The first records about airway approach were found in Egyptian tablets dating back to 3600 b.c. illustrating sketches of what seemed to be a tracheostomy. Over three thousand years later, Alexander the Great saved one of his soldiers from asphyxia by making a small tracheal incision with the tip of his spade. In 1858, Eugene Bouchut, a French pediatrician, developed a non-surgical blind orotracheal intubation technique: he developed a metal tube to enable breathing and prevent the obstruction of the pseudomembranes caused by diphtheria in the larynx. His technique was introduced at the Conference of the French Academy of Sciences in September 18, 1858 and was strongly opposed by the French surgeon Armand Trousseau, who promoted tracheostomy for airway obstruction. Trousseau was the first surgeon to perform tracheostomies in Paris and who wrote a treaty encouraging its use.1

The goal of this paper is to review the current status of knowledge related to rapid sequence intubation in patients in the Intensive Care Unit, and to summarize what needs to be done in order to reduce risks during intubation of a critically ill patient to the greatest extent possible. A thematic review was done in the PubMed, ScienceDirect, EBSCOhost, OvidSP and Scielo databases, without limiting the search by date, either in English or Spanish. The search included clinical trials, meta-analyses, practice guidelines, randomized clinical trials, reviews, case reports, classic articles, comparative studies, consensus conferences and lectures. Published articles on intubation, rapid sequence intubation and ICU intubation that focused on the approach to the airway with orotracheal tube in critically ill patients and the strategies for optimizing the maneuver, were included. The search resulted in 1,144 studies (Fig. 1). The abstracts were reviewed and the core criteria of the review were used for the final selection, namely, intubation protocols for ICU patients. Fifty essays fulfilled the selection criteria (Table 1). The results are summarized, and a modified rapid sequence intubation sequence is proposed on the basis of the review.

Fig. 1.

Search strategy flowchart.

(0,17MB).

Prior to the advent of the modern laryngoscope, the only way to visualize the larynx was through indirect techniques: the Spanish singing professor Manuel García (1805–1868) used mirrors to observe his glottis and the glottis of his students during vocalization.2 Around 1877, Friedrich von Esmarch popularized the mandibular subluxation maneuver for patency of the airway, as we actually know it.3 In 1895 Alfred Kirstein suggested that the larynx could be visualized through instruments similar to the esophagoscope4; three years later, Gustav Killian developed a laryngoscope similar to those currently used,5 and it became widely used to met the need of ensuring patency for the inflow of air into the lungs due to the increasing use of muscle relaxants.

The rapid sequence intubation (RSI) is a technique developed to rapidly secure the airway, maximally reducing the time interval between the loss of the airway protective reflexes and the oro/nasotracheal intubation. Its importance lies in providing a safe intubation in patients at high risk of bronchoaspiration.

In 2010 Jaber et al.6 published a study using a “before-after” model to compare the results of implementing an intubation protocol for ICU patients. The main complications of intubation – cardiovascular collapse and hypoxemia – were cut in half in the intervention group. According to the research it can be concluded that the protocols, conceived as orderly and sequential actions, as is the case in cardiovascular resuscitation, also improve morbi-mortality of the critical patient requiring intubation. Its protocol includes 10 steps (Table 2).

We shall now review the levels of evidence for each one of these recommendations.

The short time available in the ICU and the critical scenario make it difficult to properly assess the airway. The presence of a senior physician next to the person doing the intubation has proven to reduce the complications associated with the procedure: esophageal intubation (0.9% vs. 3.4%), traumatic intubation (1.7% vs. 6.8%), bronchoaspiration (0.9% vs. 5.8%), teeth damage (0% vs. 1.0%) and selective intubation (2.6% vs. 7.2%). The global rate of complications also decreased significantly (6.1% vs. 21.7%, p<0.0001).7

There is no evidence to date of the administration of a fluid bolus prior to intubation; however, it is logical to think that this could be beneficial for the critical patient pre-intubation – except for patients with cardiogenic pulmonary edema – due to the following reasons: (1) usually the patient is hypovolemic and (2) anesthetic agents block the sympathetic response that maintains the hemodynamic variables against hypotensive stimuli; and (3) mechanical ventilation reduces the cardiac output when compromising the preload.8

During pre-oxygenation, the nitrogen contained in the pulmonary alveoli is exchanged by oxygen, providing the patient with an additional oxygen reserve; hence, maneuvers such as laryngoscopy and intubation may be done avoiding deoxygenation. 100% oxygen is supplied through the face mask: if the patient's awareness permits, he/she is asked to breath deeply for ninety seconds or, oxygen is passively supplied for three minutes.9

