CC BY-NC-ND 4.0 · Revista Chilena de Ortopedia y Traumatología 2021; 62(01): 057-065
DOI: 10.1055/s-0041-1728739
Review Article | Artículo de Revisión

Covid-19 and Orthopedic Surgery: Review of the Literature and Evidence

Article in several languages: español | English
1   Departamento de Ortopedia y Traumatología, Universidad de Chile, Santiago, Chile
2   Departamento de Ortopedia y Traumatología, Universidad Católica de Valencia San Vicente Mártir, Valencia, España
,
Carlos Huaiquilaf
1   Departamento de Ortopedia y Traumatología, Universidad de Chile, Santiago, Chile
,
Marcelo Costa
3   Equipo de columna Redsalud Santiago, Santiago, Chile
,
Cristian Correa
4   Departamento de Ortopedia y Traumatología, Universidad de la Frontera, Temuco, Chile
,
Alan Bey
5   Universidad Finis Terrae, Región Metropolitana, Santiago, Chile
6   Universidad Diego Portales, Región Metropolitana, Santiago, Chile
,
Luis Bahamonde M
1   Departamento de Ortopedia y Traumatología, Universidad de Chile, Santiago, Chile
› Author Affiliations
 

Abstract

A pandemic has been declared due to a new highly contagious virus called severe acute respiratory syndrome coronavirus 2 (SARS-CoV2). The world has come to a halt due to the rapid expansion of this virus, whose lethality has reached 15% in some countries. In Chile, the government has taken decisive, aggressive measures in an attempt to control disease spread and provide healthcare to those who need it. These decisions include the suspension of elective surgeries and other ambulatorial procedures. As orthopedic surgeons, we have been affected by these measures, and there is doubt regarding the best course of action. We prepared this guide to summarize available evidence and orient our colleagues regarding this condition. This guide is meant to be dynamic, as new opinions, evidence and experiences arise every day. Therefore, we advise the reader to keep it as a reference, not an undisputable truth.


#

Introduction

On March 12, 2020, the World Health Organization (WHO) declared a pandemic due to the spread of a new highly contagious virus from China, called severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2).

We prepared the present guide to summarize part of the available evidence and offer guidance to orthopedic surgeons regarding this condition. This guide is meant to be dynamic, as new opinions, evidence and experiences arise every day. Therefore, we advise the reader to keep it as a reference, and not an undisputable truth. We hope to update it continuously as required.


#

What is Covid-19?

In December 2019, 41 cases of pneumonia of an unknown etiology appeared in Wuhan, China. As Wuhan is an important transport hub, most of these patients reported visiting a local fish and wildlife market during the month prior to the onset of the disease.

The virus is contracted through the respiratory tract, mainly through respiratory droplets and contact with contaminated surfaces.[1] The most frequent symptoms are fever and cough ([Table 1]), but some patients may remain afebrile.

Table 1

Symptoms

Frequency (percentage)

Authors

Fever

83–100

[1] [2]

Cough

61–90

[1] [2]

Fatigue

27–100

[1] [3]

Productive cough

21

[1]

Muscle/joint pain

14–50

[1] [3](76)

Gastrointestinal symptoms (diarrhea)

10

[1](77)

Dyspnea

12–14

[1]

Odynophagia

8

[1]

Headache, dizziness, reduced mentation

9

[1](70)

Upper-respiratory-tract symptoms (rhinorrhea, anosmia)

5

[1](69)

Multiple organ failure

6

[1](75)

Hepatomegaly/Splenomegaly

[4](75)

Encephalitis

[5]

The diagnosis is made with real-time polymerase chain reaction (RT-PCR), which has a 61% to 70% sensitivity during the first week of symptoms. From days 8 to 14, the sensitivity of this test in oropharyngeal swab samples falls from 61% to 50% in patients with severe disease, and to 29% in those with mild symptoms.[2]

Multiple detection tests have become available worldwide up to the date of the present report, using either airway or blood samples; as such, Sociedad Chilena de Infectología has prepared a review on the usefulness of different tests ([Table 2]).[2]

Table 2

Detection

Uses

Beneficiaries

Ribonucleic Acid (RNA) amplification techniques

Current infection.

