Abstract
Since the diagnosis of the first case of COVID-19 in December 2019, there have been reports of several healthcare workers infected with COVID-19. It has changed the infection control practices of most ICUs all over the world. Prevention is better than cure is definitely proven true as there is no definite cure for COVID-19 yet. Personal protective equipment and hand hygiene are a must while handling any suspected COVID-19 patient. Apart from that, there are several other things, which should be followed in ICU and specifically while caring for a patient on ventilator. There are a large number of interventions done while treating any critically ill patient in ICU, which can generate aerosols and exaggerate spread of COVID-19, which include high-flow nasal cannula, NIV, nebulization, suctioning, bag and mask ventilation, endotracheal intubation, and bronchoscopy. We will be reviewing those things beyond PPE and hand hygiene along with the rationale of each of them, which can help to minimize the risk of exposure to healthcare workers and other patients in the surrounding. It will help not only to prevent COVID-19 transmission but also to reduce overall nosocomial infection rate. As per our knowledge, this will be the first paper reviewing innovative ideas to minimize the risk of infection in a comprehensive manner.
How to cite this article: Shah V, Tyagi N, Trivedi D. Extra Precautions while Caring for a Suspected COVID-19 Patient in an ICU beyond PPE and Hand Hygiene. Indian J Crit Care Med 2021;25(3):331–336.
Keywords: Corona, COVID, High-flow nasal cannula (HFNC) oxygen therapy, ICU, Infection, Infection control, Mask, Nosocomial infection
INTRODUCTION
Since the diagnosis of the first case of COVID-19 in December 2019, there have been reports of several healthcare workers infected with COVID-19. It has changed the infection control practices of most ICUs all over the world. Prevention is better than cure is definitely proven true as there is no definite cure for COVID-19 yet. Personal protective equipment and hand hygiene are a must while handling any suspected COVID-19 patient. Apart from that, there are several other things, which should be followed in ICU and specifically while caring for a patient on ventilator. There are a large number of interventions done while treating any critically ill patient in ICU, which can generate aerosols and exaggerate spread of COVID-19, which include high-flow nasal cannula, NIV, nebulization, suctioning, bag and mask ventilation, endotracheal intubation, and bronchoscopy.
In this article, we will not be discussing routine infection control measures (e.g., proper PPE and mask/respirator usage, hand hygiene, isolation practices, disinfection of equipment, environmental cleaning, and spacing of beds) assuming they are already being followed. We will be reviewing various other minor but important things, which need to be considered for extra precautions, which can help to minimize the risk of exposure to healthcare workers and other patients in the surrounding (Fig. 1). It will help not only to prevent COVID-19 transmission but also to reduce overall nosocomial infection rate. As per our knowledge, this will be the first paper reviewing innovative ideas to minimize the risk of infection in a comprehensive manner.
Fig. 1.
Overview of extra precautions while caring for COVID-19 patient in ICU
1. Maximize air exchanges and negative pressure isolation1–3
Either natural ventilation with airflow of at least 160 L/s per patient or in negative pressure rooms with at least 12 air changes per hour is recommended during any aerosol-generating procedures. HEPA filter unit is required for the recirculation of air. One hundred percent fresh air system is better but may not be available. Apart from this, the direction and pattern of airflow are also important, and it should be from clean to dirty and laminar distribution pattern. Use area with maximum number of air changes per hour to manage critically ill COVID-19 patient to minimize the risk of cross-infections. Most of the doctors may not be aware about heating, ventilation, and air conditioning (HVAC) system in their hospital. One should confirm the number of air changes with their maintenance department and intimate them to create negative pressure if possible. If negative pressure isolation is not available, ask maintenance staff if they can create relatively negative or less positive pressure by changing flow rates.
2. Minimize transport and minimize opening and closing of the door4
Whenever opening the door, close the door as soon as possible. Minimize transport of the patient inter- or intrahospital. Transport of patient may be required for several reasons, and it is really challenging to comply with full infection control measures. Proper planning of transport route and coordination between various departments are of upmost importance. Detailed discussion on transport protocol is beyond the scope of this article.
3. Oxygen
Use minimum flow of oxygen required. Prefer low-flow oxygen delivery devices over high flow whenever possible. Use surgical/N95 mask over patient's face whenever using nasal cannula or any patient without artificial airway to minimize aerosol spread.
