CONTENTS

Basic biology

Infection control

Diagnosis

Treatment: General protocols

Treatment: Specific anti-viral & immunosuppressive therapies

Treatment: Additional issues by organ system

Prognosis

basics

COVID-19 is a non-segmented, positive sense RNA virus.

COVID-19 is part of the family of coronaviruses. This contains: (i) Four coronaviruses which are widely distributed and usually cause the common cold (but can cause viral pneumonia in patients with comorbidities). (ii) SARS and MERS – these caused epidemics with high mortality which are somewhat similar to COVID-19. COVID-19 is most closely related to SARS.

COVID-19 binds via the angiotensin-converting enzyme 2 (ACE2) receptor located on type II alveolar cells, intestinal epithelia, and the vascular endothelium (Hamming 2004). This is the same receptor as used by SARS (hence the technical name for the COVID-19, “SARS-CoV-2”). When considering possible therapies, SARS (a.k.a. “SARS-CoV-1”) is the most closely related virus to COVID-19.

COVID-19 is mutating, which may complicate matters even further. Virulence and transmission will shift over times, in ways which we cannot predict. Ongoing phylogenetic mapping of new strains can be found here.

nomenclature used in this chapter

Technically, the virus is supposed to be called “SARS-CoV-2” and the clinical illness is called “COVID-19.” This gets confusing, so for this chapter the term COVID-19 will be used to refer to both entities.

The term “SARS” will be used to refer to the original SARS virus from 2003 (which has currently been renamed SARS-CoV-1).

pathophysiology

(1) Hypoxemic respiratory failure The primary organ failure is hypoxemic respiratory failure. COVID-19 can reduce surfactant levels, potentially leading to atelectasis and de-recruitment. Pneumocytes with viral cytopathic effect are seen, implying direct virus damage (rather than a purely hyper-inflammatory injury; Xu et al 2/17). Autopsy studies show lymphocytic pneumonitis, acute fibrinous organizing pneumonia (AFOP), and diffuse alveolar damage. More discussion of lung pathology here.

(2) Cytokine storm Emerging evidence suggests that some patients may respond to COVID-19 with an exuberant “cytokine storm” reaction. This has some similarities to hemophagocytic lymphohistiocytosis and CAR-T cell cytokine release syndrome, but it appears to be a distinct entity. Clinical markers of this may include elevations of C-reactive protein and ferritin, which appear to track with disease severity and mortality (Ruan 3/3/20). This is discussed further below in the section on immunomodulation.

(3) Disseminated intravascular coagulation A major driver of pathogenesis appears to be a hypercoagulable state, likely due to both systemic inflammation and to direct endothelial injury by the virus. This is discussed further below in the section on hematology.



stages of illness – this is discussed in the section on immunomodulatory therapy.

airborne transmission

It appears increasingly likely that COVID may also be transmitted via an airborne route (small particles which remain aloft in the air for longer periods of time)( Doremalen et al. 3/17/19 ). Airborne transmission would imply the need for N95 masks (“FFP2” in Europe), rather than surgical masks.

Negative pressure rooms are ideal, but may not always be available. When negative pressure rooms aren't available, portable air filtration systems may be considered ( SSC guidelines ).

Aerosol-generating procedures may generate an increasing number of aerosol particles (e.g. intubation, extubation, noninvasive ventilation, high-flow nasal cannula, CPR prior to intubation, bag-mask ventilation, bronchoscopy, and tracheostomy). However, patients with diagnosed COVID-19 should be under aerosol precautions regardless (e.g. ANZICS recommends airborne precautions be used for critically ill patients with COVID-19).

contact transmission (“fomite-to-face”)

This mode of transmission has a tendency to get overlooked, but it may be incredibly important. This is how it works: (i) Someone with coronavirus coughs, emitting large droplets containing the virus. Droplets settle on surfaces in the room, creating a thin film of coronavirus. The virus may be shed in nasal secretions as well, which could be transmitted to the environment. (ii) The virus persists on fomites in the environment. Depending on the type of surface, virus may persist for roughly four days (Doremalen et al. 3/17/19). (iii) Someone else touches the contaminated the surface hours or days later, transferring the virus to their hands. (iv) If the hands touch a mucous membrane (eyes, nose, or mouth), this may transmit the infection.

Any effort to limit spread of the virus must block contact transmission. The above chain of events can be disrupted in a variety of ways: (a) Regular cleaning of environmental surfaces (e.g. using 70% ethanol or 0.5% sodium hypochlorite solutions; for details see Kampf et al 2020 and CDC guidelines). (b) Hand hygiene (high concentration ethanol neutralizes the virus and is easy to perform, so this might be preferable if hands aren't visibly soiled)(Kampf 2017). (c) Avoidance of touching your face. This is nearly impossible, as we unconsciously touch our faces constantly. The main benefit of wearing a surgical mask could be that the mask acts as a physical barrier to prevent touching the mouth or nose.

Any medical equipment could become contaminated with COVID-19 and potentially transfer virus to providers. A recent study found widespread deposition of COVID-19 in one patient's room, but fortunately this seems to be removable by cleaning with sodium dichloroisocyanurate (Ong et al 2020). ANZICS guidelines recommend minimization of stethoscope usage.



when can transmission occur?

(#1) Asymptomatic transmission (in people with no or minimal symptoms) is possible (Carlos del Rio 2/28). This may be a major mechanism of disease transmission, which would aggravate any attempt to contain the spread of disease (e.g., by screening for fever or other symptoms)(Lavezzo et al.).

(#2) Transmission appears to occur over roughly ~8 days following the initiation of illness. Patients may continue to have positive pharyngeal PCR for weeks after convalescence (Lan 2/27). However, virus culture methods are unable to recover viable virus after ~8 days of clinical illness (Wolfel 2020). This implies that prolonged PCR positivity probably doesn't correlate with clinical virus transmission. However, all subjects in Wolfel et al. had mild illness, so it remains possible that prolonged transmission could occur in more severe cases. CDC guidance is vague on how long patients with known COVID-19 should be isolated. Local health departments should be contacted to provide guidance regarding this.



R⌀

R⌀ is the average number of people that an infected person transmits the virus to. If R⌀ is <1, the epidemic will burn out. If R⌀ = 1, then epidemic will continue at a steady pace. If R⌀ >1, the epidemic will increase exponentially.

Current estimates put R⌀ at ~2.5-2.9 (Peng PWH et al, 2/28). This is a bit higher than seasonal influenza.

R⌀ is a reflection of both the virus and also human behavior. Interventions such as social distancing and improved hygiene will decrease R⌀. Control of spread of COVID-19 in China proves that R⌀ is a modifiable number that can be reduced by effective public health interventions. The R⌀ on board the Diamond Princess cruise ship was 15 – illustrating that cramped quarters with inadequate hygiene will increase R⌀ (Rocklov 2/28).

R⌀ may vary between different people infected with COVID-19, depending on their immune response and viral load. For example: Some people carry extremely large quantities of virus, with a strong tendency to infect others (“super-spreaders”). If present at a large social gathering, this may lead to dozens of new infections. At the other extreme: Some people may carry low or undetectable amounts of virus, with little risk of disease transmission.



personal protective equipment (PPE) (back to contents)

gear

(1) Contact precautions (waterproof gown and gloves)

(2) N95 mask or a powered, air-purifying respirator (“PAPR”).

(3) Goggles or eye shield (goggles which seal onto the face may be ideal, especially for intubation).

(4) Hair cover, especially for aerosol generating procedures (listed in the section above).

(5) Hood may be used, especially during intubations.

Shoes Shoe covers aren't recommended, as removing them may increase exposure (ANZICS guidelines). Shoes that are easily cleaned and don't need to be touched might be preferable (e.g. Danskos).



applying and removing PPE (donning & doffing)

Understanding how to put on (don) and remove (doff) personal protective equipment is extremely important (especially if contact transmission is a dominant mode of transmission).

Removing soiled PPE is the most critical and difficult aspect.

Applying and removing PPE should ideally be practiced before patients arrive (e.g. using simulation).

This video describes how to use PPE (you may skip the first 5 minutes).

some pearls about personal protective equipment

Pay attention to the junction between gloves and gowns. The gown should be tucked into the gloves (leaving no gap in-between). Using gloves with extended cuffs facilitates this (similar to sterile surgical gloves). Gloves with long cuffs may facilitate removal of the gown and gloves as a single unit (see 12:30 in the above video if this doesn't make sense).

When removing PPE, always start by first applying alcohol-based hand sanitizer to your gloves.

After fully removing PPE, sanitize hands and wrists with alcohol-based hand sanitizer again.

Create a step-wise protocol for PPE removal. Two examples are shown below, but this may very depending on your exact gear. Follow the steps slowly. 👁 Checklist for removing PPE, using a tear-away gown here (this type of gown is preferred) 👁 Checklist for removing PPE, using a gown with fixed neck ties.

Consider doffing with someone watching you (to ensure good technique). If this isn't possible, doffing in a mirror may be helpful.

signs and symptoms (back to contents)

👁 Table of symptoms described by various studies.

signs & symptoms

typical disease course

Incubation is a median of ~4 days (interquartile range of 2-7 days), with a range up to 14 days (Carlos del Rio 2/28). Rare patients may have a longer incubation, however (graphed out nicely by Lauer et al).

is a median of ~4 days (interquartile range of 2-7 days), with a range up to 14 days (Carlos del Rio 2/28). Rare patients may have a longer incubation, however (graphed out nicely by Lauer et al). Typical evolution of severe disease (based on analysis of multiple studies by Arnold Forest). Dyspnea ~ 6 days post exposure. Admission after ~8 days post exposure. ICU admission/intubation after ~10 days post exposure. However, this timing may be variable (some patients are stable for several days after admission, but subsequently deteriorate rapidly).



👁 Table of general laboratory findings described in several studies.

complete blood count

WBC count tends to be normal.

