Sandbox:Javaria: Difference between revisions

Revision as of 11:52, 20 July 2020

Overview

The feasibility of the strategy used for the management of a patient with COVID-19 depends on the patients' condition at the time of Continuous evaluation and titration of ongoing interventions ensures optimal results. The respiratory manifestations of COVID-19 may require some oxygen supplementation to ventilatory support. Autopsy findings of patients with COVID-19-associated acute respiratory distress syndrome (CARDS) demonstrated small airway occlusion due to necrosis and inflammation. The finding advocates the use of positive pressure ventilation to restore the collapsed airways. A balanced approach is required as a high end-inspiratory pressure increases the risk of lung alveolar injury.^[1]

Ventilatory support in COVID-19

The COVID-19 respiratory complications that may require mechanical ventilation include: COVID-19-associated pneumonia, COVID-19-associated acute respiratory distress syndrome (CARDS) and COVID-19-associated respiratory failure. At the start, the recommendation to treat CARDS was similar to the ones used to treat ARDS due to other causes. During the initial course of the disease, in the absence of bacterial infection in COVID-19-associated pneumonia or CARDS, the patient has normal or even high pulmonary compliance. Thus, a patient can have severe hypoxemia in the absence of tachypnoea or dyspnea. Knowledge and experience of the unique features of the disease have led the guidelines to be modified/ specified.
Acute hypoxemic respiratory failure and ARDS are more common respiratory complications in COVID-19 patients.^[2]

Supplemental Oxygen

A patient with L (low lung elastance and V/Q ratio) type of COVID-19 associated pneumonia or CARDS will benefit from increased FiO2 the most. The therapy is particularly useful if the patient is non-dyspnic.^[3]
Surviving Sepsis Campaign has the following recommendations regarding the use of supplemental oxygen in adults COVID-19 patients:^[2]
- It is strongly recommended (with moderate-quality evidence) to start the supplemental oxygen if the Spo2 is < 90%. A weak recommendation states starting the supplemental oxygen at < 92% saturation.
- In COVID-19 positive adult patients with acute hypoxemic respiratory failure on supplemental oxygen therapy, Spo2 should be maintained no higher than 96% (strong recommendation by Surviving Sepsis Campaign). This based upon the systematic review and meta-analysis of 25 RCTs that showed a linear association between the death risk and higher Spo2 targets.

Non-Invasive ventilation (NIV)

According to Chinese experts based on there experience with COVID-19 patients, both HFNC and NIPPV methods should probably be utilized in patients with PaO2/FiO2 > 150 mmHg.^[1]
NIV methods are easier and comfortable to use and work by inducing PEEP thus decreased the respiratory workload.
Sufficient evidence to prove the superiority of one of the methods (HFNC or NIPPV) is unavailable as of now (July 2020). Limited studies have suggested that HFNC improves survival and lowers the intubation rate.^[1]
Close monitoring for a deteriorating respiratory status and early intubation when indicated in a controlled setting, can help minimize the infection of health personnel and promise better patient health outcomes.^[2]

High Flow Nasal Cannula (HFNC)

Also known as high flow nasal oxygen (HFNO) or Heated humidified high-flow (HHHF) therapy is a non-invasive technique. It is a technique of delivering heated and humidified high-flow oxygen via soft and flexible nasal prongs. Humidification prevents the drying of epithelium and facilitates the removal of mucosal secretions. Other advantages include pharyngeal dead space washout and PEEP effect.^[4] A hypercapnic patient should not be administered HFNC.
HFNC is preferred over Non-invasive positive pressure ventilation (NIPPV). It is possibly due to reduced mortality and decreased intubation risk, as proved by a RCT and a meta-analysis respectively. Patient comfort better oxygenation with HFNC than NIPPV is also one of the considering factors.^[5]
Target SpO2 should be 88% -94% with minimal flow rates under 30L/min. Low flow rates help minimize aerosolization. PEEP ranges from 5-15 and peak airway pressure ranges from 8-10 cmH2O.^[6]
Surviving Sepsis Campaign (SSC) has the following recommendations regarding the use of HFNC in COVID-19 patients:^[2]
- In acute hypoxemic respiratory failure despite supplemental oxygen therapy, a weak recommendation suggests using HFNC over conventional oxygen therapy. A systematic review and meta-analysis of 9 RCTs showed that High Flow Nasal Cannula (HFNC) reduces the need for intubation.

Non-Invasive Positive Pressure Ventilation (NIPPV)

Non-invasive positive pressure ventilation (NIPPV) is a technique utilized for delivering mechanical ventilation without the use of endotracheal intubation or tracheostomy. It can be administered through a face mask, nasal mask, or a helmet and includes CPAP and BiPAP.
Many patients who develop ARDS receive a trial of non-invasive positive pressure ventilation (NIPPV) before intubation for mechanical ventilation before they clinically deteriorate or become unable to maintain adequate oxygenation. Studies from China reported (4% to 13%) of COVID-19 patients to have received non-invasive positive pressure ventilation (NIPPV).^[2]
Surviving Sepsis Campaign (SSC) has the following recommendations regarding the use of Non-invasive positive pressure ventilation (NIPPV) in adult COVID-19 patient with hypoxemic respiratory failure:^[2]
- A weak recommendation (very low-quality evidence) suggests a trial of NIPPV, if HFNC is not available and endotracheal intubation not urgently indicated. with close monitoring and short-interval assessment for worsening of respiratory failure.
- The SSC demonstrated its uncertainty regarding the safety and efficacy of helmet NIPPV in SARS Cov2 patients. Another study advocates and recommends the use of helmet NIPPV in COVID-19 care due to potential avoidance of air dispersion through the spring-valve.^[7] Having said that, the cost of a helmet may be an essential consideration for healthcare systems struggling financially.

Invasive Mechanical Ventilation (IMV)

The vascular endothelial injury in COVID-19-associated acute respiratory distress syndrome (CARDS) and diverse mortality rates across the world in CARDS patients arbitrates the importance of different mechanical ventilation strategies.
The Chinese CDC reports the case-fatality rate to be higher than 50% in patients who received invasive mechanical ventilation.^[8]
According to the American Society of Anesthesiology based upon the experience of Chinese anesthesiologists, timely (neither premature nor late) intubation and ventilation most effectual breathing assistance.^[9]
Mechanical ventilation can be used in patients who have labored breathing and are unable to maintain adequate gaseous exchange leading to hypoxemia and/or hypercapnia.
Common clinical indications of mechanical ventilation include moderate to severe dyspnea, respiratory rate (RR) > 24-30/min, accessory muscle use for breathing, and abdominal paradox. It may also be used in patients who have an inadequate arterial partial pressure of oxygen or critically low PaO2 (PaO2 < 70 mm Hg), hypercapnia PaCO2 > 45 mm Hg, and PaO2/FiO2 ≤ 300 (corrected for altitude).

Intubation

According to Americal Herat Association (AHA), intubation is indicated in:

Gas exchange abnormality: Respiratory failure (usually hypoxic in COVID-19), PaO2/FiO2 <150, NIV with FiO2 >0.6 and inability to maintain SpO2 >90%, unresponsiveness to HFNC therapy, hypercapnia with acidosis (PH< 7.3), increased work of breathing with deteriorating respiratory function.
Airway protection: Alterened mental status and neurological dysfuntions.
Pulmonary toilet: To remove excessive pulmonary secretions.

Ventilator settings

The following ventilator setting should be used:^[10]^[11]

Mode: No mode of ventilation has been suggested to be superior to others. AHA recommends assist control PRVC.
{{Respiratory rate]]: 20-25 breaths/min.
positive end-expiratory pressure (PEEP): The commonly used PEEP in the COVID-19 patients in Wuhan, China was less than 10 cm H2O. After lung recruitment maneuvers, PEEP is titrated down from a maximum of 20 cm H2O until the goals of oxygenation, plateau pressure, and compliance are all achieved. *High PEEP is recommended to treat CARDS. In Wuhan, COID-19 patients with acute hypoxemic respiratory failure showed a poor tolerance to high PEEP, possibly due to the severe lung damage by the SARS-CoV-2 virus and inflammatory reactions.^[10] The CARDS Ventilator PEEP Titration Protocol can be viewed by clicking here.
- Contraindications for the use of the PEEP may include untreated pneumothorax, very low blood pressure, elevated ICP, and pulmonary hypertension.
- Complications of PEEP may include barotrauma, such as pneumothorax and/or decreased cardiac output.
Tidal volume (Vt): Upto a maximum of 6 ml/kg (range 4-6 ml/kg) of ideal body weight and lower inspiratory pressures. Excess Vt causes alveolar overdistension and worse CARDS.
Plateau pressure (Pplat): <30 cm H2O and peak inspiratory pressure:<35 cmH2O.
FiO2: <0.6
Maintenance Goals: pH=7.25-7.42, paO2>60/ SpO2=88-96%, paCO2= 40-65/ETCO=35-60 mmHg

(permissive hypercapnia).

