Nasal High-Flow Therapy as Primary Respiratory Support for Preterm Infants without the Need for Rescue with Nasal Continuous Positive Airway Pressure

AIM

To evaluate the effectiveness of nasal high-flow therapy (nHFT) as primary respiratory support for preterm infants with respiratory distress syndrome (RDS) in two tertiary neonatal units.

METHODS

A retrospective outcome analysis of initial respiratory support strategies was performed in two tertiary neonatal units in the UK: John Radcliffe Hospital (JRH), Oxford and St Peter's Hospital (SPH), Chertsey. Infants born between 28+0 and 36+6 weeks gestational age (GA) between May 2013 and June 2015 were included.

RESULTS

A total of 381 infants, 191 from JRH and 190 from SPH, were analysed. Infants were stabilised in the delivery room using mask continuous positive airway pressure followed by nHFT. Endotracheal intubation was performed according to local protocols, depending on the severity of RDS. There were significant differences in initial intubation rates according to GA (26% JRH vs. 16.9% SPH, p < 0.001 for babies < 32 weeks GA, and 8.2% JRH vs. 6.5% SPH, p < 0.001 for babies > 32 weeks GA); however, most infants were successfully transitioned to nHFT. Intubation rates during the first 72 h were comparable between centres (14.7% JRH vs. 11.1% SPH, p = 0.29). There were no differences in neonatal morbidities, including air leak, duration of oxygen supplementation, bronchopulmonary dysplasia, sepsis, retinopathy of prematurity, intraventricular haemorrhage, necrotising enterocolitis, or median time to full-suck feeds.

CONCLUSION

Use of nHFT for primary respiratory support, without use of nasal continuous positive airway pressure as "rescue" treatment, resulted in intubation rates lower or comparable to published data from randomised controlled trials.

Delivery of positive end-expiratory pressure to preterm lambs using common resuscitation devices

BACKGROUND

In neonatal resuscitation, a ventilation device providing positive end-expiratory pressure (PEEP) is recommended. There is limited information about PEEP delivery in vivo, using different models of self-inflating bag (SIB) at different inflation rates and PEEP settings.

METHODS

We compared PEEP delivery to intubated preterm lambs using four commonly available models of paired SIBs and PEEP valves, with a T-piece, with gas flow of 8 L/min. Peak inspiratory pressure inflations of 30 cmH₂O, combined with set PEEP of 5, 7 and 10 cmH₂O, were delivered at rates of 20, 40 and 60/min. These combinations were repeated without gas flow. We measured mean PEEP, maximum and minimum PEEP, and its difference (PEEP reduction).

RESULTS

A total of 3288 inflations were analysed. The mean PEEP delivered by all SIBs was lower than set PEEP (P<0.001), although some differences were <0.5 cmH₂O. In 55% of combinations, the presence of gas flow resulted in increased PEEP delivery (range difference 0.3-2 cmH₂O). The mean PEEP was closer to set PEEP with faster inflation rates and higher set PEEPs. The mean (SD) PEEP reduction was 3.9 (1.6), 8.2 (1.8), 2 (0.6) and 1.1 (0.6) cmH₂O with the four SIBs, whereas it was 0.5 (0.2) cmH₂O with the T-piece.

CONCLUSIONS

PEEP delivery with SIBs depends on the set PEEP, inflation rate, device model and gas flow. At recommended inflation rates of 60/min, some devices can deliver PEEP close to the set level, although the reduction in PEEP makes some SIBs potentially less effective for lung recruitment than a T-piece.

European Consensus Guidelines on the Management of Respiratory Distress Syndrome - 2019 Update

As management of respiratory distress syndrome (RDS) advances, clinicians must continually revise their current practice. We report the fourth update of "European Guidelines for the Management of RDS" by a European panel of experienced neonatologists and an expert perinatal obstetrician based on available literature up to the end of 2018. Optimising outcome for babies with RDS includes prediction of risk of preterm delivery, need for appropriate maternal transfer to a perinatal centre and timely use of antenatal steroids. Delivery room management has become more evidence-based, and protocols for lung protection including initiation of CPAP and titration of oxygen should be implemented immediately after birth. Surfactant replacement therapy is a crucial part of management of RDS, and newer protocols for its use recommend early administration and avoidance of mechanical ventilation. Methods of maintaining babies on non-invasive respiratory support have been further developed and may cause less distress and reduce chronic lung disease. As technology for delivering mechanical ventilation improves, the risk of causing lung injury should decrease, although minimising time spent on mechanical ventilation using caffeine and, if necessary, postnatal steroids are also important considerations. Protocols for optimising general care of infants with RDS are also essential with good temperature control, careful fluid and nutritional management, maintenance of perfusion and judicious use of antibiotics all being important determinants of best outcome.

