Robert A. Raschke MD

Tyler J. Glenn MD

Kim I. Josen MD

HonorHealth Scottsdale Osborn Medical Center

Scottsdale, AZ USA

These are some clinical observations made after over the past 10 months, working in a busy COVID-19 ICU unit in Scottsdale, AZ. The opinions expressed here are those of the private practice authors.

Overview of triage and rounding on large numbers of COVID-19 patients in the ICU service. Our approach to bedside care of our ICU service has required abbreviation for the sake of efficiency in the face of more than a doubling of our census. Our approach to rounding is opinion-based. We’ve been forced to evolve our triage and rounding systems in order to survive.

Our hospital uses the Abbott ID-Now® rapid point-of -are test for screening all COVID-19-asymptomatic patients admitted to our hospital, but due to its low sensitivity in hospitalized patients (1). We do not trust it to rule-out COVID-19 in patients with pneumonia being admitted to the ICU and also order an in-house PCR for such patients prior to, or upon ICU admission. We are cautious about transferring COVID-19 patients out of the ICU on bilevel positive airway pressure (BiPAP) or high-flow nasal cannula since many such patients have deteriorated and bounced-back to the unit within the subsequent week.

We try to see as many of our COVID-19 ICU patients (who are practically all our patients) sequentially, without interruption if possible, leaving our masks and gowns on continuously and moving quickly from room to room, changing only gloves between patients unless a bacterial pathogen that requires contact isolation has been identified. Little/no helpful information can be gleaned by entering the room of patient who is proned in a rotoprone bed. Such patients may only be supined for brief periods, sometimes in the middle of night shift; and discussion with the nurses regarding their physical exam findings during supine positioning is high yield. Auscultation of COVID-19 patients using isolation stethoscopes is seldom of value. Palpation of the neck/trunk for crepitus, neurological examination (especially in patients emerging from heavy sedation and/or supined after prolonged proning), and assessment of fluid status are high yield. We keep track of how many days the patient has received mechanical ventilation, the cumulative fluid balance (which sometimes gets very positive), and signs and lab values possibly related to complications of COVID-19 discussed below. The duration of antibiotics and sedation medications needs constant monitoring to avoid overuse. We do not routinely follow serial INR, ferritin, CRP, or D-dimer, since these do not affect patient management. We sometimes use BNP and procalcitonin to trigger further cardiac or infectious disease evaluations respectively. We do not treat isolated elevated procalcitonin with antibiotics, nor do we treat isolated d-dimer with therapeutic dose anticoagulation.

We have been conservative in our treatment of COVID-19, relying primarily on dexamethasone and usual evidence-based critical care practice. Over the course of the outbreak, our conservative approach has been validated; various hyped but off-label therapies (hydroxychloroquine, antirheumatic therapies, universal therapeutic anticoagulation) have failed to show benefit and possibly caused harm when subjected to evidence-based scrutiny (2,3). Benefits of remdesivir in patients with advanced respiratory failure seem unclear/minimal (4). Most of our patients present to the ICU in the second or third week of illness, already having developed IgG antibodies and therefore unlikely to benefit from convalescent serum or monoclonal antibodies.

Clinical course and management of respiratory failure. Many patients remain awake and able to tolerate spontaneous ventilation with non-invasive ventilation and/or high-flow nasal canula oxygen delivering high FiO2, for as long as two weeks before they either recover or require endotracheal intubation. Before the current outbreak, it was unusual to manage severely hypoxemic patients without intubation and mechanical ventilation. For COVID-19, it seems to be the norm, with intubation delayed until the last possible moment, as it is unclear that mechanical ventilation with its attendant complications (immobility, sedation, invasive support apparatus) offer any definite benefit. Once intubated, many patients seem to transition abruptly to refractory hypoxemia and hypercarbia, which previously would have made them candidates for Extracorporeal membrane oxygenation (ECMO) transfer. In one recent case, we requested ECMO evaluation for a patient prior to intubation, anticipating that he would deteriorate badly immediately thereafter. The consultant requested intubation before ECMO evaluation, and indeed, once intubated, the patient immediately became too unstable for uncannulated transfer. In general, the numbers of patients fulfilling historical criteria for ECMO consideration have greatly overwhelmed ECMO capacity.

