REVIEW ARTICLE Year : 2021  |  Volume : 37  |  Issue : 2  |  Page : 171-178

The barrier techniques for airway management in covid-19 patients - review of literature

Pratishtha Yadav, Rakesh Garg
Department of Onco-Anaesthesia and Palliative Medicine, Dr BRAIRCH, All India Institute of Medical Sciences, New Delhi, India

Date of Submission06-Jul-2020Date of Decision13-Apr-2021Date of Acceptance14-Apr-2021Date of Web Publication15-Jul-2021

Correspondence Address:
Dr. Rakesh Garg
Department of Onco-Anaesthesia and Palliative Medicine, Dr. BRAIRCH, All India Institute of Medical Sciences, Room No. 139, First Floor, Ansari Nagar, New Delhi - 110 029
India

Source of Support: None, Conflict of Interest: None

Check

DOI: 10.4103/joacp.JOACP_411_20

The coronavirus disease 2019 (COVID-19) has emerged as a pandemic and shall prevail for some time around the globe. The disease can manifest from asymptomatic to severe respiratory compromise requiring airway intervention. Transmission of COVID-19 has been reported to be by droplets, fomites, and aerosols, and airway management is an aerosol-generating procedure. The high viral load in the patient's airway puts the clinician performing intubation at a very high risk of viral load exposure. So, the need for barrier devices was considered and led to reporting of various such devices. All these devices have been reported individually and have not been compared. We present a review of all the information on these devices based on the reported literature.

Keywords: Aerosol, airway, barrier, containment devices, COVID-19, extubation, intubation

How to cite this article:
Yadav P, Garg R. The barrier techniques for airway management in covid-19 patients - review of literature. J Anaesthesiol Clin Pharmacol 2021;37:171-8
How to cite this URL:
Yadav P, Garg R. The barrier techniques for airway management in covid-19 patients - review of literature. J Anaesthesiol Clin Pharmacol [serial online] 2021 [cited 2021 Jul 15];37:171-8. Available from: https://www.joacp.org/text.asp?2021/37/2/171/321422   Introduction 

The coronavirus disease 2019 (COVID-19) was first reported from Wuhan, China in December 2019 and it spread outside China to almost the whole of the world.[1] Since its outbreak in December 2019, the speed and severity of COVID-19 have overwhelmed the healthcare system and its providers.

Transmission of COVID-19

Transmission of COVID-19 has been reported to be by droplets, fomites, and aerosols.[2],[3] The clinical spectrum ranges from asymptomatic or mild illness to severe life-threatening complications i.e., acute respiratory distress syndrome (ARDS).[1],[4],[5] Some of the severe cases require tracheal intubation and invasive ventilation.[6] The health care providers are at constant risk of cross-contamination during the aerosol-generating procedure like laryngoscopy, tracheal intubation, extubation, tracheal suctioning, emergency surgical airway, high flow nasal cannula (HFNC), non-invasive ventilation (NIV), etc.[7],[8]

The need for barrier devices

Apart from the personal protection equipment such as face masks, face shields, and eye protection gear, several other techniques and equipment have been reported to restrict the exposure of healthcare workers to aerosols generated during airway management. One such innovation is the barrier device or aerosol box or intubation box [Table 1]. These devices are made up of various materials and have evolved to circumvent the limitations of previous devices [Table 2]. Though these devices have not been evaluated in a robust randomized controlled trial, they appear to have advantages along with some limitations as well. We reviewed the literature published on the use of various barrier devices till 20th January 2021 for airway management in COVID-19 patients.

Rigid-box type - without negative suction

Aerosol box

Dr. Hsien Yung Lai introduced a device named aerosol box designed to act as a barrier to contain aerosols.[9] It is a transparent box with 5 sides made of acrylic or polycarbonate sheets to fit over the face and chest of the patient. It has two holes on the same side. Although simple, the design is bulky with limited space and restricts hand movement. There is no provision for an assistant to reach inside and provide airway aids.