Respiratory sample

From oropharyngeal swab

- Report individual infection status, help to anticipate spread and take measures to prevent it

- Patients

- Health institutions

- Public health

Antibody detection

Current or previous infection

- Detects previously infected and susceptible subjects

- Identifies subjects with neutralizing antibodies

- Allows contact tracing

- Potentially immune subjects

- Health institutions

- Public health

Antigen detection

Current infection

- May report current infection status. Lack of sufficient data

- Patients

- Health institutions

The highest mortality rates occur in patients with comorbid conditions ([Table 3]). This virus causes two types of severe syndromes: one behaving as a cytokine storm, and the other, as an antiphospholipid syndrome. [Table 4] shows signs of poor prognosis.

Table 3

Comorbid condition

Mortality risk (percentage)*

Author

Age over 60 years

80

[1]

Age over 50 years

90

[1] [6]

Cardiovascular condition

10.5–13.2

[1] [6]

Hypertension

8.3–65.9

[1] [6] [7]

Diabetes with glycated hemoglobin (A1c) level > 7.6%

7.3–9.2

[1] [6]

Respiratory condition

8.0–10.3

[1] [6]

Cancer

5.6–7.6

[1] [6]

No comorbid conditions

0.9–1.4

[1]

Biological therapy**

[6](76)

Transplant or mesenchymal conditions**

[6](76)

HIV with CD4 cells < 200*

[6]

Table 4

Vital signs

Laboratory tests

Respiratory rate > 24/minute

D-dimer > 1,000 ng/mL

Heart rate > 125/minute

Creatine kinase level more than two-fold increased from normal values

SpO2 < 93% with room FiO2

C-reactive protein > 100

PaO2/FiO2 < 300 mmHg

Lactate dehydrogenase level > 245 U/L

Increased troponin level

Total lymphocyte count < 0.8

Ferritin level > 500 U/L


#

Treatment

The only proven treatment against coronavirus disease 2019 (Covid-19) consists of supportive measures, ranging from keeping a patient with mild disease well hydrated at home to mechanical ventilation and general management for respiratory distress.

From the point of view of traumatology and orthopedics, increased morbidity and mortality rates have been previously described in patients with pneumonia and hip fracture.[3] Similarly, there is a 5% rate of postoperative pulmonary complications following the surgical treatment for hip fracture. In a series[4] of 10 Covid-19-positive patients with major fractures, 4 died 8 to 11 days after admission to the emergency room; among them, only 1 patient was operated on promptly, resulting in early death. These patients presented neutrophilia, lymphopenia, and increased D-dimer levels compared to patients without fractures, which is in line with the greater severity of the condition.[4]


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Control Measures

All available measures are required to avoid these degrees of disease transmission ([Table 5]). Persons who came in direct contact with Covid-19 patients must be quarantined for 14 days, since 98% of the patients are symptomatic at 12 days, as previously explained.

Table 5

Measure

When

Author

Hand washing

Always

[1] [13]

Mask use

Always

[1] [13]

Social distancing (> 1 meter)

Always

[1] [13]

Personal protective equipment (PPE) use

Healthcare personnel

[13]

Quarantine for 14 days

Contact

[1]

Gloves, face cover, change clothes

Always

[13]

Public places closures (malls, schools)

Case by case

[1]

Public transportation closure

Case by case

[1]

Workplace closure

Case by case

[1]

Total quarantine

Case by case

[1]

Border closure

Stage IV

[1]

There are three key concepts:

  1. Clinical urgency.

  2. Protection of patients and the healthcare personnel.

  3. Conservation of health resources.[5]

In a stage-IV pandemic, as orthopedic surgeons, we are exposed to different mechanisms of disease transmission. In Spain, 14% of infections occur in healthcare personnel. In Wuhan, China, from December 2019 to February 2020, traumatologists reported an average incidence rate of 5.6% of SARS-CoV-2 infections across their eight hospitals; the most frequent places of suspected transmission were waiting rooms (79%), public areas of the hospital (20.8%), and surgical wards (12.5%). One in four traumatologists was directly contaminated by another colleague.[6] [7]

The mandatory use of personal protective equipment (PPE), including gowns, gloves, masks, N95, P100, and FFP2 respirators with goggles or powered air-purifying respirators (PAPRs), is critical to minimize the risk of intra-hospital disease transmission and cross-infection. Meticulous hand washing and disinfection of personal items, such as stethoscopes, cell phones, and laptops, are also recommended ([Table 6]).

