Open access peer-reviewed chapter

Airway Management in Critical Settings

Written By

ELSayed Elkarta and Magdy Eldegwy

Submitted: 07 April 2020 Reviewed: 07 September 2020 Published: 30 November 2020

DOI: 10.5772/intechopen.93923

From the Edited Volume

Special Considerations in Human Airway Management

Edited by Nabil A. Shallik

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Abstract

Airway management continues to be a challenging task for healthcare practitioners and when it comes to critical settings; it carries more challenges even for the skilled persons. Critical settings could be in fact of suits; where intervention takes place, equipment or practitioners taking care of airway management. Critically ill patients with multiple comorbidities, increasing oxygen demand and high respiratory work; that may require elective airway securing. Various protocols, guidelines and recommendations advocated for this task with the prospects of less hemodynamic alteration and prevention of pulmonary aspiration. In the former, starting oxygen therapy for all critical patients on admission was a routine following the concept; if some is good, more must be better. Nowadays excess oxygen may be unfavorable in some acute critical conditions e.g. ischemic strokes, post-acute myocardial infraction and those with hypercapnic respiratory failure. However, still high flow inspired oxygen concentration is the protocol until they are stable then its reduction to reach the targeted arterial oxygen saturation. Oxygen devices used for oxygen delivery are plenty and its selection depends on the many factors; airway patency, patient’s conscious level and compliance, and assessment of gas exchange based on arterial blood sample which is recommended for all critically ill patients. Early prompt evaluation of the airway and assessment of gas exchange using arterial blood sample analysis is curial in all critically ill patients to guide for subsequent oxygen supply and whether the patient needs ventilatory support or not. This chapter will focus on airway management, oxygen therapy and types of ventilatory support required for adult critically ill patients, while other situations’ airway management’s tools and skills will be discussed in another ones.

Keywords

  • airway
  • management
  • critical
  • hemodynamic
  • hypoxemia
  • guidelines
  • FONA

1. Introduction

Airway patency is crucial and vital for maintenance of life occurs naturally in the awake and conscious individuals or can be accomplished artificially in those becoming unable to maintain it. Incapacity of this might be intentional; as in medical procedures requiring deep sedation and/or general anesthesia or in pathological conditions; where there is an alteration in sensorium or elective airway protection needed.

Airway management is defined as an intervention using a technique, maneuver or a device to keep its patency, consequently its normal physiological functions have been achieved; providing oxygen and removing carbon dioxide.

Critical illness is a clinical condition belong to a group of medical situations sharing the need of intensive care unit (ICU) admission and have either single or multiple organ dysfunction. Critically ill patients showing different gradations of snags to maintain the airway and subsequently derangement of aerobic metabolism exists. Optimization of oxygen supply is needed, as dramatic rise of both work of breathing and oxygen demand exist.

Hypoxemia is a medical condition where the partial pressure of oxygen in the arterial blood (PaO2) is lower than normal. A PaO2 value of less than 60 mmHg in normal individuals with healthy lungs; corresponds to arterial oxygen saturation (SpO2) of 90%, is used as a cut point for hypoxemia treatment initiation. There are many causes and mechanisms of hypoxemia which required management via oxygen administration. Critically ill patients commonly showing hypoxemic status on the time of admission and oxygen supplementation should be considered in all with high flow delivery system (15 L/min) until becoming stable then reduction of inspired oxygen concentration (FIO2) to achieve a target of SpO2 of 94–98% or 88–92% for patients with risk of hypercapnic respiratory failure [1].

1.1 Physiological consideration

Airway is the natural passages of the airflow, inaugurated by nose and mouth downwards to the alveoli in the lungs, where the gas exchange takes place involuntary. Airway patency is mandatory for life and it’s the responsibility of pharyngeal-laryngeal muscles tonic control and muco-ciliary system’s clearance of mucus and foreign particles.

The airflow via the airway is intermittent and biphasic; inwards during inspiration and outwards during expiration. The work of breathing is a potential energy stored in the lung tissues during inspiration that exists by the work of overcoming the elastic forces and resistance in the airway to be enough for subsequent expiration. In compliant, healthy lung this work of breathing does not consume a portion of the body’s energy needs and its daily fraction is less than 3% of total body energy requirement [2].

Impaired consciousness, associated cervical spine trauma, burns and pulmonary shunt causing rapid desaturation and impedes preoxygenation. Besides, limited time for airway management before life-threatening hypoxia, hemodynamically (HD) unstable, imminent risk of collapse before intubation, tricky standard induction drugs effects provoke time pressure environment.