Extracorporeal membrane oxygenation (ECMO)

The use of ECMO is recommended in COVID-19 patients with refractory hypoxemia or hypercapnia who have received invasive mechanical ventilation (IMV) and prone positioning. ECMO can help avoid ventilator-induced lung injury. ^[1] It is recommended to use traditional indications in hospitals with sufficient medical resources. The WHO suggests referring patients with refractory hypoxemia despite lung-protective ventilation to the settings with expertise in ECMO.^[12] It is not known whether ECMO reduces mortality but 6.2% patients were treated with ECMO in Wuhan, China.^[13]^[14]

Stratagies to improve oxygenation

Prone position ventilation

Prone positioning is thought to improve oxygenation by improving ventilation/perfusion (V/Q) mismatching via reduced shunting of blood through under-ventilated lung tissue.
Research has shown that prone position ventilation in ARDS patients with acute hypoxemic respiratory failure and spontaneous or assisted breathing reduces the mortality by 28 and 90-days.^[15]
The strategy was widely used in COVID-19 patients in Wuhan, China.^[10]
Prone position is an early strategy rather than a desperate rescue therapy.^[16] A study by Lin Ding et al. suggests that the early application of prone ventilation with HFNC and NIV, especially in COVID-19 patients with moderate ARDS, can help avoid intubation.^[17] Prone position,with other adjunct therapies may probably be used for critically ill patients even during ECMO.^[1]
Prone position for awake patients during spontaneous or assisted breathing during NIPPV or HFNC with mild-moderate ARDS was associated with an improved oxygenation.^[18] In addition, patients with an Spo2 of 95% or greater after an hour of the prone position had a lower rate of intubation.^[19] To answer the question about the effectiveness, two RCTs are in progress NCT04347941 and NCT04350723.^[16]
The American Thoracic Society/European Society of Intensive Care Medicine/Society of Critical Care Medicine Clinical Practice and Surviving Sepsis Campaign guidelines strongly recommend (moderate evidence) Prone positioning for more than 12 hours/day in patients with severe ARDS.^[20]^[21]

Special considerationss

Lung recruitment maneuvers^[10]^[22]^[23]: Lung recruitment maneuver is the application of very high (up to 40 cm H2O) positive airway pressure during mechanical ventilation. It opens the collapsed alveoli, decreasing ventilation/perfusion (V/Q) mismatching thus improving the gas exchange. For ARDS patients, the maneuvers may help improve oxygenation and decrease the length of hospital stay with no positive effect on reducing mortality. The decision varies on a case by case basis depending upon lung condition and patient hemodynamics. On the trouble side, the maneuver may generate aerosols. High-quality evidence is lacking to support the use in ARDS patients.

Paralytics:^[24]^[25] The paralytics may be used with analgesics (fentanyl, hydromorphone) and sedatives (benzodiazepines, propofol). In CARDS patients, Richmond Agitation Sedation Scale (RASS) score of (+2 to +4) even after optimal ventilatoy settings may indicate the use of deep sedation with paralytics. If used, short-term (24– 48 hours) and intermittent muscle relaxation is recommended. Prone position ventilation may also require muscle relaxation along with sedation. Paralytics are not recommended in an unless PaO2/FiO2 < 150 mmHg. The paralytics that are being used in CARDSpatients include: Succinylcholine chloride injection USP 200 mg/10 mL and cisatracurium besylate injection USP 20 mg/10 mL.

Aerosol Generation Risk Factors and Protective Measures
Concerns have been raised for a possible risk for transmission of COVID-19 to health care personnel due to aerosol transmission.^[26] With the judicious use of the standard precautions and protective measures, the results for the mentioned interventions have been promising.


Source of aerosol generation	Protective Measures
Coughing	Utilize full Personal protective equipment (PPE) prior to entering intubation room Minimize period between removal of patient's PPE and application of face mask with viral filter Ensure sealing of face mask USe of local lidocaine via ETT or during procedures such as bronchoscopy and opoids in minimum dose
Face Mask Seal Leak	Optimum fitting of the face mask Vice (V-E) grip Use manual ventilation Ambu bag ETO2 monitoring
Non-Invasive ventilation, bronchoscopy, CPR extubation, and manual ventilation	WHO recommends the use of PPE that includes respirators, eye protection, gloves and gowns; aprons if gowns are not fluid resistant.^[27] In addition to regular precautions such as the use of PPE followed during COVID-19 pandemic following precautions as advised by CDC to prevent airborne transmission should be taken:^[28] Airborne infection isolation room (AIIR) Restricting susceptible healthcare personnel Limiting transport and movement of the patient Use of fit-tested NIOSH-approved N95 or higher level respirator for healthcare personnel. The staff who are expected to help during the procedure should be informed and ready with PPEs. If possible, use disposable bronchoscope or cleaning the suction channels with the cleaning solutions used for highly infectious materials.
Intubation	Above mentioned precautions such as the use of PPE and AIIR with minimal personnel in the room should be followed. Chest auscultation after intubation is not recommended due to aerosol transmission of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) virus. Spo2, chest movements, capnography, fogging inside of the endotracheal tube, and the color of the patient’s skin and mucous membrane can be used to confirm a successful intubation.^[10]
Tracheostomy	Above mentioned precautions such as the use of PPE and AIIR with minimal personnel in the room should be followed. During the procedure, minimal use of diathermy, and maintenance of bloodless fields should be ensured. Post-procedure, reduce the frequency of changing an inner cannula and cuff pressure checks to a possible minimum for the patient. Post tracheostomy, humidification can be provided via heat and moisture exchange filter or a water-based humidification such as hypertonic saline nebulizers. Patients should use facemasks and tracheostomy shields during trials of tracheostomy cuff deflation.^[29]

Bronchoscopy

Tracheostomy

Standard decision making for tracheostomy in a COVID patient is practiced. But owing to the potential of aerosol spread of the infection certain considerations should be kept in mind, such as the safety of other the patient's family, other patients, healthcare personnel, and the resources available.^[30]
Tracheostomy should be delayed until at least the 10th day of mechanical ventilation. It should be considered only when the patient is clinically improving. The decision of extubation should be limited to the patients who have a high chance of success.^[29]

CPR

American Heart Association's (AHA) interim BLS Healthcare Provider Adult Cardiac Arrest Algorithm for Suspected or Confirmed COVID-19 Patients can be accessed by clicking here.^[31]

References

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↑ "Coronavirus (COVID-19) Resources for CPR Training | American Heart Association CPR & First Aid".

[pmid32506258-1] 1.0 ^1.1 ^1.2 ^1.3 ^1.4 Shang Y, Pan C, Yang X, Zhong M, Shang X, Wu Z, Yu Z, Zhang W, Zhong Q, Zheng X, Sang L, Jiang L, Zhang J, Xiong W, Liu J, Chen D (June 2020). "Management of critically ill patients with COVID-19 in ICU: statement from front-line intensive care experts in Wuhan, China". Ann Intensive Care. 10 (1): 73. doi:10.1186/s13613-020-00689-1. PMC 7275657 Check |pmc= value (help). PMID 32506258 Check |pmid= value (help).

[AlhazzaniMøller2020-2] 2.0 ^2.1 ^2.2 ^2.3 ^2.4 ^2.5 Alhazzani, Waleed; Møller, Morten Hylander; Arabi, Yaseen M.; Loeb, Mark; Gong, Michelle Ng; Fan, Eddy; Oczkowski, Simon; Levy, Mitchell M.; Derde, Lennie; Dzierba, Amy; Du, Bin; Aboodi, Michael; Wunsch, Hannah; Cecconi, Maurizio; Koh, Younsuck; Chertow, Daniel S.; Maitland, Kathryn; Alshamsi, Fayez; Belley-Cote, Emilie; Greco, Massimiliano; Laundy, Matthew; Morgan, Jill S.; Kesecioglu, Jozef; McGeer, Allison; Mermel, Leonard; Mammen, Manoj J.; Alexander, Paul E.; Arrington, Amy; Centofanti, John E.; Citerio, Giuseppe; Baw, Bandar; Memish, Ziad A.; Hammond, Naomi; Hayden, Frederick G.; Evans, Laura; Rhodes, Andrew (2020). "Surviving Sepsis Campaign: Guidelines on the Management of Critically Ill Adults with Coronavirus Disease 2019 (COVID-19)". Critical Care Medicine. 48 (6): e440–e469. doi:10.1097/CCM.0000000000004363. ISSN 0090-3493.

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[pmid27698207-4] Zhang J, Lin L, Pan K, Zhou J, Huang X (December 2016). "High-flow nasal cannula therapy for adult patients". J. Int. Med. Res. 44 (6): 1200–1211. doi:10.1177/0300060516664621. PMC 5536739. PMID 27698207.

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[SartiniTresoldi2020-18] Sartini, Chiara; Tresoldi, Moreno; Scarpellini, Paolo; Tettamanti, Andrea; Carcò, Francesco; Landoni, Giovanni; Zangrillo, Alberto (2020). "Respiratory Parameters in Patients With COVID-19 After Using Noninvasive Ventilation in the Prone Position Outside the Intensive Care Unit". JAMA. 323 (22): 2338. doi:10.1001/jama.2020.7861. ISSN 0098-7484.