Laryngeal closure impedes non-invasive ventilation at birth

BACKGROUND

Non-invasive ventilation is sometimes unable to provide the respiratory needs of very premature infants in the delivery room. While airway obstruction is thought to be the main problem, the site of obstruction is unknown. We investigated whether closure of the larynx and epiglottis is a major site of airway obstruction.

METHODS

We used phase contrast X-ray imaging to visualise laryngeal function in spontaneously breathing premature rabbits immediately after birth and at approximately 1 hour after birth. Non-invasive respiratory support was applied via a facemask and images were analysed to determine the percentage of the time the glottis and the epiglottis were open.

HYPOTHESIS

Immediately after birth, the larynx is predominantly closed, only opening briefly during a breath, making non-invasive intermittent positive pressure ventilation (iPPV) ineffective, whereas after lung aeration, the larynx is predominantly open allowing non-invasive iPPV to ventilate the lung.

RESULTS

The larynx and epiglottis were predominantly closed (open 25.5%±1.1% and 17.1%±1.6% of the time, respectively) in pups with unaerated lungs and unstable breathing patterns immediately after birth. In contrast, the larynx and the epiglottis were mostly open (90.5%±1.9% and 72.3%±2.3% of the time, respectively) in pups with aerated lungs and stable breathing patterns irrespective of time after birth.

CONCLUSION

Laryngeal closure impedes non-invasive iPPV at birth and may reduce the effectiveness of non-invasive respiratory support in premature infants immediately after birth.

The Use of Peritoneal Dialysis in Phenobarbitone Toxicity in a Critically Unwell Neonate

BACKGROUND

Phenobarbitone (PB) is the first-line anti-convulsant for neonatal seizures. The use of peritoneal dialysis (PD) to enhance drug elimination in cases of neonatal PB overdose has not been reported.

OBJECTIVE

To report a case of neonatal severe PB toxicity and review the elimination of PB by PD.

METHODS

Assessment of PD drug clearance.

RESULTS

A neonate with prolonged seizures was administered PB. Encephalopathy and myocardial failure developed, which were initially suspected to be secondary to hypoxia. At 42 h of age, the serum PB concentration was in the toxic range at 131 mg/L. Despite supportive care, the infant's condition deteriorated with escalating inotropes and the need for CPR. Enhanced PB elimination via multiple-dose activated charcoal and exchange transfusion were considered too risky. Hourly PD cycles via Tenckhoff catheter were commenced, based on reports suggesting that PD enhances PB clearance. The clinical state of the infant then improved. PD administration was continued for 60 h, recovering 20% of the estimated total PB body load. The infant survived and there were no PD complications.

CONCLUSIONS

PD increased PB clearance in this neonate, correlating with clinical recovery. Where other techniques are not possible, PD may have a role to play in enhancing PB elimination.

Devices used for stabilisation of newborn infants at birth

This review examines devices used during newborn stabilisation. Evidence for their use to optimise the thermal, respiratory and cardiovascular management in the delivery room is presented. Mechanisms of action and rationale of use are described, current developments are presented and areas of future research are highlighted.

Optimising Intravenous Volume Resuscitation of the Newborn in the Delivery Room: Practical Considerations and Gaps in Knowledge

Volume resuscitation (VR) for the treatment of newborn shock is a rare but potentially lifesaving intervention. Conducting clinical studies to assess the effectiveness of VR in the delivery room during newborn stabilization is challenging. We review the available literature and current management guidelines to determine which infants will benefit from VR, the frequency of VR, and the choice of agents used. In addition, the potential role for placental transfusion in the prevention of newborn shock is explored.

Evidence Support and Guidelines for Using Heated, Humidified, High-Flow Nasal Cannulae in Neonatology: Oxford Nasal High-Flow Therapy Meeting, 2015

Nasal high-flow therapy (nHFT) has become a popular form of noninvasive respiratory support in neonatal intensive care units. A meeting held in Oxford, UK, in June 2015 examined the evidence base and proposed a consensus statement. In summary, nHFT is effective for support of preterm infants following extubation. There is growing evidence evaluating its use in the primary treatment of respiratory distress. Further study is needed to assess which clinical conditions are most amenable to nHFT support, the most effective flow rates, and escalation and weaning strategies. Its suitability as first-line treatment needs to be further evaluated.

