Summary
Background
Electrical Cardiometry™ (EC) estimates cardiac parameters by measuring changes in thoracic electrical bioimpedance during the cardiac cycle. The ICON®, using four electrocardiogram electrodes (EKG), estimates the maximum rate of change of impedance to peak aortic blood acceleration (based on the premise that red blood cells change from random orientation during diastole (high impedance) to an aligned state during systole (low impedance)).
Objective
To determine whether continuous cardiac output (CO) data provide additional information to current anesthesia monitors that is useful to practitioners.
Methods
After IRB approval and verbal consent, 402 children were enrolled. Data were uploaded to our anesthesia record at one‐minute intervals. Ten‐second measurements (averaged over the previous 20 heart beats) were downloaded to separate files for later comparison with routine OR monitors.
Results
Data from 374 were in the final cohort (loss of signal or improper lead placement); 292 012 measurements during 58 049 min of anesthesia were made in these children (1 day to 19 years and 1 to 107 kg). Four events had a ≥25% reduction in cardiac index at least 1 min before a clinically important change in other monitored parameters; 18 events in 14 children confirmed manifestations of other hemodynamic measures; eight events may have represented artifacts because the observed measurements did not seem to fit the clinical parameters of the other monitors; three other events documented decreased stroke index with extreme tachycardia.
Conclusions
Electrical cardiometry provides real‐time cardiovascular information regarding developing hemodynamic events and successfully tracked the rapid response to interventions in children of all sizes. Intervention decisions must be based on the combined data from all monitors and the clinical situation. Our experience suggests that this type of monitor may be an important addition to real‐time hemodynamic monitoring.
Optimal perioperative analgesia for infants and children after major abdominal surgery poses a challenge when central neuraxial techniques are contraindicated. As a regional anesthesia technique, the transversus abdominis plane (TAP) block has been shown to reduce opioid consumption and improve pain scores compared to traditional perioperative pain strategies. Accordingly, TAP blocks may be considered as an alternative to central neuraxial analgesia to optimize perioperative pain control. Advancements in ultrasound technology have further improved the reliability and safety profile of this technique. Despite growing recognition of the diverse clinical scenarios where TAP blocks may be of benefit, its use among pediatric anesthesiologists remains limited. This article describes the history, anatomy, and a review of the current literature on TAP blocks with an emphasis on outcomes in pediatric patients.
Summary
Dr. John J. ‘Jack’ Downes (1930–), the anesthesiologist‐in‐chief at The Children's Hospital of Philadelphia (1972–1996), has made numerous contributions to pediatric anesthesia and critical care medicine through a broad spectrum of research on chronic respiratory failure, status asthmaticus, postoperative risks of apnea in premature infants, and home‐assisted mechanical ventilation. However, his defining moment was in January 1967, when The Children's Hospital of Philadelphia inaugurated its pediatric intensive care unit—the first of its kind in North America. During his tenure, he and his colleagues trained an entire generation of pediatric anesthesiologists and intensivists and set a standard of care and professionalism that continues to the present day. Based on an interview with Dr. Downes, this article reviews a career that advanced pediatric anesthesia and critical care medicine and describes the development of that first pediatric intensive care unit at The Children's Hospital of Philadelphia.
The history of pediatric anesthesia is fascinating in terms of how inventive anesthesiologists became over time to address the needs for advances in surgery. We have many pioneers and heroes. We hope you will enjoy this brief overview and that we have not left out any of the early contributors to our speciality. Obviously there is insufficient space to include everyone.
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