Size of corona virus is 125 nm.5 Due to such small size, filter is mandatory when managing any patient with COVID-19 on ventilator.
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Five types of devices are available:
Heat and moisture exchanger (HME) without filter,
Mechanical/hydrophobic filter,
Electrostatic filter,
Heat and moisture exchanger with mechanical/hydrophobic filter (HMEF), and
Heat and moisture exchanger with electrostatic filter (HMEF).
Out of these five types, HME with electrostatic filter and HME without electrostatic filter are most commonly available and used in India.
For bacterial and viral filters, one that filters particles in size >0.2–0.3 μm with >95% viral filtration efficiency (VFE) should be used. VFE of 99.99% means that only one particle in 104 will pass through the filter under standard test conditions and usually at flow rate of 30 L/min, so the higher the flow rate, the lower the efficiency.
Mechanical filter has more dead space and requires minimum 150 mL of tidal volume, but it is more efficient and less affected by water vapor.
Use heat and moisture exchanger and high-efficiency bacterial/viral filter (HMEF) between catheter mount connected to facemask (when using NIV or doing bag and mask ventilation) or endotracheal or tracheostomy tube and Y-piece of ventilator circuit or Ambu bag/self-inflating bag (Fig. 2A).
Use high-efficiency bacterial/viral filter on the expiratory port of ventilator (Fig. 2B).
Mechanical filters are preferred over electrostatic filters.
Avoid using heated humidifier. Theoretically, it decreases the risk of room contamination during the disconnection of circuit but increases viral load in circuit. It increases the risk of blockage of the filter.
Keep in mind higher resistance due to HME filter and change immediately when blocked or soiled. It should be changed routinely every 48 hours or as per manufacturer recommendation.
Figs 2A and B.
(A) HME filter between catheter mount and Y-piece; (B) HME (without filter) at expiratory limb of ventilator circuit (right)
5. High-flow nasal cannula (HFNC)11,12
HFNC is recommended by surviving sepsis campaign guidelines, and it is preferred over NIV whenever available.
If using high-flow nasal cannula, use medical or N95 mask to cover patient's mouth and nose. Use minimum flow required to avoid aerosol spread.
6. Noninvasive ventilation (NIV)12
Use full facemask over nasal or oronasal mask to minimize aerosol spread.
Use mask with bronchoscopy port when doing bronchoscopy. Ideally, bronchoscopy should be avoided as it creates aerosol spread (Fig. 3).
Mask should have tight seal and minimum leak.
Mask should be nonvented. Vented masks should be avoided.
Avoid using single-limb circuit over dual-limb circuit. If using portable CPAP machine and need to single-limb circuit, use exhalation valve in circuit and keep HME filter between facemask and exhalation valve in circuit.
Use minimum effective pressure (pressure support/inspiratory pressure and PEEP).
Fig. 3.
NIV mask for bronchoscopy (upper arrow for oral route and lower arrow for nasal route)
7. Precautions for intubation11,13–15
Early versus late intubation is controversial as per available data till now. Decision to intubate should be individualized.
It must be done by expert. Keep minimum staff in room. Totally, three individuals are required, which include one expert for intubation, one assistant, and one staff to give drugs.
Rapid sequence intubation should be done.
Keep low threshold for intubation to avoid crash intubation and minimize aerosol spread with HFNC/NIV.
Avoid bag and mask ventilation.
Preoxygenation for 3–5 min.
Mask ventilation through close circuit through ventilator rather than bag and mask ventilation if necessary.
Use HME filter as discussed earlier whenever doing bag and mask ventilation or mask ventilation using ventilator.
Supraglottic airway is preferred over facemask ventilation.
Ensure complete neuromuscular blockage before attempting intubation and even before mask ventilation.
Clamping ET tube/attach HME filter while intubation.
Use video laryngoscope for intubation if available.
Using plastic drapes or aerosol box during intubation.15 Role of aerosol box during intubation is controversial and not routinely recommended.
Inflate cuff with air immediately after intubation to keep cuff pressure 25–30 mm Hg and make sure there is no leak.
Monitor cuff pressure every 6–8 hours and minimize leak.
Higher risk of leak with peak inspiratory pressure higher than cuff pressure. Increase cuff pressure before performing any recruitment maneuver.