Lymphopenia is common, seen in ~80% of patients (Guan et al 2/28, Yang et al 2/21). The optimal cutoff for defining lymphopenia is unclear; a cutoff of <1,500 b/L may increase sensitivity for diagnosis of COVID-19 (Goyal et al).

may increase sensitivity for diagnosis of COVID-19 (Goyal et al). Mild thrombocytopenia is common (but platelets are rarely <100). Lower platelet count is a poor prognostic sign (Ruan et al 3/3).

coagulation studies

Abnormal coagulation labs are frequently seen. Generally, the most notable finding is markedly elevated D-dimer levels.

For more see the hematology section below.

inflammatory markers

C-reactive protein (CRP) COVID-19 increases CRP. This seems to track with disease severity and prognosis. In a patient with severe respiratory failure and a normal CRP, consider non-COVID etiologies (such as heart failure). Young et al. 3/3 found low CRP levels in patients not requiring oxygen (mean 11 mg/L, interquartile range 1-20 mg/L) compared to patients who became hypoxemic (mean 66 mg/L, interquartile range 48-98 mg/L). Ruan et al 3/3 found CRP levels to track with mortality risk (surviving patients had a median CRP of ~40 mg/L with an interquartile range of ~10-60 mg/L, whereas patients who died had a median of 125 mg/L with an interquartile range of ~60-160 mg/L). 👁 Image of prognostic labs including CRP.

Procalcitonin Severe COVID-19 can moderately increase procalcitonin levels (e.g., within a range of roughly 1-10 ng/ml). For example, among patients with severe disease, 14% had a procalcitonin level >0.5 ng/ml (Guan et al 2/28). Among patients with known COVID-19, an elevated procalcitonin is a poor prognostic sign (likely reflecting of cytokine storm)(Lippi et al. 2020). A markedly elevated procalcitonin (>>10 ng/ml) might suggest the presence of a bacterial infection, rather than COVID-19.



evaluation for competing diagnoses

PCR for influenza and other respiratory viruses (e.g. RSV) may be helpful. Detection of other respiratory viruses doesn't prove that the patient isn't co-infected with COVID-19 ~5% of patients may be co-infected with both COVID-19 and another virus)(Wang et al.). However, the rate of viral co-infection is dynamic, depending on the prevalence of other viruses in the community. Recent studies from New York suggested a co-infection rate of only 1-2% (Goyal et al, Richardson et al).

Conventional viral panels available in some hospitals will test for “coronavirus.” This test does not work for COVID-19! This PCR test for “coronavirus” is designed to evaluate for four coronaviruses which usually cause mild illness. Ironically, a positive conventional test for “coronavirus” actually makes it less likely that the patient has COVID-19.

Blood cultures should be performed as per usual indications.

specific testing for COVID-19 (back to contents)

specimens

(1) Nasopharyngeal swab should be sent.

(2) If intubated, tracheal aspirate should be performed.

(3) Bronchoalveolar lavage or induced sputum are other options for a patient who isn't intubated. However, obtaining these specimens may pose substantial risk of transmission. It's dubious whether these tests are beneficial if done for the sole purpose of evaluating for coronavirus (see the section below on bronchoscopy).



limitations in determining the performance of RT-PCR

(1) RT-PCR performed on nasal swabs depends on obtaining a sufficiently deep specimen. Poor technique will cause the PCR assay to under-perform.

(2) COVID-19 isn't a binary disease, but rather there is a spectrum of illness. Sicker patients with higher viral burden may be more likely to have a positive assay. Likewise, sampling early in the disease course may reveal a lower sensitivity than sampling later on.

(3) Most current studies lack a “gold standard” for COVID-19 diagnosis. For example, in patients with positive CT scan and negative RT-PCR, it's murky whether these patients truly have COVID-19 (is this a false-positive CT scan, or a false-negative RT-PCR?). Convalescent serologies may help resolve this problem (although they may to have their own limitations as well).



specificity

Specificity seems to be high (although contamination can cause false-positive results).

sensitivity may not be terrific

Sensitivity compared to CT scans In a case series diagnosed on the basis of clinical criteria and CT scans, the sensitivity of RT-PCR was only ~70% (Kanne 2/28). Sensitivity varies depending on assumptions made about patients with conflicting data (e.g. between 66-80%)(Ai et al.). 👁 Image of analysis of Ai et al. to determine sensitivity & specificity of PCR here.

Among patients with suspected COVID-19 and a negative initial PCR, repeat PCR was positive in 15/64 patients (23%). This suggests a PCR sensitivity of <80%. Conversion from negative to positive PCR seemed to take a period of days, with CT scan often showing evidence of disease well before PCR positivity (Ai et al.).

Bottom line? PCR seems to have a sensitivity somewhere on the order of ~75%. A single negative RT-PCR doesn't exclude COVID-19 (especially if obtained from a nasopharyngeal source or if taken relatively early in the disease course). If the RT-PCR is negative but suspicion for COVID-19 remains, then ongoing isolation and re-sampling several days later should be considered.



CXR & CT scan (back to contents)

general description of imaging findings on chest x-ray and CT scan

The typical finding is patchy ground glass opacities, which tend to be predominantly peripheral and basal (Shi et al 2/24). The number of involved lung segments increases with more severe disease. Over time, patchy ground glass opacities may coalesce into more dense consolidation.

Infiltrates may be subtle on chest X-ray. 👁 Image of example chest X-ray here. 👁 Image of example CT scans here.

Findings which aren't commonly seen, and might argue for an alternative or superimposed diagnosis: Pleural effusion is uncommon (seen in only ~5%). COVID-19 doesn't appear to cause masses, cavitation, or lymphadenopathy.



sensitivity and time delay

Limitations in the data Data from different studies conflict to a certain extent. This probably reflects varying levels of exposure intensity and illness severity (cohorts with higher exposure intensity and disease severity will be more likely to have radiologic changes).

Sensitivity of CT scanning? Sensitivity among patients with positive RT-PCR is high. Exact numbers vary, likely reflecting variability in how scans are interpreted (there currently doesn't seem to be any precise definition of what constitutes a “positive” CT scan). Sensitivity of 86% (840/975) in Guan et al. Sensitivity of 97% (580/601) in Ai et al. Among patients with constitutional symptoms only (but not respiratory symptoms), CT scan may be less sensitive (e.g., perhaps ~50%)(Kanne 2/27).

CT scan abnormalities might emerge before symptoms? Shi et al. performed CT scanning in 15 healthcare workers who were exposed to COVID-19 before they became symptomatic. Ground glass opacification on CT scan was seen in 14/15 patients! 9/15 patients had peripheral lung involvement (some bilateral, some unilateral). Emergence of CT abnormality before symptoms explains the existence of an asymptomatic carrier state (discussed above).

Chest X-ray Sensitivity of chest X-ray is lower than CT scan for subtle opacities. In Guan et al., the sensitivity of chest x-ray was 59%, compared to 86% for CT scan. Among one patient series in New York City, 17% of patients with COVID-19 had clear admission chest radiographs (Goyal et al).



further information

technique

In order to achieve sensitivity, a thorough lung examination is needed (taking a “lawnmower” approach, attempting to visualize as much lung tissue as possible).

A linear probe may be preferable for obtaining high-resolution images of the pleural line (to make the distinction between a smooth, normal pleural line versus a thickened and irregular pleural line).

COVID-19 typically creates patchy abnormalities on CT scan. These will be missed unless ultrasonography is performed overlying the abnormal lung tissue.

More on this from 5 minute sono here.

findings

The findings on lung ultrasonography appear to correlate very well with the findings on chest CT scan.

With increasing disease severity, the following evolution may be seen (Peng 2020) (A) Least severe: Mild ground-glass opacity on CT scan correlates to scattered B-lines. (B) More confluent ground-glass opacity on CT scan correlates to coalescent B-lines (“waterfall sign”). (C) With more severe disease, small peripheral consolidations are seen on CT scan and ultrasound. (D) In the most severe form, the volume of consolidated lung increases. 👁 Image of these patterns here.

Other features: Peripheral lung abnormalities can cause disruption and thickening of the pleural line. Areas of normal lung (with an A-line pattern) can be seen early in disease, or during recovery. Tiny pleural effusions may be seen, but substantial pleural effusions are uncommon (Peng 2020). As with CT scans, abnormalities are most common in the posterior & inferior lungs.

For excellent examples of the correlation between CT scan and lung ultrasonography see Huang et al.

performance

Sensitivity of lung ultrasonography isn't clearly defined. Sensitivity will depend on several factors (most notably disease severity, presence of obesity, and thoroughness of scanning). My guess is that a thorough ultrasound exam might have a sensitivity somewhere between CT scanning and chest X-ray (e.g., perhaps sensitivity ~75%?)(Huang et al.). There isn't solid data yet, but it's probably reasonable to extrapolate from our experiences regarding other types of pneumonia.

Specificity is extremely low. A patchy B-line or consolidation pattern can be seen in any pneumonia or interstitial lung disease. Thus, clinical correlation is necessary (e.g., evaluation of prior chest imaging studies to see if chronic abnormalities are present). Note that supine, hospitalized patients may have B-lines and consolidation in a posterior and inferior distribution due to atelectasis. Thus, the lung ultrasonography may have greatest sensitivity and specificity among ambulatory patients.



general approach to imaging (back to contents)

all imaging modalities are nonspecific

All of the above techniques (CXR, CT, sonography) are nonspecific. Patchy ground-glass opacities may be caused by a broad range of disease processes (e.g. viral and bacterial pneumonias). For example, right now in the United States, someone with patchy ground-glass opacities on CT scan would be much more likely to have a garden variety viral pneumonia (e.g. influenza or RSV) rather than COVID-19.

Imaging cannot differentiate between COVID-19 and other forms of pneumonia.

Imaging could help differentiate between COVID-19 and non-pulmonary disorders (e.g. sinusitis, non-pulmonary viral illness).

Ultimately, the imaging is only one bit of information which must be integrated into clinical context.

possible approach to imaging in COVID-19

Below is one possible strategy to use for patients presenting with respiratory symptoms and possible COVID-19.

The temptation to get a CT scan in all of these patients should be resisted. In most cases, a CT scan will probably add little to chest X-ray and lung ultrasonography (in terms of actionable data which affects patient management).