We have tried several approaches to invasive mechanical ventilation, but each has drawbacks. Our primary mode of ventilation, pressure-regulated volume control, has sometimes resulted in high plateau and driving pressures as respiratory system compliance worsens. We’ve used pressure control ventilation in some patients to limit driving pressure, but this has led to unrecognized worsening of respiratory acidosis in some. We have managed several episodes of cardiac arrest due to uncontrolled combined respiratory and metabolic acidosis in COVID-19 patients being treated with permissive hypercapnia ventilation who subsequently developed acute renal failure. We are now trying airway pressure-release ventilation (APRV) as an optional approach in which we try to avoid proning and heavily sedating the patient, but aim for Richmond Agitation-Sedation Scale (RASS) of -1 to -2 and allow maintenance of spontaneous respiratory efforts by the patient during “T high”. It is not clear whether any of these approaches results in better clinical outcomes.

Our use of prone positioning has increased dramatically. Self-proning of awake patients receiving non-invasive mechanical ventilation or high-flow nasal canula oxygen has allowed some to survive episodes of severe oxygen desaturation and avoid intubation. We have extensively utilized proning in mechanically ventilated patients with PaO2/FiO2 <150. Several of our patients experienced cardiopulmonary arrest when briefly supined resulting in several fatalities. Consequently, we have learned to placed US-guided internal jugular central venous catheters and chest tubes in patients in proned and semi-proned positions. We have noted that at some point, prone positioning needs to be abandoned if the patient is ever going to recover, even if their PaO2/FiO2 ratio falls upon supine positioning. In such patients, supine positioning allows reduction of heavy sedation and resumption/improvement of spontaneous breathing efforts that may allow ventilator weaning to slowly proceed.

Complications of COVID-19 in the ICU. We have seen more barotrauma than previously described, some occurring during non-invasive ventilation prior to endotracheal intubation (5). Point of care chest ultrasonography has been instrumental in several cases in which anterior pneumothoraces were not clearly apparent on chest radiography, except perhaps as a deep sulcus sign, and also to rapidly rule-out pneumothorax as a cause of acute cardiopulmonary decompensation.

Hypotension requiring intravenous vasopressors is common (6). In many cases, it seems due to sepsis and sedation with propofol and/or dexmedetomidine. We have occasionally seen acute or chronic cardiomyopathy, but not as often as noted early in the pandemic (7). We have repeatedly diagnosed relative adrenal insufficiency later in the hospital course –after dexamethasone has been discontinued. Such patients commonly received etomidate during intubation which could possibly be contributory.

Bacterial co-infections are uncommon at presentation, consistent with published meta-analysis (8), and we do not routinely give antibiotics to all patients with COVID-19 pneumonia up front. Later in the course of mechanical ventilation, many patients experience recurrent fever, leukocytosis, elevated procalcitonin and/or worsening pulmonary status prompting endotracheal secretion and blood cultures and empirical antibiotics. We have commonly isolated a wide variety of potential bacterial pathogens from the respiratory secretions of such patients including methicillin-sensitive Staphylococcus aureus (MRSA), methicillin-resistant Staphylococcus aureus (MRSA), gram negative rods, some multi-drug resistant. We recently isolated carbapenem-resistant Enterobacter. It is uncertain whether these represent true cases of secondary pneumonia.

Coagulopathy related to COVID-19 is complex and increased risk of thrombosis and bleeding seem apparent (9). We administer enhanced prophylactic-dose anticoagulation to all our patients (typically 40mg enoxaparin every 12 hours in patients without morbid obesity or renal failure), but do not treat elevated d-dimers with therapeutic anticoagulation in the absence of documented venous thromboembolism (4). A minority of our patients have had documented venous thromboemboli prior to ICU admission and a few have had acute myocardial infarctions and strokes. We try to get CT angiography of the chest and doppler ultrasound of the lower extremities on all patients requiring mechanical ventilation. Bedside ultrasonography demonstrating acute right heart failure has been helpful in a few cases in which pulmonary emboli were suspected but the patient too unstable for CT angio or VQ scan. Three of our patients experienced CNS hemorrhages, two of which were fatal. Gastrointestinal bleeding is not uncommon.