Table 6

Location

Mechanism

Study groups involved

Screening

Screening and initial examination

1. Surgical mask

2. AAMI level II regular gown

3. Goggles or face shields

4. Gloves

5. Hand hygiene before and after examining each patient

Outpatient medical visit 1

Examination of Covid-19-negative patients with no respiratory signs

1. Surgical mask

2. Gloves

3. Attention to environmental contamination (tools, work items)

4. Hand hygiene before and after examining each patient

Outpatient medical visit 2

Examination of Covid-19-positive patients or subjects with fever and/or respiratory signs

1. Tight-fitting NIOSH-certified N95 mask (if available) or surgical mask (consider double/multiple mask technique and ensure a perfect fit)

2. AAMI level II regular gown

3. Goggles or face shields

4. Gloves (consider double gloving)

5. Hand hygiene before and after examining each patient

Procedure room

Non-invasive care of Covid-19-positive patients or subject with fever and/or respiratory signs

1. Tight-fitting NIOSH-certified N95 mask (if available) or surgical mask (consider double/multiple mask technique and ensure a perfect fit)

2. AAMI level II regular gown

3. Goggles or face shields

4. Gloves (consider double gloving)

5. Hand hygiene before and after examining each patient

Preanesthesia room

Avoid unnecessary contact between orthopedists and patients. The anesthetist must be protected during aerosol-generating procedures

1. Powered air-purifying respirators (PAPRs) if available, or

2. Tight-fitting NIOSH-certified N95 mask

3. Eye protection: goggles (with lateral cover) or face shields

4. AAMI level III disposable surgical gown

5. Double surgical gloves with extended cuff (alternatively, vertical strips of tape can be used to keep gloves secured to gown)

6. Shoes must be fluid-resistant and easily decontaminated (disposable shoe covers may increase contamination risk)

7. Hand hygiene before and after putting on/taking off personal protective equipment (PPE)

8. Take a shower after procedures generating respiratory aerosols.

Operating Room 1

Urgent surgery, damage control, minimizing risk and surgical time in Covid-19-positive patients or subjects with fever and/or respiratory signs.

(Operating room with no aerosol generation)

1. PAPRs if available or

2. Tight-fitting NIOSH-certified N95 mask

3. Eye protection: goggles (with lateral cover) or face shields

4. AAMI level III disposable surgical gown

5. Double surgical gloves with extended cuff (alternatively, vertical strips of tape can be used to keep gloves secured to gown)

6. Shoes must be fluid-resistant and easily decontaminated (disposable shoe covers may increase contamination risk)

7. Hand hygiene before and after putting on/taking off PPE

Operating room 2

Urgent surgery with aerosol generation and blood droplets in Covid-19-positive patients or subjects with fever and/or respiratory signs

1. PAPRs if available or

2. Tight-fitting NIOSH-certified N95 mask

3. Eye protection: goggles (with lateral cover) or face shields

4. AAMI level III disposable surgical gown

5. Double surgical gloves with extended cuff (alternatively, vertical strips of tape can be used to keep gloves secured to gown)

6. Shoes must be fluid-resistant and easily decontaminated (disposable shoe covers may increase contamination risk)

7. Hand hygiene before and after putting on/taking off PPE

8. Take a shower after procedures generating respiratory aerosols.

Recovery room

PPE removal

1. Pay special attention to avoid self-contamination during PPE removal.


#
#

Allocating Orthopedic Surgery Units

Teams must be created and absolutely isolated from each other.[8] Ideally, teams should be created at least 12 days[9] or 2 weeks apart to meet minimal service requirements. There must be teams to care for Covid-19-positive patients and teams to care for negative patients. Surgeons should not work more than 6 hours at a time to avoid exposure and fatigue.[6]


#

Management of Orthopedic Conditions at the Emergency Room

From a “viral” point of view, there are several alternatives for trauma patients requiring urgent care:

Types of “Viral” Patients in General Emergency Care Visits

  1. Patient previously diagnosed as Covid-19-positive.

  2. Patient under preventive quarantine due to direct contact with a Covid-19-positive subject.

  3. Symptomatic patient under no quarantine.

  4. Asymptomatic patient under no quarantine but within a total quarantine perimeter due to location at an epidemiologically dangerous area with untreated contacts.