When should resuscitation at birth cease?

It is rare for newborn infants to require prolonged resuscitation at birth. While there are detailed national and international guidelines on when and how to provide resuscitation to newborns, there is little existing guidance on when newborn resuscitation should be stopped. In this paper we review current guidance surrounding adult, paediatric and neonatal resuscitation as well as recent evidence of outcome for newborn infants requiring prolonged resuscitation. We discuss the ethical principles that can potentially guide decisions surrounding resuscitation and post-resuscitation care. We also propose a structured approach to stopping resuscitation.

Reliability of Single-Use PEEP-Valves Attached to Self-Inflating Bags during Manual Ventilation of Neonates--An In Vitro Study

Introduction

International resuscitation guidelines suggest to use positive end-expiratory pressure (PEEP) during manual ventilation of neonates. Aim of our study was to test the reliability of self-inflating bags (SIB) with single-use PEEP valves regarding PEEP delivery and the effect of different peak inflation pressures (PIP) and ventilation rates (VR) on the delivered PEEP.

Methods

Ten new single-use PEEP valves from 5 manufacturers were tested by ventilating an intubated 1kg neonatal manikin containing a lung model with a SIB that was actuated by an electromechanical plunger device. Standard settings: PIP 20cmH₂O, VR 60/min, flow 8L/min. PEEP settings of 5 and 10cmH₂O were studied. A second test was conducted with settings of PIP 40cmH₂O and VR 40/min. The delivered PEEP was measured by a respiratory function monitor (CO₂SMO⁺).

Results

Valves from one manufacturer delivered no relevant PEEP and were excluded. The remaining valves showed a continuous decay of the delivered pressure during expiration. The median (25^th and 75^th percentile) delivered PEEP with standard settings was 3.4(2.7–3.8)cmH₂O when set to 5cmH₂O and 6.1(4.9–7.1)cmH₂O when set to 10cmH₂O. Increasing the PIP from 20 to 40 cmH₂O led to a median (25^th and 75^th percentile) decrease in PEEP to 2.3(1.8–2.7)cmH₂O and 4.3(3.2–4.8)cmH₂O; changing VR from 60 to 40/min led to a PEEP decrease to 2.8(2.1–3.3)cmH₂O and 5.0(3.5–6.2)cmH₂O for both PEEP settings.

Conclusion

Single-use PEEP valves do not reliably deliver the set PEEP. PIP and VR have an effect on the delivered PEEP. Operators should be aware of these limitations when manually ventilating neonates.

Assessing the tongue colour of newly born infants may help to predict the need for supplemental oxygen in the delivery room

AIM

It takes several minutes for infants to become pink after birth. Preductal oxygen saturation (SpO2) measurements are used to guide the delivery of supplemental oxygen to newly born infants, but pulse oximetry is not available in many parts of the world. We explored whether the pinkness of an infant's tongue provided a useful indication that supplemental oxygen was required.

METHODS

This was a prospective observational study of infants delivered by Caesarean section. Simultaneous recording of SpO2 and visual assessment of whether the tongue was pink or not was made at 1-7 and 10 min after birth.

RESULTS

The 38 midwives and seven paediatric trainees carried out 271 paired assessments on 68 infants with a mean (SD) birthweight of 3214 (545) grams and gestational age of 38 (2) weeks. When the infant did not have a pink tongue, this predicted SpO2 of <70% with a sensitivity of 26% and a specificity of 96%.

CONCLUSION

Tongue colour was a specific but insensitive sign that indicated when SpO2 was <70%. When the tongue is pink, it is likely that an infant has an SpO2 of more than 70% and does not require supplemental oxygen.

Influences of a dedicated parental training program on parent-child interaction in preterm infants

OBJECTIVE

To investigate influences on the interaction between preterm infants and their parents by a dedicated parental training program on the care of preterm infants.

METHODS

Standardized scenarios of mother-child interactions (50 mother-child dyads of very low birth weight infants (VLBWI), birth weight<1500g) were videotaped in two perinatal centers (PC-A, PC-B). The videos were reviewed and scored using a standardized instrument. In both centers, parents were integrated in the daily care by pediatric nurses, while additionally PC-A had a structured parental training program.