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[FanDel_Sorbo2017-20] Fan, Eddy; Del Sorbo, Lorenzo; Goligher, Ewan C.; Hodgson, Carol L.; Munshi, Laveena; Walkey, Allan J.; Adhikari, Neill K. J.; Amato, Marcelo B. P.; Branson, Richard; Brower, Roy G.; Ferguson, Niall D.; Gajic, Ognjen; Gattinoni, Luciano; Hess, Dean; Mancebo, Jordi; Meade, Maureen O.; McAuley, Daniel F.; Pesenti, Antonio; Ranieri, V. Marco; Rubenfeld, Gordon D.; Rubin, Eileen; Seckel, Maureen; Slutsky, Arthur S.; Talmor, Daniel; Thompson, B. Taylor; Wunsch, Hannah; Uleryk, Elizabeth; Brozek, Jan; Brochard, Laurent J. (2017). "An Official American Thoracic Society/European Society of Intensive Care Medicine/Society of Critical Care Medicine Clinical Practice Guideline: Mechanical Ventilation in Adult Patients with Acute Respiratory Distress Syndrome". American Journal of Respiratory and Critical Care Medicine. 195 (9): 1253–1263. doi:10.1164/rccm.201703-0548ST. ISSN 1073-449X.

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[urlCoronavirus_(COVID-19)_Update:_Daily_Roundup_May_5,_2020_|_FDA-25] "Coronavirus (COVID-19) Update: Daily Roundup May 5, 2020 | FDA".

[pmid32442035-26] Schünemann HJ, Khabsa J, Solo K, Khamis AM, Brignardello-Petersen R, El-Harakeh A, Darzi A, Hajizadeh A, Bognanni A, Bak A, Izcovich A, Cuello-Garcia CA, Chen C, Borowiack E, Chamseddine F, Schünemann F, Morgano GP, Muti-Schünemann G, Chen G, Zhao H, Neumann I, Brozek J, Schmidt J, Hneiny L, Harrison L, Reinap M, Junek M, Santesso N, El-Khoury R, Thomas R, Nieuwlaat R, Stalteri R, Yaacoub S, Lotfi T, Baldeh T, Piggott T, Zhang Y, Saad Z, Rochwerg B, Perri D, Fan E, Stehling F, Akl IB, Loeb M, Garner P, Aston S, Alhazzani W, Szczeklik W, Chu DK, Akl EA (May 2020). "Ventilation Techniques and Risk for Transmission of Coronavirus Disease, Including COVID-19: A Living Systematic Review of Multiple Streams of Evidence". Ann. Intern. Med. doi:10.7326/M20-2306. PMC 7281716 Check |pmc= value (help). PMID 32442035 Check |pmid= value (help). Vancouver style error: initials (help)

[urlapps.who.int-27] "apps.who.int" (PDF).

[urlTransmission-Based_Precautions_|_Basics_|_Infection_Control_|_CDC”-28] "Transmission-Based Precautions | Basics | Infection Control | CDC"".

[McGrathBrenner2020-29] 29.0 ^29.1 McGrath, Brendan A; Brenner, Michael J; Warrillow, Stephen J; Pandian, Vinciya; Arora, Asit; Cameron, Tanis S; Añon, José Manuel; Hernández Martínez, Gonzalo; Truog, Robert D; Block, Susan D; Lui, Grace C Y; McDonald, Christine; Rassekh, Christopher H; Atkins, Joshua; Qiang, Li; Vergez, Sébastien; Dulguerov, Pavel; Zenk, Johannes; Antonelli, Massimo; Pelosi, Paolo; Walsh, Brian K; Ward, Erin; Shang, You; Gasparini, Stefano; Donati, Abele; Singer, Mervyn; Openshaw, Peter J M; Tolley, Neil; Markel, Howard; Feller-Kopman, David J (2020). "Tracheostomy in the COVID-19 era: global and multidisciplinary guidance". The Lancet Respiratory Medicine. 8 (7): 717–725. doi:10.1016/S2213-2600(20)30230-7. ISSN 2213-2600.

[ZhangHuang2020-30] Zhang, Xiaomeng; Huang, Qiling; Niu, Xun; Zhou, Tao; Xie, Zhen; Zhong, Yi; Xiao, Hongjun (2020). "Safe and effective management of tracheostomy in COVID ‐19 patients". Head & Neck. 42 (7): 1374–1381. doi:10.1002/hed.26261. ISSN 1043-3074. line feed character in |title= at position 49 (help)

[urlCoronavirus_(COVID-19)_Resources_for_CPR_Training_|_American_Heart_Association_CPR_&_First_Aid-31] "Coronavirus (COVID-19) Resources for CPR Training | American Heart Association CPR & First Aid".