  5. Asymptomatic patient under no quarantine and outside the perimeter of a total quarantine.

In stage IV, the postponement of all possible elective surgeries has been determined under ministerial decree and global recommendation,[10] along with all ambulatory or urgent medical attention for conditions that are not life-threatening or potentially leading to severe sequelae. The pathophysiology of SARS-CoV-2 in the human body,[11] affecting not only the alveolar epithelium but also the kidney, liver, brain and intestine,[12] increases the morbidity and mortality of trauma[4] or invasive-surgery patients. The stress associated with a fracture and its surgical treatment can trigger an oxidative cascade and excessive inflammatory response that decreases the immune capacity of the patient, thus increasing lung and systemic damage from SARS-CoV-2 and other pathogens.[3]

Different surgical and orthopedics associations worldwide recommend Covid-19-related measures for the care of trauma patients at the emergency room.[10] [13] [14]

The following is a summary of Covid-19-related recommended measures for trauma-patient care at the emergency room:

  1. Staff. The presence of personnel at all levels should be minimized.

  2. Avoid the presence of non-essential work materials.

  3. Provide safe and effective dispensers of protective gowns, shoe covers and masks, as well as containers for their disposal. Anything used with the patient must be discarded immediately upon completion of care.

  4. Minimize imaging requests to avoid patient referral to the imaging service.

  5. Avoid traffic of personnel entering and leaving the Covid-19 traumatology ward.

  6. Perform resolutive procedures for the repair of soft tissue.

  7. At the end of the care, do not allow the patient to wander outside the ward. In case of a major (spinal, femoral) or open fracture requiring hospitalization and/or surgical management, a computed tomography scan of the thorax should be requested because the Covid-19 test result may be delayed. In a recent study[4] evaluating patients with major fractures and Covid-19, three of them were negative on RT-PCR on admission, and their diagnosis was confirmed by a computed tomography scan revealing findings suggestive of pneumonia related to SARS-CoV-2.[4] [15]

  8. At outpatient discharge, schedule a supervised appointment to a specialty office dully prepared for two situations: Covid-19-positive or suspected trauma patients, and patients with no Covid-19 suspicion. If possible, follow-up visits should be carried out via telemedicine.

The remaining trauma patients, with little suspicion of Covid-19, should be submitted to rapid tests to rule out infection in 10 to 15 minutes due to the high percentage (ranging from 25% to 50%) of asymptomatic subjects. For trauma studies, request a supplementary chest radiography.[13]

Severe polytraumatized patients deserve a special mention, since resuscitation or acute care rooms must follow all hygiene and protection measures for the trauma team. In the epidemiological context, every patient with these features must be considered potentially infected.[13]


#

Pediatric Emergency Trauma Patient

Although pediatric cases should follow the same aforementioned recommendations, their musculoskeletal biology warrants some considerations[14] [16]

If possible, treat the following diagnostic suspicions with no radiology support:

  • Soft tissue injuries.

  • Wrist, scaphoid, forearm, clavicle, and proximal humeral fractures.

  • Long bone fractures with clinical deformity.

  • Foot fractures with no significant clinical deformity or swelling.


#

The Following Injuries Can Be Treated with no Cast (Using Removable Immobilization)

  • Knee ligament and simple patellar injuries.

  • Stable ankle fractures.

  • Rearfoot, midfoot, and forefoot injuries.

A one-time outpatient check-up at 4 to 12 weeks, depending on the fractured limb or bone, is acceptable for most injuries. Close initial follow-up with radiographs at 2 weeks and subsequent teleconferences at 4 to 6 weeks is appropriate at these circumstances:

  • Patellar subluxations and dislocations, knee ligament injury, and meniscal injuries, except for locked knee.

  • Lateral malleolar fractures and potential ankle avulsion fractures.

  • Foot injuries, except for suspected midfoot and rearfoot injuries.