From a critical care perspective, CT scanning will likely add little to the management of these patients (all of whom will have diffuse infiltrates).

👁 Schema for imaging patients with respiratory symptoms and suspected COVID-19.

additional information:

RSNA focus page on coronavirus (contains fantastic slide show that provides an appreciation of possible imaging findings in a few minutes)

Risks of bronchoscopy: May cause some deterioration in clinical condition (due to instillation of saline and sedation). Enormous risk of transmission to providers. Considerable resource allocation (requires N95 respirators, physicians, respiratory therapists) – all resources which will be in slim supply during an epidemic.

Benefits of bronchoscopy: Benefit of diagnosing COVID-19 is dubious at this point (given that treatment is primarily supportive).

Bottom line on bronchoscopy? Bronchoscopy might be considered in situations where it would otherwise be performed (e.g. patient with immunosuppression with concerns for Pneumocystis pneumonia or fungal pneumonia). Bronchoscopy should usually not be done for the purpose of ruling COVID-19 in or out (Bouadma et al.).



diagnostic approach for admitted patients (back to contents)

👁 Checklist of tests to consider when evaluating a patient with respiratory failure and suspected COVID-19

👁 One possible diagnostic flow chart for an ill patient admitted to hospital with suspected COVID-19.

This approach is based on the availability of a PCR assay for COVID with a reasonably short turn-around time. This currently isn't a reality in most locations in the United States. Hopefully it will be soon.

Requiring a negative influenza PCR before testing for COVID isn't desirable, because ~5% of patients may be co-infected ( Wang et al. ). Thus, a positive influenza PCR cannot exclude COVID. The rate of double-positivity may decrease over time, as the rate of influenza in the community decreases.

The largest challenge may be determining who needs to be ruled out for COVID (i.e., who needs to be entered into this algorithm in the first place). Currently there is no simple answer for this – clinical judgement is required. Ruling out too many patients will result in excessive consumption of masks in patients who don't have COVID. Additionally, placing patients under COVID precautions may impair their care (e.g., isolation may serve as a barrier to obtaining scans or to family visitation). Ruling out too few patients may result in nosocomial transmission of COVID.



approach to ED patients getting admitted to the hospital (back to contents)

diagnostic tests

Chest X-ray (useful to prognosticate patients and avoid missing non-COVID pathology – even in the era of POCUS).

Labs CBC with differential. Electrolytes, coagulation studies. COVID prognostication labs: C-reactive protein, Lactate dehydrogenase (LDH), D-dimer, Ferritin. Blood cultures x2. Swab for COVID & respiratory viruses.

Additional studies as clinically warranted (EKG, POCUS, etc.).

CT chest Generally not needed solely for purpose of diagnosing COVID (especially if there are characteristic abnormalities on CXR and POCUS). However: if the patient is going to the scanner for another reason (e.g. trauma, abdominal pain, etc) and you are concerned about COVID – then strongly consider adding a chest CT while the patient is in the scanner.



cardiovascular & Bp support

A fluid-conservative strategy is often advisable (for example, avoid reflexive use of 30 cc/kg fluid boluses).

For patients with a history of diarrhea and clinical evidence of hypovolemia, titrated fluid administration may be beneficial.

pulmonary

For patients with significant dyspnea or hypoxemia, try to stabilize with one of the following techniques: Awake proning +/- high-flow nasal cannula (note: proning may also work with a standard nasal cannula). CPAP (or BiPAP with high levels of end-expiratory pressure). This may be provided using a facial mask, or a helmet interface.

When in doubt, err on the side of avoiding intubation.

For patients with hypoxemia, start dexamethasone 6 mg daily (or an equivalent dose of another steroid).

(or an equivalent dose of another steroid). Treatment pathways are evolving rapidly – have a low threshold to consult with MICU to assess the patient and collaborate on plan (i.e. ward vs. ICU). Beware of “silent hypoxemia” – patients may be very hypoxemic but look good (without much dyspnea). The first sign of deterioration is often escalating oxygen requirement, rather than dyspnea.



renal

There is an enormous tendency for patients to develop acute kidney injury.

Aggressively avoid all nephrotoxins (especially NSAIDs and vancomycin). (Note: Contrast dye probably isn't nephrotoic. If you need to get a scan with contrast, then just get it with contrast.)

(especially NSAIDs and vancomycin).

infectious disease

For patients with infiltrates and possible bacterial pneumonia: usual treatment is azithromycin plus ceftriaxone.

Avoid vancomycin (if high index of suspicion for MRSA pneumonia consider linezolid or ceftaroline).

approach to inpatient management of non-intubated patient (back to contents)

daily examination: focus on

Do not use a stethescope (this is a fomite that poses risk of disease transmission).

(this is a fomite that poses risk of disease transmission). Cardiac and lung ultrasonography may be performed as indicated for changes in clinical status. Lung ultrasonography (not ascultation) is the preferred modality for evaluating pulmonary status.



labs

Daily labs Electrolytes, Creatinine, Magnesium, Phosphate CBC with differential D-dimer C-reactive protein

Admission labs: all of the above plus: Urine pregnancy test in reproductive-age women Blood culture x2 Tracheal aspirate for gram stain & culture Urine legionella & pneumococcal antigens Liver function tests Coagulation tests including INR, PTT, fibrinogen Ferritin, LDH



cardiovascular

Usually target a roughly even fluid balance for patients on the hospital ward (unless there are ongoing fluid losses such as diarrhea, or objective evidence of hypovolemia). Avoid fluid boluses (more on this here and here). Avoid maintenance fluid infusions (ANZICS guidelines).

Consider discontinuation of home antihypertensive agents (especially ACE-inhibitors or ARBs). The use of ACE inhibitors or ARBs among outpatients is controversial, but among ill inpatients these agents are potentially nephrotoxic and should be avoided.

pulmonary

Oxyg en supplementation (1) Start with low-flow nasal cannula (e.g. 1-6 liters/minute). (2) For dyspnea or worsening desaturation, consider early implementation of either HFNC (ideally with awake proning) or CPAP/BiPAP. The approach to respiratory support is discussed further below. Consult ICU early for deteriorating patients, as this can escalate rapidly.

Provide dexamethasone 6 mg daily for patients requiring oxygen (or an equivalent dose of steroid).

Avoid nebulized bronchodilators Only use bronchodilators if truly indicated. Instead of nebulizers, use a metered dose in haler (4-8 puffs may be roughly equivalent to one nebulizer treatment).



renal

⚠️ Avoid nephrotoxins (especially NSAIDs).

infectious diseases

Initially most patients will be on empiric antibiotics for bacterial pneumonia (e.g. azithromycin plus ceftriaxone).

Follow microbiologic studies.

heme

DVT prophylaxis (continue unless platelets <30, as COVID-19 may cause a pro-coagulable form of DIC despite low platelet count)(B&W guidelines).

For patients with marked D-dimer elevation, consider higher doses of enoxaparin (more on this below).

Conservative transfusion strategy (generally avoid transfusion unless HgB <7 mg/dL, or <8 mg/dL with active myocardial ischemia).

neurology

May use acetaminophen 1 gram enterally q6hr for antipyretic and analgesic effects.

Melatonin 5 mg QHS for sleep (Zhang et al 2020, Zhou et al. 2020).

⚠️ Avoid NSAIDs (may cause nephrotoxicity and possibly up-regulate the ACE2 receptor, thereby worsening infection)

approach to intubated ICU patient (back to contents)

daily examination: focus on

Ventilator Ventilator settings & synchrony with ventilator. Confirm ETT depth at the upper teeth (ensure no migration of the tube). Tighten connections between ETT, connecting tubing, and ventilator (to prevent accidental disconnection).

Neurologic status.

Cardiac and lung ultrasonography if clinical question.

Do not use a stethescope (this is a fomite that poses risk of disease transmission).

labs

Daily labs Electrolytes, Creatinine, Magnesium, Phosphate CBC with differential D-dimer C-reactive protein, Ferritin, LDH Possibly troponin (to surveil for development of myocarditis, not acute coronary syndrome)

Intermittent labs Triglycerides every 72 hours for patients on propofol (surveillance for propofol infusion syndrome). Liver function tests every other day. Thromboelastography (TEG) if questions arise about the overall balance of coagulation.

Admission labs : all of the above plus: Urine pregnancy test in reproductive-age women Blood culture x2 Tracheal aspirate for gram stain & culture Urine legionella & pneumococcal antigens) Complete set of coagulation labs (INR, PTT, fibrinogen, thromboelastography if available)

: all of the above plus:

cardiovascular

Initially, patients may be hypovolemic (e.g., due to diarrhea and poor oral intake). Titrated fluid resuscitation may be helpful initially, based on physical examination and history. It may be reasonable to allow patients to have a net positive fluid status over the first couple days in ICU.

After the first couple days in ICU, avoid fluid boluses (more on this here and here) & avoid maintenance fluid infusions (ANZICS guidelines). Follow fluid balance and target an even fluid status (or possibly diuresis for patients with evidence of volume overload).

Consider using low-dose vasopressor as necessary to support MAP (rather than fluid).

Consider discontinuation of home antihypertensive agents (especially ACE-inhibitors or ARBs). Sedation and positive-pressure ventilation will tend to reduce the blood pressure, so antihypertensive agents may be unnecessary.

pulmonary

Lung-protective ventilation APRV might be the preferred ventilator mode (a primary pathophysiological problem is atelectasis, which APRV manages well). Conventional low-tidal volume ventilation is also effective.

Steroid Start dexamethasone 6 mg daily or equivalent steroid dose.

⚠️ Avoid ABG/VBG if possible. Consider trending etCO2 and minute ventilation instead of obtaining serial ABG/VBG measurements. Oxygen saturation generally does appear to track with pO2 in these patients and can be used to titrate oxygen administration.



gastrointestinal

Enteral nutrition.