Cessation of the desirable airflow in critically ill patients could be due to a variety of reasons, foremost of those is the airway obstruction. Airway obstruction might occur at any, upper parts; due to foreign body, mucus, secretions, blood and decreased sensorium or lower parts; due to aspiration, infection and spasm of bronchial muscles. Different maneuvers and devices used to eliminate the airway obstruction thus maintenance of airflow will be gained.

Airway management in critically ill patient aimed for:

  1. Improving the oxygenation.

  2. Airway protection and prevention of pulmonary aspiration.

  3. Adjunct for procedures; diagnostic e.g. bronchoscopy or therapeutic e.g. banding of bleeding esophageal varices.

  4. Relieve the distress of dyspnea.

  5. Reduce the work of breathing.

  6. Improve CO2 clearance.

  7. Altered sensorium, required airway protection.

  8. Others in ICU.

1.2 Anatomical consideration

Critical illness and its management protocols might hinder the airway anatomy, fluid resuscitation and capillary leak makes the airway edematous and distorted. Furthermore, the patient demography, body mass index (BMI), associated neurological and cardiopulmonary comorbidities, and the indication of ICU admission contribute to anatomical difficulties.

1.3 Devices of oxygen delivery

Oxygen (O2); is an inert gas essential for life, being inspired through the airway and transported via the lungs towards the blood to be used in cellular respiration and delivery of energy needed for body metabolism. Human body uptake of oxygen in concentration of 20.95% from air by natural airways; nose and mouth, transported down along the conductive airways to be resting in the alveoli where the gas exchange happening. Physiological and pathological conditions required an increased FIO2 to meet the body oxygen requirement and its high demand. Devices are designed to facilitate oxygen delivery from artificial oxygen sources in correspond to the target of FIO2, patient’s breathing effort and patient’s device compliance [3].

All critically ill patients must have high-flow oxygen delivery device (15 L/min), until stable status achieved, then oxygen requirement could be individually determined depending on the existing pathology. Patient’s breathing effort is the primary determinant for the oxygen delivery device selection. Critically ill patients might be one of two groups; spontaneous breathing group or assisted ventilation one and each group has a preference in oxygen delivery system [4].

1.3.1 Spontaneous- breathing group

Patients with breathing effort requiring O2 delivering device matched for their breathing power (Table 1).

O2 flow rate (L/min)FIO2Example
Fixed-Performance Devices2 - 15Unknown; depend on patient’s effort and O2 flow rateSimple face mask, face mask with reservoir bag, nasal cannula. (Figure 1)
Variable-Performance DevicesHigh, up to 45Well-known, fixed.All obey a principle of high airflow O2 enrichment (HAFOE). (Figure 2)

Table 1.

Oxygen delivery devices [3].

Figure 1.

Oxygen delivery devices (simple face mask with reservoir bag & nasal cannula).

Figure 2.

Oxygen delivery devices (HAFOE).

1.3.2 Assisted ventilation group

In this group of critically ill patients, failure to maintain oxygenation and/or ventilation despite an increase in FIO2 or development of apnea and indicated mechanical ventilation (MV), airway supporting device might be perpetual or temporary as a bridge till the steady one is fixed. Noninvasive positive pressure ventilation (NIPPV), could have both properties as it might be a tie till improvement or securing definitive airway securing device suitable for MV.

Bag-mask with self-inflating reservoir bag; (Figure 3) is considered the simplest and commonest O2 delivery device used in critically ill patients for oxygenation until an airway securing device fixed. It provides FIO2 close to 100% while the only O2 delivery device able to provide 100% FIO2 is the anesthetic breathing system.

Figure 3.

Oxygen delivery devices. (bag-mask with self-inflating reservoir bag).

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2. Airway management in ICU

Airway management in ICU is unlike that carried out in operation theater (OT) and higher in its complications; brain damage and death, and most of it is done on urgent and emergency basis in lack of experienced airway management professionals. In addition; critically ill patients showing limited cardiopulmonary reserve, this increases their risk of hypoxemia and hypotension upon exposure to airway management medications. Subsequently, tracheal intubation for those categories of patients could be life-threatening condition; up to 40% of patients are associated with increase in complication rates of hypoxemia (25%) [5] and hypotension (10–25%) [6], arrhythmia, cardiac arrest and death [7] upon exposure to airway stimulation or pharmacological agents used for it.