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 *Sufficient evidence to prove the superiority of one of the methods (HFNC or NIPPV) is unavailable as of now (July 2020). Limited studies have suggested that HFNC improves survival and lowers the intubation rate.<ref name="pmid32506258">{{cite journal |vauthors=Shang Y, Pan C, Yang X, Zhong M, Shang X, Wu Z, Yu Z, Zhang W, Zhong Q, Zheng X, Sang L, Jiang L, Zhang J, Xiong W, Liu J, Chen D |title=Management of critically ill patients with COVID-19 in ICU: statement from front-line intensive care experts in Wuhan, China |journal=Ann Intensive Care |volume=10 |issue=1 |pages=73 |date=June 2020 |pmid=32506258 |pmc=7275657 |doi=10.1186/s13613-020-00689-1 |url=}}</ref>
 *Close monitoring for a deteriorating respiratory status and early [[intubation]] when indicated in a controlled setting, can help minimize the [[infection]] of health personnel and promise better [[patient]] health outcomes.<ref name="AlhazzaniMøller2020">{{cite journal|last1=Alhazzani|first1=Waleed|last2=Møller|first2=Morten Hylander|last3=Arabi|first3=Yaseen M.|last4=Loeb|first4=Mark|last5=Gong|first5=Michelle Ng|last6=Fan|first6=Eddy|last7=Oczkowski|first7=Simon|last8=Levy|first8=Mitchell M.|last9=Derde|first9=Lennie|last10=Dzierba|first10=Amy|last11=Du|first11=Bin|last12=Aboodi|first12=Michael|last13=Wunsch|first13=Hannah|last14=Cecconi|first14=Maurizio|last15=Koh|first15=Younsuck|last16=Chertow|first16=Daniel S.|last17=Maitland|first17=Kathryn|last18=Alshamsi|first18=Fayez|last19=Belley-Cote|first19=Emilie|last20=Greco|first20=Massimiliano|last21=Laundy|first21=Matthew|last22=Morgan|first22=Jill S.|last23=Kesecioglu|first23=Jozef|last24=McGeer|first24=Allison|last25=Mermel|first25=Leonard|last26=Mammen|first26=Manoj J.|last27=Alexander|first27=Paul E.|last28=Arrington|first28=Amy|last29=Centofanti|first29=John E.|last30=Citerio|first30=Giuseppe|last31=Baw|first31=Bandar|last32=Memish|first32=Ziad A.|last33=Hammond|first33=Naomi|last34=Hayden|first34=Frederick G.|last35=Evans|first35=Laura|last36=Rhodes|first36=Andrew|title=Surviving Sepsis Campaign: Guidelines on the Management of Critically Ill Adults with Coronavirus Disease 2019 (COVID-19)|journal=Critical Care Medicine|volume=48|issue=6|year=2020|pages=e440–e469|issn=0090-3493|doi=10.1097/CCM.0000000000004363}}</ref>
 ====High Flow Nasal Cannula (HFNC)====
-*Also known as high flow nasal oxygen (HFNO) or Heated humidified high-flow (HHHF) therapy is a non-invasive technique. It is a technique of delivering heated and humidified high-flow oxygen via soft and flexible nasal prongs. Humidification prevents the drying of [[epithelium]] and facilitates the removal of [[mucosa]]l secretions. Other advantages include pharyngeal [[dead space]] washout and [[PEEP]] effect.<ref name="pmid27698207">{{cite journal |vauthors=Zhang J, Lin L, Pan K, Zhou J, Huang X |title=High-flow nasal cannula therapy for adult patients |journal=J. Int. Med. Res. |volume=44 |issue=6 |pages=1200–1211 |date=December 2016 |pmid=27698207 |pmc=5536739 |doi=10.1177/0300060516664621 |url=}}</ref>
+*Also known as high flow nasal oxygen (HFNO) or Heated humidified high-flow (HHHF) therapy is a non-invasive technique. It is a technique of delivering heated and humidified high-flow oxygen via soft and flexible nasal prongs. Humidification prevents the drying of [[epithelium]] and facilitates the removal of [[mucosa]]l secretions. Other advantages include pharyngeal [[dead space]] washout and [[PEEP]] effect.<ref name="pmid27698207">{{cite journal |vauthors=Zhang J, Lin L, Pan K, Zhou J, Huang X |title=High-flow nasal cannula therapy for adult patients |journal=J. Int. Med. Res. |volume=44 |issue=6 |pages=1200–1211 |date=December 2016 |pmid=27698207 |pmc=5536739 |doi=10.1177/0300060516664621 |url=}}</ref> A [[hypercapnic]] patient should not be administered HFNC.
-*Surviving Sepsis Campaign (SSC) has the following recommendations regarding the use of HFNC in [[COVID-19]] patients:<ref name="AlhazzaniMøller2020">{{cite journal|last1=Alhazzani|first1=Waleed|last2=Møller|first2=Morten Hylander|last3=Arabi|first3=Yaseen M.|last4=Loeb|first4=Mark|last5=Gong|first5=Michelle Ng|last6=Fan|first6=Eddy|last7=Oczkowski|first7=Simon|last8=Levy|first8=Mitchell M.|last9=Derde|first9=Lennie|last10=Dzierba|first10=Amy|last11=Du|first11=Bin|last12=Aboodi|first12=Michael|last13=Wunsch|first13=Hannah|last14=Cecconi|first14=Maurizio|last15=Koh|first15=Younsuck|last16=Chertow|first16=Daniel S.|last17=Maitland|first17=Kathryn|last18=Alshamsi|first18=Fayez|last19=Belley-Cote|first19=Emilie|last20=Greco|first20=Massimiliano|last21=Laundy|first21=Matthew|last22=Morgan|first22=Jill S.|last23=Kesecioglu|first23=Jozef|last24=McGeer|first24=Allison|last25=Mermel|first25=Leonard|last26=Mammen|first26=Manoj J.|last27=Alexander|first27=Paul E.|last28=Arrington|first28=Amy|last29=Centofanti|first29=John E.|last30=Citerio|first30=Giuseppe|last31=Baw|first31=Bandar|last32=Memish|first32=Ziad A.|last33=Hammond|first33=Naomi|last34=Hayden|first34=Frederick G.|last35=Evans|first35=Laura|last36=Rhodes|first36=Andrew|title=Surviving Sepsis Campaign: Guidelines on the Management of Critically Ill Adults with Coronavirus Disease 2019 (COVID-19)|journal=Critical Care Medicine|volume=48|issue=6|year=2020|pages=e440–e469|issn=0090-3493|doi=10.1097/CCM.0000000000004363}}</ref>
+*HFNC is preferred over [[Positive airway pressure|Non-invasive positive pressure ventilation (NIPPV)]]. It is possibly due to reduced [[mortality rate|mortality]] and decreased [[intubation]] risk, as proved by a [[Randomized controlled trial|RCT]] and a meta-analysis respectively. [[Patient]] comfort better oxygenation with HFNC than NIPPV is also one of the considering factors.<ref name="FratThille2015">{{cite journal|last1=Frat|first1=Jean-Pierre|last2=Thille|first2=Arnaud W.|last3=Mercat|first3=Alain|last4=Girault|first4=Christophe|last5=Ragot|first5=Stéphanie|last6=Perbet|first6=Sébastien|last7=Prat|first7=Gwénael|last8=Boulain|first8=Thierry|last9=Morawiec|first9=Elise|last10=Cottereau|first10=Alice|last11=Devaquet|first11=Jérôme|last12=Nseir|first12=Saad|last13=Razazi|first13=Keyvan|last14=Mira|first14=Jean-Paul|last15=Argaud|first15=Laurent|last16=Chakarian|first16=Jean-Charles|last17=Ricard|first17=Jean-Damien|last18=Wittebole|first18=Xavier|last19=Chevalier|first19=Stéphanie|last20=Herbland|first20=Alexandre|last21=Fartoukh|first21=Muriel|last22=Constantin|first22=Jean-Michel|last23=Tonnelier|first23=Jean-Marie|last24=Pierrot|first24=Marc|last25=Mathonnet|first25=Armelle|last26=Béduneau|first26=Gaëtan|last27=Delétage-Métreau|first27=Céline|last28=Richard|first28=Jean-Christophe M.|last29=Brochard|first29=Laurent|last30=Robert|first30=René|title=High-Flow Oxygen through Nasal Cannula in Acute Hypoxemic Respiratory Failure|journal=New England Journal of Medicine|volume=372|issue=23|year=2015|pages=2185–2196|issn=0028-4793|doi=10.1056/NEJMoa1503326}}</ref>
-**In [[COVID-19]] positive adult [[patients]] with acute [[respiratory failure|hypoxemic respiratory failure]] despite [[oxygen therapy|supplemental oxygen therapy]], a weak recommendation suggests using HFNC over conventional [[oxygen therapy]]. A systematic review and meta-analysis of 9 [[Randomized controlled trial|RCTs]] showed that High Flow Nasal Cannula (HFNC) reduces the need for [[intubation]].
+*Target SpO2 should be 88% -94% with minimal flow rates under 30L/min. Low flow rates help minimize aerosolization. [[PEEP]] ranges from 5-15 and peak airway pressure ranges from 8-10 cmH2O.<ref name="urlOxygenation and Ventilation of COVID 19 Patients | American Heart Association CPR & First Aid">{{cite web |url=https://cpr.heart.org/en/resources/coronavirus-covid19-resources-for-cpr-training/oxygenation-and-ventilation-of-covid-19-patients |title=Oxygenation and Ventilation of COVID 19 Patients &#124; American Heart Association CPR & First Aid |format= |work= |accessdate=}}</ref>
-**A weak recommendation (low-quality evidence) also prefers using HFNC over [[Positive airway pressure|Non-invasive positive pressure ventilation (NIPPV)]]. It is possibly due to reduced [[mortality rate|mortality]] and decreased [[intubation]] risk, as proved by a [[Randomized controlled trial|RCT]] and a meta-analysis respectively. [[Patient]] comfort better oxygenation with HFNC than NIPPV is also one of the considering factors.<ref name="FratThille2015">{{cite journal|last1=Frat|first1=Jean-Pierre|last2=Thille|first2=Arnaud W.|last3=Mercat|first3=Alain|last4=Girault|first4=Christophe|last5=Ragot|first5=Stéphanie|last6=Perbet|first6=Sébastien|last7=Prat|first7=Gwénael|last8=Boulain|first8=Thierry|last9=Morawiec|first9=Elise|last10=Cottereau|first10=Alice|last11=Devaquet|first11=Jérôme|last12=Nseir|first12=Saad|last13=Razazi|first13=Keyvan|last14=Mira|first14=Jean-Paul|last15=Argaud|first15=Laurent|last16=Chakarian|first16=Jean-Charles|last17=Ricard|first17=Jean-Damien|last18=Wittebole|first18=Xavier|last19=Chevalier|first19=Stéphanie|last20=Herbland|first20=Alexandre|last21=Fartoukh|first21=Muriel|last22=Constantin|first22=Jean-Michel|last23=Tonnelier|first23=Jean-Marie|last24=Pierrot|first24=Marc|last25=Mathonnet|first25=Armelle|last26=Béduneau|first26=Gaëtan|last27=Delétage-Métreau|first27=Céline|last28=Richard|first28=Jean-Christophe M.|last29=Brochard|first29=Laurent|last30=Robert|first30=René|title=High-Flow Oxygen through Nasal Cannula in Acute Hypoxemic Respiratory Failure|journal=New England Journal of Medicine|volume=372|issue=23|year=2015|pages=2185–2196|issn=0028-4793|doi=10.1056/NEJMoa1503326}}</ref>