RESULTS

PC-A and PC-B were comparable regarding patient spectrum and number of admissions of VLBWIs/year. Both centers had similar care values with respect to the "baby friendly" initiative. No significant differences were seen in characteristics of patients (gestational age, birth weight, postnatal age) and mothers (age, parity, marital status, professions). However, in scoring the mother-child interactions significant differences were observed: In contrast to PC-B the recorded behavior in mother-child dyads of PC-A was significantly more often scored as interaction-oriented.

CONCLUSION

A dedicated, structured, and actively encouraging training program for parents of preterm infants was found to be more strongly correlated toward neurodevelopmental enhancing mother-child-interactions than an approach of merely integrating parents into daily care routine.

Unraveling the Links Between the Initiation of Ventilation and Brain Injury in Preterm Infants

The initiation of ventilation in the delivery room is one of the most important but least controlled interventions a preterm infant will face. Tidal volumes (V T) used in the neonatal intensive care unit are carefully measured and adjusted. However, the V Ts that an infant receives during resuscitation are usually unmonitored and highly variable. Inappropriate V Ts delivered to preterm infants during respiratory support substantially increase the risk of injury and inflammation to the lungs and brain. These may cause cerebral blood flow instability and initiate a cerebral inflammatory cascade. The two pathways increase the risk of brain injury and potential life-long adverse neurodevelopmental outcomes. The employment of new technologies, including respiratory function monitors, can improve and guide the optimal delivery of V Ts and reduce confounders, such as leak. Better respiratory support in the delivery room has the potential to improve both respiratory and neurological outcomes in this vulnerable population.

Techniques to ascertain correct endotracheal tube placement in neonates

BACKGROUND

The success rate of correct endotracheal tube (ETT) placement for junior medical staff is less than 50% and accidental oesophageal intubation is common. Rapid confirmation of correct tube placement is important because tube malposition is associated with serious adverse outcomes including hypoxaemia, death, pneumothorax and right upper lobe collapse.ETT position can be confirmed using chest radiography, but this is often delayed; hence, a number of rapid point-of-care methods to confirm correct tube placement have been developed. Current neonatal resuscitation guidelines advise that correct ETT placement should be confirmed by the observation of clinical signs and the detection of exhaled carbon dioxide (CO2). Even though these devices are frequently used in the delivery room to assess tube placement, they can display false-negative results. Recently, newer techniques to assess correct tube placement have emerged (e.g. respiratory function monitor), which have been claimed to be superior in the assessment of tube placement.

OBJECTIVES

To assess various techniques for the identification of correct ETT placement after oral or nasal intubation in newborn infants in either the delivery room or neonatal intensive care unit compared with chest radiography.

SEARCH METHODS

We searched the Cochrane Central Register of Controlled Trials (CENTRAL,The Cochrane Library 2012, Issue 4), MEDLINE (January 1996 to June 2014), EMBASE (January 1980 to Juen 2014) and CINAHL (January 1982 to June 2014). We searched clinical trials registers and the abstracts of the Society for Pediatric Research and the European Society for Pediatric Research from 2004 to 2014. We did not apply any language restrictions.

SELECTION CRITERIA

We planned to include randomised and quasi-randomised controlled trials and cluster trials that compared chest radiography with clinical signs, respiratory function monitors, exhaled CO2 detectors or ultrasound for the assessment of correct ETT placement either in the delivery room or the neonatal intensive care unit.

DATA COLLECTION AND ANALYSIS

Two review authors independently evaluated the search results against the selection criteria. We did not perform data extraction and 'Risk of bias' assessments because we identified no studies that met our inclusion criteria.

MAIN RESULTS

We did not identify any studies meeting the criteria for inclusion in this review.

AUTHORS' CONCLUSIONS

There is insufficient evidence to determine the most effective technique for the assessment of correct ETT placement either in the delivery room or the neonatal intensive care unit. Randomised clinical trials comparing either of these techniques with chest radiography are warranted.

Techniques to ascertain correct endotracheal tube placement in neonates

BACKGROUND

The success rate of correct endotracheal tube (ETT) placement for junior medical staff is less than 50% and accidental oesophageal intubation is common. Rapid confirmation of correct tube placement is important because tube malposition is associated with serious adverse outcomes including hypoxaemia, death, pneumothorax and right upper lobe collapse.ETT position can be confirmed using chest radiography, but this is often delayed; hence, a number of rapid point-of-care methods to confirm correct tube placement have been developed. Current neonatal resuscitation guidelines advise that correct ETT placement should be confirmed by the observation of clinical signs and the detection of exhaled carbon dioxide (CO2). Even though these devices are frequently used in the delivery room to assess tube placement, they can display false-negative results. Recently, newer techniques to assess correct tube placement have emerged (e.g. respiratory function monitor), which have been claimed to be superior in the assessment of tube placement.