Stress ulcer prophylaxis.

renal

⚠️ Avoid nephrotoxins (especially NSAIDs).

infectious diseases

Initially most patients will be on empiric antibiotics for bacterial pneumonia (typically azithromycin plus ceftriaxone). Discontinue ceftriaxone within <48 hours if no evidence of bacterial infection. ⚠️ Avoid vancomycin. These patients don't tend to have MRSA, but they do often develop kidney injury. If MRSA coverage is truly necessary, consider linezolid or ceftaroline.

Follow microbiologic studies.

heme

DVT prophylaxis (continue unless platelets <30, as COVID-19 may cause a pro-coagulable form of DIC despite low platelet count)(B&W guidelines).

(continue unless platelets <30, as COVID-19 may cause a pro-coagulable form of DIC despite low platelet count)(B&W guidelines). Consider anticoagulation for DIC: Little evidence, but patients with D-dimer >1,000-2,000 ng/ml may benefit from therapeutic anticoagulation (e.g. therapeutic doses of low molecular-weight heparin)(see figure below & this section).

Conservative transfusion strategy (generally avoid transfusion unless HgB <7 mg/dL, or <8 mg/dL with active myocardial ischemia).

endocrine

Follow glucose levels periodically.

Insulin as needed to avoid severe hyperglycemia (consider allowing some permissive hyperglycemia, to reduce the need for frequent glucose checks).

neurology

Acetaminophen 1 gram enterally q6hr scheduled (for antipyretic and analgesic effects).

1 gram enterally q6hr scheduled (for antipyretic and analgesic effects). Opioid bolus PRN pain (e.g. fentanyl 50 mcg IV q30 min PRN breakthrough pain).

bolus PRN pain (e.g. fentanyl 50 mcg IV q30 min PRN breakthrough pain). Low-dose propofol as a titratable sedative (e.g. ideally around 0-30 mcg/kg/min). COVID-19 patients appear prone to developing hypertriglyceridemia (possibly due to systemic inflammation). Ideally keep propofol doses low, to avoid hypertriglyceridemia (which may necessitate stopping propofol entirely).

as a titratable sedative (e.g. ideally around 0-30 mcg/kg/min). Adjunctive atypical antipsychotic (e.g. 10-20 mg olanzapine per tube QHS, or quetiapine).

per tube QHS, or quetiapine). For ongoing pain, consider adding a pain-dose ketamine infusion (0.1-0.3 mg/kg/hr)(more on this here).

infusion (0.1-0.3 mg/kg/hr)(more on this here). Melatonin 5 mg QHS for sleep (Zhang et al 2020, Zhou et al. 2020).

5 mg QHS for sleep (Zhang et al 2020, Zhou et al. 2020). ⚠️ Avoid NSAIDs (may cause nephrotoxicity and possibly up-regulate the ACE2 receptor, thereby worsening infection).

(More on analgesia and sedation in this section below).

lines & tubes

(1) Orogastric tube or small-bore post-pyloric feeding tube.

(2) Central line Low threshold to place a quad-lumen central line with meticulous sterility. Best site may be left internal jugular vein (save the right internal jugular for dialysis or ECMO). Consider early transition to a PICC catheter for patients with an ongoing ICU stay.

(3) Arterial line Potentially useful for a patient in shock on multiple vasopressors. For non-shocked patients, utility of an arterial line is dubious. This may serve only to encourage frequent ABG/VBG draws (which are unlikely to materially improve care and will cause anemia).



stages of illness & timing of therapies (back to contents)

The above staging system was proposed by Siddiqi et al. Patient courses may vary, making discrete staging challenging. However, this provides a useful conceptualization of the disease process.

stage I (early infection)

Clinically : Incubation followed by non-specific symptoms (e.g. malaise, fever, dry cough). This phase may last for several days, with fairly mild symptoms. Patients often don't require hospital admission.

: Incubation followed by non-specific symptoms (e.g. malaise, fever, dry cough). This phase may last for several days, with fairly mild symptoms. Patients often don't require hospital admission. Biologically : Viral replication occurs. An innate immune response follows, but this fails to contain the virus. Symptoms reflect a combination of direct viral cytopathic effect and innate immune responses (e.g. Type-I interferon release).

: Viral replication occurs. An innate immune response follows, but this fails to contain the virus. Symptoms reflect a combination of direct viral cytopathic effect and innate immune responses (e.g. Type-I interferon release). Treatment : Anti-viral therapies could be beneficial, especially in patients predicted to be at higher risk for poor outcome. Anti-viral therapies probably have maximal efficacy when given early, during this phase. Interferon I-beta could theoretically be useful to augment the innate immune system response to the virus. This involves rendering cells resistant to viral infection, an intervention which would probably be most effective if deployed as early as possible (however this is a theoretical consideration, which currently is not recommended). Immunosuppression could theoretically be dangerous at this point, as it could delay the development of an adequate adaptive immune response. For example, early initiation of steroid has been shown to prolong virus shedding in SARS (Lee et al 2004).

:

stage II (pulmonary phase)

Clinically : Despite being stable for several days during Stage I, as patients enter Stage II they may abruptly deteriorate (often with worsening hypoxemic respiratory failure). Patients will often present to the hospital at this point. They may progress rapidly to ARDS, requiring intubation. Markers of systemic inflammation are often moderately elevated (e.g. C-reactive protein, ferritin).

: Despite being stable for several days during Stage I, as patients enter Stage II they may abruptly deteriorate (often with worsening hypoxemic respiratory failure). Patients will often present to the hospital at this point. They may progress rapidly to ARDS, requiring intubation. Markers of systemic inflammation are often moderately elevated (e.g. C-reactive protein, ferritin). Biologically: An adaptive immune response occurs, which causes a reduction in viral titers. However, this also leads to increased levels of inflammation and tissue damage.

An adaptive immune response occurs, which causes a reduction in viral titers. However, this also leads to increased levels of inflammation and tissue damage. Treatment : Antiviral-therapy could be beneficial (although the later on that antiviral treatment is initiated, the less effective it is likely to be). Some immunosuppression could be beneficial for patients with more severe manifestations (e.g., moderate dose steroid).

:

stage III (hyperinflammation phase / cytokine storm)

Clinically : Patients deteriorate with progressive disseminated intravascular coagulation and multi-organ failure (e.g. vasodilatory shock, myocarditis). Laboratory abnormalities include marked elevation of D-dimer, C-reactive protein, and ferritin. Patients may initially respond well to intubation and ventilation during stage II, but subsequently develop increasing levels of inflammation, which leads to clinical deterioration.

: Patients deteriorate with progressive disseminated intravascular coagulation and multi-organ failure (e.g. vasodilatory shock, myocarditis). Laboratory abnormalities include marked elevation of D-dimer, C-reactive protein, and ferritin. Patients may initially respond well to intubation and ventilation during stage II, but subsequently develop increasing levels of inflammation, which leads to clinical deterioration. Biologically : The adaptive immune response spirals into an immunopathological dysregulated cytokine storm (Mehta et al.).

: The adaptive immune response spirals into an immunopathological dysregulated cytokine storm (Mehta et al.). Treatment : All the treatments from Stage II may be continued (e.g. moderate-dose steroid and antiviral therapy). Depending on the level of inflammation, a higher dose of steroid could be considered.

:

steroid isn't indicated in early disease

Early administration of steroid may increase viral shedding (e.g. administration during the replicative phase)(Lee et al 2004)

Most patients recover well without severe sequelae – so obviously steroid cannot benefit such patients.

Steroid should not be used in patients with normal oxygenation.

steroid is indicated for patients with acute hypoxemic respiratory failure

The RECOVERY trial demonstrated a mortality benefit using dexamethasone 6 mg daily for up to 10 days among hospitalized patients requiring supplemental oxygen or mechanical ventilation.

Indications for steroid include the following: (1) Acute hypoxemic respiratory failure (true increase in oxygen requirement compared to baseline) (2) Requirement for mechanical ventilation (3) Another accepted indication for steroid (e.g. COVID plus asthma or COPD exacerbation)



dose and duration of steroid

Dose Dexamethasone 6 mg daily for up to 10 days was studied in the RECOVERY trial, so this is the most evidence-based dose. If dexamethasone isn't available, other equivalent doses of steroid may be utilized: Oral betamethasone 6 mg (overall most similar to dexamethasone) IV or oral methylprednisolone 32 mg Oral prednisone 40 mg or prednisolone 40 mg Higher doses of steroid (e.g. dexamethasone 10-20 mg daily or equivalent doses of methylprednisolone) could be considered in patients with ARDS (based on the DEXA-ARDS trial), especially in the face of elevated or rising inflammatory markers. Laboratory markers which could support a need for higher doses of steroid might include CRP >125 mg/dL, Ferritin >1,000 ng/mL, LDH > 300 U/L, and D-dimer > 1,000 ng/mL. If higher doses of steroid are used, the dose may be reduced to ~6 mg/day dexamethasone or equivalent as soon as improvement occurs (e.g. falling CRP).

Duration The RECOVERY trial protocol involved dexamethasone 6 mg/day for up to 10 days. However, the median duration of steroid utilization in that study was only 7 days. Therefore, if patients are making solid clinical improvement then it may be safe to discontinue dexamethasone prior to 10 days. Dexamethasone has a long biological half-life, so it will auto-taper and thereby prevent rebound inflammation. If using a shorter-acting steroid (e.g. prednisone or methylprednisolone) it could be reasonable to taper off over ~3 days to mimic the pharmacokinetics of dexamethasone.



background on antiviral therapy 🛑

For maximal benefit, antiviral therapy probably needs to be started very early after the initial develop of symptoms (i.e. during the viral response phase). Unfortunately, most patients present to the hospital with severe illness after about a week of clinical illness.

To date, evidence with numerous anti-viral therapies has proven to be dissapointing (listed below).

Overall, the use of antiviral therapy for critically ill patients with COVID-19 may be limited.

basics

Remdesivir is a nucleoside analogue developed in response to the 2015 Ebola outbreak. It didn't really work for Ebola, so further approval or testing wasn't pursued at that time.

Remdesivir is an investigational drug which is not currently FDA approved for any indication, including COVID-19. However, remdesivir has received an emergency use authorization (EUA) for COVID-19 (a lower bar than FDA approval).

safety & side effects

To date, published experience with remdesivir involves well under a thousand patients. As such, this is a very new drug which we don't fully understand. Little is known regarding side-effects. Over time, it's likely that additional side-effects will emerge.