Modified aerosol box

Later, a modified version was taller and bigger and with side ports than the original design as released.[10] The design is ergonomically superior as it can accommodate obese patients, allows the use of the ramp, and extra space for airway maneuvering. Also, the top part is sloping to reduce the glare and suitable for short-statured operators. Further, it was modified by the addition of the front lip and base support to prevent it from slipping, if the head end is raised.

Aerosol box 2.0

Aerosol box 2.0 is a lightweight crystalline box with four circular access ports, two for the clinician and two lateral access ports for the assistant.[11] Clips are added to hold the suction device and video laryngoscope. The design is angulated to allow easy accessibility. This updated design is supposed to provide better protection and reduce macroscopic contamination.

Modified neonatal incubator hood

Rahmoune et al.,[12] recycled and reused neonatal incubator hood into a barrier device. The portholes provide entry to the hands of the operator, and the side ports can be used by an assistant to perform additional maneuvers. The main drawbacks are heavy design, and its cleaning can be cumbersome.

Two-piece modification of barrier box

To circumvent unanticipated difficult intubation, Chen G et al.,[13] suggested dividing the box into two pieces- the top and the bottom for its easy removal. Semi-lunar cuts are scooped out on both halves to make armholes for the operator.

Intubation box-IIT Guwahati

The students of the Indian Institute of Technology (IIT), Guwahati have developed 'low cost intubation boxes' made of transparent acrylic sheets with armholes on one side.[14]

Rigid-box type - with negative suction

Placement of a barrier device solely cannot impart full protection from the aerosols as small droplets remains suspended in the environment. To solve this problem, the provision of negative suction rooms was put forward.[15]

Negative pressure intubation box by Bon Secours St. Francis

The engineering team at the Bon Secours Health Systems facilities has designed a negative pressure acrylic box with two armholes with rubber gaskets.[16] Negative suction is created with a help of vacuum attachment connected to the intubation box via hose pipes with an intervening High-efficiency particulate air (HEPA) filter.

Thalia intubation box 2.0

Thalia intubation box is the thermo-formed acrylic box with an angled viewing window.[17] It is taller with reduced width and length as compared to the original Thalia box. The box has three arm ports. An additional 7/8 inch vacuum port is added.

Sheet type-without negative suction

The plastic sheet barrier device shields the operator against aerosol spray and imparts protection to the health worker. Other points to be considered are the time required to set up, patients' tolerance to the device, ease of disposal or decontamination of the device after use, and cost and production of the device. The aerosol boxes provide protection but are bulky, time-consuming to set up, and may restrict hand movement. This has led to the development of an economical alternative i.e., sheet-based barrier devices.

Modified double plastic sheets

Ibrahim et al.,[18] described the use of double plastic drapes made up of disposable bags. Improvised double sheets can be made by making a 12-15 cm radius facial opening on the lower layer of the disposable plastic sheet. Two 7 cm long openings are made on the lateral side of the upper layer to allow passage of clinicians' hands to perform airway maneuvers. The proximal ends of the sheets are sealed and taped to the procedure table and the distal ends are taped at the patient's chest. Due to the flexibility of the plastic sheets, the restriction of hand around the armholes is less as compared to rigid boxes. Modified double plastic sheets provide almost equivalent protection as compared to modified aerosol boxes.[17]

Plastic on bag barrier drape system

Another modification of plastic clear sheets is proposed by Brown et al.,[19] This plastic on bag barrier drape system requires a 40 gallons drawstring bag and a clear rectangular plastic sheet. The drawstring bag covers the head end of the patients' table. Another rectangular plastic sheet is taped at the chest level and rolled over the patient's head including the anesthesiologist's hands underneath. To tighten the sheet downwards, a clamp was attached to it. In the end, the patient can be extubated in between the sheets and sheet along all disposables are rolled on a drawstring bag and disposed.