OBJECTIVES

To assess various techniques for the identification of correct ETT placement after oral or nasal intubation in newborn infants in either the delivery room or neonatal intensive care unit compared with chest radiography.

SEARCH METHODS

We searched the Cochrane Central Register of Controlled Trials (CENTRAL,The Cochrane Library 2012, Issue 4), MEDLINE (January 1996 to June 2014), EMBASE (January 1980 to Juen 2014) and CINAHL (January 1982 to June 2014). We searched clinical trials registers and the abstracts of the Society for Pediatric Research and the European Society for Pediatric Research from 2004 to 2014. We did not apply any language restrictions.

SELECTION CRITERIA

We planned to include randomised and quasi-randomised controlled trials and cluster trials that compared chest radiography with clinical signs, respiratory function monitors, exhaled CO2 detectors or ultrasound for the assessment of correct ETT placement either in the delivery room or the neonatal intensive care unit.

DATA COLLECTION AND ANALYSIS

Two review authors independently evaluated the search results against the selection criteria. We did not perform data extraction and 'Risk of bias' assessments because we identified no studies that met our inclusion criteria.

MAIN RESULTS

We did not identify any studies meeting the criteria for inclusion in this review.

AUTHORS' CONCLUSIONS

There is insufficient evidence to determine the most effective technique for the assessment of correct ETT placement either in the delivery room or the neonatal intensive care unit. Randomised clinical trials comparing either of these techniques with chest radiography are warranted.

Accuracy of a disposable compared to a non-disposable infant T-piece resuscitator

Both disposable and non-disposable T-piece resuscitator (TPR) devices are used. Accuracy of the disposable and non-disposable infant TPR was compared. Peak inspiratory pressures (PIP) and positive end-expiratory pressures (PEEP) were measured during ventilation of a test lung. Measured PIP ±1 cmH2O and PEEP ±0.5 cmH2O of the desired pressures were considered acceptable. We tested the following: (A) Accuracy of setting pressures using built-in manometers of three disposable TPRs, (B) Minimal and maximal PIP and PEEP levels for the non-disposable and disposable TPR were measured using different gas flow rates, and (C) Accuracy of 25 caregivers setting pressures (PIP 25 cmH2O and PEEP 5 cmH2O). The results of the tests performed were as follows: (A) With pressures set: PIP 20, 25, 30, and 40 cmH2O and PEEP 5-8 cmH2O with 1 cmH2O stepwise increment, measured PIPs and PEEPs were in acceptable range. (B) At gas flow rates 5, 8, 10, and 15 L/min (disposable vs. non-disposable), min-max PIP were 4.0-43.2 vs. 2.9-77.1 cmH2O and min-max PEEP were 0.3-22.3 and 0.6-59.7 cmH2O. (C) Set PIP (cmH2O) by participants using disposable vs. non-disposable TPR was 25.8 (0.8) vs. 25.9 (1.3) (ns). PEEP was 5.4(0.5) vs. 4.7(0.5); p < 0.001.

CONCLUSION

The accuracy of the disposable TPR is comparable to that of the non-disposable TPR.

Dead space reduction by Kolobow's endotracheal tube does not justify the waiving of volume monitoring in small, ventilated lungs

In ventilated preterm infants the flow sensor contributes significantly to the total apparatus dead space, which may impair gas exchange. The aim of the study was to quantify to which extent a dead space reduced Kolobow tube (KB) without flow sensor improves the gas exchange compared with a conventional ventilator circuit with flow sensor [Babylog 8000 (BL)]. In a cross-over trial in 14 tracheotomized, surfactant-depleted (saline lavage) and mechanically ventilated newborn piglets (age <12 h; body weight 705-1200 g) BL and KB was applied alternately for 15 min and blood gases were recorded. The inner diameter of the endotracheal tube was 3.6 mm and the apparatus dead space of BL and KB including the endotracheal tube were 3.0 and 1.34 mL. Despite a 50 % apparatus dead space reduction with KB compared to BL statistically significant improvements were only observed for body weights <900 g. In this weight group median paCO2 was decreased by 5 mmHg (p < 0.01), whereas the improvement decreased with decreasing baseline paCO2. Furthermore, median paO2 was increased by 4 mmHg (p < 0.05) and O2 saturation was increased by 2.5 % (p < 0.05). No significant changes were seen in the circulatory parameters. In very small, ventilated lungs the use of KB improved the gas exchange; however, the improvement was moderate and does not justify the waiving of volume monitoring.

