The therapeutic value of atropine for critical care intubation

Airway Management of Critically Ill Pediatric Patients with Suspected or Proven Coronavirus Disease 2019 Infection: An Intensivist Point of View

Advanced airway management of critically ill children is crucial for novel coronavirus disease 2019 (COVID-19) management in the pediatric intensive care unit, whether due to shock and hemodynamic collapse or acute respiratory failure. In this article, intubation is challenging due to the particularities of children's physiology and the underlying disease's pathophysiology, especially when an airborne pathogen, like COVID-19, is present. Unfortunately, published recommendations and guidelines for COVID-19 in pediatrics do not address in-depth endotracheal intubation in acutely ill children. We discussed the caveats and pitfalls of intubation in critically ill children.

[Paediatric Life Support]

The European Resuscitation Council (ERC) Paediatric Life Support (PLS) guidelines are based on the 2020 International Consensus on Cardiopulmonary Resuscitation Science with Treatment Recommendations of the International Liaison Committee on Resuscitation (ILCOR). This section provides guidelines on the management of critically ill or injured infants, children and adolescents before, during and after respiratory/cardiac arrest.

European Resuscitation Council Guidelines 2021: Paediatric Life Support

These European Resuscitation Council Paediatric Life Support (PLS) guidelines, are based on the 2020 International Consensus on Cardiopulmonary Resuscitation Science with Treatment Recommendations. This section provides guidelines on the management of critically ill infants and children, before, during and after cardiac arrest.

Premedication practices for tracheal intubation in neonates transported by French medical transport teams: a prospective observational study

OBJECTIVES

Premedication practices for neonatal tracheal intubations have not yet been described for neonatal transport teams. Our objective is to describe the use of sedation/analgesia (SA) for tracheal intubations and to assess its tolerance in neonates transported by medical transport teams in France.

SETTING

This prospective observational study was part of the EPIPPAIN 2 project and collected around-the-clock data on SA practices in neonates intubated by all five paediatric medical transport teams of the Paris region during a 2-month period. Intubations were classified as emergent, semiemergent and non-emergent. Sedation level and conditions of intubation were assessed with the Tonus, Reactivity, Awareness and Conditions of intubation to Help in Endotracheal intubation Assessment (TRACHEA score). The scores range from 0 to 10 representing an increasing ladder from adequate to inadequate sedation, and from excellent to very poor conditions of intubation.

PARTICIPANTS

40 neonates intubated in 28 different centres.

RESULTS

The mean (SD) age was 34.9 (3.9) weeks, and 62.5% were intubated in the delivery room. 30/40 (75%) of intubations were performed with the use of SA. In 18/30 (60.0%) intubations performed with SA, the drug regimen was the association of sufentanil and midazolam. Atropine was given in 19/40 intubations. From the 16, 21 and 3 intubations classified as emergent, semiemergent and non-emergent, respectively, 8 (50%), 19 (90.5%) and 3 (100%) were performed with SA premedication. 79.3% of intubations performed with SA had TRACHEA scores of 3 or less. 22/40 (55%) infants had at least one of the following adverse events: muscle rigidity, bradycardia below 100/min, desaturation below 80% and nose or pharynx-larynx bleeding. 7/24 (29.2%) of those who had only one attempt presented at least one of these adverse events compared with 15/16 (93.8%) of those who needed two or more attempts (p<0.001).

CONCLUSION

SA premedication is largely feasible for tracheal intubations performed in neonates transported by medical transport teams including intubations judged as emergent or semiemergent.

TRIAL REGISTRATION NUMBER

NCT01346813; Results.

Premedication for Endotracheal Intubation in the Neonate

Endotracheal intubation, a common procedure in neonatal intensive care, results in distress and disturbs physiologic homeostasis in the newborn. Analgesics, sedatives, vagolytics, and/or muscle relaxants have the potential to blunt these adverse effects, reduce the duration of the procedure, and minimize the number of attempts necessary to intubate the neonate. The medical care team must understand efficacy, safety, and pharmacokinetic data for individual medications to select the optimal cocktail for each clinical situation. Although many units utilize morphine for analgesia, remifentanil has a superior pharmacokinetic profile and efficacy data. Because of hypotensive effects in preterm neonates, sedation with midazolam should be restricted to near-term and term neonates. A vagolytic, generally atropine, blunts bradycardia induced by vagal stimulation. A muscle relaxant improves procedural success when utilized by experienced practitioners; succinylcholine has an optimal pharmacokinetic profile, but potentially concerning adverse effects; rocuronium may be the agent of choice based on more robust safety data despite a relatively prolonged duration of action. In the absence of an absolute contraindication, neonates should receive analgesia with consideration of sedation, a vagolytic, and a muscle relaxant before endotracheal intubation. Neonatal units must develop protocols for premedication and optimize logistics to ensure safe and timely administration of appropriate agents.

Atropine augments cardiac contractility by inhibiting cAMP-specific phosphodiesterase type 4

Atropine is a clinically relevant anticholinergic drug, which blocks inhibitory effects of the parasympathetic neurotransmitter acetylcholine on heart rate leading to tachycardia. However, many cardiac effects of atropine cannot be adequately explained solely by its antagonism at muscarinic receptors. In isolated mouse ventricular cardiomyocytes expressing a Förster resonance energy transfer (FRET)-based cAMP biosensor, we confirmed that atropine inhibited acetylcholine-induced decreases in cAMP. Unexpectedly, even in the absence of acetylcholine, after G-protein inactivation with pertussis toxin or in myocytes from M₂- or M_1/3-muscarinic receptor knockout mice, atropine increased cAMP levels that were pre-elevated with the β-adrenergic agonist isoproterenol. Using the FRET approach and in vitro phosphodiesterase (PDE) activity assays, we show that atropine acts as an allosteric PDE type 4 (PDE4) inhibitor. In human atrial myocardium and in both intact wildtype and M₂ or M_1/3-receptor knockout mouse Langendorff hearts, atropine led to increased contractility and heart rates, respectively. In vivo, the atropine-dependent prolongation of heart rate increase was blunted in PDE4D but not in wildtype or PDE4B knockout mice. We propose that inhibition of PDE4 by atropine accounts, at least in part, for the induction of tachycardia and the arrhythmogenic potency of this drug.