Known side-effects at this point: Infusion-related reactions (may include hypotension, nausea/vomiting, diaphoresis). Elevated liver enzymes (AST, ALT, hyperbilirubinemia). Volunteers given remdesivir have reported phlebitis, constipation, headache, ecchymosis, nausea, and extremity pain (Jorgensen CJ et al).

Remdesivir may be contraindicated in renal insufficiency . To date, studies involving remdesivir in COVID-19 have excluded these patients due to concern that the intravenous vehicle sulfobutylether beta-cyclodextrin could accumulate – so the safety of remdesivir in this context is unknown.

. To date, studies involving remdesivir in COVID-19 have excluded these patients due to concern that the intravenous vehicle sulfobutylether beta-cyclodextrin could accumulate – so the safety of remdesivir in this context is unknown. Given that remdesivir is a nucleoside analogue it might be teratogenic. In the ACTT-1 trial, women of child-bearing age were required to use contraception for a month after exposure to remdesivir.

efficacy

Two RCTs are available regarding the use of remdesivir in COVID-19. Remdesivir appears to accelerate recovery by ~1-4 days.

There is currently no robust evidence that remdesivir improves mortality or affects long-term outcomes. The largest study (ACTT-1) showed a possible reduction in mortality after 14 days, but over time it appears that this mortality difference may dissipate.

dosing & monitoring

200 mg IV once, followed by 100 mg IV for four days for a five-day total course (the ACTT-1 trial used a ten-day course, but a more recent RCT suggested that a 5-day course is sufficient according to a preliminary press release).

Avoid in patients with glomerular filtration rate <30 ml/min.

Follow liver function tests

Consider avoiding pregnancy for one month after exposure (per ACTT-1 trial protocol).

additional information

thoughtful fluid resuscitation

Gentle fluid administration could be considered for patients with evidence of hypoperfusion and a history suggestive of total body hypovolemia (e.g. prolonged nausea/vomiting and diarrhea).

Aggressive fluid resuscitation (e.g. blind administration of 30 cc/kg fluid) should be avoided.

Patients rarely are shocked on admission (even among critically ill patients, admission blood pressure is generally normal and lactate elevations are mild-moderate)(Yang et al 2/21). Overall, the rate of reported “sepsis” is generally low (<5%). The virus doesn't seem to generally cause a septic shock picture (but of course, patients may always suffer from superimposed bacterial septic shock).

More discussion on fluid therapy for COVID-19 is here.

troponin elevation

Troponin elevation is common (especially high-sensitivity troponin). This is a strong predictor of mortality. Among non-survivors, troponin tends to increase steadily from day 4 of illness through day 22 (Zhou et al. 2020).

Potential causes of troponin elevation in COVID-19 patients may include: Myocardial injury (troponin elevation without symptoms/ EKG/echo findings of myocardial ischemia) Type-I MI (plaque rupture) – this is probably among the least common causes. Type-II MI (stress MI) Stress cardiomyopathy (a.k.a. Takotsubo cardiomyopathy) Viral cardiomyopathy

Investigation should focus on integration of EKG and echocardiographic findings as well as clinical context.

In most cases, specific therapies for acute coronary syndrome will not be indicated.

cardiomyopathy

Fulminant cardiomyopathy can occur. This may be a late feature, which can occur even after patients are recovering from respiratory failure.

Cardiogenic shock appears to be an important cause of death, contributing to ~7-33% of deaths (Ruan 3/3/20). However, this wasn't a prominent feature in the series of patients at Cornell in New York City (Goyal et al).

It's unclear whether this represents a viral cardiomyopathy (virus can be recovered from myocardial tissue), stress/Takotsubo cardiomyopathy, or cardiac dysfunction due to cytokine storm (i.e., a feature of virus-induced hemophagocytic lymphohistiocytosis).

Evaluation: EKG, echocardiography, and troponin levels to evaluate for acute coronary occlusion.

arrhythmia ??

Palpitations were reported in 7% of patients in one cohort (Liu 2020).

A large series reported arrhythmia in 17% of patients, but didn't specify further (Wang 2/7/30).

These studies lack control groups, so it's unclear to what extent COVID may be causing arrhythmias (or whether arrhythmias simply occur in sick patients).

shock

Rarely present upon admission, but can be a late finding among critically ill patients in ICU.

Potential causes: Cardiogenic shock (i.e. myocarditis) Secondary bacterial infection with septic shock Cytokine storm / hemophagocytic lymphohistiocytosis Pulmonary embolism Pulmonary hypertension due to excessive mean airway pressures (e.g. PEEP or APRV) Anaphylactic reaction to medication

Evaluation Complete septic workup (e.g. blood cultures, sputum culture, chest X-ray, examination of line sites) Bedside echocardiogram and physical examination Review of serial labs (hemophagocytic lymphohistiocytosis labs should be measured routinely).

Treatment Vasopressor support as guided by echocardiography and physical examination. Empiric antibiotic therapy if concern for septic shock. Corticosteroid therapy may be considered (although most patients will be on this allready). Inhaled pulmonary vasodilator could be considered for intubated patients with acute cor pulmonale.



additional information:

Zheng YY et al. COVID-19 and the cardiovascular system. Nature Reviews, 3/5/20.

The Coronavirus Conundrum, Hypertension Edition (NephJC blog, by Matthew Sparks and Swapnil Hiremath et al.)

Are patients with hypertension and diabetes mellitus at increased risk for COVID-19 infection? Fang et al, Lancet 3/11/20.

high flow nasal cannula (back to contents)

safety of HFNC

There is widespread concern that using HFNC could increase the risk of viral transmission. This doesn't appear to be evidence-based.

Guidelines say HFNC is safe. ANZICS guidelines on COVID-19 state the following: “High flow nasal oxygen (HFNO) therapy (in ICU): HFNO is a recommended therapy for hypoxia associated with COVID-19 disease, as long as staff are wearing optimal airborne PPE.” “The risk of airborne transmission to staff is low with well fitted newer HFNO systems when optimal PPE and other infection control precautions are being used. Negative pressure rooms are preferable for patients receiving HFNO therapy.” Surviving Sepsis Guidelines state: “For acute hypoxemic respiratory failure despite conventional oxygen therapy, we suggest using HFNC over conventional oxygen therapy (weak recommendation, low quality of evidence” WHO guidelines on COVID-19 state that “Recent publications suggest that newer HFNC and NIV systems with good interface fitting do not create widespread dispersion of exhaled air and therefore should be associated with low risk of airborne transmission.”

Reasons that HFNC might not increase viral transmission are: HFNC supplies gas at a rate of ~40-60 liters/minute, whereas a normal cough achieves flow rates of ~400 liters/minute (Mellies 2014). Therefore, it's doubtful that a patient on HFNC is more contagious than a patient on standard nasal cannula who is coughing. HFNC typically requires less maintenance than invasive mechanical ventilation. For example, a patient who is on HFNC watching television may be less likely to spread the virus compared to an intubated patient whose ventilator is alarming every 15 minutes, requiring active suctioning and multiple providers in the room. The intubation procedure places healthcare workers at enormous risk of acquiring the virus, so intubation with a goal of reducing transmission is probably counterproductive (see figure above from Tran 2012). 👁 Image of risk factors for nosocomial SARS transmission from Tran et al. here. Existing evidence does not support the concept that HFNC increases pathogen dispersal substantially (although the evidence is extremely sparse). This includes a small study of patients with bacterial pneumonia (Leung 2018) and an abstract regarding particulate dispersal by volunteers (Roberts 2015).



evidentiary basis for HFNC

HFNC is generally a rational front-line approach to noninvasive support in patients with ARDS (based partially on the FLORALI trial).

One case series from China suggested that HFNC was associated with higher rates of survival than either noninvasive or invasive ventilation (of course, this could reflect its use in less sick patients)(Yang et al, see table 2).

A management strategy for COVID-19 by a French group used HFNC preferentially, instead of BiPAP (Bouadma et al.).

(1) continuous positive airway pressure (CPAP) might be the best modality of noninvasive support

Atelectasis leading to hypoxemia seems to be a major problem among these patients. 👁 Image of progressive alveolar collapse.

CPAP could have major advantages here: CPAP can provide the greatest amount of mean airway pressure, and thus most effective recruitment. 👁 Image comparing mean airway pressure due to CPAP vs. BiPAP. CPAP doesn't augment tidal volumes, so this could facilitate more lung-protective ventilation.

Possible approach to CPAP therapy in COVID-19: Increase the CPAP pressure to 15-18 cm if tolerated. Titrate FiO2 against oxygen saturation. Falling FiO2 requirements indicate effective recruitment, whereas rising FiO2 requirements suggest CPAP failure. Monitor tidal volumes and minute ventilation 👁 Image illustrating how a noninvasive ventilator can be used as a monitor.

Further discussion of CPAP in COVID-19.

(2) role of BiPAP?

BiPAP could provide benefit beyond CPAP by providing some mechanical support for the work of breathing. However, this does carry a theoretical risk of possibly encouraging the patient to take excessively large breaths (thereby inducing lung damage).

The ideal BiPAP settings probably involve using a high level of end-expiratory pressure with a low driving pressure (e.g., 16 cm inspiratory pressure with 12 cm expiratory pressure). This will closely resemble CPAP, with a little added support.

BiPAP could be particularly useful in patients with combined syndromes (e.g. COPD plus COVID-19).

(3) helmet interface

A helmet interface may have several advantages: It could reduce environmental contamination (Cabrini 2020; Hui 2015). There is a decreased risk of aspiration if emesis occurs. In one RCT investigating ARDS, the helmet reduced intubation rates and possibly mortality (Patel 2016). The helmet can be set up without requiring a ventilator, thereby potentially sparing ventilators for other patients.

Helmets have previously not been used in the United States, but they have become available currently.