Three-drape technique

Aerosols and the droplets generated during the procedure can settle on any surface and act as a source of contamination. Matava et al.,[20] suggested a low-cost three-drape technique where three clear plastic drapes, first one is placed below the patient's head over the procedure table, the second covers the torso from the neck down, and the third covers the patient's head from mid sternum level to prevent spillage to the surrounding areas.

Adaptation of plastic barrier sheet

Yang YL et al.,[21] have put forward a simple innovative idea to use a plastic sheet with two cross cuts (X) across the drape reinforced using tape. First 'X' is to pass the anesthesia breathing circuit and the smaller second cut is to allow passage of video laryngoscope, endotracheal tube, or suction tip.

Extubation barrier drape

Extubation barrier drape comprises of a large clear plastic drape (137 × 229 cm) with a small 1-2 cm slit.[22] The assembly is placed around the tracheal tube and sealed with tape before extubation. When the patient is extubated, the drape will contain all the aerosols generated during the extubation. In the end, the drape can be discarded along with the tracheal tube.

Sheet type-with negative suction

Negative pressure barrier tent for Extubation

During tracheal intubation, the patient is paralyzed and if the adequate depth is maintained, the degree of aerosolization can be drastically reduced. Whereas, during extubation the patient is awake and there is a high probability of coughing and aerosol generation. A simple technique has been suggested by Hung et al.,[23] to be used during extubation. It comprises a tent made up of clear plastic sheet and negative suction. The plastic bag is split from one side and placed over the patient like a tent with an apical hole. The bag is secured with tape around the endotracheal tube to create a tight seal. The whole arrangement is such that the patient with the distal end of the endotracheal tube lies within the tent and the ventilatory circuit with the proximal end lies outside the tent. While pulling out the endotracheal tube the plastic tent is gently lifted creating a negative suction inside the tent. The aerosols generated are removed via endotracheal tube tip and into the attached filter. A simulated study has also demonstrated suspended drifting of the droplet nuclei towards the endotracheal tube tip inside the tent. Thus, this negative pressure barrier tent has the potential to contain large as well as smaller aerosols.

Hybrid type-without negative suction

The rigid-box type barrier devices are made up of plexiglass which is bulky and difficult to transport. The decontamination of boxes is often cumbersome. To overcome this issue, a hybrid device with qualities of both rigid box and the flexible sheet was invented.

Portable light hood device

A portable light hood device, a type of hybrid barrier device comprised of a light-weighted PVC framework covered with semi-transparent nylon sheets on four sides with two sides uncovered.[24] The uncovered sides allow the hood to be placed over the chest for airway management. After use, the contaminated nylon sheets can be disposed-off.

COVID intubation tent/box

Another barrier device in the list is the COVID tent/box put forward by 'Your Design Medical'.[25] Its design is based on two principles- negative pressure and directional shielding. It comprises of 'L' shaped framework made up of 6 ½ inch PVC pipes of length 23.5 inches each. PVC pipes are put together with the help of four 3-way and curved standard fittings at junctions. The whole framework is then covered with a clear vinyl sheet forming a pyramid-shaped hood. The sheet can be cut out within seconds to make way for the clinician's and assistant's hands. Overhead arms 6 inches long can be added on the top braces, this prevents the sheets from falling over the patient creating additional space.

Intubation aerosol containment system (IACS)

IACS comprises of two parts, a polycarbonate barrier (PCB) with two circular arm ports and a transparent plastic drape attached to the upper and lateral edges of PCB.[26] The sheet extends up to the chest and lower limbs of the patient. The front side is slanting downwards, and the upper portion is tapered towards the patient to allow an optimal view of the patient. IACS was tested with a commercial fog machine, no escape of mist was noticed.

Patient Particle Containment Chamber (PPCC)

It has a modified octagonal PVC pipe framed structure with shower liner drape secured with binder clips with a weighted tube to contour the patient.[27] The simulation experiment demonstrated that PPC can contain 99% of the spray paint particles sprayed over 90 secs.