Differential effects of immaturity and neonatal lung disease on the lung function of very low birth weight infants at 48-52 postconceptional weeks

BACKGROUND

The pathogenesis of chronic lung disease of prematurity involves maturational arrest and neonatal lung disease (NLD) followed by mechanical ventilation (MV). However, the effect of these factors on postnatal lung function is not well established. Therefore, the aim of this study was to examine the differential effects of immaturity and NLD requiring MV on lung function test (LFT) parameters within 4 months after discharge.

PATIENTS AND METHODS

A total of 386 very low birth weight (VLBW) infants (birth weight <1,500 g) were examined at a median postmenstrual age of 49 weeks. Two hundred twenty-six infants (59%) were born before the 28th week of gestation, and 247 infants (64%) had NLD requiring invasive MV. LFTs included tidal breathing measurements, measurement of respiratory mechanics assessed by occlusion test, body plethysmography, SF6 multiple breath washout, forced expiratory flow (VmaxFRC') by rapid thoraco-abdominal compression technique, end-expiratory CO2 (Pet CO2 ), exhaled NO (FeNO), and arterialized capillary blood gas analysis.

MAIN RESULTS

Multivariate analysis indicated that severe immaturity was mainly associated with changes in the breathing pattern (reduced tidal volume (P = 0.003) and increased respiratory rate (P = 0.03)), a reduced VmaxFRC' (P = 0.004) and lower respiratory compliance (P < 0.001). NLD requiring MV, but not immaturity, was significantly and independently associated with increased respiratory and airway resistances (both P = 0.003), reduced FRCSF6 (P = 0.03), increased Pet CO2 (P = 0.019) and lower FeNO (P < 0.001). Both immaturity and NLD requiring MV caused a lower paO2 (P < 0.001) and higher a paCO2 .

CONCLUSIONS

Lung function after discharge of VLBW infants is differentially affected by both immaturity and NLD requiring MV. With increasing prematurity, intubated and mechanically ventilated infants are at increased risk of developing impaired lung function which can be detected by LFT.

[Google translate is not sufficient to overcome language barriers in neonatal medicine]

Language barriers hinder the interaction with patients and relatives. The use of language services increases knowledge, satisfaction and the use of medical care and thus improves patient's clinical outcome. The recommended use of professional interpreters (PI) is not always feasible. We tested an online translation tool as an alternative for PI for the transla-tion of standardized sentences from a neonatal doctor-/nurse-relative-interview.Translation of 20 sentences from a German neonatal intensive care unit parent information brochure to English, Portuguese and Arabic, using Google Translate (GT). Assessment of accuracy concerning grammar and content, in a second step simplification of all incorrect sentences, translation by GT and critical re-assessment and evaluation.An average of 42% of the sentences was correctly translated concerning grammar and content. The proportion of incorrectly translated sentences varied between 45-70%. By simpli-fication another 23% were translated correctly.Translations by GT were often incorrect in content and grammar. We suppose that the design of GT, which is a statistical translation engine, might be an explanation for this phenomenon. Presently, GT cannot guarantee unambiguous translations and cannot substitute PIs, only in particular circumstances, the use of GT or similar engines may be justified. For future use of electronic translation services, we suggest to compile a catalogue of sentences containing central information, which can be translated into defined foreign languages without misinterpretation or loss of information.