Incapacity to perform tracheal intubation at the first attempt “first pass success” has higher risk than that in OT and occurs in 30% of ICU intubations [8]. Many factors contribute to that; lack of competent and expert professional for intubation, patient’s factors and pharmacological agents’ dosage choices. This came with the conclusion of Fourth National Audit Project (NAP4), as it showed around 25% of airway management done in ICU & ED are associated with major adverse effects mostly due to the aforementioned factors [9]. Moreover, equipment unavailability, unfamiliarity and inadequate planning resulting in more stressful environment and subsequently delay in airway management with increasing morbidity and mortality.

ICU settings are not suitably planned for airway management due to several reasons. Limited access to the patient as the bed space is crowded by monitoring, ventilator and other equipment, (Figure 4) in addition of the ICU bed is less maneuverable compared to the OT table with unavailability of advanced airway management equipment making it more challenging. Moreover, varying team members of multi-professional backgrounds with non-enough time, experience, accompanying medical devices (collars, masks) and sensorium alteration lead to improper airway assessment beside and inability to ensure adequate preoxygenation necessary to avoid the hypoxia during airway instrumentation. Moreover, unavailability of trained assistance such as anesthesia nurse or technician and lack of structured airway management for ICU staff.

Figure 4.

ICU bed vs. OT space (showed crowding with monitoring, equipment and ventilators).

Communication and proper documentation of the airway assessment and its management throughout different hospital facilities is crucial and it might affect the workflow performance. Checklist is the best method of communication among the healthcare professionals from different medical background. Equipment, medications preparation checklist and proper assignment of human forces could make the airway management scenario less stressful and empower its success among critically ill patients.

Quite few challenges could be integrated in airway management for ICU adults, so we can wrap up the considerations and specific precautions that must be accomplish making it less pressure and successfully performed procedure (Table 2).

2.1 Pre-intervention stage

Thorough clinical assessment and prediction of threats that may limit the success of airway management of critically ill patients could be addressed in this time. Also, optimization of all factors; position, preparation and preoxygenation, accentuates the accomplishment of proper airway management intervention.

2.1.1 Airway assessment challenges

Not only thorough assessment of the airway in critically ill patient is vital for successful and safe management but it is unique and carries challenges as compared to that done for patients undergoing daily elective or emergency airway management. Varieties airway assessment modalities, techniques and scoring system had been proposed to allow its safe and easy practice management. Despite the anesthesiologists’ or intensivists’predictions of anticipated airway difficulties are a strong diagnostic modality with high positive ratio, but the high proportion of unanticipated difficult endotracheal intubation and its low positive predictive values limits its reliability as a diagnostic test in medical practice [9].

Moreover, the proposed airway assessment scales vary from the simple, that often fail to address the many factors associated with a difficult airway, to the complex, which are impractical as a clinical tool. None have been shown to be accurate in predicting airway management problems, and none have been assessed in the ED setting [10].

NAP4 reports identified frequent airway management failure rate and the high-risk airway patient’s identification was not managed through an appropriate airway management approach [9].

Standard airway assessment in critically ill patients is usually unfeasible and difficult to be done especially in those dependent on oxygen delivery devices; face mask or nasal cannula, to avoid hypoxia and provide adequate preoxygenation. The only validated airway assessment scoring system reliable for critically ill patients is the MACOCHA score (Table 3) [11]. It has the advantage of being created with easy identifiable and clinically appropriate variables. Additionally, its used objectives are close to those identified in OT and include risk factors associated with difficult tracheal intubation [12]. Considering any investigations of the airway that already done; such as chest x-ray, CT scan and 3D and Virtual Endoscopy (VE) could be helpful in airway evaluation and might be derive the plan for airway management in critically ill patients [13].

ChallengeConsiderationPrecaution
ICU environmentICU space;• Ideal stuff positioning
Equipment;• Standard airway trolley availability
• Advanced airway; VL, FOB, Bougie available
Team member;• Team members briefing and specific task assignment
Patient-relatedPhysiological;• HO instability• Optimization & vasopressors proactively use.
• Pulmonary shunt• Optimal preoxygenation with O2 delivery devices.
• Limited reserve & time for airway management• Systematic, logical, and strategic airway management techniques escalation.
Anatomical;Anticipation and plan for failure.
Difficult airways;• Recognition and readiness for difficulties.
• MACOCHA score use.
• Reduce number of attempts.
• Appropriate induction medications, NMBS is routine.
• Plan for failure.
• Consider FONA.
Urgency;• Checklist in preparation and communication.
• Follow up guidelines & standardized protocols.
Pharmacological agents;• Ketamine is recommended.
• Avoid over sedation.
• Routine use of NMBS.
• Consider induction time longer than traditional.
Aspiration risk;• Modified RSI with cricoid pressure or DSI.
• Head-up position.
Postintubation careRed flag recognition;• ETT obstruction, displacement.
• Ventilators mechanics and Monitoring: ETT related.