  • Displaced wrist, forearm, clavicle and humerus fractures, including proximal humeral fractures, reduced at the operating room.

  • Supracondylar Gartland type-2 or -3 fractures requiring reduction under anesthesia.


#

Injuries Definitively Managed with Cast at the Emergency Room for Eventual Removal at Home and Subsequent Teleconference at 4 to 6 Weeks

  • Ankle fractures with no neurovascular or soft tissue involvement (Salter Harris 2, triplane fracture, Tillaux fracture). A small number of these patients may require intervention:

    • Admit the patient if there is a high risk of compartment syndrome (high-energy injuries or adolescent subjects).

    • Consider sedation to reduce a clinically important deformity.

    • Accept that residual deformity, joint involvement, or poor union may require corrective surgery.

  • Displaced wrist fractures reduced at the emergency room in children under 10 years old.

  • Non-displaced ankle and forearm fractures.

  • Non-displaced supracondylar, Gartland 2 fractures.

  • Clavicle fractures.

  • Non-displaced lateral condylar fractures.

Regarding the aforementioned recommendations, there should be a strong agreement at the institutional level to coordinate and unify the management of all adult and pediatric patients according with the local epidemiological, infectious, and healthcare scenario.


#
#

Performance of Surgeries during this Stage

Initially, we recommend reviewing informed consent forms and adding information regarding Covid-19.[9] Assume all patients are asymptomatic carriers because tests have shown variable sensitivity, ranging from 77% to 92%, and there were severe cases with repeated negative tests.[17] [18] [19]


#

How to Manage the Operating Room in Cases of Confirmed or Suspicious Covid-19-Positive Patients?

Ideally, due to the large amount of aerosol, the main mechanism for the spread of SARS-Cov2,[20] operating rooms must be negatively pressured, especially in surgeries under gas sedation or general anesthesia. So far, there are few reports about it, mainly two,[21] [22] including one on negative pressure use during anesthetic induction, and another in patients with colon cancer submitted to surgery. Laminar flow is not recommended.[23]

At least three filters between the patient and the operating room staff are required (for instance, respirator, mask use by the staff, and mask use by the patient until intubation).

The PPE should include a mask with N95 filters or similar (FPP2 or FPP3), eye protection, gloves, disposable apron, blue balaclava,[23] shoe covers,[24] [25] [26] and, ideally, a face shield[23] ([Table 6]). Suits with headtops[23] are not recommended because the motor unit may spread infected droplets inside the garment, maybe even increasing the viral load.

All aerosol-generating situations must be avoided during surgery. Two specific recommendations include the use of a covered electrosurgical unit with suction (cut the blue part of the suction tube and, with a scalpel, make a slot at the transparent part to pass the tip of the electrosurgical unit; this enables smoke [which aerosolizes the virus] aspiration during the section) and to avoid pulsatile rinsing.[23] In addition, be careful when drilling, and, if possible, use a manual drill that produces lower levels of blood dispersion and aerosol formation.[23]

As far as possible, use absorbable sutures and cover the wounds with transparent plastic (such as Tegaderm [3M, Saint Paul, Minnesota, US]) to observe them without uncovering. Minimize contact with the patient at the outpatient setting[23] (wounds can also be monitored using telemedicine).

It is recommended that the anesthesiologist stay alone with the patient at the operating room, and an anesthesia assistant is deemed unnecessary. The operating room nurse should never contact the medical surgical nurse, only leave supplies on the sterile table.[9] Everyone should stay inside the operating room until the patient leaves it; next, PPE must be properly removed within the operating room ([Fig. 1]).[22]

Zoom Image
Fig. 1 Management of coronavirus disease 2019 (Covid-19) patients in the operating room.

#

What Surgeries Should be Performed in This Period?

Vital urgencies and/or with risk of major sequelae (amputation, para/quadriplegia).

  • Severe hand/foot injury.

  • Compartment syndrome.

  • Unstable pelvic fracture with current or imminent hemodynamic compromise.

  • Spinal cord trauma with neurological compromise.

  • Tumors with imminent long bone and/or spinal fracture with current or imminent neurological compromise.

  • Cauda equina syndrome.

  • Dislocation of native or prosthetic joints (reduction at the emergency room).