+*Surviving Sepsis Campaign (SSC) has the following recommendations regarding the use of HFNC in [[COVID-19]] patients:<ref name="AlhazzaniMøller2020">{{cite journal|last1=Alhazzani|first1=Waleed|last2=Møller|first2=Morten Hylander|last3=Arabi|first3=Yasadult een M.|last4=Loeb|first4=Mark|last5=Gong|first5=Michelle Ng|last6=Fan|first6=Eddy|last7=Oczkowski|first7=Simon|last8=Levy|first8=Mitchell M.|last9=Derde|first9=Lennie|last10=Dzierba|first10=Amy|last11=Du|first11=Bin|last12=Aboodi|first12=Michael|last13=Wunsch|first13=Hannah|last14=Cecconi|first14=Maurizio|last15=Koh|first15=Younsuck|last16=Chertow|first16=Daniel S.|last17=Maitland|first17=Kathryn|last18=Alshamsi|first18=Fayez|last19=Belley-Cote|first19=Emilie|last20=Greco|first20=Massimiliano|last21=Laundy|first21=Matthew|last22=Morgan|first22=Jill S.|last23=Kesecioglu|first23=Jozef|last24=McGeer|first24=Allison|last25=Mermel|first25=Leonard|last26=Mammen|first26=Manoj J.|last27=Alexander|first27=Paul E.|last28=Arrington|first28=Amy|last29=Centofanti|first29=John E.|last30=Citerio|first30=Giuseppe|last31=Baw|first31=Bandar|last32=Memish|first32=Ziad A.|last33=Hammond|first33=Naomi|last34=Hayden|first34=Frederick G.|last35=Evans|first35=Laura|last36=Rhodes|first36=Andrew|title=Surviving Sepsis Campaign: Guidelines on the Management of Critically Ill Adults with Coronavirus Disease 2019 (COVID-19)|journal=Critical Care Medicine|volume=48|issue=6|year=2020|pages=e440–e469|issn=0090-3493|doi=10.1097/CCM.0000000000004363}}</ref>
+**In acute [[respiratory failure|hypoxemic respiratory failure]] despite [[oxygen therapy|supplemental oxygen therapy]], a weak recommendation suggests using HFNC over conventional [[oxygen therapy]]. A systematic review and meta-analysis of 9 [[Randomized controlled trial|RCTs]] showed that High Flow Nasal Cannula (HFNC) reduces the need for [[intubation]].
@@ Line 40: / Line 40: @@
 * Mechanical ventilation can be used in patients who have labored breathing and are unable to maintain adequate gaseous exchange leading to [[hypoxemia]] and/or [[hypercapnia]].
 * Common clinical indications of mechanical ventilation include moderate to severe [[dyspnea]], [[respiratory rate]] (RR) > 24-30/min, accessory muscle use for breathing, and abdominal paradox. It may also be used in patients who have an inadequate arterial partial pressure of oxygen or critically low PaO2 (PaO2 < 70 mm Hg), hypercapnia PaCO2 > 45 mm Hg, and PaO2/FiO2 ≤ 300 (corrected for altitude).
+====Intubation====
+According to [[Americal Herat Association]] (AHA), [[intubation]] is indicated in:
+*'''Gas exchange abnormality''': [[Respiratory failure]] (usually hypoxic in [[COVID-19]]), PaO2/FiO2 <150, NIV with FiO2 >0.6 and inability to maintain SpO2 >90%, unresponsiveness to HFNC therapy, [[hypercapnia]] with [[acidosis]] (PH< 7.3), increased work of breathing with deteriorating respiratory function.
+*'''Airway protection''': [[Alterened mental status]] and neurological dysfuntions.
+*''Pulmonary toilet'': To remove excessive pulmonary secretions.
 ====Ventilator settings====
 The following ventilator setting should be used:<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref><ref name="urlNHLBI ARDS Network | Tools">{{cite web |url=http://www.ardsnet.org/tools.shtml |title=NHLBI ARDS Network &#124; Tools |format= |work= |accessdate=}}</ref>
-*'''Mode''': No mode of ventilation has been suggested to be superior to others.
+*'''Mode''': No mode of ventilation has been suggested to be superior to others. [[American Heart Association|AHA]] recommends assist control PRVC.
-*'''[[Positive end-expiratory pressure|positive end-expiratory pressure (PEEP)]]''': The commonly used [[PEEP]] in the [[COVID-19]] patients in Wuhan, China was less than 10 cm H2O. It is advised that after lung recruitment maneuvers, is to set PEEP at 20 cm H2O and titrate down in a decrement of 2 to 3 cm H2O each time until the goals of oxygenation, plateau pressure, and compliance are all achieved. The [[COVID-19-associated acute respiratory distress syndrome|CARDS]] Ventilator [[PEEP]] Titration Protocol can be viewed by [https://www.nebraskamed.com/sites/default/files/documents/covid-19/ards-ventilator-peep-titration-protocol.pdf?date=03242020 clicking here].
+*''{{Respiratory rate]]'': 20-25 breaths/min.
+*'''[[Positive end-expiratory pressure|positive end-expiratory pressure (PEEP)]]''': The commonly used [[PEEP]] in the [[COVID-19]] patients in Wuhan, China was less than 10 cm H2O. After lung recruitment maneuvers, [[PEEP]] is titrated down from a maximum of 20 cm H2O until the goals of [[oxygenation]], plateau pressure, and [[compliance]] are all achieved. *High [[PEEP]] is recommended to treat CARDS. In Wuhan, [[COID-19]] patients with acute hypoxemic [[respiratory failure]] showed a poor tolerance to high [[PEEP]], possibly due to the severe lung damage by the [[SARS-CoV-2]] virus and [[inflammation|inflammatory]] reactions.<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref>  The [[COVID-19-associated acute respiratory distress syndrome|CARDS]] Ventilator [[PEEP]] Titration Protocol can be viewed by [https://www.nebraskamed.com/sites/default/files/documents/covid-19/ards-ventilator-peep-titration-protocol.pdf?date=03242020 clicking here].
 **''Contraindications'' for the use of the [[PEEP]] may include untreated [[pneumothorax]], [[hypotension|very low blood pressure]], elevated [[intracranial pressures|ICP]], and [[pulmonary hypertension]].
 **''Complications'' of [[PEEP]] may include [[barotrauma]], such as [[pneumothorax]] and/or decreased [[cardiac output]].
-*'''[[Lung volumes#Measurement and values|Tidal volume]] (Vt)''':  Upto a maximum of 6 ml/kg of ideal body weight and lower inspiratory pressures.
+*'''[[Lung volumes#Measurement and values|Tidal volume]] (Vt)''':  Upto a maximum of 6 ml/kg (range 4-6 ml/kg) of ideal body weight and lower inspiratory pressures. Excess Vt causes alveolar overdistension and worse [[CARDS]].
-* '''Plateau pressure''' (Pplat): < 28 to 30 cm H2O
+* '''Plateau pressure''' (Pplat): <30 cm H2O and peak inspiratory pressure:<35 cmH2O.
-*PEEP must be as high as possible to maintain the driving pressure (Pplat-PEEP) as low as possible (< 14 cmH2O)
+*'''FiO2''': <0.6
+*'''Maintenance Goals''': pH=7.25-7.42, paO2>60/ SpO2=88-96%, paCO2= 40-65/ETCO=35-60 mmHg
+ (permissive hypercapnia).
+===Extracorporeal membrane oxygenation (ECMO) ===
-Marini et al. suggest
+* The use of ECMO is recommended in [[COVID-19]] patients with refractory [[hypoxemia]] or [[hypercapnia]] who have received invasive mechanical [[ventilation]] (IMV) and prone positioning. ECMO can help avoid ventilator-induced lung injury. <ref name="pmid32506258">{{cite journal |vauthors=Shang Y, Pan C, Yang X, Zhong M, Shang X, Wu Z, Yu Z, Zhang W, Zhong Q, Zheng X, Sang L, Jiang L, Zhang J, Xiong W, Liu J, Chen D |title=Management of critically ill patients with COVID-19 in ICU: statement from front-line intensive care experts in Wuhan, China |journal=Ann Intensive Care |volume=10 |issue=1 |pages=73 |date=June 2020 |pmid=32506258 |pmc=7275657 |doi=10.1186/s13613-020-00689-1 |url=}}</ref> It is recommended to use traditional indications in hospitals with sufficient medical resources. The [[WHO]] suggests referring [[patients]] with refractory [[hypoxemia]] despite lung-protective [[ventilation]] to the settings with expertise in ECMO.<ref name="urlClinical management of COVID-19">{{cite web |url=https://www.who.int/publications/i/item/clinical-management-of-severe-acute-respiratory-infection-when-novel-coronavirus-(ncov)-infection-is-suspected |title=Clinical management of COVID-19 |format= |work= |accessdate=}}</ref> It is not known whether ECMO reduces mortality but 6.2% [[patients]] were treated with ECMO in Wuhan, China.<ref name="ZengCai2020">{{cite journal|last1=Zeng|first1=Yingchun|last2=Cai|first2=Zhongxiang|last3=Xianyu|first3=Yunyan|last4=Yang|first4=Bing Xiang|last5=Song|first5=Ting|last6=Yan|first6=Qiaoyuan|title=Prognosis when using extracorporeal membrane oxygenation (ECMO) for critically ill COVID-19 patients in China: a retrospective case series|journal=Critical Care|volume=24|issue=1|year=2020|issn=1364-8535|doi=10.1186/s13054-020-2840-8}}</ref><ref name="LiHou2020">{{cite journal|last1=Li|first1=Chenglong|last2=Hou|first2=Xiaotong|last3=Tong|first3=Zhaohui|last4=Qiu|first4=Haibo|last5=Li|first5=Yimin|last6=Li|first6=Ang|title=Extracorporeal membrane oxygenation programs for COVID-19 in China|journal=Critical Care|volume=24|issue=1|year=2020|issn=1364-8535|doi=10.1186/s13054-020-03047-6}}</ref>