The low compliance of the helmet interface may make it difficult to synchronize with the patient when performing BiPAP. Thus, these devices might work a bit better with CPAP.

safety when using CPAP, BiPAP, or helmets

Viral filters are essential to create a closed system and limit transmission. A discussion of how to configure this is located here. This is possible with either a two-limb system involving a full featured mechanical ventilator, or a one-limb system involving a dedicated BiPAP machine (e.g. Respironics V60).

Improved mask seal may improve safety.

Helmet masks might theoretically have an advantage here.

awake prone positioning (back to contents)

basics

This involves a non-intubated patient who prones themselves by lying on their belly. For patients with difficult lying in a prone position, alternating between lying on different sides might also be beneficial.

Can be combined with simultaneous use of any other noninvasive support device (e.g. low-flow nasal cannula, high-flow nasal cannula, BiPAP, CPAP, or even helmet noninvasive ventilation).

Requires cooperative patient with intact mentation.

Could be useful especially in situations where access to invasive ventilation is limited.

physiology: why it works?

Same physiology as proning a patient who is intubated (proning is proning). For example: May improve secretion clearance. May recruit atelectatic lung tissue in the dependent lung basis (this seems to be a major issue in COVID-19 patients).

Proning intubated patients with COVID-19 is widely reported to be successful in improving oxygenation. It stands to reason that similar success could be obtained by proning a patient who isn't intubated.

Awake proning was recommended by Sun et al. as one technique which could be used to avoid intubation for patients with COVID-19 (Sun et al.).

nuts and bolts

Help patient lie on their belly in a prone position. For patients with difficulty maintaining this position, other positions may be used (e.g. rotating between lying on alternate sides and sitting bolt upright). The most important aspect might be to avoid spending considerable time in a supine position (which promotes atelectasis).

Make sure support devices are well secured to the patient (e.g. it could be helpful to use tegaderm to anchor a nasal cannula).

Encourage proning as much as is tolerated (ideally ~12-18 hours/day, but this may be difficult for some patients).

Follow oxygenation and FiO2 requirement. Ideally an improvement in oxygenation should be seen within a few hours. If no change in oxygenation is observed, ongoing pronation may have less merit.

additional information

overall schema for noninvasive support (back to contents)

general comments

Many “rules” are circulating regarding COVID-19 (e.g. you must never use HFNC or BiPAP). These don't appear to be evidence-based or guideline-supported.

Patients vary widely, so use common sense.

indications for intubation?

An “early intubation” strategy involving intubation of every patient who requires >6 liters nasal cannula will lead to unnecessary intubations and likely iatrogenic harm. Thus, efforts should be made to avoid intubation if possible (using HFNC, noninvasive support, and/or awake proning).

Patients who can avoid intubation have a substantially better prognosis than patients who are intubated. Although this obviously doesn't prove causality, it does suggest that intubation should be avoided whenever possible.

Ultimately, the decision to intubate is based on the clinical judgement of the bedside practitioner. Key factors to consider in this decision may include: (1) Oxygenation There is no well-defined oxygen saturation trigger for intubation. Inability to maintain saturation >80% may be considered an indication for intubation, but not necessarily an absolute one. (2) Respiratory distress & work of breathing It's important to differentiate between tachypnea versus respiratory distress. Tachypnea without increased work of breathing is less concerning. Increased work of breathing (e.g., accessory muscle use, sensation of air hunger, diaphoresis) is more worrisome. (3) Clinical trajectory A relatively stable or improving trajectory may favor ongoing observation. Ongoing decline over time may favor intubation.

Additional discussion of intubation timing Martin Tobin: Physiological principles to guide respiratory management in COVID-19



See the COVID-19 Airway Page by Scott Weingart for this.

invasive mechanical ventilation (back to contents)

pathophysiology: COVID & ARDS

(1) Patients with COVID who are intubated will generally meet the Berlin definition of ARDS ([#1] above). However, since this definition is extremely broad, meeting it doesn't have any specific clinical implication.

(2) A predominant problem seems to be atelectasis. COVID patients may respond favorably to positive airway pressure (e.g., higher levels of PEEP or APRV) with recruitment of lung tissue and improved oxygenation.

(3) Many COVID patients appear to have PseudoARDS ([#4] above) PseudoARDS refers to patients with severe hypoxemia who have improvements in the P/F ratio to higher than 150 following ~12 hours of optimization on the ventilator. PseudoARDS is clinically relevant because these patients are less likely to benefit from proning. Prone ventilation does appear to work well for patients with COVID, but it may increase requirements for sedation and paralytics (thereby potentially extending time on the ventilator). Thus, if basic ventilator optimization is capable of obtaining a P/F ratio >150, then proning may not be beneficial.

(4) Gattinoni's H/L model has been disproven and should not be used to guide ventilator management.

Further discussion: Different types of ARDS Evidence regarding compliance & PseudoARDS.



airway pressure release ventilation (APRV)

Early APRV could be very useful for these patients (i.e. used as the initial ventilator mode, rather than a salvage mode).

Benefits of APRV include: (1) A primary physiologic problem in COVID appears to be de-recruitment, which is well managed by APRV. A drop in FiO2 requirement to ~50% is often seen within 6-12 hours on APRV (full recruitment takes time). (2) APRV often allows for improvement in hypoxemia without paralysis and/or proning. This may avoid iatrogenic complications from these interventions (e.g. delirium, myopathy). (3) APRV is a more comfortable mode than conventional volume-cycled ventilation. This may allow us to render patients comfortable and awake on the ventilator more easily, while using fewer medications (an especially important challenge as we run out of many sedatives).

A practical guide to using APRV in COVID can be found here. APRV initiation can cause hemodynamic shifts, so pay careful attention to blood pressure during initiation.

True failure to respond to APRV within 12-24 hours (e.g. with PaO2/FiO2 <100-150) would be a strong argument to move towards prone ventilation (discussed here). However, when started early APRV may be more likely to succeed – thereby avoiding the need for proning.

The main limitation to APRV is that many centers aren't familiar with it or don't have ventilators which can provide APRV.

conventional low tidal-volume ventilation

This will likely be the most commonly used mode of ventilation, given a strong evidentiary basis as well as widespread experience.

Tidal volumes should be targeted to a lung-protective range (6 cc/kg ideal body weight, with some liberalization to 8 cc/kg if necessary). MDCalc can be used to calculate appropriate endotracheal tube depth & tidal volumes.

There is no consensus regarding exactly how to titrate PEEP. ARDSnet PEEP tables may represent a reasonable starting point. Titration to clinical effect may be useful if there is sufficient time and experience to do this. 👁 Image of ARDSnet low-PEEP & high-PEEP tables here. The concept of using unusually low levels of PEEP does not appear to be evidence-based and is not recommended for COVID. Low levels of PEEP may cause partial atelectasis of the lungs, leading to atelectotrauma (repeated opening and closing of the alveoli with each respiratory cycle). Substantial atelectotrauma may be even more dangerous than barotrauma.



permissive hypercapnia & optimization of metabolic acid/base status

Regardless of the ventilator mode, permissive hypercapnia may be useful. The safe extent of permissive hypercapnia is unknown, but as long as hemodynamics are adequate, a pH above roughly ~7.15 may be tolerable (hypercapnia is preferred over lung-injurious ventilation).

A common error is to focus solely on respiratory parameters in order to improve the pH, while ignoring metabolic acid/base status. For example: ICU patients often have non-anion-gap metabolic acidosis (NAGMA). Treatment of NAGMA with bicarbonate may be the safest way to address a low pH (rather than increasing the intensity of mechanical ventilation and thereby threatening the lung). Even if the metabolic acid/base status is normal, IV bicarbonate may still be considered to improve pH, while simultaneously continuing lung-protective ventilation (discussed here). Targeting a mildly elevated serum bicarbonate can facilitate safe ventilation with low tidal volumes (more on different forms of IV bicarbonate here).



proning

Prior to consideration of proning, optimization on the ventilator for 12-24 is generally preferable (discussed here).

For failure to respond to initial ventilator optimization (e.g. with persistent PaO2/FiO2 below 150 mm), prone ventilation should be considered.

Proning is effective at increasing oxygenation, but it has the drawback of requiring deeper levels of sedation. Paralysis may be needed, but many patients can tolerate proning without paralysis (simply with deep sedation). Increasing levels of sedation (with or without paralysis) may increase the risk of delirium and myopathy, potentially prolonging the length of ventilation.

inhaled pulmonary vasodilators

Inhaled pulmonary vasodilators offer potential efficacy with few drawbacks: i) Improved ventilation/perfusion matching may improve oxygenation. ii) Pulmonary vasodilation may off-load the right ventricle, avoiding cor pulmonale. iii) Inhaled vasodilators generally have little effect on systemic hemodynamics (thereby avoiding systemic hypotension).

Potential indications: (1) Refractory hypoxemia (2) Hemodynamic instability with evidence of cor pulmonale (e.g. right ventricular dilation on echocardiography)



additional information:

Mechanical ventilation and coronavirus pneumonia (Giuseppe Natalini, ventilab blog, Google translation from Italian)

disaster ventilation strategies (back to contents)

[1] splitting ventilators

In a dire emergency, one ventilator can be used to support several patients.

Pressure-cycled ventilation should be used, with a driving pressure <13-15 cm (Aoyama et al. 2018).

Blog exploring the general strategy to setting the ventilators here.

Columbia Presbyterian protocol for splitting ventilators here.

Some additional ideas about how to hook everything up here.

[2] outpatient-design BiPAP machines for intubated patients?

It could be concievable to connect outpatient BiPAP machines to endotracheal tubes.

FiO2 might be limited (bleeding in wall oxygen might only achieve a limited FiO2, maybe around 50-60%) ???

This would require the patient to spontaneously trigger breaths, so light sedation would be needed.

Compared to the split ventilator technique (above), BiPAP devices could be used with less ill patients: Splitting the ventilator requires deep sedation and provides full ventilator support – this is better for the sickest patients. BiPAP machines require light sedation and provides partial support – this could be used for less ill patients. Home-design BiPAP masks are often unable to generate high flow rates, so they won't be able to support patients who are dyspneic with high flow demands.