Table 2.

ICU airway management challenges, considerations and precautions.

Abbreviations definition; VL: video-laryngoscope. FOB: fiberoptics laryngoscope. MACOCHA: Mallampati score, Apnea syndrome, Cervical spine limitation, Opening mouth, Coma, Hypoxia, Anesthesiologist non-trained. FONA: front of neck airway. NMBS: neuromuscular blockers. RSI: rapid sequence induction. DSI: delayed sequence induction

FactorsPoints
Factors related to patientMallampati score III or IV
Obstructive sleep apnea syndrome (OSA)
Reduced mobility of cervical spine.
Limited mouth opening <3cm.
5
2
2
1
Factors related to pathologyComa
Sever hypoxemia (<80%)
1
1
Factors related to operator1
Total:12

Table 3.

MACOCHA score [11].

Abbreviations definition: MACOCHA= Mallampati score III or IV, Apnea syndrome, Cervical spine limitation, Opening mouth <3cm, Coma, Hypoxia, Anesthesiologist non-trained.

Score: 0-12 =easy; 12=difficult.

It’s recommended to define the cricothyroid membrane for possible front of neck airway (FONA) as a strategy of a plan for failure. This could be done by manual palpation; laryngeal handshake technique [14] (Figure 5) or using ultrasound that is accurately defining cricothyroid membrane site, measurements and surrounding structures such as thyroid gland and its vessels [15].

Figure 5.

Laryngeal handshake technique.

2.1.2 Preparation and preoxygenation challenges

Formerly it’s mentioned that; checklist, proper communication, documentation and team briefing with specific task assignment is a key for successful airway management in critical settings. Standard pre-intubation checklist has been developed via Difficult Airway Society (DAS), Intensive Care Society (ICS), Faculty of Intensive Care Medicine (FICM) and Royal College of Anesthetists (RCoA), United Kingdom solving this high-pressure situation (Figure 6).

Figure 6.

Pre-management preparation; patient, equipment, team assignment.

Efficient preoxygenation with end-tidal oxygen concentration of more than 85% is the target [16] must be done in parallel to assessment and preparation. Traditional techniques are somewhat doing this task [17] and the choice of oxygen delivery device depends on the patient’s comfort, device availability and the indication for intervention. Although use FIO2 of 100% with high flow rate; 10–15 L/min in a tight-sealed facemask for 3 minutes could be enough in intact spontaneously breathing derive [18] but the use of simple face mask even with reservoir bag is not recommended [19]. Moreover, non-invasive positive pressure ventilation (NIPPV) and continuous positive pressure ventilation (CPAP) could be alternatives for preoxygenation in seriously hypoxic patients resulting in improved oxygenation and prevention of atelectasis associated with FIO2 of 100% via supporting the minute volume ventilation (MVV) [20].

High flow nasal oxygenation (HFNO) between 30 and 70 L/min is a suitable method for preoxygenation that showed safety to extend the safe apnea time during airway instrumentation and effectiveness when combined with NIPPV use [21]. Not only, continuous positive airway pressure (CPAP) delivery with a tight-sealed facemask of 5–10 cm H2O is recommended for preoxygenation, but also, the use of nasal oxygen with a flow of 5 L/min throughout airway management [19] and might be achieved by NIPPV especially in patients with respiratory failure [20].

Plan for failure must be the strategy of airway management planning, allowing logical and prepared expectations for different scenarios that might occur during the procedure. The guidelines resulted from collaborations of DAS/ICS/FICM/RCoA in United Kingdom with the aim of providing structured, standard and systematic approach of airway management in critically ill patients with the concern of not being a replacement of clinical judgment but rather an organizational and individual framework for clinical practice preparation and health care professionals training [19] (Figure 7).

Figure 7.

DAS/ICS/FICM/RCoA guidelines for ETI in critically ill patients.

Providing the patient’s comfort, upper airway patency, optimizing functional residual capacity and decreasing aspiration risk; sniffing position is desirable as an initial position for airway management in critical settings, [22] while titration of bed head-up if cervical spine injury was suspected or confirmed [22, 23] and with prevalence of obesity among population, ramping position could be an alternative [24].