Hybrid type-with negative suction

Vacuum-assisted negative pressure isolation hood (VANISH) system

A mobile and readily available Stryker Neptune™ (Stryker Corporation, Kalamazoo, Michigan) high-powered suction system is added to the conventional design to create a negative pressure biohazard isolation environment.[28] As compared to the wall suctions, the Stryker Neptune generates greater suction with better air exchange.[29],[30] Moreover, the in-line Stryker Neptune HEPA filter can be used in multiple patients and need not be replaced for each new patient.

Aerosol containment enclosure (ACE)

Aerosol containment enclosure (ACE) is a combination of modified intubation box with a provision for negative suction.[31] It comprises a silicone gasket with arm ports for the main operator and an assistant. The size of the gasket is wide enough to suit a wide range of patients. The roof is sloping to prevent glaring and ensure optimal visualization. Arm ports are wider, and a silicon gasket is added to improve the seal around the arms. A high-density polyethylene sheet extends from the gasket to cover the whole of the patient. There is a provision to generate negative pressure using two hospitals' suctions. ACE with negative pressure has been shown to contain airborne particles in a simulation study.[31]

COVID-19 Airway Management Isolation Chamber (CAMIC) system

CAMIC[32] comprises of polyvinyl chloride hollow frame with fenestrations, covered with a clear surgical bag. There are an internal suction and oxygen delivery system that creates laminar flow and facilitates evacuation of droplets. Preliminary tests have demonstrated the removal of >99% of smoke and nebulized saline particles with the minimal leak. It can also be used during non-invasive airway management like high flow oxygen, nebulization, continuous positive airway pressure ventilation.

Evidence for aerosol containment boxes in clinical practice

The majority of the barrier devices invented are plastic drape type (59%) and the rest are box type (42%).[33] Due to time constraints, to date, no large-scale randomized control trial has been conducted to provide solid evidence in support of these devices. The majority of the recommendations are based primarily on the visual assessment of aerosol and droplet spread. Experiments simulating cough in a mannequin have been conducted to check their efficacy. Box type was the first barrier device described but is often associated with the delay in time to intubation and worsening of laryngoscopic views. On the other hand, the plastic sheet system apart from being simplistic has demonstrated better efficacy and usability so far.[33]

Canelli et al.,[34] conducted a simulation study mimicking cough, using a fluorescent dye (10 mL) filled latex balloon placed at the hypopharynx of the mannequin. They reported that when an aerosol box was used, the dye was observed only inside the box, gloves, and gown of the clinician. Although, the box restricts hand mobility and makes the use of additional aids difficult.

To determine the efficacy and superiority over the previously described aerosol boxes, Ibrahim et al.,[18] performed a simulation using a tracheal tube cuff balloon filled with 30 mL fluorescent dye. The balloon was inflated till it burst, simulating a cough. The experiment was performed in 4 settings: with PPE only, with aerosol box, modified aerosol box, and modified double plastic drapes. Both modified aerosol boxes and modified double plastic sheets provided good protection in this mannequin study but one must be aware of its limitations and use it only as an adjunct to PPE methods.

Another simulation study on pediatric mannequin covered with single clear plastic drape, three drapes technique and without any barrier technique was performed using 0.5 mL of fluorescent resin powder. The degree of aerosolization was reduced with a single drape technique but the maximum reduction was demonstrated using the three-drape technique.

Chahal et al.,[31] evaluated protective capability and differential pressures generated in aerosol containment enclosure (ACE) with negative pressure. Authors observed that the device could contain smoke, fluorescein, and sodium saccharine aerosol in all the experimental settings as compared to identical barrier devices with non-occluded ports and ambient pressures.