Acute renal failure is common and complicates permissive hypercarbia, sometimes necessitating high dose bicarbonate infusions (6). Circuit thrombosis during dialysis is common, perhaps a manifestation of COVID-19 coagulopathy, and sometime necessitating therapeutic anticoagulation.

End of life issues. It is our impression that the mortality in intubated patients is higher this winter than it was previously in the pandemic. This might be because patients are receiving more aggressive therapy earlier in the course of illness, and often are only intubated after failing a prolonged course of non-invasive mechanical ventilation. Perhaps this selects treatment-unresponsive patients for intubation. Prognostication seems very difficult. We treated an 89-year patient with severe comorbidities who rapidly recovered after a 4-day course of mechanical ventilation and a 28-year-old previously healthy man who died despite receiving veno-venous ECMO. We have not found clinical scoring systems such as

Sequential Organ Failure Assessment (SOFA) to be helpful in prognosis, since many patients have isolated severe single organ dysfunction at the time of ICU admission, and therefore have similar SOFA scores – mostly comprised of points given for severe respiratory failure. Old-fashioned bedside common sense and family discussion still seem the best approach to determining code status. It is logistically difficult/impossible to safely administer CPR to some patients who are proned, especially those that are morbidly obese. We have told families that we are instituting limited code status (no CPR, no ACLS) in such situations, subsequently discussing resumption of full code status if/when the patient recovers enough to tolerate resumption of supine positioning.

Psychosocial issues. Incredible emotional injury is being experienced by patients’ families. Several of our patients come from families in which two or three primary relatives have already died from COVID-19. We called one patient’s wife to inform her that her husband had narrowly survived a prolonged arrest secondary to pneumothorax, interrupting her during her son’s funeral, who had died from COVID-19 pneumonia the previous week. Eventually, that family suffered the death of three primary relatives from COVID-19 over the course of three weeks.

We have tried to use cellular technology to help mitigate restricted family visitation, but it seems a poor substitute. Our nurses have had some patients make cell phone video messages to their loved ones before intubation – sometimes the last memory their families will ever have of them. We have held our cellphones by the ears of COVID-19 patients as they are dying so that their loved ones can say goodbye. It was heart-wrenching to hear a husband of 42 years sobbing uncontrollably over the phone, telling his dying wife that he loved her, and how much he’s going to miss her as we prepared to remove her endotracheal tube to let her die.

The nurses, respiratory techs and physicians have shown incredible bravery and self-sacrifice and outward morale is good. But all are suffering severe vicarious injuries the full effect of which may not be apparent for years to come. Much of the human connection previously so important to ICU practice has been lost – few of the patients can interact, and the families are generally not allowed to visit. We simply don’t have the time anymore to call them as often as we would like, and it’s unusual to call them with good news. We should plan for a future increase in PTSD and burn-out among healthcare providers.

We are grateful to have received my COVID-19 vaccination, and I was sincerely astounded by the organizational excellence of the vaccination event implemented by HonorHealth here in Phoenix. They did a very good job that will serve our entire vaccine-willing population in the coming months.