Investigating the European perspective of neonatal point-of-care echocardiography in the neonatal intensive care unit--a pilot study

Point-of-care functional neonatal echocardiography (fnECHO) is increasingly used to assess haemodynamic status or patency of the ductus arteriosus (PDA). In Australasia, 90 % of neonatal intensive care units (NICUs) practice point-of-care fnECHO. The Australian Society of Ultrasound Medicine offers a training certificate for fnECHO. In Europe, the use and indications of fnECHO and the extent of point-of-care fnECHO training and accreditation are unknown. We aimed to assess utilisation and training of fnECHO in Europe. For this, we conducted an email survey of 45 randomly chosen tertiary NICUs in 17 European countries. The recall rate was 89 % (n = 40). Neonatologists with skills in fnECHO worked in 29 NICUs (74 %), but paediatric cardiologists would routinely perform most fnECHOs. Twenty-four-hour echocardiography service was available in 31 NICUs (78 %). Indications for fnECHO included assessment of haemodynamic volume status (53 %), presence or absence of pulmonary hypertension of the neonate (55 %), indication for and effect of volume replacement therapy (58 %), PDA assessment and monitoring of PDA treatment (80 %). Teaching of fnECHO was offered to trainees in 22 NICUs (55 %). Teaching of fnECHO was provided by paediatric cardiologists (55 %) or by neonatologists (45 %). Only six (15 %) national colleges accredited fnECHO teaching courses.

CONCLUSION

fnECHO is widely practiced by neonatologists across Europe for a broad range of clinical questions. However, there is a lack of formal training and accreditation of fnECHO skills. This could be addressed by designing a dedicated European fnECHO training programme and by agreeing on a common European certificate of fnECHO.

Do we deliver the pressures we intend to when using a T-piece resuscitator?

Background

A T-piece resuscitator (TPR) uses a built-in manometer to set the inflation pressures, but we are not informed what pressures are actually delivered distally. Aim of this study was to measure the proximal and distal pressures under different gas conditions when using a TPR.

Methodology/Findings

A test lung was ventilated using a TPR (PIP 25 cmH₂O, PEEP 5 cmH₂O) with a gas flow rate of 8 L/min. A) Pressure delivered by six different TPRs was tested. To test variability 20 participants were asked to set PEEP and PIP pressures to 25/5 cmH₂O. B) PIP and PEEP were measured proximal and distal of the TPR when using standard tubing or heated tubing with or without a humidifier. In experiment A mean (SD) proximal PIP and PEEP of the TPRs were respectively 20.3 (0.3) cmH₂O (19.9–20.6 cmH₂O) and 4.9 (0.1) cmH₂O. When 20 participants set pressures; PIP 26.7 (0.5) cm H₂O and PEEP 5.9 (0.44) cmH₂O were measured. Experiment B showed that the decrease of PIP between proximal and distal pressures was not clinically significant. However there was a significant decrease of PEEP using the standard tubing (5.1 (0.1) cmH₂O proximally versus 4.8 (0.2) cmH₂O distally; p<0.001) compared to, when using a humidifier with associated tubing and the humidifier turned on, 5.1 (0.1) proximally versus 3.9 (0.2) cmH₂O distally; (p<0.001).

Conclusion/Significance

The accuracy of the built-in manometer of a TPR is acceptable. Most pressures set proximally are comparable to the actual pressures delivered distally. However, when using tubing associated with the humidifier PEEP decreases distally by 1.1–1.2 cmH₂O and users should anticipate on this.

Pathophysiology of neonatal transition and meaningful measures for the initial stabilisation of extremely premature neonates

This report discusses the physiological aspects of neonatal transition from breathing liquid to air. Further, we discuss reasonable medical interventions to actively assist a gentle transition, and focus on team aspects of preparing both the perinatal team and parents for the challenging situation of preterm labour and delivery. Our aim is to critically evaluate current concepts on the physiology of neonatal transition and the current assessment of the newborn infant, to present means to facilitate non-traumatic pulmonary aeration and ways to foster successful teamwork and professional parental guidance in the delivery room. The authors report on their own work and on that of other research groups, as recently published in peer reviewed medical journals. When born, the newborn needs to rapidly clear his/her lungs from fluid to establish breathing. Active fluid transport and passive resorption help to establish the pulmonary functional residual capacity (FRC). Prenatal administration of corticosteroids helps to form and maintain the FRC of the newborn. Many very low gestational age neonates (ELGAN) will breathe at birth but require medical assistance. This is best done by giving distending positive airway pressure at levels of 5 cmH(2)O, or greater. Monitoring of these infants should be by peripheral pulse oximetry. Some ELGANs may require non-invasive ventilation and/or exogenous Surfactant replacement, and even fewer may require intubation and mechanical ventilation. The obstetric and neonatal teams need to coordinate their joined efforts to secure a safe delivery for mother and child. Ways of communication between teams and parents are presented. Many neonatal teams use video recording as a tool to assess and improve their work. We give insights into the use of video as a means to improve teamwork and patient care alike.