On a related note, Trilogy devices could probably easily be repurposed to be used as ventilators.

[3] oxylator resuscitator

Small automated device which can provide pressure-cycled ventilation.

Relatively inexpensive and there still seems to be a reasonable supply available.

Allows for delivering titratable levels of PEEP.

More information: How to use the oxylator resuscitator with PEEP valve and HEPA filters here. EMCrit page on the oxylator here.



[4] votran automatic resuscitator

These are small plastic devices which can provide pressure cycled ventilation (more here). In some ways, they may be conceptualized as a simplified and primitive version of an oxylator resuscitator. They are designed for field use in a disaster.

Unlike the oxylator resuscitator, this device doesn't allow for the addition of higher levels of PEEP (PEEP is fixed at a relatively low level, around ~5-8 cm). i) This renders it unsuitable for use in patients with ARDS. ii) In a dire emergency, the votran automatic resuscitator might be used in less ill patients (e.g. a patient with trauma or drug intoxication), thereby freeing up other ventilators to be used on sicker COVID patients.



overall strategy for ventilator shortage

There is no one-size-fits all solution. Different strategies may work for different types of patients. Any way that we can free up ventilators is beneficial.

For example: Splitting ventilators: Could be used for extremely ill patients (intubated, on deep sedation). BiPAP machines attached to endotracheal tubes: Could be used for patients who are close to weaning off ventilation. Votran automatic resuscitator: Might be used for patients intubated for non-pulmonary reasons (patients with normal lungs).



potential pitfalls

Patients with COVID-19 often respond well to intubation and positive pressure ventilation (probably reflecting lung recruitment). Unfortunately, they may continue to have a tendency to de-recruit their lungs. Consequently, there may be an increased risk of deterioration after extubation.

Overall it seems that patients with COVID-19 can be weaned off ventilation similarly to other patients, with the exception that post-extubation BiPAP might be a stronger consideration.

post-extubation support

ANZICS guidelines state that HFNC and/or noninvasive ventilation (with a well fitted facemask and separate inspiratory and expiratory limbs) can be considered as bridging therapy post-extubation, but must be provided with strict airborne PPE. CPAP therapy or BiPAP (with high end-expiratory pressure) might be useful to prevent de-recruitment in these patients. (More on COVID-19 & CPAP here). By the time of extubation, patients will often have been ill for well over a week. It's likely that their viral load will be decreasing at that point, so the risk of virus transmission may be lower (compared to the initial intubation). More on transmission above.



transaminase elevation

COVID can cause mild elevation of transaminases (e.g. in 200's). However, fulminant hepatitis or liver failure hasn't been reported (B&W guidelines).

Potential mechanisms of liver injury include (B&W guidelines) Direct viral infection Drug hepatotoxicity Shock liver Cytokine storm / hemophagocytic lymphohistiocytosis (this might be associated more closely with bilirubin elevation)

Many medications used in these patients may also elevate transaminases, so liver function test abnormality mandates medication review.

epidemiology & timing

Renal failure requiring dialysis is reported in a subset of patients admitted to ICU (probably ~5%).

It tends to be a late finding, occurring 1-2 weeks after admission.

pathology & pathogenesis

Acute tubular necrosis due to generalized multi-organ failure is probably the predominant mechanism.

Complement deposition in the tubules was observed in six patients within an autopsy study, raising the question of whether this may be a contributory mechanism (Diao B et al.).

Virus can bind to proximal tubular epithelial cells (which express the ACE2 receptor), so direct viral infection is possible.

treatment is supportive

Avoid nephrotoxins.

Re-dose renally cleared medications.

Hemodialysis indications seem to be the same as for other patients. The prognosis of patients requiring dialysis appears poor. COVID-19: one study found a mortality of 10/10 patients in a recent study on COVID-19 (Zhou et al). SARS: Renal failure correlated with poor prognosis (92% mortality with renal failure versus 9% without). In multivariable analysis, renal failure was the strongest predictor of mortality (more-so even than ARDS)(Chu et al. 2005). Goals of care should be explored prior to proceeding to hemodialysis. Avoid giving excess fluid, as this may necessitate dialysis to remove fluid. COVID-19 patients may be hyper-coagulable, so heparin or citrate anticoagulation anticoagulation may be important to maintain a CRRT circuit.



further information

initial empiric antibiotics

Initially, there may be concerns regarding the possibility of a superimposed bacterial pneumonia. When in doubt, it may be sensible to obtain bacterial cultures, prior to initiation of empiric antibiotic therapy. Based on culture results, antibiotics might be discontinued in <48 hours if there isn't evidence of a bacterial infection (this is exactly the same as management of influenza pneumonia).

Azithromycin may possibly have beneficial anti-viral properties and/or immunomodulatory properties. This will generally be initiated initially, for coverage of possible bacterial pneumonia.

may possibly have beneficial anti-viral properties and/or immunomodulatory properties. MRSA coverage? COVID doesn't seem to increase the risk of MRSA (unlike influenza). This based on anecdotal reports, with a very low level of evidence. MRSA therapy could be instituted based on typical indications for a patient with community-acquired pneumonia (further discussion here and here). Excessive use of vancomycin should be discouraged, as patients are at substantial risk of developing renal failure. 👁 Algorithm for who needs MRSA coverage in context of community-acquired pneumonia.



delayed bacterial superinfection

Bacterial pneumonia can emerge during the hospital course (especially ventilator-associated pneumonia in patients who are intubated). Among patients who died from COVID-19, one series found that 11/68 (16%) had secondary infections (Ruan 3/3/20).

This may be investigated and treated similarly to other ventilator-associated pneumonias, or hospital-acquired pneumonias.

disseminated intravascular coagulation (back to contents)

pathophysiology

COVID produces a form of disseminated intravascular coagulation (DIC) which is usually marked by hypercoagulability.

The exact causes of this are unclear and likely numerous. They could include the following: (1) Inflammation (e.g. IL-6) stimulates up-regulation of fibrinogen synthesis by the liver (Carty 2010). (2) Virus directly binds endothelial cells.

There is likely a bi-directional, synergistic relationship between DIC and cytokine storm (wherein each exacerbates the other).

DIC appears to be a driver of disease severity. As might be expected, it is a strong prognostic factor for poor outcome (Tang et al. 2020). Microthrombi have been reported as autopsy findings in patients with COVID-19 (Luo et al.)



hematologic abnormalities seen in COVID-19

D-dimer : Dramatic elevations in D-dimer are the hallmark laboratory abnormality of COVID-DIC (figure above). Patients with D-dimer >1,000 at admission are twenty times more likely to die than patients with lower D-dimer values (Zhou et al.).

: Fibrinogen : In clinical practice, fibrinogen is generally elevated or normal. However, in extremely severe and late-stage disease, consumption of fibrinogen may occur leading to hypofibrinogenemia (Han et al. 2020).

: Thrombocytopenia can occur, but this is less common than in other forms of DIC.

can occur, but this is less common than in other forms of DIC. PT and INR is often slightly elevated

is often slightly elevated aPTT (activated partial thromboplastin time) may be reduced slightly.

(activated partial thromboplastin time) may be reduced slightly. Thromboelastography (TEG) (Panigada et al.) Reduced R-time indicating enzymatic hypercoagulability in 50% of patients (but it may rarely be increased in some patients). Increased maximal amplitude (MA) indicating excess platelet/fibrinogen function in 83% of patients. Reduced Lys-30 is extremely common.

(Panigada et al.) Antithrombin levels may be slightly diminished.

may be slightly diminished. Factor VIII and von Willebrand factor are considerably increased.

are considerably increased. Figures 👁 Image of DIC labs in survivors versus non-survivors over time. 👁 Image of D-dimer, ferritin, LDH, and Lymphocyte trends over time in survivors & non-survivors. 👁 Image of WBC, lymphocytes, and D-dimer over time in survivors vs. non-survivors.



ISTH diagnostic scoring system for DIC

Various scoring systems for DIC exist, this seems to be the most widely accepted. Note that DIC can exist without abnormal fibrinogen (Levi et al. 2009).

In one patient series, 71% of COVID patients who died met ISTH criteria for DIC, whereas only 0.6% of survivors did (Tang et al. 4/18).

evaluation for clinical thrombosis

Bedside ultrasonography to evaluate for deep vein thrombosis may be considered, especially if there are other clinical features of DVT/PE.

CT pulmonary angiography May be useful in select patients. Logistically, large-volume CT scanning of patients with COVID is often impossible (e.g. risk of disease transmission and inability to transport unstable patients to the scanner).



DVT prophylaxis

DVT prophylaxis should generally be maintained – unless platelets are below 25 (ISTH guidelines 3/25).

DVT prophylaxis alone will very frequently fail in patients with COVID-19. Klok et al found that despite DVT prophylaxis, about 27% of patients had venous thromboembolic events and 4% had arterial thromboembolic events (which is likely an underestimate, due to lack of systematic screening for these events and truncated observation periods for some patients). Consequently, these authors suggested doubling the typical dose of prophylactic heparin (e.g. enoxaparin 40 mg twice daily, rather than once daily). Spiezia L et al. reported that despite DVT prophylaxis, 5/22 (23%) of patients were noted to develop deep vein thrombosis (a figure which likely underestimates the true burden of venous thromboembolic disease).

Higher doses of prophylactic heparin may be considered in patients with moderately elevated D-dimer (e.g. ~500-1,500 ng/ml). For example: GFR > 30 ml/min: Enoxaparin 0.5 mg/kg BID. Check an Xa level four hours after the third dose, targeting a level of ~0.5-0.8 IU/ml. GFR < 30 ml/min: Unfractionated heparin ~7,500 units q8hr (consider adjusting dose for patients with atypical weight).



empiric heparin anticoagulation?

Therapeutic anticoagulation with heparin has been suggested for patients with D-dimer over 2,000 ng/ml, but this remains unproven (Lin et al., Tang et al. 3/27).

Most patients with COVID seem to be extremely hypercoagulable. This would support a potential role for heparin anticoagulation, and also bolster the safety of heparin administration (some patients appear heparin-resistant – again suggesting that heparin is probably fairly safe here).