References

1. Basu A, Zinger T, Inglima K, Woo KM, Atie O, Yurasits L, See B, Aguero-Rosenfeld ME. Performance of Abbott ID Now COVID-19 Rapid Nucleic Acid Amplification Test Using Nasopharyngeal Swabs Transported in Viral Transport Media and Dry Nasal Swabs in a New York City Academic Institution. J Clin Microbiol. 2020 Jul 23;58(8):e01136-20. [CrossRef] [PubMed]
2. WHO Solidarity Trial Consortium, Pan H, Peto R, Henao-Restrepo AM, et al. Repurposed Antiviral Drugs for Covid-19 - Interim WHO Solidarity Trial Results. N Engl J Med. 2020 Dec 2:NEJMoa2023184. [CrossRef] [PubMed]
3. Salama C, Han J, Yau L, et al. Tocilizumab in Patients Hospitalized with COVID-19 Pneumonia. N Engl J Med. 2020 Dec 17. [CrossRef] [PubMed]
4. American Society of Hematology. COVID-19 Resources: COVID-19 and VTE/Anticoagulation: Frequently asked questions. Version 5.1 (last updated December 24, 2020). Available at: https://www.hematology.org/covid-19/covid-19-and-vte-anticoagulation (accessed 1/3/21).
5. Botta M, Tsonas AM, Pillay J, et al., PRoVENT-COVID Collaborative Group. Ventilation management and clinical outcomes in invasively ventilated patients with COVID-19 (PRoVENT-COVID): a national, multicentre, observational cohort study. Lancet Respir Med. 2020 Oct 23:S2213-2600(20)30459-8. [CrossRef] [PubMed]
6. Cummings MJ, Baldwin MR, Abrams D, et al. Epidemiology, clinical course, and outcomes of critically ill adults with COVID-19 in New York City: a prospective cohort study. Lancet. 2020 Jun 6;395(10239):1763-1770. [CrossRef] [PubMed]
7. Arentz M, Yim E, Klaff L, Lokhandwala S, Riedo FX, Chong M, Lee M. Characteristics and Outcomes of 21 Critically Ill Patients With COVID-19 in Washington State. JAMA. 2020 Apr 28;323(16):1612-1614. [CrossRef] [PubMed]
8. Langford BJ, So M, Raybardhan S, Leung V, Westwood D, MacFadden DR, Soucy JR, Daneman N. Bacterial co-infection and secondary infection in patients with COVID-19: a living rapid review and meta-analysis. Clin Microbiol Infect. 2020 Dec;26(12):1622-1629. [CrossRef] [PubMed]
9. Helms J, Tacquard C, Severac F, et al., CRICS TRIGGERSEP Group (Clinical Research in Intensive Care and Sepsis Trial Group for Global Evaluation and Research in Sepsis). High risk of thrombosis in patients with severe SARS-CoV-2 infection: a multicenter prospective cohort study. Intensive Care Med. 2020 Jun;46(6):1089-1098. [CrossRef] [PubMed]
10. Hayek SS, Brenner SK, Azam TU, et al. In-hospital cardiac arrest in critically ill patients with covid-19: multicenter cohort study. BMJ. 2020 Sep 30;371:m3513. [CrossRef] [PubMed]

Cite as: Raschke RA, Glenn TJ, Josen KI. Clinical Care of COVID-19 Patients in a Front-line ICU. Southwest J Pulm Crit Care. 2021;22(1):11-15. doi: https://doi.org/10.13175/swjpcc070-20 PDF

Intubation is one of, and perhaps the, highest risk procedures a critically ill patient can require, and the practice has largely been extrapolated from knowledge gained from airway management in the operating room (OR). Trouble arises when one encounters challenges with placing the tube or performing mask ventilation, termed the ‘difficult airway’. The difficult airway in the OR is relatively rare yet can be catastrophic when it is encountered unexpectedly. As a result, significant resources are devoted to developing task forces, guidelines, new devices and airway adjuncts to help manage the difficult airway and prevent avoidable complications. Outside of the OR, the difficult airway is encountered more frequently and with potentially devastating consequences. Reflexively, it is easy to blame the increased incidence on the skill of those managing airways as airway management has historically been viewed as a laryngoscopy problem--difficulty for us is the source of risk for the patient. Many facilities relegate airway management to an on-call anesthesiologist, leading to a significant variability in training and skill in airway management; and physicians skilled in life support but cannot safely put their patients on life support. Newer devices have led to a significant reduction in the difficulty with laryngoscopy, and it is becoming increasing clear to us that the terminology related to airway management outside of the OR should be reconsidered. Airway management outside of the OR commonly starts with the difficult airway because of the severely altered physiology, thus the importance of first-attempt success. Our current definition of the difficult airway lacks complete appreciation of the risks in these patients by focusing on the difficulty with laryngoscopy for the operator. For airway management of critically ill patients outside of the OR to positively impact patient outcomes, we must broaden our understanding of the risks associated with intubation.

There is no doubt that the difficulty one experiences in performing mask ventilation, laryngoscopy or tracheal intubation puts the patient at risk of untoward complications. However, limiting the focus to this traditional definition neglects the danger to the patient, which can occur in the absence of any technical difficulties. There is a strong association in the published literature between the number of intubation attempts and procedural complications (1-3), however there is also a significant risk of complications despite successful first-attempt tracheal intubation (i.e., no difficulty) (3). Thus, skillfully performing laryngoscopy and tracheal intubation that succeeds easily on the first attempt in a patient with physiologic derangements presents significant danger with airway management. This derangement may relate to a host of physiologic or pathologic issues and the resulting danger to the patient often relates to the consequences of hypoxemia or hypotension. To reduce the danger to the patient, careful attention is required to prepare the patient for induction, laryngoscopy and transition to positive pressure ventilation with emphasis on preoxygenation, maintenance of oxygenation and hemodynamic optimization.

