Abstract
The World Health Organization has recently defined the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection a pandemic. The infection, that may cause a potentially very severe respiratory disease, now called coronavirus disease 2019 (COVID-19), has airborne transmission via droplets. The rate of transmission is quite high, higher than common influenza. Healthcare workers are at high risk of contracting the infection particularly when applying respiratory devices such as oxygen cannulas or noninvasive ventilation. The aim of this article is to provide evidence-based recommendations for the correct use of “respiratory devices” in the COVID-19 emergency and protect healthcare workers from contracting the SARS-CoV-2 infection.
Abstract
This article provides evidence-based recommendations for the correct use of “respiratory devices” in the COVID-19 emergency to protect healthcare workers from contracting the SARS-CoV-2 infection https://bit.ly/2wEcyHW
Introduction
Since the positive laboratory test result of “patient 1” in Codogno, Italy, on 21 February 2020, Italian medical health personnel have been fighting the COVID-19 disease caused by a new coronavirus, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). In the past two decades, two other coronaviruses switched hosts into humans; SARS-CoV in the Guangdong province (China), finally contained on 5 July 2003, and Middle East Respiratory Syndrome coronavirus, which has caused around 2500 cases since September 2012 [1]. The SARS and Middle East Respiratory Syndrome outbreaks were characterised by the so-called “super spreading events”, often occurring in hospitals [2].
There are currently official recommendations available on this topic from the World Health Organization (WHO) and national/international scientific societies [3–6]. The aim of this article is not only to summarise some of the official recommendations (i.e. WHO, European of Centre of Disease Prevention and Control and the Italian Department of Health), but also to provide a comparison between them.
How can we minimise contagion among healthcare professionals, what are the measures to take and what are the methods of ventilatory support at lower risk of contamination?
This article tries to answer these fundamental questions through a diversified approach.
Accordingly, this document is divided into three parts, as follows. 1) Risk of transmission during oxygen administration/high flow nasal cannula (HFNC) oxygen therapy, continuous positive airway pressure (CPAP) and noninvasive ventilation (NIV). 2) Safety measures to minimise COVID-19 transmission through contact/droplets. 3) Precautions to minimise transmission in the case of aerosol-generating procedures in COVID-19 patients.
1. Risk of transmission during oxygen administration via nasal cannula/HFNC/CPAP/NIV
The risk of transmission of respiratory infections for healthcare workers depends on several conditions; some of them are nonspecific such as prolonged exposure, inadequate hand hygiene and personal protective equipment (PPE), insufficient spacing or rooms without negative pressure or insufficient air changes every hour [7]. In healthcare workers' clinical practice, another important variable to consider is the exhaled air dispersion distance during oxygen administration and ventilatory support.
All data relating to exhaled air dispersion during such procedures come from scientific studies conducted in a negative pressure room, on a high-fidelity human patient simulator (HPS) that represents a 70 kg adult male sitting on a 45° inclined hospital bed. Exhaled air dispersion distance from the HPS has been evaluated using a laser smoke visualisation method and calculated on the median sagittal plane. Table 1 shows the maximum dispersion distances, the medium values are as follows.
Oxygen therapy via nasal cannula: exhaled air spreads from the HPS's nostrils towards the end of the bed almost horizontally to 66 cm when the oxygen flow setting is 1 L·min−1, to 70 cm when it is increased to 3 L·min−1 and 1 m when it is 3–5 L·min−1 [8].
Oxygen therapy via oronasal masks: the exhaled air jet reaches 40 cm with an oxygen flow of 4 L·min−1 [9].
Oxygen therapy via Venturi mask: exhaled air dispersion distance reduces with increasing lung injury. Delivering 24% oxygen with a flow rate at 4 L·min−1 in a normal lung and severe lung injury setting produces an air dispersion of 40 cm and 32 cm, respectively. When 40% oxygen is delivered at an 8 L·min−1 flow rate the exhaled air dispersion distance is, in the same two lung settings, 33 cm and 29 cm, respectively [10]. These distances were studied in a general ward without negative pressure, but with double exhaust fans for room ventilation. When they were off, the air ventilation rates on the ward dropped significantly and the exhaled smoke filled the ward within 5 min.