Start mechanical ventilation only after inflating cuff to avoid leak and aerosolization.
8. Prepare for extubation
Aerosol box and plastic drapes are also helpful and easier to use during extubation and then intubation15 (Fig. 4).
Use of mild sedation (dexmedetomidine/fentanyl, etc.), intracuff lidocaine to avoid coughing during extubation.13,16
Start nasal oxygen/high-flow nasal cannula after extubation.
Immediately apply surgical/N95 mask to face after extubation.
Fig. 4.
Aerosol box for intubation and extubation
9. Precautions while disconnecting ventilator
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Minimize disconnection to avoid derecruitment and exposure of virus to environment. If disconnection is necessary (e.g., while shifting patient and emptying water in circuit), follow below-mentioned steps:
Preoxygenation with 100% oxygen for 2–3 min,
Keep ventilator on standby,
Clamp ET tube (if intubated),
Disconnect (with direction of both disconnected ends facing down rather than up) circuit with HME still connected to patient, and
Reconnect after doing activity for which it was disconnected and unclamp ET tube if clamped before reconnecting.
10. Cover equipment with transparent sheet8
Covering ventilator with transparent plastic drape. Cover any other equipment (multipara monitor, X-ray, echo, USG machine, etc.) being used with plastic drape (Fig. 5). Placing the ventilator and syringe pump outside the room if feasible (e.g., through a wall port). This allows to do necessary settings and changes whenever required without exposure to staff, although no proven benefit.
Figs 5A and B.
Transparent plastic sheet covering (A) ventilator and (B) monitor
11. Use disposable accessories8
Use disposable expiratory valve and new flow sensor when available. (Dragor has disposable expiratory valve available.) If not, clean and disinfect expiratory valve and flow sensor as per manufacturer instructions.
If available, use disposable ECG leads, SpO2 probes, temperature probes, NIBP cuff, etc. Otherwise, clean and disinfect as per manufacturer recommendation before reuse.
12. Avoid routine suctioning17
Use of close suction is mandatory to avoid aerosol spread when available.
Continuous suctioning can be done during aerosol-generating procedures like intubation, tracheostomy, and bronchoscopy as it helps to minimize the risk of nosocomial transmission.
13. Minimize nebulization12,18
Nebulization creates aerosolization, so unnecessary routine nebulization should be avoided.
MDI with spacer is preferred if nebulization required.
MDI can be used along with close suction device as well, which has separate port/adapter for MDI (Fig. 6).
If cannot use MDI and nebulization is essential, use jet nebulizer or vibrating mesh nebulizer, which should be inline close circuit nebulization from ventilator.
Whenever available, use T-connector with auto shutoff function (one-way valve) to attach nebulizer chamber and use HME filter with switch to on or off (bypass) HME filter to avoid disconnection and keep circuit closed before and after nebulization (Figs 7 and 8).
Fig. 6.
Close suction with MDI attached to MDI adapter
Figs 7A and B.
Novel T-connector for nebulization with auto shut-off function: (A) Without nebulizer chamber; (B) nebulizer chamber attached to T-connector
Figs 8A and B.
Novel HME design: (A) HME active; (B) HME bypassed during nebulization
14. Minimize chest physiotherapy19,20
Most patients with COVID-19 do not require routine chest physiotherapy. Most interventions in respiratory physiotherapy are potentially aerosol generating, so it should be done only when deemed necessary. Italian association of respiratory physiotherapist and international experts in cardiorespiratory physiotherapy have come up with recommendation for physiotherapy in the management of COVID-19 patients. Each hospital should make their own policy and protocol as per available resources and feasibility, and standard preventive measures must be followed.
Apart from the PPE kit, hand hygiene, and above measures, there are some in vitro studies of povidone-iodine nasal solution to mitigate virus transmission. It has been found to be effective for contact time as short as 15 seconds and even in 0.5% concentration, but further clinical studies are needed to establish benefit.21
Footnotes
Source of support: Nil
Conflict of interest: None
Orcid
Vitrag Shah https://orcid.org/0000-0001-8337-7708
Niraj Tyagi https://orcid.org/0000-0001-5862-9731
Darshan Trivedi https://orcid.org/0000-0002-4186-0854
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