Patients may face danger in any of the three phases of airway management: preparation and planning, implementation of the plan, or post-intubation management. Each phase presents both patient and contextual factors that accumulates and potentially compounds danger. Incomplete preparation, prolonged attempts at tracheal tube placement, disturbed physiology, an unskilled operator in a familiar environment or a skilled operator in an unfamiliar environment all contribute to different phenotypes of complications.  All can lead to different phenotypes of complications. Contextual factors include issues such as provider skill, access to equipment and help, various biases and conditions that in part are defined as human factors and are well-known to influence patient outcomes. To help mitigate technical difficulty experienced by the clinician and danger to the patient, special attention must be paid to each phase of airway management.

There are three phenotypes of complications that can arise from tracheal intubation. While the incidence of complications increases with successive attempts, the etiology and opportunity to attenuate those complications differs (Figure 1).

Figure 1. Studies outside of the OR show increased complications with successive attempts, with 10-20% for first attempt, 40-60% for second attempt, etc. However, different phenotypes of complications likely contribute differently at each point during airway management and thus provide various clinical and research targets. Incomplete or inadequate preparation or planning results in avoidable intubation-related complications because of early depletion of oxygen reserve, leading to aborted attempts or adverse events earlier than expected (Green bars). Complications that occur due to difficulty with laryngoscopy, tube placement, or mask ventilation despite pre-intubation optimization and preparation increase with successive attempts (Red bars). This is the traditional “difficult airway.” Complications that occur because of altered physiology likely contribute to the majority of complications with 1 or 2 attempts. These patients are so physiologically disturbed (e.g., hypoxemic respiratory failure, RV failure, tamponade), that they are intolerant of any attempt, any apnea, or the transition to positive pressure ventilation. These are the patients that when they degenerate into cardiac arrest despite first attempt success, we tell ourselves that they were just really sick and there’s nothing we could have done.

Complications can arise from inadequate preparation such as preoxygenation, improper positioning or an incomplete plan. Other complications arise from true difficulty with laryngoscopy, tube placement, or mask ventilation despite adequate preparation. With both of these types of complications, repeated attempts can lead to airway injury and edema that can precipitate a can’t-intubate can’t oxygenate scenario, but also the risk is from an association with the depletion of oxygen reserve, hemodynamic consequences of hypoventilation, or aspiration of gastric contents leading to critical hypoxemia. It is this latter association that should be eliminated with an increased focus on danger. Some patients have physiologic challenges that increase the risk of complications with any attempt (i.e. the “physiologically” difficult airway). These disturbances can be so severe that despite optimal preparation, risk cannot be completely obviated. By better understanding the danger presented by these three phenotypes, there is potential to clinically and scientifically approach airway management in critically ill patients that we have not considered historically. To date, we have typically focused efforts on preventing complications related to difficult laryngoscopy, yet the most significant danger likely comes from incomplete preparation and unfriendly physiology.   

Continuing to use the ‘difficult airway’ nomenclature in the critically ill patient risks confusion and undue variability without addressing the overall danger. For example, does anticipating difficulty and altering the plan, which then results in no difficulty being encountered during the intubation qualify as a difficult airway? Should one write a note in the chart, register the patient with a database, and send the patient a letter notifying them of the difficult airway they were predicted to have, but yet did not have? This presents a Schrödinger’s cat paradox in that the airway is both difficult and not difficult at the same time. From a research perspective, the term ‘difficult airway’ can be fraught with ambiguity or error. Studies comparing devices, techniques, or methods often focus either on the anticipated difficult airway, which is poorly predicted, deliberately exclude difficult airway patients, or isolate one aspect while ignoring the others (e.g. apneic oxygenation while ignoring preoxygenation) (4-11). Conversely, focusing on laryngoscopy-related complications ignores significant danger in airway management from incomplete preparation and difficult physiology-related complications, especially considering most patients are intubated in the first two attempts. We should refocus our energies on mitigating the danger by optimizing the pre- and peri-intubation process. Research should focus on how to best reduce complications associated with multiple attempts and disturbed physiology, and eliminate complications related to poor preparation altogether. These efforts will elevate our expertise in placing patients on life support to the level our patients deserve.