Oxygen therapy via non-rebreathing mask: exhaled air dispersion distance is <10 cm irrespective of oxygen flow rate (6–8–10–12 L·min−1) in either normal lung or severe lung injury [6].
CPAP via oronasal mask: (CPAP 5, 10, 15 or 20 cmH2O) exhaled air disperses evenly in all directions through the mask's vent holes at a very low normalised smoke concentration irrespective of the severity of lung injury [11] and, therefore, it was not feasible to measure distinct exhaled air dispersion.
CPAP via nasal cannula (nasal pillows): there is an increase of air dispersion with increasing CPAP and a reduction of air dispersion with worsening lung injury. Using two types of nasal pillows, at a maximum CPAP of 20 cmH2O and with a normal lung, maximum air dispersion distances are 26.4 cm (Nuance Pro Gel) and 33.2 cm (Swift FX) [11].
HFNC: in a normal lung, there is an increase of air dispersion distance with increasing flow to a maximum of 17.2 cm at 60 L·min−1. With this flow rate, when nasal cannula is tightly connected lateral air dispersion is negligible, otherwise it can reach 62 cm. Worsening lung injury causes a reduction in air dispersion distance from HPS [11].
NIV via full-face mask: in the Bilevel setting (inspiratory positive airway pressure (IPAP) 10 cmH2O and expiratory positive airway pressure (EPAP) 5 cmH2O) with a single limb circuit connected to HPS, the exhaled air jet spreads through the mask's holes up to 69.3 cm, 61.8 cm and 58 cm in the normal lung, mild lung injury and severe lung injury setting, respectively. Increasing IPAP leads to increasing exhaled air dispersion distance, e.g. with IPAP 18 cmH2O exhaled air jet reaches 91.6 cm [12].
NIV via helmets: with IPAP 12 cmH2O and EPAP 10 cmH2O, the exhaled air dispersion distance is 17 cm in normal lung and 15 cm in mild or severe lung injury. With IPAP 20 cmH2O the air dispersion distances in three different settings (normal lung, mild lung injury and severe lung injury) are 27, 23 and 18 cm, respectively (e.g. Oxygen Head Tent; Sea-Long, Waxahachie, TX, USA). Helmets with a tight air cushion around the neck–helmet interface, in a double limb circuit, have negligible air dispersion during NIV application (e.g. CaStar R; StarMed, Wokingham, UK) [12].
Nebulisation of drugs with the jet nebuliser causes sideways leakage of exhaled air and the distance increases with increasing lung injury. Dispersion distance is: 45 cm in the normal lung setting (oxygen consumption 200 mL·min−1, lung compliance 70 mL·cm−1 H2O); 54 cm in mild lung injury (oxygen consumption 300 mL·min−1, lung compliance 35 mL·cm−1 H2O); and 80 cm in severe lung injury (oxygen consumption 500 mL·min−1, lung compliance 10 mL·cm−1 H2O) [10].
Coughing, without wearing a mask, produces an exhaled air jet on a median sagittal plane of 68 cm from HPS (the patient); wearing a surgical mask reduces this distance to 30 cm, while wearing a N95 mask the distance was reduced to 15 cm. It is necessary to be aware that wearing a mask does not prevent air leakage between the mask and the skin; air dispersion distance is 28 cm with a surgical mask and 15 cm with a N95 mask [13].
