Early detection of cold stress to prevent hypothermia: A narrative review.

Temperature monitoring is essential for assessing neonates and providing appropriate neonatal thermal care. Thermoneutrality is defined as the environmental temperature range within which the oxygen and metabolic consumptions are minimum to maintain normal body temperature. When neonates are in an environment below thermoneutral temperature, they respond by vasoconstriction to minimise heat losses, followed by a rise in metabolic rate to increase heat production. This condition, physiologically termed cold stress, usually occurs before hypothermia. In addition to standard axillary or rectal temperature monitoring by a thermometer, cold stress can be detected by monitoring peripheral hand or foot temperature, even by hand-touch. However, this simple method remains undervalued and generally recommended only as a second and lesser choice in clinical practice. This review presents the concepts of thermoneutrality and cold stress and highlights the importance of early detection of cold stress before hypothermia occurs. The authors suggest systematic clinical determination of hand and foot temperatures by hand-touch for early detection of physiological cold stress, in addition to monitoring core temperature for detection of established hypothermia, particularly in low-resource settings.

Incidence and Causes of Infusion Alarms in a Neonatal and Pediatric Intensive Care Unit: A Prospective Pilot Study.

OBJECTIVES: To evaluate the incidence and causes of infusion alarms in a NICU/PICU setting. METHODS: We conducted a 90-day prospective analysis of event logs downloaded daily from infusion pumps (syringe and volumetric pumps). The details about conditions surrounding alarm events were described daily by bedside nurses on a standardized form. The occlusion pressure alarm was set at 300 mm Hg on each device. RESULTS: Forty-one pediatric patients including 12 neonates, mean weight 11.0 ± 11.3 kg (minimum-maximum, 0.48-50), were included for a total infusion time of 2164 hours. Eight hundred forty-three infusion alarms were documented (220 [26.1%] occlusion; 273 [32.4%] infusion completed; 324 [38.4%] door open/syringe disengagement; 26 [3.1%] air-in-line) resulting in an incidence of 4.7 infusion (1.2 occlusion) alarms per patient per day.Detailed conditions surrounding occlusion alarm events were documented in only 22.7% (50/220) of the cases. Of these, 36% (18/50) were related to closed or clamped lines, 4% (2/50) to syringe change, 16% (8/50) to drug injection, and 8% (4/50) to patient-related factors. The remaining 36% (18/50) occurred without any apparent external cause during ongoing infusion, among these drug incompatibilities were a potential cause for 12 events. CONCLUSION: Alarms from infusion pumps were frequent in the NICU/PICU setting, a quarter of them resulting from line occlusion. Other than well-known triggers (mechanical and patient factors), drug incompatibilities were identified as a potential cause for occlusion alarms in this pilot study.

[Improve the extravasation assessment of peripheral venous catheter by nurses, with the establishment of a standardized instrument and suitable for children] / Amélioration de la mesure d'extravasation des cathéters veineux périphériques par les infirmières en pédiatrie, grâce à l'utilisation d'un instrument d'évaluation spécifique.

In pediatric and neonatal intensive care units, severity assessment of extravasation is difficult, considering the specificity of this population. The purpose of this study was to demonstrate the ability to improve the measurement of extravasation by nurses with the establishment of a standardized instrument and suitable for children. 66 nurses, randomly assigned to two groups, assessed the severity of extravasations using 15 clinical vignettes.The intervention group with the Pediatric Peripheral Intravenous Infiltration Scale (PIV Scale) (n=33) and the control group based on clinical judgment only (n=33). The reference were obtained from a group of experts. For both groups, concordance and sensitivity were calculated. Concordance and sensitivity were improved by the use of the PIV scale κ=0,62 (IC 95% ; 0,57-0,67) vs κ=0,51 (IC 95 % ; 0,45-0,57), and (69 %) vs (60 %) (p<0,001), respectively. Severity assessment of extravasation on peripheral venous accesses by nurses was improved with the use of the PIV scale, compared to clinical judgment. As this study was based on clinical vignettes, further studies are needed to confirm these results in clinical setting.

Patient-ventilator asynchrony during noninvasive pressure support ventilation and neurally adjusted ventilatory assist in infants and children.