An in-situ simulation cross-over study to evaluate the impact of two aerosol boxes (an early-generation and a latest-generation box) on intubation in patients.[35] Intubation time without the box was found to be significantly shorter as compared to use of any of the boxes. It was stated that aerosol boxes can increase intubation time and may expose patients to the risk of hypoxia. In one case breach of PPE was also noted.

Since the introduction of the aerosol box, there has been a race to develop more innovative equipment, although none of them have been tested in ideal patient conditions. Some of them were tested by simulating cough in a mannequin but the method of simulation cannot be considered ideal. Considering the limitation of previous simulation models, another attempt was made by Simpson et al.,[36] with more standardized equipment. The authors used Hudson RCI "Micro Mist" small volume nebulizer (Teleflex, Wayne, PN, USA) without facemask and generated aerosols of size 0.3-5.0 micron by nebulization of 5 mL saline at 6 L/min flow. The authors reported that the sealed intubation box decreases the spread of 0.3 to 2.5-micron particles as compared to a setup with no device. No difference was noted between no device, horizontal drape, and vertical drape setups. Finally, a significant increase in airborne particle exposure was noted when the patient coughed within an aerosol box as compared to other devices or no device. This is supported by a simulation study of Dalli et al.,[37] which demonstrated that there is a substantial escape of contaminated air from armholes, especially during coughing. The sealed box with suction was able to demonstrate adequate protection, but only if continuous suction is applied.

Fried et al.,[38] simulated coughs in both box and sheet type intubation boxes. It was inferred that both types can contain droplets during simulated coughs but redirect aerosolized particles towards the foot end.

Considering the lack of resources, a hybrid barrier device with negative suction that can be partially reused with easy decontamination can be appropriate for the Indian resource-limited setting. But we must always emphasize the use of other personal protective equipment along with proper hand hygiene.[39]

The aerosol generation under regional techniques

Patients undergoing surgery under regional anesthesia also possess the risk to health care workers. The use of the triple-layer mask is an accepted norm for patients. Even in cases, where oxygen supplementation is required, a triple-layered surgical mask should be worn over the oxygen delivery device.

  Conclusion 

There is an urgent need for testing these devices in real-time clinical settings. It must be kept in mind that these kinds of devices cannot replace existing PPE precautions; rather they can be used as an additional aid to PPE. The use of such boxes must never compromise a patient safety or complicate the procedure. There is very limited data supporting such barrier devices, and we must embrace such innovations with caution.

Financial support and sponsorship

Nil.

Conflicts of interest

There are no conflicts of interest.

 