Thus, we can state that CPAP via an oronasal mask and NIV via a helmet equipped with an inflatable neck cushion are the ventilatory support methods that allow the minimum room air contamination. However, we can argue that pressures set during NIV via helmet ventilation are relatively low. Moreover, all examined studies used smoke as the air exhaled marker, while viral transmission seems to happen through droplets; droplets are, indeed, heavier thus they should follow a briefer trajectory than the smoke. All results shown should, therefore, represent the upper limit of exhaled air dispersion and thus overestimate it. It's interesting to note, however, that all studies (except the one that used a Venturi mask) were conducted in a negative pressure room with at least six air changes per hour (minimum air changes recommended by WHO is 12 per hour) [4, 14]. In medical wards not equipped with negative pressure rooms, like those which admit most COVID-19 patients because of reduced bed availability, it is reasonable to imagine a higher exhaled air dispersion and contamination.
2. Safety measure to minimise COVID-19 transmission through contact/droplets
Exhaled aerosol size depends on the characteristics of the fluid, the force and pressure at the moment of emission, and environmental conditions (e.g. temperature, relative humidity and air flow). Large size particles remain suspended in the air for a short period and settle within 1 m from the source. Smaller particles evaporate rapidly, while dry residues slowly settle and remain suspended for a variable amount of time. Infectious respiratory aerosols are as follows. 1) Droplets: respiratory aerosol >5 µm diameter; 2) droplets nuclei: dry part of the aerosol (<5 µm diameter) which results from the evaporation of coughed or sneezed droplets or from exhaled infectious particles [14]. According to the available evidence, SARS-CoV-2 transmission occurs through droplets.
Preventive measurements for patients, healthcare workers and community
Wash your hands often with an alcohol-based (>65%) detergent if your hands are not apparently dirty, with soap and water if they are contaminated. Always wash your hands after contact with respiratory secretions
Avoid contact with eyes, nose and mouth
Sneeze and cough into a bent elbow or tissue and then throw it away
Wear a surgical mask if respiratory symptoms appear and immediately afterwards wash your hands
Keep a distance of at least 1 m from patients with respiratory symptoms
Prevention and control of suspected COVID-19 syndrome
Patient placement
Patients should be placed in isolation rooms with negative pressure (at least 12 air changes per hour) a dedicated bathroom and, if possible, an anteroom. If negative pressure rooms are not available, choose rooms with natural ventilation with airflow of at least 160 L·s−1 per patient [4]. If single rooms are not accessible, patients with suspected SARS-CoV-2 infection should be placed in the same room. Patients' beds should be located at least 1 m away from each other. It is critical that the area prepared to receive suspect patients is equipped with all the necessary PPE. All patients should wear a medical mask. It is critical to limit the number of healthcare professionals in contact with confirmed or suspected cases of COVID-19. It is better to put together a team of healthcare professionals who deal exclusively with suspected or confirmed cases to minimise the risk of transmission. A reminder to all the people who enter the patient's room is recommended, including healthcare workers and family members.
PPE
Masks and respirators
Fabric masks (cotton or gauze) should not be used and are not recommended in any circumstance. Medical or surgical masks could be flat or plated (some are cup-shaped) and suitable for covering the nose and mouth. Secure them to the head with elastics or laces. These devices are made to guarantee one-way protection for healthcare workers, in order to capture their droplets. Respirators are tight masks that must seal off the wearer's face and work in a bidirectional sense, in particular for the protection of the wearer (e.g. from dust or fibres present in the air). The American system classifies ventilators according to the percentage of particles with a diameter >0.3 µm that can be filtered by the masks themselves, while the European system distinguishes them according to the FFP1/2/3 classification. The N95 mask according to the American classification system is able to remove 95% of all particles with a diameter >0.3 µm and it is comparable to a FFP2 mask according to the European classification system (table 2) [15].
How to properly wear FFP2 and FFP3 masks
Carefully place the mask on the face and cover the nose and mouth to minimise the space between the face and mask;
While using the mask avoid touching it with your hands
Remove the mask using the appropriate technique (avoid contact with the front of the mask, remove the lace from behind)
After removal or when inadvertently touching a used mask, clean your hands using an alcohol-based cleaner or wash your hands using soap and water if visibly soiled
Throw the disposable masks away after each use in a closed bag and dispose of them immediately after removal [16]
The WHO advises healthcare workers to keep the same mask (FFP2 or higher) while routine care is being performed on multiple patients who have the same diagnosis, in order to rationalise the use of PPE and avoid an early depletion of stocks. Evidence indicates that FFP2/3 maintain their protection even when they are used for a long time. However, wearing a respirator for >4 h can cause discomfort and should be avoided [3]. Masks and respirators are important PPE for protection against SARS-COV-2, but alone are not enough.
