Clinical applications of photoplethysmography in paediatric intensive care

Objective: The photoplethysmographic wave is displayed by most pulse oximeters. It may be used as anon-invasive alternative to invasive arterial blood pressure trace analysis for continuous haemodynamic monitoring in selected situations. Patients and setting: Four cardiac patients treated in atertiary neonatal-paediatric intensive care unit. Measurements: Simultaneous monitoring of the photoplethysmographic wave, ECG, and invasive blood pressure. Results and conclusions: Photoplethysmography allows for monitoring pulse rate in patients with (possible) heart rate/pulse rate dissociation (pacemaker dependency, pulsatile ventricular assist device); monitoring sudden changes in heart beat volume, which are unrelated to respiration (pulseless electrical activity, pulsus alternans); and monitoring respiratory-dependent fluctuations of the plethysmographic wave (heart failure, hypovolaemia, asthma, upper airway obstruction, pericardial effusion). Deterioration, slowly evolving over time, may be detected by this metho

Antithrombin activity in children with chylothorax

Objective: To determine whether increased antithrombin loss is present in children with chylothorax after cardiac surgery. Methods: Plasma and pleural effusion samples of children with chylous and non-chylous pleural effusion were assayed for antithrombin activity. Results: Ten children with chylothorax and five children with non-chylous pleural effusion were investigated. There was statistically significant increase in mean antithrombin activity in chylous samples (32.2 ± 11.4%) compared to non-chylous samples (14.4 ± 13.9%), and significant decrease in plasma of children with chylothorax (44.6 ± 15.4%) compared to children with non-chylous pleural effusion (69.9 ± 22.4%). Seven of 10 children with chylous and none of the children without chylous developed thrombosis (p < 0.007). Conclusions: Increased loss of antithrombin is present in children with chylothorax, potentially predisposing these children to an increased risk of thrombosis. Repeated antithrombin substitution should be considered in critically ill children with chylothora

Three Consecutive Outbreaks of Serratia marcescens in a Neonatal Intensive Care Unit

We investigated an outbreak of Serratia marcescens in the neonatal intensive care unit (NICU) of the University Hospital of Zurich. S. marcescens infection was detected in 4 children transferred from the NICU to the University Children's Hospital (Zurich). All isolates showed identical banding patterns by pulsed-field gel electrophoresis (PFGE). In a prevalence survey, 11 of 20 neonates were found to be colonized. S. marcescens was isolated from bottles of liquid theophylline. Despite replacement of these bottles, S. marcescens colonization was detected in additional patients. Prospective collection of stool and gastric aspirate specimens revealed that colonization occurred in some babies within 24 hours after delivery. These isolates showed a different genotype. Cultures of milk from used milk bottles yielded S. marcescens. These isolates showed a third genotype. The method of reprocessing bottles was changed to thermal disinfection. In follow-up prevalence studies, 0 of 29 neonates were found to be colonized by S. marcescens. In summary, 3 consecutive outbreaks caused by 3 genetically unrelated clones of S. marcescens could be documented. Contaminated milk could be identified as the source of at least the third outbrea

Clinical applications of photoplethysmography in paediatric intensive care

Objective: The photoplethysmographic wave is displayed by most pulse oximeters. It may be used as a non-invasive alternative to invasive arterial blood pressure trace analysis for continuous haemodynamic monitoring in selected situations. Patients and setting: Four cardiac patients treated in a tertiary neonatal-paediatric intensive care unit. Measurements: Simultaneous monitoring of the photoplethysmographic wave, ECG, and invasive blood pressure. Results and conclusions: Photoplethysmography allows for monitoring pulse rate in patients with (possible) heart rate/pulse rate dissociation (pacemaker dependency, pulsatile ventricular assist device); monitoring sudden changes in heart beat volume, which are unrelated to respiration (pulseless electrical activity, pulsus alternans); and monitoring respiratory-dependent fluctuations of the plethysmographic wave (heart failure, hypovolaemia, asthma, upper airway obstruction, pericardial effusion). Deterioration, slowly evolving over time, may be detected by this method

Age, sex and diagnoses of included patients.

<p>Age, sex and diagnoses of included patients.</p

Questionnaires.

<p>Questionnaires.</p

List of questions, method of data collection and data format.

<p>List of questions, method of data collection and data format.</p