  References 
1.Guan WJ, Ni ZY, Hu Y, Liang WH, Ou CQ, He JX, et al. Clinical characteristics of coronavirus disease 2019 in China. N Engl J Med 2020;382:1708-20.  
    2.Van Doremalen N, Bushmaker T, Morris DH, Holbrrok MG, Gamble A, Tamin A, et al. Aerosol and surface stability of SARS-CoV-2 as compared with SARS-CoV-1. N Engl J Med 2020;382:1564-7.  
    3.Yu IT, Qiu H, Tse LA, Wong TW. Severe acute respiratory syndrome beyond Amoy Gardens: Completing the incomplete legacy. Clin Infect Dis 2014;58:683–6.  
    4.Huang C, Wang Y, Li X, Ren L, Zhao J, Hu Y, et al. Clinical features of patients infected with 2019 novel coronavirus in Wuhan, China. Lancet 2020;395:497–506.  
    5.Chen N, Zhou M, Dong X, Qu J, Gong F, Han Y, et al. Epidemiological and clinical characteristics of 99 cases of 2019 novel coronavirus pneumonia in Wuhan, China: A descriptive study. Lancet 2020;395:507–13.  
    6.Yang X, YuY, Xu J, Shu H, Xia J, Liu H, et al. Clinical course and outcomes of critically ill patients with SARS-CoV-2 pneumonia in Wuhan, China: A single-centered, retrospective, observational study. Lancet Respir Med 2020;8:P475-81.  
    7.Tang JW, Tambyah PA, Hui DS. Emergence of a novel coronavirus causing respiratory illness from Wuhan, China. J Infect 2020;80:350–71.  
    8.Ong SW, Tan YK, Chia PY, Lee TH, Ng OT, Wong MS, et al. Air, surface environmental, and personal protective equipment contamination by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) from a symptomatic patient. JAMA 2020;323:1610-2.  
    9.Everington K. Taiwanese doctor invents device to protect US doctors against coronavirus. Taiwan News. Available from: https://www.taiwannews.com.tw/en/news/3902435. [Last accessed on 2020 Apr 05].  
    10.Malik JS, Jenner C, Ward PA. Maximising application of the aerosol box in protecting healthcare workers during the COVID-19 pandemic. Anaesthesia 2020;75:974-5.  
    11.López Hernández MN, Álvarez Reséndiz GE, Galván Talamantes Y, Lagarda Cuevas J, Wilson-Manríquez EA, Calva Ruiz DS, et al. Aerosol box 2.0: Adjustments and improvements made in Mexico for intubating patients during the coronavirus disease 2019 pandemic. A A Pract 2020;14:e01273.  
    12.Rahmoune FC, Ben Yahia MM, Hajjej R, Pic S, Chatti K. Protective device during airway management in patients with Coronavirus disease (COVID-19). Anesthesiology 2020;133:473-5.  
    13.Chen G, Irie T. COVID-19 Safety Innovations: Intubation-Extubation Boxes v3: Thinking Inside the Box. Available from: https://www.mskcc.org/clinical-trials-updates/msk-covid-19-innovation-hub/covid-19-safety-innovations-intubation-extubation-boxes. [Last accessed on 2020 Apr 05].  
    14.Kanagaraj S, Kapil S. IIT Guwahati students design, develop low-cost intubation boxes. Available from: https://health.economictimes.indiatimes.com/news/medical-devices/iit-guwahati-students-design-develop-low-cost-intubation-boxes/7548985.[Last accessed on 2020 Apr 05].  
    15.World Health Organization, Pandemic and Epidemic Diseases, World Health Organization. Infection prevention and control of epidemic- and pandemic-prone acute respiratory infections in health care: WHO Guidelines. 2014. Available from: http://apps.who.int/iris/bitstream/10665/112656/1/9789241507134_eng.pdf?ua=1. [Last accessedon 2020 Apr 05].  
    16.Walsh D, Engineering facility, Bon Secours Health System's, (2020, April) Bon Secours St. Francis develops negative pressure intubation box. Available from: https://greenvillejournal.com/health/bon-secours-st-francis-develops-negative-pressure-intubation-box/. [Last accessed on 2020 Apr 05].  
    17.Thalia Covid-19 intubation box 2.0. Available from: https://www.thaliacapos.com/pages/thaliabox#4874891. [Last accessed on 2020 Apr 05].  
    18.Ibrahim M, Khan E, Babazade R, Simon M, Vadhera R. Comparison of the effectiveness of different barrier enclosure techniques in protection of healthcare workers during tracheal intubation and extubation. AA Pract 2020;14:e01252.  