Other PPE
Correct PPE depends on the specific activity and healthcare setting. Table 3 shows which devices should be used based on the activity and contact with the patient [3]. Healthcare workers must wear a FFP2 mask, goggles or face shield, a long-sleeved water-resistant gown and gloves. If water-resistant gowns are not available, single-use plastic aprons should be worn over the gowns to avoid body contamination. After the patient's examination, PPE must be properly stripped and disposed of. Healthcare workers should avoid contact with the eyes and nose via potentially contaminated gloves or bare hands.
Table 4 further illustrates the European of Centre of Disease Prevention recommendations for the protection of healthcare workers [5].
A recent WHO document illustrates the correct dressing and undressing procedure, while a recent Italian Department of Health indication also summarises the dressing and undressing procedure (table 5) [6]. During the undressing procedure, it is crucial to avoid contact with potentially contaminated PPE, face, skin and mucosa. It is important to dispose of single-use PPE in the undressing area.
Medical devices must be disposable or dedicated to a single patient (stethoscope, sphygmomanometer and thermometers). If these devices are used on different patients, they must be washed and disinfected after visiting each patient (using 70% ethyl alcohol). Clean and disinfect the surfaces with which patients come into contact.
Moving or transporting patients outside their room or dedicated area should be avoided if not necessary. Use portable X-ray machines or bedside chest ultrasound. If it is necessary to transport the patient, use pre-established preferential routes to minimise the exposure of healthcare professionals and other patients, by making the latter wear a mask. Make sure that transport personnel follow standard precautions and wear PPE [17].
Optimising the availability of PPE
Considering the global shortage of PPE, the following strategies can guarantee greater availability of PPE. Using PPE appropriately allows us to preserve it for situations of real transmission risk. Therefore, it is necessary to select the appropriate PPE and learn the right way to wear, remove and dispose of them properly. Strategies for optimising PPE include the following.
Telemedicine to evaluate suspected cases of COVID-19 (e.g. toll-free numbers available in Italy)
Use physical barriers to reduce exposure to the COVID-19 virus such as glass or plastic windows; this approach could be implemented in triage procedures
Limit the number of healthcare workers in patients' rooms if they are not directly involved in patient care. Schedule all the activities in order to reduce the number of times entering the patients' rooms (e.g. check vital signs when administering drugs or leaving food while performing other routine activities) and plan which activities should be carried out at the patient's bed [3]
3. Precautions to minimise transmission in case of aerosol-generating procedures in COVID-19 patients
Aerosol-generating procedures expose healthcare workers at high risk of contagion [7]. Aerosol-generating procedures include airway suction, bronchoscopy, endotracheal intubation, tracheostomy and cardiopulmonary resuscitation. In a recent publication, the WHO also includes NIV [3]. Whenever possible, these procedures should be performed, in negative pressure rooms with a minimum of 12 air changes per hour or at least 160 L·s−1 per patient in facilities with natural ventilation, according to WHO guidelines [4].
Healthcare workers performing aerosol-generating procedures should wear a waterproof long-sleeved gown, double non-sterile gloves, eye protection (with lateral protection) and a respirator that ensures a level of protection equal or greater than N95/FFP2 (table 2). The document issued by the European Centre for Disease Prevention and Control suggests a FFP3 mask for aerosol-generating procedures (table 3) [5].
The practical recommendations for critical care and anaesthesiology teams released by a group of Canadian anaesthesiologists [18] also suggest the following additional measures for endotracheal intubation.