All airway management in critical settings must be carried out in presence of standard ASA monitoring; electrocardiogram (ECG)/heart rate (HR), non-invasive blood pressure (NIBP), pulse oximetry with oxygen saturation (SPO2), end-tidal carbon dioxide (EtCO2) [25]. Invasive blood pressure (IBP) is desirable either vasopressors in-use or HD instability is most likely expected and end-tidal oxygen concentration (EtO2) monitoring; if available.

2.1.3 Anesthesia induction and pharmacological considerations

Hypnosis, analgesia and skeletal muscle relaxation is a triad to commence general anesthesia required for airway management and instrumentation. A variety of pharmacological agents are described to achieve this task with specific considerations in dosing titration, delayed onset and extended effect duration.

Airway management of critically ill patients is mostly carried out in ICU while the risk to be done in non-ICU suites still considerable. Non-ICU suites include pre-hospital area, emergency department, radiology department and inpatient ward which carry the risk of difficultly and hence increase in adverse consequences of airway management, that will be discussed separately in corresponding chapters.

There are many factors recommended to reach the optimal airway management in critically ill patients including; intravenous induction agents, use of fast onset neuromuscular blocking agent (NMBA), precautions against pulmonary aspiration, laryngoscopic techniques aimed at first-pass success, and confirmation of successful tracheal intubation by waveform capnography.

Rapid sequence induction and intubation (RSII) is a technique commonly used to protect the airway against gastric contents aspiration and modified to be implemented in some clinical circumstances. A classic RSII consists of oxygen administration, application of cricoid pressure, and the avoidance of mask ventilation before insertion of an endotracheal tube (ETT) for airway securement [26].

A modified RSII in comparison to a classic RSII is to attempt for lung ventilation using positive-pressure ventilation via a facemask [27] before airway securement by ETT.

Delayed sequence intubation (DSI) seems to be safe, effective and could offer an alternative of rapid sequence induction in patients requiring emergency airway management who cannot tolerate preoxygenation or peri-intubation procedures [28]. The ideal DSI induction agent is Ketamine as it preserves airway reflexes and respiratory drive permitting preoxygenation and procedural sedation. DSI technique steps are; ensure the patient has a patent airway, place standard nasal cannula at 5 liters/min in awake patient and increases to 15 liters/min in unconscious one prior to placement of the preoxygenation device. Preoxygenation device choices based on the patient’s SpO2: if SpO2 > 95% use bag-valve-mask (BVM) with PEEP valve and a good seal at 15 L/min O2, or non-rebreather (NRB) mask and a good seal at 15 L/min O2 (or more) while SpO2 < 95%: use BVM with PEEP valve and a good seal and preoxygenate for at least 3 minutes [19].

2.1.3.1 Induction agents

Choice of induction drug is according to hemodynamic status of the patient; Ketamine is increasingly favored in most circumstances [29]. Administration of a rapidly acting opioids enables lower doses of hypnotics to be used, maintaining cardiovascular stability and minimizing changes of intracranial pressure.

Etomidate as an induction agent is not a first line for intubation in the critically ill patients because the other induction agents have been successfully used without risk of adrenal suppression. Its relative value of short-term hemodynamic stability that is accompanied by a potential adverse effect of adrenal suppression making its use as an anesthetic induction agent in critically ill patients is controversial, although it provides excellent intubating conditions [30]. Another meta-analysis also investigating non-intubation-related adverse effects of Etomidate in critically ill patients stated that its use is not worsening of mortality, organ dysfunction or resource utilization, even if it’s adverse effects on adrenal gland function [31]. It’s found that hypotension was more prevalent in patients receiving Etomidate compared with Ketamine in the first 24 hours after intubation and subsequent mechanical ventilation [32].

Moreover, Propofol has temporary hypotension episodes as compared to Etomidate, but there is no difference in patients requiring vasopressors after 24 hours [33]. Propofol and Ketamine mixture may have an improved hemodynamic profile compared with Etomidate. Few studies evaluated Etomidate versus Ketamine, finding no difference between them [34].

Dexmedetomidine, Remifentanil and Droperidol have been suggested as induction agents for DSI, but these agents do not have the same pattern of Ketamine as rapid onset, preservation of airway reflexes, intact respiratory drive and safety profile. Fentanyl have a significant sedative effect in addition to analgesia, that may be helpful when titrated to the desirable effect and to avoid over sedation.

NMBA improves intubating conditions, facemask ventilation, nasogastric tube insertion hence, reduction in the number of intubations attempts and optimizing chest wall compliance [35]. Succinylcholine has many side-effects including life-threatening hyperkalemia and its short duration of action can spared for difficult intubation scenarios. Rocuronium could be the choice in the critically ill patients, providing similar intubating conditions to Succinylcholine and can be antagonized using Sugammadex [36].