Jarrod M Mosier, MD^1,2,; George Kovacs, MD³; J. Adam Law, MD⁴; John C Sakles, MD¹

¹Department of Emergency Medicine, University of Arizona. 1609 N. Warren Ave, Tucson, AZ 85724

²Division of Pulmonary, Allergy, Critical Care, and Sleep. Department of Medicine, University of Arizona. 1501 N Campbell Ave, Tucson, AZ 85721

³ Departments of Emergency Medicine, Anaesthesia, Medical Neuroscience, Dalhousie University, Halifax, NS B3H 3A7

⁴ Departments of Anesthesiology and Emergency Medicine, Dalhousie University, Halifax, NS B3H 3A7

References

1. Sakles JC, Chiu S, Mosier J, Walker C, Stolz U. The importance of first pass success when performing orotracheal intubation in the emergency department. Acad Emerg Med. 2013;20(1):71-8. [CrossRef] [PubMed]
2. Mort TC. Emergency tracheal intubation: complications associated with repeated laryngoscopic attempts. Anesth Analg. 2004;99(2):607-11. [CrossRef] [PubMed]
3. Hypes C, Sakles J, Joshi R, Greenberg J, Natt B, Malo J, Bloom J, Chopra H, Mosier J. Failure to achieve first attempt success at intubation using video laryngoscopy is associated with increased complications. Intern Emerg Med. 2017 Dec;12(8):1235-43. [CrossRef] [PubMed]
4. Griesdale DE, Chau A, Isac G, Ayas N, Foster D, Irwin C, Choi P, Canadian Critical Care Trials G: Video-laryngoscopy versus direct laryngoscopy in critically ill patients: a pilot randomized trial. Can J Anaesth. 2012;59(11):1032-1039. [CrossRef] [PubMed]
5. Silverberg MJ, Li N, Acquah SO, Kory PD. Comparison of video laryngoscopy versus direct laryngoscopy during urgent endotracheal intubation: a randomized controlled trial. Crit Care Med. 2015 Mar;43(3):636-41. [CrossRef] [PubMed]
6. Driver BE, Prekker ME, Moore JC, Schick AL, Reardon RF, Miner JR. Direct Versus Video Laryngoscopy Using the C-MAC for Tracheal Intubation in the Emergency Department, a Randomized Controlled Trial. Acad Emerg Med. 2016, 23(4):433-9. [CrossRef] [PubMed]
7. Janz DR, Semler MW, Lentz RJ, et al. Randomized Trial of Video Laryngoscopy for Endotracheal Intubation of Critically Ill Adults. Crit Care Med. 2016;44(11):1980-7. [CrossRef] [PubMed]
8. Janz DR, Semler MW, Joffe AM, et al. A multicenter randomized trial of a checklist for endotracheal intubation of critically ill adults. Chest. 2017 Sep 14. pii: S0012-3692(17)32685-5. [CrossRef] [PubMed]
9. Semler MW, Janz DR, Russell DW, Casey JD, Lentz RJ, Zouk AN, deBoisblanc BP, Santanilla JI, Khan YA, Joffe AM et al. A multicenter, randomized trial of ramped position vs sniffing position during endotracheal intubation of critically ill adults. Chest. 2017;152(4):712-2. [CrossRef] [PubMed]
10. Semler MW, Janz DR, Lentz RJ, et al. Randomized trial of apneic oxygenation during endotracheal intubation of the critically ill. Am J Respir Crit Care Med. 2016 Feb 1;193(3):273-80. [CrossRef] [PubMed]
11. Lascarrou JB, Boisrame-Helms J, Bailly A, et al. Video Laryngoscopy vs direct laryngoscopy on successful first-pass orotracheal intubation among ICU patients: a randomized clinical trial. JAMA. 2017;317(5):483-93. [CrossRef] [PubMed]

Cite as: Mosier JM, Kovacs G, Law JA, Sakles JC. The dangerous airway: reframing airway management in the critically ill. Southwest J Pulm Crit Care. 2018;16(2):99-102. doi: https://doi.org/10.13175/swjpcc004-18 PDF