Prioritise a planned early intubation rather than an emergency intubation, at high risk of contagion
If possible, avoid bag-mask ventilation
Ensure adequate patient sedation
Minimise the number of healthcare workers in the room to essential team members
Provide all necessary equipment and medication in the room, do not use the crash trolley
This document also suggests wearing a shield visor in addition to protective goggles in order to guarantee double protection. Canadian anaesthesiologists' advice to consider the use of powered air purifying respirators (PAPRs) for high-risk procedures (figure 1). PAPRs use a battery-powered fan to conduct air through a filter allowing the wearer to breathe through a mask or a helmet. PAPRs may offer greater protection than FFP2, even if there is no evidence about comparison of these PPEs in terms of viral transmission. However, the use of PAPRs is burdened by the high costs and communication limits determined by the noise of the fan. Another risk that must be considered is the high probability of contamination during the undressing procedures, which makes it necessary to support healthcare workers with expert staff.
More specific precautions are provided by the Chinese Thoracic Society [19], which gives further suggestions for the treatment and ventilatory support of COVID-19 patients.
Do not use humidifiers during conventional oxygen therapy
The patient has to wear the surgical mask to reduce contamination risk of the room
During HFNC treatment, ensure correct placement of the nasal cannulas (which must be completely inserted in the nostrils and secured with the elastic bands on the patient's head in order to minimise lateral losses). Place a surgical mask over the nasal cannulas (figure 2)
During NIV support, use a double-limb circuit with a non-vented mask. Place three filters per ventilator: between the expiratory port and the ventilator; between the inspiratory port and the ventilator; and another filter near the patient's mask. The interface with the lowest risk of aerosol emission is the helmet equipped with an inflatable neck cushion
If bag-mask ventilation is needed, place a filter between the bag valve and the mask/endotracheal tube to reduce airborne contamination
Use closed circuits in case suction is needed
Use PPE during bronchoscopy
Ensure the patient wears a cap that also covers the eyes in order to reduce the risk of face contamination (with eye discharge) during bronchoscopy. Place a suction catheter in the patient's oral cavity to ensure a local negative pressure that reduces the droplets released by the patient. Cover the patient's mouth with a mask. The suction circuit must be closed. If patient is supported by NIV, use the access through the hole on the patient's mask
A shower is recommended after undressing, including disinfection of the ears and mouth
Conclusions
According to evidence, approximately 20% of COVID-19 patients develop a severe or critical form of disease (Adult Respiratory Distress Syndrome), which in 19–32% of cases requires respiratory support treatment [20]. Oxygen therapy, HFNC, CPAP and NIV are noninvasive support methods with a high risk of aerosol dispersion, especially in unprotected environments. Being aware of the exhalation distance of the various methods allows us to favour those with the lowest risk (e.g. helmet with an inflatable neck cushion) and to take the necessary precautions (e.g. correct placing of the HFNC). Despite the high risk of contagion during these procedures, evidence suggests that the observance of the indications for the use of PPE are effective in preventing infections among healthcare workers. In a case–control study conducted during the SARS epidemic in Hong Kong [21] which investigated the effective adhesion of personnel to PPE (gloves, disposable shirts, goggles and masks) none of the staff reporting use of all measures contracted the virus, while all the infected staff had omitted at least one measure. Given the high risk of emission of large quantities of droplets, aerosol-generating procedures require greater precaution by healthcare personnel.
Footnotes
Provenance: Submitted article, peer reviewed
Conflict of interest: M. Ferioli has nothing to disclose.
Conflict of interest: C. Cisternino has nothing to disclose.
Conflict of interest: V. Leo has nothing to disclose.
Conflict of interest: L. Pisani has nothing to disclose.
Conflict of interest: P. Palange has nothing to disclose.
Conflict of interest: S. Nava has nothing to disclose.
- Received March 24, 2020.
- Accepted March 27, 2020.
- Copyright ©ERS 2020.
This article is open access and distributed under the terms of the Creative Commons Attribution Non-Commercial Licence 4.0.