Graded sedation intubation without use of NMBA has also been proposed and clinically considered for technique of choice of airway management in critically ill patients [37].

2.2 Intervention stage

This is the subsequent stage, that follows patient’s optimization achieved through concomitant preoxygenation, positioning and preparation of staff, equipment and medications. It is a highly stressful time and must be carried out in a strictly controlled and strategic manner.

Current guidelines state four main routes or plans as standard practice and should be done in sequence. From practical point, we believe that algorism might be modified or interchanged according to the given circumstances, such as in ED and prehospital critical settings, health care professionals could go for plan B/C straight away bypassing plan A because of limited facilities and unsuitable environment that mandate minimal airway manipulation with accomplishment of securing airway patency, proper oxygenation and/or ventilation.

2.2.1 Plan A

Plan A stresses on maintenance of oxygenation either via continuous nasal cannula or interrupted facemask application between laryngoscopic attempts and allowing enough time for desirable effect of pharmacological agents, laryngoscopy attempts using direct (DL) or video-laryngoscope (VL).

With a maximum of three trials, confirmed endotracheal intubation (ENI) through capnography with waveform trace and direct visualization of ETT pass beyond the vocal cords, the call for help of the appropriate help once failed first attempt is a must. Absence of wave trace capnography is a confirmation of failed ETI after exclusion of other causes such as ETT obstruction, pulmonary edema and cardiac arrest. Chest auscultation and its rise during inspiration are rarely used as indicator for successful ETI in critically ill patients [38].

First attempt of ETI, must be done by the most trained, proficient available and must have all team support and consideration of manoeuvers or manipulations with the aim of improving laryngoscopy is recommended after failed first attempt [19]. Operator replacement and equipment change; use of a different blade, addition of others; bougie and external laryngeal manipulation might be reasonable and helpful.

Despite of fulfilling all the available recourses to achieve an optimal laryngoscopic view, with failure of the ETI attempts, either three done or not, the team leader must swiftly proceed to the next airway management plan. DL is the standard use in ETI during daily clinical practice hence its use experience is granted. On the other hand, VL should be in preparation for difficult situation; MACOCHA score > 3 [11] and ensure its availability for critically ill patient management. DL versus VL is the choice of the professionals involved in the airway management scenario and could be the device selected for first attempt according to the institutional policy and training preferences [39].

2.2.2 Plan B/C: (backup plan)

Critically ill patients’ lifesaving by maintaining oxygenation during airway management is the priority and failed ETI [8] in the preceding plan A could resulted in sever hypoxemia [6, 40] that has several serious consequences. It’s the responsibility of the team leader to ensure maintenance of adequate oxygenation throughout the stages of airway management. ETT considered as a standard and definitive airway securing device while alternatives used to provide oxygenation in scenarios of failed ETI such as supraglottic airway (SGA) devices and facemask ventilation device.

SGA is considered as a plan B rescue device which consist of variety of devices used for the same purpose; securing upper airway patency that does not require long experience. Facemask ventilation used as a plan C with the purpose of providing O2 till an alternative being fixed. DAS/ICS/FICM/RCoA guidelines use SGA (plan B) and facemask ventilation (plan C) alternatively to ensure oxygenation after plan A failure confirmation with maximum three turn attempts [19].

Second-generation laryngeal mask airways (LMA) not only possess a design of providing oxygenation, reduce the aspiration risk and conduit for fiberoptic intubation (FOI) [40], but also, promising successful performance in critical areas have been reported [41] so, it’s the model of SGA devices to be considered in standard practice and should be available in the difficult airway management trolley. Provision of oxygenation, airway securing, avoidance of aspiration with minimal airway trauma, constantly remain the goals throughout the intervention and subsequent plan to awake patient, wait for airway expert, Fiberoptic Intubation (FOI) through LMA attempt for once or proceed to FONA remains the area of discussion among the airway management team [19].

Basically, it’s not recommended to proceed for blind ETI via LMA, [42] on the other hand, FOB accessibility in ICU should be granted [14, 43]. There are alternatives to perform LMA/FOI-guided either using small ETT 6.0 mm inner diameter mounted over the FOB to be advanced through LMA or using Aintree intubation catheter (Cook Medical, Bloomington, IN, USA), that permits ETT > 7.0 mm inner diameter without interruption of oxygenation. Blind ETI with use of either gum elastic bougie or tube exchange catheter (Frova catheter; Cook Medical, Bloomington, IN, USA) is not advisable in critically ill patients as it’s associated with tracheal injury, pharyngeal perforation, bronchial bleeding and accused for subsequent positive pressure ventilation-related pneumomediastinum [44].