-**Lower PEEP: “type L,” characterized by low lung elastance (high compliance), lower lung weight as estimated by CT scan, and a low response to PEEP
-**Higher PEEP: Initially it was recommended that the guidelines for [[ARDS]] must be followed for respiratory support in [[COVID-19|SARS Cov2]] patients. But the data from China helped inform and reform regarding the strategies. '''In Wuhan, patients with acute hypoxemic respiratory failure due to COVID-19 have a poor tolerance to high PEEP, likely as the result of the direct and severe lung damage by the [[SARS-CoV-2]] virus and inflammatory reactions.'''<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref>
 ==Stratagies to improve oxygenation==
@@ Line 64: / Line 70: @@
 *Research has shown that [[prone position]] ventilation in [[ARDS]] patients with acute hypoxemic [[respiratory failure]] and spontaneous or assisted breathing reduces the mortality by 28 and 90-days.<ref name="pmid29576824">{{cite journal |vauthors=Xie H, Zhou ZG, Jin W, Yuan CB, Du J, Lu J, Wang RL |title=Ventilator management for acute respiratory distress syndrome associated with avian influenza A (H7N9) virus infection: A case series |journal=World J Emerg Med |volume=9 |issue=2 |pages=118–124 |date=2018 |pmid=29576824 |pmc=5847497 |doi=10.5847/wjem.j.1920-8642.2018.02.006 |url=}}</ref>
 *The strategy was widely used in [[COVID-19]] patients in Wuhan, China.<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref>
-*[[Mechanical ventilation initial ventilator settings#Proning|Prone position]] is an early strategy rather than a desperate rescue therapy.<ref name="TeliasKatira2020">{{cite journal|last1=Telias|first1=Irene|last2=Katira|first2=Bhushan H.|last3=Brochard|first3=Laurent|title=Is the Prone Position Helpful During Spontaneous Breathing in Patients With COVID-19?|journal=JAMA|volume=323|issue=22|year=2020|pages=2265|issn=0098-7484|doi=10.1001/jama.2020.8539}}</ref> A study by Lin Ding et al. suggests that the early application of prone ventilation with HFNC and NIV, especially in [[COVID-19]] patients with moderate [[ARDS]], can help avoid [[intubation]].<ref name="pmid32000806">{{cite journal |vauthors=Ding L, Wang L, Ma W, He H |title=Efficacy and safety of early prone positioning combined with HFNC or NIV in moderate to severe ARDS: a multi-center prospective cohort study |journal=Crit Care |volume=24 |issue=1 |pages=28 |date=January 2020 |pmid=32000806 |pmc=6993481 |doi=10.1186/s13054-020-2738-5 |url=}}</ref>
+*[[Mechanical ventilation initial ventilator settings#Proning|Prone position]] is an early strategy rather than a desperate rescue therapy.<ref name="TeliasKatira2020">{{cite journal|last1=Telias|first1=Irene|last2=Katira|first2=Bhushan H.|last3=Brochard|first3=Laurent|title=Is the Prone Position Helpful During Spontaneous Breathing in Patients With COVID-19?|journal=JAMA|volume=323|issue=22|year=2020|pages=2265|issn=0098-7484|doi=10.1001/jama.2020.8539}}</ref> A study by Lin Ding et al. suggests that the early application of prone ventilation with HFNC and NIV, especially in [[COVID-19]] patients with moderate [[ARDS]], can help avoid [[intubation]].<ref name="pmid32000806">{{cite journal |vauthors=Ding L, Wang L, Ma W, He H |title=Efficacy and safety of early prone positioning combined with HFNC or NIV in moderate to severe ARDS: a multi-center prospective cohort study |journal=Crit Care |volume=24 |issue=1 |pages=28 |date=January 2020 |pmid=32000806 |pmc=6993481 |doi=10.1186/s13054-020-2738-5 |url=}}</ref> Prone position,with other adjunct therapies may probably be used for critically ill patients even during ECMO.<ref name="pmid32506258">{{cite journal |vauthors=Shang Y, Pan C, Yang X, Zhong M, Shang X, Wu Z, Yu Z, Zhang W, Zhong Q, Zheng X, Sang L, Jiang L, Zhang J, Xiong W, Liu J, Chen D |title=Management of critically ill patients with COVID-19 in ICU: statement from front-line intensive care experts in Wuhan, China |journal=Ann Intensive Care |volume=10 |issue=1 |pages=73 |date=June 2020 |pmid=32506258 |pmc=7275657 |doi=10.1186/s13613-020-00689-1 |url=}}</ref>
 * [[Mechanical ventilation initial ventilator settings#Proning|Prone position]] for awake patients during spontaneous or assisted breathing during NIPPV or HFNC with mild-moderate [[ARDS]] was associated with an improved oxygenation.<ref name="SartiniTresoldi2020">{{cite journal|last1=Sartini|first1=Chiara|last2=Tresoldi|first2=Moreno|last3=Scarpellini|first3=Paolo|last4=Tettamanti|first4=Andrea|last5=Carcò|first5=Francesco|last6=Landoni|first6=Giovanni|last7=Zangrillo|first7=Alberto|title=Respiratory Parameters in Patients With COVID-19 After Using Noninvasive Ventilation in the Prone Position Outside the Intensive Care Unit|journal=JAMA|volume=323|issue=22|year=2020|pages=2338|issn=0098-7484|doi=10.1001/jama.2020.7861}}</ref> In addition, patients with an Spo2 of 95% or greater after an hour of the [[Mechanical ventilation initial ventilator settings#Proning|prone position]] had a lower rate of [[intubation]].<ref name="ThompsonRanard2020">{{cite journal|last1=Thompson|first1=Alison E.|last2=Ranard|first2=Benjamin L.|last3=Wei|first3=Ying|last4=Jelic|first4=Sanja|title=Prone Positioning in Awake, Nonintubated Patients With COVID-19 Hypoxemic Respiratory Failure|journal=JAMA Internal Medicine|year=2020|issn=2168-6106|doi=10.1001/jamainternmed.2020.3030}}</ref> To answer the question about the effectiveness, two [[Randomized controlled trial|RCTs]] are in progress [https://clinicaltrials.gov/ct2/show/NCT04347941 NCT04347941] and [https://clinicaltrials.gov/ct2/show/NCT04350723 NCT04350723].<ref name="TeliasKatira2020">{{cite journal|last1=Telias|first1=Irene|last2=Katira|first2=Bhushan H.|last3=Brochard|first3=Laurent|title=Is the Prone Position Helpful During Spontaneous Breathing in Patients With COVID-19?|journal=JAMA|volume=323|issue=22|year=2020|pages=2265|issn=0098-7484|doi=10.1001/jama.2020.8539}}</ref>
 *The American Thoracic Society/European Society of Intensive Care Medicine/Society of Critical Care Medicine Clinical Practice and Surviving Sepsis Campaign guidelines strongly recommend (moderate evidence) [[Mechanical ventilation initial ventilator settings#Proning|Prone positioning]] for more than 12 hours/day in patients with severe [[ARDS]].<ref name="FanDel Sorbo2017">{{cite journal|last1=Fan|first1=Eddy|last2=Del Sorbo|first2=Lorenzo|last3=Goligher|first3=Ewan C.|last4=Hodgson|first4=Carol L.|last5=Munshi|first5=Laveena|last6=Walkey|first6=Allan J.|last7=Adhikari|first7=Neill K. J.|last8=Amato|first8=Marcelo B. P.|last9=Branson|first9=Richard|last10=Brower|first10=Roy G.|last11=Ferguson|first11=Niall D.|last12=Gajic|first12=Ognjen|last13=Gattinoni|first13=Luciano|last14=Hess|first14=Dean|last15=Mancebo|first15=Jordi|last16=Meade|first16=Maureen O.|last17=McAuley|first17=Daniel F.|last18=Pesenti|first18=Antonio|last19=Ranieri|first19=V. Marco|last20=Rubenfeld|first20=Gordon D.|last21=Rubin|first21=Eileen|last22=Seckel|first22=Maureen|last23=Slutsky|first23=Arthur S.|last24=Talmor|first24=Daniel|last25=Thompson|first25=B. Taylor|last26=Wunsch|first26=Hannah|last27=Uleryk|first27=Elizabeth|last28=Brozek|first28=Jan|last29=Brochard|first29=Laurent J.|title=An Official American Thoracic Society/European Society of Intensive Care Medicine/Society of Critical Care Medicine Clinical Practice Guideline: Mechanical Ventilation in Adult Patients with Acute Respiratory Distress Syndrome|journal=American Journal of Respiratory and Critical Care Medicine|volume=195|issue=9|year=2017|pages=1253–1263|issn=1073-449X|doi=10.1164/rccm.201703-0548ST}}</ref><ref name="RhodesEvans2017">{{cite journal|last1=Rhodes|first1=Andrew|last2=Evans|first2=Laura E.|last3=Alhazzani|first3=Waleed|last4=Levy|first4=Mitchell M.|last5=Antonelli|first5=Massimo|last6=Ferrer|first6=Ricard|last7=Kumar|first7=Anand|last8=Sevransky|first8=Jonathan E.|last9=Sprung|first9=Charles L.|last10=Nunnally|first10=Mark E.|last11=Rochwerg|first11=Bram|last12=Rubenfeld|first12=Gordon D.|last13=Angus|first13=Derek C.|last14=Annane|first14=Djillali|last15=Beale|first15=Richard J.|last16=Bellinghan|first16=Geoffrey J.|last17=Bernard|first17=Gordon R.|last18=Chiche|first18=Jean-Daniel|last19=Coopersmith|first19=Craig|last20=De Backer|first20=Daniel P.|last21=French|first21=Craig J.