It has been usually argued that during RSI positive pressure ventilation (PPV) should be avoided because gastric insufflation favors bronchoaspiration.10 However, after August 19, 1961 when Sellick published his famous cricoid pressure maneuver to avoid regurgitation of the gastric contents during the induction of anesthesia, the recommendations state in a footnote that experienced practitioners may administer PPV, if the inspiratory pressure does not exceed 20cm H2O.11,12 Moreover, there are certain cases in which PPV prior to intubation, within the context of RSI, is strongly recommended: obese patient, pregnant women, pediatric patient and critically ill patients.13 A recent clinical study in 53 patients showed that pressure-supported non-invasive ventilation, as a pre-oxygenation method, was more effective than non-inhalation ventilation mask and reserve bag.14

Stept and Safar published in July 1970 the iconic protocol for induction – intubation to prevent gastric aspiration.15 The key objective of the rapid sequence intubation technique is to reduce the period of time between loosing the airway protective reflexes and the intubation with an oro/nasotracheal tube with pneumatic plugging sleeve.16 The technique was intended for patients at high risk of aspiration.

The original algorithm considers the administration of a predetermined intravenous dose of sodium thiopental (150μg), followed by the immediate administration of succinylcholine (100mg), establishing intubation conditions in less than one minute.15 Sodium thiopental acts as a hypnotic agent, while succinylcholine relaxes the adductor laryngeal muscles.

There has been considerable controversy about the best hypnotic agent for RSI. Two aspects should then be considered: (1) intubation conditions and (2) hemodynamic variability. Dobson et al.16 compared thiopental and rocuronium vs. propofol and rocuronium, and found better intubation conditions with propofol, apparently due to propofol's enhanced effectiveness to inhibit the pharyngeal and laryngeal reflexes.

It should be kept in mind that the ideal hypnotic agent for an ICU patient is one that leads to minimum change in the hemodynamic parameters; however, contrary to our objectives, thiopental and propofol, cause marked hypotension. Etomidate and ketamine are effective hypnotic agents in patients hemodynamically compromised,17,18 and hence are the agents of choice in ICU patients. Please keep in mind that etomidete's ability to induce adrenal failure and thus its use is contraindicated in septic patients.19 Likewise, ketamine should not be used in patients with elevated intraocular pressure or in patients with space occupying lesions due to its known effect of raising the intracranial pressure.20

Should you administer a predetermined fixed dose of the hypnotic agent (as suggested by Stept and Safar in their original paper) or, on the contrary should the agent be titrated until loss of consciousness is obtained? With the former approach there is a risk of under or over-dosing the patient allowing the patient to be conscious or inducing drastic hemodynamic changes with the latter.13 In both cases, the muscle relaxant is administered upon loss of consciousness. Those who are against of the titration technique claim that the induction last longer as compared to the classic technique; however, some authors like Barr and Thornley21 have shown that while total induction time is longer, the period of time between loss of consciousness and intubation remains unchanged.

In the RSI puzzle, succinylcholine is the key player: why? What makes succinylcholine so special? Studies show that when succinylcholine is used in RSI protocols, identical intubation conditions are achieved, regardless of the hypnotic agent selected.22 A recent systematic review by Cochrane evidences that succinylcholine is superior to rocuronium to create excellent intubation conditions and should be the first choice in rapid sequence intubation for the normal patient.23 While the proposal of Stept and Safar included a standard 100mg dose for an average 70kg individual, later studies established that the dose should be 1mg/kg.

Up to this point, we have explained in detail why succinylcholine is the muscle relaxant of choice for rapid sequence intubation in the standard patient. However, ICU patients are not candidates for receiving succinylcholine, due to the extended periods of immobility these patients endure; already after 6–12hours of immobilization, patients up-regulate the nicotinic acetylcholine receptors, both within and outside the neuromuscular plate and start the expression of the α7AChR isoform.24,25 In view of the depolarization by succinylcholine, the normal receptors and the new isoforms start releasing intracellular potassium26; this is compounded by the fact that isoform α7AChR strongly and persistently depolarizes, not just in response to endogenous succinylcholine and acetylcholine, but also on account of its choline metabolite. Additionally, the absolute rise in the number of receptors leads to an overproduction of potassium.23 Following the administration of 1mg/kg of succinylcholine, the serum potassium elevation in a normal individual usually does not exceed 0.5mmol/l, while in an immobile individual may raise to 3mmol/l.27,28