2.2.3 Plan D; life-saving front of neck airway (FONA)

Life-threatening hypoxemia development in critically ill patients is frequent [45] and might be encountered at any stage of airway intervention, hence its prevention though ETI (plan A), SGA and facemask (plan B/C) use is emphasized. Not only, plan of failure with serious hypoxemia elaboration could drive towards FONA (Figure 8) but also, inadequate minimal oxygenation, aspiration, difficult ventilation and failure of LMA/FOI are potential indications [46]. Forever, efforts to eliminate cannot intubate cannot oxygenate (CICO) scenario must be maintained and its causes must be corrected while preparation of FONA is being proposed. The possible reasons for CICO might be related to patient’s (airway; impacted foreign body or laryngeal narrowing either from inside as laryngeal edema or from outside as high cricoid pressure), cardiovascular collapse or related to equipment failure.

Figure 8.

Plan D protocol in DAS/ICS/FICM/RCoA guidelines.

Late FONA during airway management scenario is common and is responsible for its associated morbidity and mortality [43, 47]. FONA setup prior to and at declaration of CICO occurred in three steps; immediate availability of FONA set, opening the set after one failed attempt of plan B/C and immediate FONA set use on CICO declaration [19].

FONA either scalpel cricothyroidotomy or other techniques; which need experience, specific preparations and include non-scalpel cricothyroidotomy, percutaneous tracheostomy and surgical tracheostomy. Scalpel cricothyroidotomy recommended in DAS guidelines offers the following advantages; timesaving, reliable, conducted in few steps with well-known immediately available equipment, high success rate, fitting for most of patients and providing definitive airway device [48]. For a brief technique steps of scalpel cricothyroidotomy and tracheostomy in ICU, will be discussed in another chapter.

Plan D (FONA) failure means a bad scenario that carries poor prognosis and must be avoided by follow-up FONA steps in a proper way as once it encountered, non-scalpel cricothyroidotomy by experienced professional, percutaneous dilatable tracheostomy and surgical tracheostomy have to be proposed immediately without delay.

2.3 Post-intervention stage

2.3.1 Post-intubation care

Not only providing airway securing device in critically ill patients is highly challenging, but post airway securing maintenance is also important to prevent airway displacement or obstruction. In addition of airway care, sedation and/or muscle relaxation are typically administered. They are not only having high-risk during intubation but also afterwards in rates of 82%; airway displacement and blockage, with 25% leading to death [49].

Furthermore; postintubation hypoxia occurred from multiple attempts, interruption of oxygenation, alveolar de-recruitment and collapse, and changes in the alveolar gas exchange may indicate an increase in initial lung volumes settings and benefiting from recruitment manoeuvers [38].

Attention payed towards recognition of red flag in intubated patients such as absent air entry on auscultation, abnormal EtCO2, increasing peak airway pressure (PAP), unattained inhaled tidal volume and abnormal chest x-ray findings, mandate immediate management.

2.3.2 Weaning and extubation

Airway securing device in critically ill patients might be temporary for bridging a reversible and treatable medical disorder or permanent for irreversible and long-term pathology that demanding it. The former, long-term medical conditions, alternative tracheostomy have to be considered with a debate of its timing, On the other hand in reversible and corrected medical conditions; weaning and extubation must be considered in due time to avoid complications of prolonged ETT. Critically ill patients’ intubation is challenging and extubation does too.

Tracheostomy might be an alternative of ETT as a definitive airway in critically ill patients in incidence of 7–19% [50] while extubation is the plan once the circumstances permit. Extubation is an elective procedure and mandates careful evaluation, preparation with the target of maintenance of oxygenation and stand-by intubation plan if extubation failure takes place.

DAS incorporated extubation guidelines in anesthesia practice and could derive that in ICU and summarized in four steps; [51].

Step 1: Plan for extubation:

  1. Considering the reasons for intubation in addition of the complications of prolonged dependence on ETT and its anatomical and physiological consequences.

  2. “At-risk” extubation is a term used to describe the possible hazards associated with extubation process and must be considered in the plan step, especially the pre-existing factors.

  3. A difficult airway trolley equipment and monitors should be immediately available for use.

Step 2: Prepare the extubation:

  1. Target for optimization of airway and spontaneous ventilation to ensure the success of extubation.

  2. This could be carried out by different methods such as ETT cuff leak test; to exclude laryngeal edema, spontaneously breathing trial (SBT), gastric decompression; as gastric distension results in diaphragmatic splint and breathing restriction. The plan for airway rescue must be considered and discussed in preparation.