OBJECTIVES: To document the prevalence of asynchrony events during noninvasive ventilation in pressure support in infants and in children and to compare the results with neurally adjusted ventilatory assist. DESIGN: Prospective randomized cross-over study in children undergoing noninvasive ventilation. SETTING: The study was performed in a PICU. PATIENTS: From 4 weeks to 5 years. INTERVENTIONS: Two consecutive ventilation periods (pressure support and neurally adjusted ventilatory assist) were applied in random order. During pressure support (PS), three levels of expiratory trigger (ETS) setting were compared: initial ETS (PSinit), and ETS value decreased and increased by 15%. Of the three sessions, the period allowing for the lowest number of asynchrony events was defined as PSbest. Neurally adjusted ventilator assist level was adjusted to match the maximum airway pressure during PSinit. Positive end-expiratory pressure was the same during pressure support and neurally adjusted ventilator assist. Asynchrony events, trigger delay, and cycling-off delay were quantified for each period. RESULTS: Six infants and children were studied. Trigger delay was lower with neurally adjusted ventilator assist versus PSinit and PSbest (61 ms [56-79] vs 149 ms [134-180] and 146 ms [101-162]; p = 0.001 and 0.02, respectively). Inspiratory time in excess showed a trend to be shorter during pressure support versus neurally adjusted ventilator assist. Main asynchrony events during PSinit were autotriggering (4.8/min [1.7-12]), ineffective efforts (9.9/min [1.7-18]), and premature cycling (6.3/min [3.2-18.7]). Premature cycling (3.4/min [1.1-7.7]) was less frequent during PSbest versus PSinit (p = 0.059). The asynchrony index was significantly lower during PSbest versus PSinit (40% [28-65] vs 65.5% [42-76], p < 0.001). With neurally adjusted ventilator assist, all types of asynchronies except double triggering were reduced. The asynchrony index was lower with neurally adjusted ventilator assist (2.3% [0.7-5] vs PSinit and PSbest, p < 0.05 for both comparisons). CONCLUSION: Asynchrony events are frequent during noninvasive ventilation with pressure support in infants and in children despite adjusting the cycling-off criterion. Compared with pressure support, neurally adjusted ventilator assist allows improving patient-ventilator synchrony by reducing trigger delay and the number of asynchrony events. Further studies should determine the clinical impact of these findings.

Optimizing patient-ventilator synchrony during invasive ventilator assist in children and infants remains a difficult task*.

OBJECTIVES: To document and compare the prevalence of asynchrony events during invasive-assisted mechanical ventilation in pressure support mode and in neurally adjusted ventilatory assist in children. DESIGN: Prospective, randomized, and crossover study. SETTING: Pediatric and Neonatal Intensive Care Unit, University Hospital of Geneva, Switzerland. PATIENTS: Intubated and mechanically ventilated children, between 4 weeks and 5 years old. INTERVENTIONS: Two consecutive ventilation periods (pressure support and neurally adjusted ventilatory assist) were applied in random order. During pressure support, three levels of expiratory trigger setting were compared: expiratory trigger setting as set by the clinician in charge (PSinit), followed by a 10% (in absolute values) increase and decrease of the clinician's expiratory trigger setting. The pressure support session with the least number of asynchrony events was defined as PSbest. Therefore, three periods were compared: PSinit, PSbest, and neurally adjusted ventilatory assist. Asynchrony events, trigger delay, and inspiratory time in excess were quantified for each of them. MEASUREMENTS AND MAIN RESULTS: Data from 19 children were analyzed. Main asynchrony events during PSinit were autotriggering (3.6 events/min [0.7-8.2]), ineffective efforts (1.2/min [0.6-5]), and premature cycling (3.5/min [1.3-4.9]). Their number was significantly reduced with PSbest: autotriggering 1.6/min (0.2-4.9), ineffective efforts 0.7/min (0-2.6), and premature cycling 2/min (0.1-3.1), p < 0.005 for each comparison. The median asynchrony index (total number of asynchronies/triggered and not triggered breaths ×100) was significantly different between PSinit and PSbest: 37.3% [19-47%] and 29% [24-43%], respectively, p < 0.005). With neurally adjusted ventilatory assist, all types of asynchrony events except double-triggering and inspiratory time in excess were significantly reduced resulting in an asynchrony index of 3.8% (2.4-15%) (p < 0.005 compared to PSbest). CONCLUSIONS: Asynchrony events are frequent during pressure support in children despite adjusting the cycling off criteria. Neurally adjusted ventilatory assist allowed for an almost ten-fold reduction in asynchrony events. Further studies should determine the clinical impact of these findings.