Leiman showed that in addition to the raise in potassium following a succinylcholine injection, the automaticity of the cardiac cells increases and the threshold for ventricular fibrillation decreases as a result of the rise in catecholamines. Succinylcholine briefly raises the levels of norepinephrine and epinephrine due to its impact on the presynaptic nicotinic receptors of the postganglionic sympathetic nerve endings.29

Then, what is the option to relax patients in the ICU? Rocuronium is a non-depolarizing muscle relaxant with the fastest onset of action. At a 0.8–1.2mg/kg dose it provides excellent intubation conditions in 60seconds.26 Three clinical trials showed that in emergency situations, rocuronium was equivalent to succinylcholine in developing acceptable intubation conditions.30–32 In view of the available evidence and considering the unjustified risks when administering depolarizing muscle relaxants, we walk away from Jaber's protocol to recommend the use of rocuronium over succinylcholine in ICU patients.

By applying pressure over the cricoid cartilage against the cervical vertebrae of a corpse, Sellick realized that regurgitation of the gastric contents in the pharynx could be prevented. Then he applied the technique in 26 patients with high risk of aspiration during anesthetic induction, and none of them experienced regurgitation or vomiting. Since then, Sellick's maneuver (SM) is a must when intubating patients at high risk of aspiration. The current recommendation is to apply a pressure of 10 Newton (N) (1kg) in the patient when awake and 30N (3kg)37 in the unconscious patient. There have been however several reports about fatal aspiration and regurgitation, despite the use of the SM.38,39 Other studies report worsening of the intubation conditions.40 Inappropriate timing for administering the SM, excessive strength or compression of the thyroid instead of the cricoid cartilage, would be the reasons for the SM associated issues.10 However, when the maneuver is adequately performed – as shown by Sellick – it contributes to prevent the passage of gastric contents into the airway.

Two studies showed that capnography has a 100% sensitivity and specificity to confirm the correct placement of the tube in the trachea, in patients with cardiorespiratory arrest.41,42 The American Heart Association (AHA), the European Resuscitation Council and the International Liaison Committee of Resuscitation (ILCOR) recommend that, in addition to auscultation and to the direct visual examination, capnography should be used to confirm a successful intubation.43,44

The most recent Cochrane review on hypotensive shock45 23 clinical controlled, randomized studies including 3212 patients with hypotensive shock were analyzed. The authors concluded that there is no difference among the six vasopressors (norepinephrine, dopamine, epinephrine, vasopressin, terlipressin, dobutamine) analyzed in terms of mortality and that probably, the choice of vasopressor does not affect the final result. However, in one of the largest studies comparing norepinephrine versus dopamine,46 the subgroup analysis according to the type of shock, showed a beneficial effect on the 28-day mortality in patients with cardiogenic shock treated with norepinephrine; the drawback was that the randomization was not stratified and hence the differences could have been random. Until additional information is made available, it is impossible to determine which is the vasopressor of choice for the management of persistent hypotension.

What is protective ventilation? According to Cochrane,47 protective ventilation is the ventilator strategy using tidal volumes below or equal to 7ml/kg, and plateau pressures below 31mm H2O. Amato et al.,48 among several authors, showed the benefits of using low tidal volumes: patients under protective ventilation die less (38% vs. 71%), mechanical ventilation weaning is easier and faster (66% vs. 29%) and barotrauma is lower (7% vs. 42%). In an independent study, Ranieri showed that protective ventilation decreases the cellular inflammatory response.49 The same Cochrane group found that those patients exhibited a lower mortality at 28 days, as compared to patients ventilated with high tidal volumes (9.4–9.9ml/kg) and plateau pressure above (31–37mm H2O). On the other hand, and contrary to Jaber's recommendations, the ALVEOLI50 trial failed to evidence discrepancies in mortality of the patients in response to PEEP variations, regardless of a high or low PEEP. A major requirement is to preserve a low tidal volume.

Based on the scrutiny of the available medical literature on RSI in the ICU, we would like to suggest a modified sequence (Table 3), convinced that only a rigorous follow-up of our will show the benefit of the technique.

The adoption of protocols is a strategy that has proven to be of lower mortality in medical practice, for reasons including the fact that our reasoning may get blurred under highly stressing situations. Protocols are a tool to regain control of the situation and provide us with valuable time to analyze the circumstances surrounding the event. This modified Jaber's protocol for rapid sequence induction – intubation in the intensive care unit is intended as a handy therapeutic tool for critical patients; we hope that, just as with the original protocol, the modified algorithm will contribute to reduce the morbidity and mortality in our patients.

None.

The authors have no conflicts of interest to declare.