  • Joint fractures with major deformity resulting in neurological and/or vascular compromise that does not improve after orthopedic reduction and adequate immobilization.

  • Gustilo III or equivalent open fractures.

  • Femoral fracture in subjects under 45 years old.

  • Abscesses with no septic compromise: drainage at the emergency room.

  • Infectious arthritis with systemic involvement (formal sepsis): main operating room.

  • Traumatic injuries with no fractures but with neurovascular compromise.

  • Open traumatic injuries with no fractures and with acute or subacute tendon injury.

  • Patient with previous joint replacement who presents fever, or requires wound drainage.

Urgencies with Delayed Treatment

  • Gustilo I to II or equivalent open fractures.

  • Hip fractures in elderly subjects must be resolved within 48 to 72 hours.

  • Long bone fractures in the lower extremities: distal tibial fracture, tibial plateau fracture Schatzker IV to VI. Reduction in one surgical time; consider the external fixator as definitive surgery if it is used.

  • Rapidly-progressive cervicoarthrosis myelopathy.

  • Disabling radiculopathy with ≤ M3 motor impairment.

  • Patient with indication for joint replacement who presents pain exacerbation.

  • Compressive vertebral fracture, except for those orthopedically treated.

  • Spine infection.

  • Symptomatic proximal junctional kyphosis.

  • Scoliosis with neurological deficit.


#

Delayed Treatment with Potential Disability that May Be a Candidate for Complex Reconstruction

  • Displaced fractures not described in the previous sections with no risk of exposure, neurological or vascular compromise after reduction.

  • Knee ligament injuries that do not involve formal knee dislocation.


#

Non-urgent Conditions

  • Any other orthopedic pathology not described here.

Hospitalizations should be reduced as much as possible; the length of stay should be shorter than 23 hours; patients should be operated as soon as possible.[27]


#
#

Resuming Elective Surgery

To resume elective surgeries, we recommend the following:

  1. At least 14 days of downward disease transmission curve.

  2. Clear, institutionalized protocols and compliance control.

  3. Screening: prioritize more severe, urgent cases.

  4. Consider mandatory testing of all patients who must undergo surgery, considering the high percentage of false-negative results (30%). Screening must include two tests.

  5. Do not relax personal protective measures.

  6. Consider the capacity of beds at the hospital's intensive care unit before resuming surgery.

  7. Consider whether support units are available. These units may have been closed due to personnel issues, financial problems, or contamination.

  8. Psychological status of the personnel working at the reopening.

  9. Do not reduce the quality of care.[28]


#

Conclusions

  1. Minimize contact with the patient, whether at the outpatient facility, emergency room or surgical setting.

  2. Be very strict with personal protection measures.

  3. Do not operate anything that is not strictly urgent.

  4. Maintain the communication and cohesion of the medical teams, including for doctors in training.

  5. Prepare for urgent care.

  6. Do not disseminate unconfirmed information.

  7. Centralize decisions and the use of the operating algorithm in leadership groups.


#
#

Conflicto de Intereses

Los autores declaran no haber conflicto de intereses.

Authors' Contributions

The present aerticle was approved by all subscribed authors:


Karen Weissmann: study conception, manuscript draft, revision, and approval of the final version for publication.


Carlos Huaiquilaf: manuscript draft, revision, and approval of the final version for publication.


Marcelo Costa: manuscript draft, revision, and approval of the final version for publication.


Cristian Correa: manuscript draft, revision, and approval of the final version for publication.


Alan Bey: manuscript draft.


Luis Bahamondes: manuscript draft, revision, and approval of the final version for publication.


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Address for correspondence

Karen A. Weissmann
Departamento de Ortopedia y Traumatología, Universidad de Chile
avenida Libertador Bernardo O'Higgins 1.058, Santiago de Chile
Chile   

Publication History

Received: 27 April 2020

Accepted: 21 January 2021

Article published online:
02 June 2021

© 2021. Sociedad Chilena de Ortopedia y Traumatologia. This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commecial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

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Fig. 1 Manejo de pacientes con Covid-19 en pabellón.
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Fig. 1 Management of coronavirus disease 2019 (Covid-19) patients in the operating room.