    19.Brown S, Patrao F, Verma S, Lean A, Flack S, Polaner D. Barrier system for airway management of COVID-19 patients. Anesth Analg 2020;131:e34-5.  
    20.Matava CT, Yu J, Denning S. Clear plastic drapes may be effective at limiting aerosolization and droplet spray during extubation: Implications for COVID-19. Can J Anaesth 2020;67:902-4.  
    21.Yang YL, Huang CH, Luk HN, Tsai PB. Adaptation to the plastic barrier sheet to facilitate intubation during the COVID-19 pandemic. Anesth Analg 2020;131:e97-9.  
    22.Patino Montoya M, Chitilian HV. Extubation barrier drape to minimise droplet spread. Br J Anaesth 2020;125:e195-6.  
    23.Hung O, Hung D, Hung C, Stewart R. A simple negative-pressure protective barrier for extubation of COVID-19 patients. Can J Anaesth 2020;1-3. doi: 10.1007/s12630-020-01720-6.  
    24.Kangas-Dick AW, Swearingen B, Wan E, Chawla K, Wiesel O. Safe extubation during the COVID-19 pandemic. Respir Med 2020;170:106038. doi: 10.1016/j.rmed. 2020.106038.  
    25.Henneman J. Creating a biohazard space for COVID19 intubation: A covid intubation tent/box. Your Design Medical. Available from: https://yourdesignmedical.com/blogs/making-a-safe-intubation-space-for-covid19/creating-a-biohazard-space. [Last accessed on 2020 Apr 05].  
    26.Gore RK, Saldana C, Wright DW, Klein AM. Intubation containment system for improved protection from aerosolized particles during airway management. IEEE J Transl Eng Health Med 2020;8:1600103.  
    27.Maloney LM, Yang AH, Princi RA, Eichert AJ, Hébert DR, Kupec TV, et al. A COVID-19 airway management innovation with pragmatic efficacy evaluation: The patient particle containment chamber. Ann Biomed Eng 2020;48:2371-6.  
    28.Convissar D, Chang CY, Choi WE, Chang MG, Bittner EA. The Vacuum Assisted Negative Pressure Isolation Hood (VANISH) system: Novel application of the stryker neptune suction machine to create COVID-19 negative pressure isolation environments. Cureus 2020;12:e8126.  
    29.Are there guidelines for anesthesia suction?. 2015. Available from: https://www.apsf.org/article/are-there-guidelines-for-anesthesia-suction/. [Last accessed on 2020 Apr 05].  
    30.Neptune 2 waste management system site preparation, installation, and maintenance guide. 2015. Available from: http://mplusmedtech.com/16001/pdf/11686.pdf. [Last accessed on 2020 Apr 05].  
    31.Chahal AM, Dewark KV, Gooch R, Fukushima E, Hudson ZM. A rapidly deployable negative pressure enclosure for aerosol-Generating medical procedures. medRxiv 2020. doi: 10.1101/2020.04.14.20063958.  
    32.Blood TC Jr, Perkins JN, Wistermayer PR, Krivda JS, Fisher NT, Riley CA, et al. COVID-19 airway management isolation chamber. Otolaryngol Head Neck Surg 2021;164:74-81.  
    33.Price C, Ben-Yakov M, Choi J, Orchanian-Cheff A, Tawadrous D. Barrier enclosure use during aerosol-generating medical procedures: A scoping review. Am J Emerg Med 2021;41:209-18.  
    34.Canelli R, Connor CW, Gonzalez M, Nozari A, Ortega R. Barrier enclosure during endotracheal intubation. N Engl J Med 2020;382:1957-8.  
    35.Begley JL, Lavery KE, Nickson CP, Brewster DJ. The aerosol box for intubation in coronavirus disease 2019 patients: An in-situ simulation crossover study. Anaesthesia 2020;75:1014-21.  
    36.Simpson, JP, Wong DN, Verco L, Carter R, Dzidowski M, Chan PY. Measurement of airborne particle exposure during simulated tracheal intubation using various proposed aerosol containment devices during the COVID-19 pandemic. Anaesthesia 2020. doi: 10.1111/anae. 15188.  
    37.Dalli J, Khan M, Marsh B, Nolan K, Cahill R. Evaluating intubation boxes for airway management. Br J Anaesth 2020;125:e293-5.  
    38.Fried EA, Zhou G, Shah R, Shin DW, Shah A, Katz D, et al. Barrier devices, intubation, and aerosol mitigation strategies: PPE in the time of COVID-19. Anesth Analg 2021;132:38-45.  
    39.Kearsley R. Intubation boxes for managing the airway in patients with COVID-19. Anaesthesia 2020;75:969.  
    

 
 

  [Table 1], [Table 2]