemic-related shortages. Nevertheless, through our multidisciplinary approach to reacting to the pandemic's urgent needs, we demonstrated agility to bring stakeholders together to maximize the use of scarce resources and build resiliency. We believe this method can be rapidly replicated as future needs arise.

Feasibility of Non-invasive Fetal Electrocardiographic Interval Measurement in the Outpatient Clinical Setting.

Non-invasive fetal electrocardiography (ECG) is a promising method for evaluating fetal cardiac electrical activity. Despite advances in fetal ECG technology, its ability to provide reliable, interpretable results in a typical outpatient fetal cardiology setting remains unclear. We sought to determine the feasibility of measuring standard ECG intervals in an outpatient fetal cardiology practice using an abdominal fetal ECG device that employs blind source separation with reference, an innovative signal-processing technique for fetal ECG extraction. Women scheduled for clinically indicated outpatient fetal echocardiogram underwent 10 min of fetal ECG acquisition from the maternal abdomen using specialized gel electrodes. A bedside laptop computer performed fetal ECG extraction, allowing real-time visualization of fetal and maternal ECG signals. Offline post-processing of 1 min of recorded data yielded fetal P-wave duration, PR interval, QRS duration, RR interval, QT interval, and QTc. Fifty-five fetuses were studied with gestational age 18-37 weeks, including 13 with abnormal fetal echocardiogram findings and three sets of twins. Interpretable results were obtained in 91% of fetuses, including 85% during the vernix period and 100% of twin fetuses. PR interval and RR interval of 18-24 week gestation fetuses were significantly shorter than those with gestational age 25-31 and 32-37 weeks. Of the six fetuses with abnormal rhythms on fetal echocardiogram, fetal ECG tracing was interpretable in five and matched the rhythm noted on fetal echocardiogram. Abdominal fetal ECG acquisition is feasible for arrhythmia detection and ECG interval calculation in a routine clinical setting.

A novel surgical navigation technology for placement of implants in slipped capital femoral epiphysis.

BACKGROUND: Fixation with a single screw is the recommended treatment for slipped capital femoral epiphysis (SCFE). Achieving optimal implant positioning can be difficult owing to the complex geometry of the proximal femur in SCFE. We assessed a novel navigation technology incorporating an inertial measurement unit to facilitate implant placement in an SCFE model. METHODS: Guidewires were placed into 30 SCFE models, using a navigation system that displayed the surgeon's projected implant trajectory simultaneously in multiple planes. The accuracy and the precision of the system were assessed as was the time to perform the procedure. RESULTS: Implants were placed an average of 5.3 mm from the femoral head center, with a system precision of 0.94 mm. The actual trajectory of the implant deviated from the planned trajectory by an average of 4.9° ± 2.2°. The total average procedure time was 97 seconds. CONCLUSION: The use of computer-based navigation in a SCFE model demonstrated good accuracy and precision in terms of both implant trajectory and placement in the center of the femoral head.