|last22=Fujishima|first22=Seitaro|last23=Gerlach|first23=Herwig|last24=Hidalgo|first24=Jorge Luis|last25=Hollenberg|first25=Steven M.|last26=Jones|first26=Alan E.|last27=Karnad|first27=Dilip R.|last28=Kleinpell|first28=Ruth M.|last29=Koh|first29=Younsuk|last30=Lisboa|first30=Thiago Costa|last31=Machado|first31=Flavia R.|last32=Marini|first32=John J.|last33=Marshall|first33=John C.|last34=Mazuski|first34=John E.|last35=McIntyre|first35=Lauralyn A.|last36=McLean|first36=Anthony S.|last37=Mehta|first37=Sangeeta|last38=Moreno|first38=Rui P.|last39=Myburgh|first39=John|last40=Navalesi|first40=Paolo|last41=Nishida|first41=Osamu|last42=Osborn|first42=Tiffany M.|last43=Perner|first43=Anders|last44=Plunkett|first44=Colleen M.|last45=Ranieri|first45=Marco|last46=Schorr|first46=Christa A.|last47=Seckel|first47=Maureen A.|last48=Seymour|first48=Christopher W.|last49=Shieh|first49=Lisa|last50=Shukri|first50=Khalid A.|last51=Simpson|first51=Steven Q.|last52=Singer|first52=Mervyn|last53=Thompson|first53=B. Taylor|last54=Townsend|first54=Sean R.|last55=Van der Poll|first55=Thomas|last56=Vincent|first56=Jean-Louis|last57=Wiersinga|first57=W. Joost|last58=Zimmerman|first58=Janice L.|last59=Dellinger|first59=R. Phillip|title=Surviving Sepsis Campaign: International Guidelines for Management of Sepsis and Septic Shock: 2016|journal=Intensive Care Medicine|volume=43|issue=3|year=2017|pages=304–377|issn=0342-4642|doi=10.1007/s00134-017-4683-6}}</ref>
@@ Line 71: / Line 77: @@
 ===Special considerationss===
 *'''Lung recruitment maneuvers'''<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref><ref name="CuiCao2020">{{cite journal|last1=Cui|first1=Yu|last2=Cao|first2=Rong|last3=Wang|first3=Yu|last4=Li|first4=Gen|title=Lung Recruitment Maneuvers for ARDS Patients: A Systematic Review and Meta-Analysis|journal=Respiration|volume=99|issue=3|year=2020|pages=264–276|issn=0025-7931|doi=10.1159/000501045}}</ref><ref name="pmid27855477">{{cite journal |vauthors=Hodgson C, Goligher EC, Young ME, Keating JL, Holland AE, Romero L, Bradley SJ, Tuxen D |title=Recruitment manoeuvres for adults with acute respiratory distress syndrome receiving mechanical ventilation |journal=Cochrane Database Syst Rev |volume=11 |issue= |pages=CD006667 |date=November 2016 |pmid=27855477 |pmc=6464835 |doi=10.1002/14651858.CD006667.pub3 |url=}}</ref>: Lung recruitment maneuver is the application of very high (up to 40 cm H2O) [[positive airway pressure]] during mechanical [[ventilation]]. It opens the collapsed [[alveoli]], decreasing [[Ventilation-perfusion mismatch|ventilation/perfusion (V/Q) mismatching]] thus improving the gas exchange. For [[ARDS]] patients, the maneuvers may help improve oxygenation and decrease the length of hospital stay with no positive effect on reducing mortality. The decision varies on a case by case basis depending upon lung condition and [[patient]] hemodynamics.  On the trouble side, the maneuver may generate aerosols. High-quality evidence is lacking to support the use in [[ARDS]] patients.
-*'''[[Paralytics]]''':<ref name="pmid32360979">{{cite journal |vauthors=Payen JF, Chanques G, Futier E, Velly L, Jaber S, Constantin JM |title=Sedation for critically ill patients with COVID-19: Which specificities? One size does not fit all |journal=Anaesth Crit Care Pain Med |volume=39 |issue=3 |pages=341–343 |date=June 2020 |pmid=32360979 |pmc=7189860 |doi=10.1016/j.accpm.2020.04.010 |url=}}</ref><ref name="urlCoronavirus (COVID-19) Update: Daily Roundup May 5, 2020 | FDA">{{cite web |url=https://www.fda.gov/news-events/press-announcements/coronavirus-covid-19-update-daily-roundup-may-5-2020 |title=Coronavirus (COVID-19) Update: Daily Roundup May 5, 2020 &#124; FDA |format= |work= |accessdate=}}</ref> The [[paralytics]] may be used with [[sedative]]s and [[analgesic]]s. In [[COVID-19-associated acute respiratory distress syndrome|CARDS]] patients, Richmond Agitation Sedation Scale (RASS) score of (+2 to +4) indicates the use of deep [[sedation]] with [[paralytics]]. The use of short-term (24– ƒ48 hours) and intermittent muscle relaxation is recommended. Prone position ventilation may also require muscle relaxation along with sedation. Use of [[paralytics]] is not recommended in an unless PaO2/FiO2 < 150 mmHg. The paralytics that are being used in [[COVID-19-associated acute respiratory distress syndrome|CARDS]]patients include: [[Suxamethonium chloride|Succinylcholine chloride injection]] USP 200 mg/10 mL and [[Cisatracurium|cisatracurium besylate injection]] USP 20 mg/10 mL.
+*'''[[Paralytics]]''':<ref name="pmid32360979">{{cite journal |vauthors=Payen JF, Chanques G, Futier E, Velly L, Jaber S, Constantin JM |title=Sedation for critically ill patients with COVID-19: Which specificities? One size does not fit all |journal=Anaesth Crit Care Pain Med |volume=39 |issue=3 |pages=341–343 |date=June 2020 |pmid=32360979 |pmc=7189860 |doi=10.1016/j.accpm.2020.04.010 |url=}}</ref><ref name="urlCoronavirus (COVID-19) Update: Daily Roundup May 5, 2020 | FDA">{{cite web |url=https://www.fda.gov/news-events/press-announcements/coronavirus-covid-19-update-daily-roundup-may-5-2020 |title=Coronavirus (COVID-19) Update: Daily Roundup May 5, 2020 &#124; FDA |format= |work= |accessdate=}}</ref> The [[paralytics]] may be used with [[analgesic]]s ([[fentanyl]], [[hydromorphone]]) and [[sedative]]s ([[benzodiazepines]], [[propofol]]). In [[COVID-19-associated acute respiratory distress syndrome|CARDS]] patients, Richmond Agitation Sedation Scale (RASS) score of (+2 to +4) even after optimal ventilatoy settings may indicate the use of deep [[sedation]] with [[paralytics]]. If used, short-term (24– 48 hours) and intermittent muscle relaxation is recommended. Prone position ventilation may also require muscle relaxation along with sedation. [[Paralytics]] are not recommended in an unless PaO2/FiO2 < 150 mmHg. The paralytics that are being used in [[COVID-19-associated acute respiratory distress syndrome|CARDS]]patients include: [[Suxamethonium chloride|Succinylcholine chloride injection]] USP 200 mg/10 mL and [[Cisatracurium|cisatracurium besylate injection]] USP 20 mg/10 mL.
-'''Aerosol Generation Risk Factors and Protective Measures'''
+'''Aerosol Generation Risk Factors and Protective Measures'''<br>
+Concerns have been raised for a possible risk for transmission of [[COVID-19]] to health care personnel due to aerosol transmission.<ref name="pmid32442035">{{cite journal |vauthors=Schünemann HJ, Khabsa J, Solo K, Khamis AM, Brignardello-Petersen R, El-Harakeh A, Darzi A, Hajizadeh A, Bognanni A, Bak A, Izcovich A, Cuello-Garcia CA, Chen C, Borowiack E, Chamseddine F, Schünemann F, Morgano GP, Muti-Schünemann GEU, Chen G, Zhao H, Neumann I, Brozek J, Schmidt J, Hneiny L, Harrison L, Reinap M, Junek M, Santesso N, El-Khoury R, Thomas R, Nieuwlaat R, Stalteri R, Yaacoub S, Lotfi T, Baldeh T, Piggott T, Zhang Y, Saad Z, Rochwerg B, Perri D, Fan E, Stehling F, Akl IB, Loeb M, Garner P, Aston S, Alhazzani W, Szczeklik W, Chu DK, Akl EA |title=Ventilation Techniques and Risk for Transmission of Coronavirus Disease, Including COVID-19: A Living Systematic Review of Multiple Streams of Evidence |journal=Ann. Intern. Med. |volume= |issue= |pages= |date=May 2020 |pmid=32442035 |pmc=7281716 |doi=10.7326/M20-2306 |url=}}</ref> With the judicious use of the standard precautions and protective measures, the results for the mentioned interventions have been promising.
 <br />
 {| class="wikitable"
@@ Line 86: / Line 94: @@
 * Minimize period between removal of patient's [[Personal protective equipment|PPE]] and application of face mask with viral filter
 * Ensure sealing of face mask
-* Adequate dosage and time for paralytic drugs
+* USe of local [[lidocaine]] via [[ETT]] or during procedures such as [[bronchoscopy]] and [[opoids]] in minimum dose
 |-
 |Face Mask Seal Leak
@@ Line 95: / Line 103: @@
 * ETO2 monitoring
 |-
-|[[Intubation]], NIV, manual [[ventilation]], [[CPR]], [[tracheostomy]] and [[bronchoscopy]]
+|Non-Invasive ventilation, [[bronchoscopy]], [[CPR]]<br> [[extubation]], and manual [[ventilation]]
 |
 *[[WHO]] recommends the use of [[PPE]] that includes respirators, eye protection, gloves and gowns; aprons if gowns are not fluid resistant.<ref name="urlapps.who.int">{{cite web |url=https://apps.who.int/iris/bitstream/handle/10665/331498/WHO-2019-nCoV-IPCPPE_use-2020.2-eng.pdf |title=apps.who.int |format= |work= |accessdate=}}</ref>
-*Chest [[auscultation]] after [[intubation]] is not recommended due to aerosol transmission of the [[SARS-CoV-2|severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)]] virus.