Step 3: Perform extubation:

  1. Avoid interruption of oxygenation by pre-extubation oxygenation via FIO2 of 100% O2.

  2. Patient’s position; without adequate supporting evidence any one over the other, it’s advisable extubation in head-up or semi-recumbent position especially in obese patients.

  3. Gentle suctioning of oropharyngeal cavity and extubation in fully awake state or conscious-sedation state using Remifentanil [52] might be alternatives.

Step 4: post-extubation care:

  1. Beware of Warning signs of early airway compromise; stridor, obtunded breathing and agitation.

  2. Standard monitoring should be continued in post-extubation phase.

  3. Standard respiratory care for patients with airway compromise.

  4. Upright position, and high-flow humidified oxygen administration.

  5. Documentation and recommendations for future management.

  6. Clinical details and instructions for extubation and post-extubation care should be recorded focusing on difficulties and details of airway management and future recommendations should be recorded.

2.4 Special circumstances

  1. Airway management for ICU procedures like bronchoscopy, please refer to other chapters.

  2. Full stomach in ICU, will be discussed in another chapter.

  3. Previous tracheostomy that recently disconnected, it’s advisable to re-cannulate the stoma but proceed for FONA should not be delayed [19].

  4. ETT exchange in ICU remains common for many reasons that happening frequently such as ETT displacement or occlusion by crusted mucus, cuff rupture or surgical procedures mandate other ETT type. This task has to be taken seriously and reviewing the initial ETI documentation is essential and will provide a logical ETT exchange plan. Tube-exchange catheter is designed for that, providing its use with DL or VL which has superior glottic view, greater success rate and fewer complications [53]. New ETI could be another alternative but with the previous ETI documentation, all precautions and recommendations discussed earlier must be considered.

  5. Varieties of abnormal clinical status might be accompanying the airway management in critically ill patients such as obesity, burn, pregnancy etc.… and required specific considerations, please review the book chapters for more details.

  6. Specific alteration in airway management in COVID19 might be considered despite few data available. High Flow Nasal Cannula (HFNC) suggested to reduce the requiring supported ventilation [54] and NIV might reduce the rate of tracheal intubation [55]. Tracheal intubation in COVID 19 patients is considered as highest risk for health care professionals cross-infection and could be carried out in controlled environment [56]. More details about this topic will be available in specific chapter.

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3. Training and skills maintenance

Critically ill patients usually are underestimated as specific airway difficulty and being at high risk of failure. Not only due to infrequent training of focused airway and crisis management but also, physicians may neither have anesthesia rotation nor airway skills required for difficult airway management. Training on sole skills performance is unsatisfactory to achieve maximum safety [57] and ineffective teamwork that includes poor communication, lack of shared targets, situational awareness, role assignment, leadership, coordination, mutual respect and post-event debriefings is associated with poor patients’ outcome [58].

Focused risk assessment training, prevention of hypoxia, airway red flags, early call for help and request for advanced airway skills in concomitant with specific protocols and guideline presented. Team training, focused airway management training courses and workshops including simulation-based education are crucial and step up for airway management in both ED and ICU suites.

The crisis resource management (CRM) techniques from aviation industry has been advocated for use in ICU to promote a team approach to patient care and safety in critical settings [59]. The committee on quality of healthcare in America believes that health care organization should accomplished team training programs for health care professionals in critical care areas using demonstrating message such as crew resources management techniques employed in aviation, including simulation as people make fewer errors when they work in teams [60].

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4. Conclusion

Airway management in critically ill patient continues to be challenging for health care professionals even for expertise requiring implementation of specific guidelines and protocols to eliminate the its adverse consequences. Airway management tools and skills needed, could be attained through formal training by anesthesia clinical rotation, airway management courses, workshops and simulation training.

Teamwork is a key for success and must be proceeded by debriefing and specific task assignments. Plan of failure in a step wise approach for success and airway management should be considered early without delay that will be associated with more difficulties and unwanted outcome.

Optimization of oxygen delivery throughout the airway intervention is mandatory and should not be compromised for any reason. FONA should be considered in primary preparation and must be done in appropriate time without delay. Documentations and records must involve all stages of airway management and include details of difficulties.

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Written By

ELSayed Elkarta and Magdy Eldegwy

Submitted: 07 April 2020 Reviewed: 07 September 2020 Published: 30 November 2020