+*In addition to regular precautions such as the use of [[PPE]] followed during [[COVID-19]] pandemic following precautions as advised by [[CDC]] to prevent [[Airborne transmission|airborne]] transmission should be taken:<ref name="urlTransmission-Based Precautions | Basics | Infection Control | CDC”">{{cite web |url=https://www.cdc.gov/infectioncontrol/basics/transmission-based-precautions.html |title=Transmission-Based Precautions &#124; Basics &#124; Infection Control &#124; CDC” |format= |work= |accessdate=}}</ref>
-*[[Oxygen saturation|Spo2]], chest movements, [[capnography]], fogging inside of the [[endotracheal tube]], and the color of the patient’s skin and [[mucous membrane]] can be used to confirm a successful [[intubation]].<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref>
-|-
-|Non-Invasive ventilation (HFNC and [[Positive airway pressure|NIPPV]])
-|
-*Both HFNC and [[Positive airway pressure|NIPPV]] methods used in [[COVID-19]] patients generate [[aerosols]]. Concerns have been raised for a possible risk for transmission of [[COVID-19]] to health care personnel.<ref name="pmid32442035">{{cite journal |vauthors=Schünemann HJ, Khabsa J, Solo K, Khamis AM, Brignardello-Petersen R, El-Harakeh A, Darzi A, Hajizadeh A, Bognanni A, Bak A, Izcovich A, Cuello-Garcia CA, Chen C, Borowiack E, Chamseddine F, Schünemann F, Morgano GP, Muti-Schünemann GEU, Chen G, Zhao H, Neumann I, Brozek J, Schmidt J, Hneiny L, Harrison L, Reinap M, Junek M, Santesso N, El-Khoury R, Thomas R, Nieuwlaat R, Stalteri R, Yaacoub S, Lotfi T, Baldeh T, Piggott T, Zhang Y, Saad Z, Rochwerg B, Perri D, Fan E, Stehling F, Akl IB, Loeb M, Garner P, Aston S, Alhazzani W, Szczeklik W, Chu DK, Akl EA |title=Ventilation Techniques and Risk for Transmission of Coronavirus Disease, Including COVID-19: A Living Systematic Review of Multiple Streams of Evidence |journal=Ann. Intern. Med. |volume= |issue= |pages= |date=May 2020 |pmid=32442035 |pmc=7281716 |doi=10.7326/M20-2306 |url=}}</ref>
-*With the judicious use of the standard precautions and protective measures, the results for the aforementioned interventions have been promising. So, in addition to regular precautions such as the use of [[PPE]] followed during [[COVID-19]] pandemic following precautions as advised by [[CDC]] to prevent [[Airborne transmission|airborne]] transmission should be taken:<ref name="urlTransmission-Based Precautions | Basics | Infection Control | CDC”">{{cite web |url=https://www.cdc.gov/infectioncontrol/basics/transmission-based-precautions.html |title=Transmission-Based Precautions &#124; Basics &#124; Infection Control &#124; CDC” |format= |work= |accessdate=}}</ref>
 **[[Airborne transmission|Airborne infection]] isolation room (AIIR)
 **Restricting susceptible healthcare personnel
 **Limiting transport and movement of the [[patient]]
 **Use of fit-tested [[Occupational safety and health|NIOSH]]-approved  N95 or higher level respirator for healthcare personnel.
+**The staff who are expected to help during the procedure should be informed and ready with [[PPE]]s.
+*If possible, use disposable [[bronchoscope]] or cleaning the suction channels with the cleaning solutions used for highly [[infectious]] materials.
+|-
+|[[Intubation]]
+|
+*Above mentioned precautions such as the use of [[PPE]] and AIIR with minimal personnel in the room should be followed.
+*Chest [[auscultation]] after [[intubation]] is not recommended due to aerosol transmission of the [[SARS-CoV-2|severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)]] virus.
+*[[Oxygen saturation|Spo2]], chest movements, [[capnography]], fogging inside of the [[endotracheal tube]], and the color of the patient’s skin and [[mucous membrane]] can be used to confirm a successful [[intubation]].<ref name="MengQiu2020">{{cite journal|last1=Meng|first1=Lingzhong|last2=Qiu|first2=Haibo|last3=Wan|first3=Li|last4=Ai|first4=Yuhang|last5=Xue|first5=Zhanggang|last6=Guo|first6=Qulian|last7=Deshpande|first7=Ranjit|last8=Zhang|first8=Lina|last9=Meng|first9=Jie|last10=Tong|first10=Chuanyao|last11=Liu|first11=Hong|last12=Xiong|first12=Lize|title=Intubation and Ventilation amid the COVID-19 Outbreak|journal=Anesthesiology|volume=132|issue=6|year=2020|pages=1317–1332|issn=0003-3022|doi=10.1097/ALN.0000000000003296}}</ref>
+|-
+|[[Tracheostomy]]
+|
+*Above mentioned precautions such as the use of [[PPE]] and AIIR with minimal personnel in the room should be followed.
+*During the procedure, minimal use of [[diathermy]], and maintenance of bloodless fields should be ensured.
+*Post-procedure, reduce the frequency of changing an inner cannula and cuff pressure checks to a possible minimum for the patient.
+*Post [[tracheostomy]], humidification can be provided via heat and moisture exchange filter or a water-based humidification such as [[hypertonic saline]] [[nebulizers]].
+*Patients should use facemasks and tracheostomy shields during trials of [[tracheostomy]] cuff deflation.<ref name="McGrathBrenner2020">{{cite journal|last1=McGrath|first1=Brendan A|last2=Brenner|first2=Michael J|last3=Warrillow|first3=Stephen J|last4=Pandian|first4=Vinciya|last5=Arora|first5=Asit|last6=Cameron|first6=Tanis S|last7=Añon|first7=José Manuel|last8=Hernández Martínez|first8=Gonzalo|last9=Truog|first9=Robert D|last10=Block|first10=Susan D|last11=Lui|first11=Grace C Y|last12=McDonald|first12=Christine|last13=Rassekh|first13=Christopher H|last14=Atkins|first14=Joshua|last15=Qiang|first15=Li|last16=Vergez|first16=Sébastien|last17=Dulguerov|first17=Pavel|last18=Zenk|first18=Johannes|last19=Antonelli|first19=Massimo|last20=Pelosi|first20=Paolo|last21=Walsh|first21=Brian K|last22=Ward|first22=Erin|last23=Shang|first23=You|last24=Gasparini|first24=Stefano|last25=Donati|first25=Abele|last26=Singer|first26=Mervyn|last27=Openshaw|first27=Peter J M|last28=Tolley|first28=Neil|last29=Markel|first29=Howard|last30=Feller-Kopman|first30=David J|title=Tracheostomy in the COVID-19 era: global and multidisciplinary guidance|journal=The Lancet Respiratory Medicine|volume=8|issue=7|year=2020|pages=717–725|issn=22132600|doi=10.1016/S2213-2600(20)30230-7}}</ref>
 |}
 <br />
+==Bronchoscopy==
+==Tracheostomy==
+*Standard decision making for [[tracheostomy]] in a [[COVID]] patient is practiced. But owing to the potential of aerosol spread of the [[infection]] certain considerations should be kept in mind, such as the safety of other the patient's family, other [[patient]]s, healthcare personnel, and the resources available.<ref name="ZhangHuang2020">{{cite journal|last1=Zhang|first1=Xiaomeng|last2=Huang|first2=Qiling|last3=Niu|first3=Xun|last4=Zhou|first4=Tao|last5=Xie|first5=Zhen|last6=Zhong|first6=Yi|last7=Xiao|first7=Hongjun|title=
+            Safe and effective management of tracheostomy in
+            COVID
+            ‐19 patients
+          |journal=Head & Neck|volume=42|issue=7|year=2020|pages=1374–1381|issn=1043-3074|doi=10.1002/hed.26261}}</ref>
+*Tracheostomy should be delayed until at least the 10th day of mechanical [[ventilation]]. It should be considered only when the [[patient]] is clinically improving. The decision of extubation should be limited to the [[patient]]s who have a high chance of success.<ref name="McGrathBrenner2020">{{cite journal|last1=McGrath|first1=Brendan A|last2=Brenner|first2=Michael J|last3=Warrillow|first3=Stephen J|last4=Pandian|first4=Vinciya|last5=Arora|first5=Asit|last6=Cameron|first6=Tanis S|last7=Añon|first7=José Manuel|last8=Hernández Martínez|first8=Gonzalo|last9=Truog|first9=Robert D|last10=Block|first10=Susan D|last11=Lui|first11=Grace C Y|last12=McDonald|first12=Christine|last13=Rassekh|first13=Christopher H|last14=Atkins|first14=Joshua|last15=Qiang|first15=Li|last16=Vergez|first16=Sébastien|last17=Dulguerov|first17=Pavel|last18=Zenk|first18=Johannes|last19=Antonelli|first19=Massimo|last20=Pelosi|first20=Paolo|last21=Walsh|first21=Brian K|last22=Ward|first22=Erin|last23=Shang|first23=You|last24=Gasparini|first24=Stefano|last25=Donati|first25=Abele|last26=Singer|first26=Mervyn|last27=Openshaw|first27=Peter J M|last28=Tolley|first28=Neil|last29=Markel|first29=Howard|last30=Feller-Kopman|first30=David J|title=Tracheostomy in the COVID-19 era: global and multidisciplinary guidance|journal=The Lancet Respiratory Medicine|volume=8|issue=7|year=2020|pages=717–725|issn=22132600|doi=10.1016/S2213-2600(20)30230-7}}</ref>
+==CPR==
+American Heart Association's (AHA) interim ''BLS Healthcare Provider Adult Cardiac Arrest Algorithm for Suspected or Confirmed COVID-19 Patients'' can be accessed by [https://cpr.heart.org/-/media/cpr-files/resources/covid-19-resources-for-cpr-training/english/algorithmbls_adult_cacovid_200406.pdf?la=en clicking here].<ref name="urlCoronavirus (COVID-19) Resources for CPR Training | American Heart Association CPR & First Aid">{{cite web |url=https://cpr.heart.org/en/resources/coronavirus-covid19-resources-for-cpr-training |title=Coronavirus (COVID-19) Resources for CPR Training &#124; American Heart Association CPR & First Aid |format= |work= |accessdate=}}</ref>
+==References==
+{{Reflist|2}}