Very late-stage, profound disease may be marked by low fibrinogen levels, which could theoretically produce a hemorrhagic phenotype. Anticoagulation could theoretically be harmful in that situation.

One possible approach to anticoagulation in COVID-19 is shown below. This is not supported by any high-level evidence. Anticoagulation decisions should ideally be individualized, so this is merely intended as one schema for approaching these patients.

In addition to prevention of thrombosis, heparin could reduce cytokine levels, thereby improving cytokine storm (Shi et al. 4/7). Further discussion of multiple possible benefits of heparin in COVID-19 in this article by Thachil.

thrombolysis (tissue plasminogen activator, i.e. tPA) ???

This could be considered for a patient who was peri-arrest with a high suspicion for pulmonary embolism.

RCTs may be warranted to evaluate this further (for discussion see Moore et al. 3/20).

purpura fulminans

Extreme, pro-thrombotic form of DIC causing widespread subcutaneous purpura which may progress to ischemic necrosis of the fingers and toes.

This can occur in COVID-19. Diagnosis is clinical based on characteristic appearance of the extremities as well as laboratory derangements (e.g. marked elevation of D-dimer). 👁 Example here from Lin et al.

Treatment of purpura fulminans is challenging: Heparin anticoagulation is generally recommended. However, antithrombin-3 deficiency is common, so these patients are often heparin resistant. Achieving a therapeutic heparin level may require large doses of heparin, or even supplementation of anti-thrombin levels. Topical nitroglycerine and possibly intravenous epoprostanol might be used to cause cutaneous vasodilation and avoid digit loss. More on purpura fulminans here.



additional information

Comments & discussion page on COVID-DIC here.

IBCC chapter on DIC here.

glycemic control & diabetes (back to contents)

Background ACE2 receptor is present in the islets of langerhans within pancreas, raising the possibility that virus could directly affect the endocrine pancreas (Yang et al. 2010). SARS has been shown to induce a transient state of insulin resistance. Currently there isn't any evidence available regarding COVID-19.

Possible predictions regarding COVID-19?? ( Currently these are guesses ). (1) Patients with Type-I diabetes and COVID-19 might present with diabetic ketoacidosis (rather than with typical pulmonary symptoms). (2) Patients without diabetes may develop hyperglycemia in the ICU which requires more aggressive management than the average patient.

).

analgosedation for the intubated patient (back to contents)

why optimal analgosedation is essential

Achieving a patient who is mentating normally and is comfortable on the ventilator is enormously beneficial, for numerous reasons: (1) This may reduce the respiratory rate and thereby promote lung-protective ventilation. (2) An awake and cooperative patient is vastly easier to extubate. (3) Avoidance of delirium may improve long-term neurocognitive function? (4) It's just a nice thing to do for the patient.



unique challenges faced in COVID patients

(1) Patients often remain on the ventilator for relatively long periods of time (e.g. >7-14 days). Prolonged use of some medications may cause dependence and even withdrawal (e.g. opioids or dexmedetomidine).

(2) Patients seem to develop hyperlipidemia rapidly if exposed to higher doses of propofol (possibly related to a component of hemophagocytic lymphohistiocytosis).

(3) Medication shortages are beginning to emerge (especially intravenous medications). This may necessitate a transition to oral agents (which seem to be in better supply).

construction of a multi-modal analgosedative regimen

The key concept here is using relatively low doses of multiple different medications to function in a synergistic fashion.

Using relatively low doses of each individual medication optimizes the efficacy/toxicity ratio of that medication.

One example of an analgosedative ladder for COVID is shown below; For ongoing pain, analgesics are added on sequentially. For ongoing anxiety, sedatives are added on sequentially.

A useful combination may be: melatonin, olanzapine, propofol, acetaminophen, ketamine, and PRN opioid. A surprising number of patients can be rendered awake and comfortable on the ventilator with this combination (especially when using a comfortable ventilator mode, such as APRV).

analgesic #1: scheduled acetaminophen

Acetaminophen should be scheduled at a dose of 1 gram q6hr. In cirrhosis or severe alcoholism, the dose may be cut in half (500 mg q6hr).

Acetaminophen provides mild analgesia as well as antipyresis (both effects with a goal of improving patient comfort).

analgesic #2: pain-dose ketamine infusion

A low-dose ketamine infusion has numerous potential benefits: (1) Provides mild analgesia (reducing the amount of opioid required). (2) Ketamine attenuates the development of opioid tolerance and opioid-induced hyperalgesia, thereby blunting opioid side-effects. (Barr 2013, Angst 2003). (3) Ketamine exerts anti-depressant effects which may improve patient mood, even at low doses (Rasmussen 2013, Zarate 2006). (4) Ketamine might weakly inhibit IL-6 (deep dive on this by Adam Thomas et al. here). This isn't a real reason to use ketamine, but perhaps a fringe benefit.

The usual dose is 0.1-0.3 mg/kg/hr. At the higher end of this range, mild psychotomimetic effects may be seen. These effects are often beneficial (e.g. mild sedative effect), but occasional patients will have disturbing hallucinations. Empirical dose-titration can generally find a sweet spot where there is analgesia, but no problematic psychotomimetic side-effects. When in doubt, it's safer to stay closer to the 0.1 – 0.15 mg/kg dose range.



analgesic #3-4: opioids

PRN boluses of opioid are generally preferable: Since bolus doses given only when necessary, this limits the total dose of opioid. Thus, it's probably preferable to use large PRN boluses, compared to a continuous infusion.

Opioid infusions are prone to numerous problems: They tend to run longer and at higher doses than necessary, thereby increasing toxicity. Fentanyl tends to accumulate in fat tissue over time, which can be extremely problematic. Fentanyl infusions expose patients to massive cumulative doses of opioid (e.g. 50 mcg/hr fentanyl for a day is equivalent to ~240 mg oxycodone). If opioid infusions are used, a daily interruption or dose-reduction should be performed (to verify that the dose of opioid being used is indeed necessary). For patients on an opioid infusion, always ensure that a substantial amount of opioid (e.g. ~25-50%) is being given in the form of PRN boluses. If a patient is on a continuous infusion and receiving no PRN boluses, that implies that the infusion rate is unnecessarily high.



sedative #1: melatonin

Effects: (1) This may help maintain day-night circadian rhythm, thereby providing very weak sedative activity at night (Mistraletti et al. 2015). (2) Some evidence suggests that melatonin may prevent delirium, although this is controversial. (3) Melatonin could theoretically have some anti-viral effects (Zhang et al 2020, Zhou et al. 2020).

The usual dose is 5 mg QHS.

sedative #2: atypical antipsychotics with sedative-predominant properties (olanzapine, quetiapine)

Rationale: (1) These may promote a hemodynamically stable sedative regimen (by reducing the dose of propofol required). (2) Antipsychotics provide sedation without promoting delirium (“non-deleriogenic sedatives”). (3) Timed administration may promote sleep.

Olanzapine The major advantage of olanzapine is that it doesn't prolong QT or cause Torsades de Pointes. The most logical dosing schedule might be 5-20 mg QHS. The drawback of olanzapine is that it has a relatively low maximum dose (20 mg), which may limit its potency.

Quetiapine The major advantage of quetiapine may be a higher maximum dose (800 mg/day). At these doses, it may be a bit more powerful than olanzapine. The drawback of quetiapine is that it does increase the QT interval. Quetiapine has a shorter half-life than olanzapine, so it should be dosed twice daily (for use as a maintenance sedative). A higher dose may be given at night to promote sleep (e.g. 50 mg in the morning and 100 mg before sleep).



sedative #3: propofol or dexmedetomidine infusion

Dexmedetomidine Generally not ideal in COVID patients, due to the long duration of sedation necessary (patients will become dependent on dexmedetomidine and subsequently withdraw from it).

Propofol infusion is generally preferable here. COVID patients appear prone to developing hypertriglyceridemia due to propofol (possibly because of underlying hemophagocytosis). This is problematic, because severe hypertriglyceridemia may necessitate completely stopping propofol. Using low doses of propofol (e.g. 5-30 mcg/kg/min) may avoid the development of hypertriglyceridemia.



sedative #4: PRN IV haloperidol

IV haloperidol could be useful for patients with agitated delirium.

Haloperidol may increase the QT interval, so caution is required.

sedative #5: phenobarbital

Phenobarbital is particularly effective in patients with a history of alcoholism. However, as we encounter shortages of other sedatives, low-dose phenobarbital as an adjunctive, general-purpose sedative may become increasingly useful (Gagnon et al. 2017). Due to balanced effects on the glutamate and GABA systems, phenobarbital may be less deleriogenic than benzodiazepines.

Typical dosing regimen: Loading dose: 5-10 mg/kg once. Maintenance dose: 1-2 mg/kg q8-q12 hr. For patients on ongoing maintenance therapy, check levels occasionally (targeting a level of ~5-20 mg/L). Phenobarbital may also be given enterally with 100% bioavailability and fairly rapid absorption.



sedative #6: benzodiazepines

Benzodiazepines are generally an agent of last resort in the ICU, due to their tendency to cause delirium.

Sometimes PRN benzodiazepines are necessary. In this situation, the dose of benzodiazepine should be minimized. Simultaneous efforts should be made to augment other sedatives and analgesics, with a goal of minimizing benzodiazepine exposure.

other neurologic problems (back to contents)

overview

Patients with COVID-19 are at risk for a variety of neurological problems, especially if critically ill. It will be difficult sorting out common complications of critical illness versus unique features of COVID-19 (Aaroe et al. 4/16). Common complications of critical illness Delirium Critical illness myopathy and neuropathy (especially among patients receiving extended paralysis) Cerebrovascular disease More unique complications related specifically to COVID-19 Guillain-Barre Syndrome Acute Disseminated Encephalomyelitis (ADEM) Acute necrotizing encephalopathy Direct viral encephalitis



Guillain-Barre Syndrome (GBS)

Data is currently limited to a five-patient case series (Toscano et al. 4/17).

This seems to begin ~5-10 days after the initiation of clinical illness (coincident with development of adaptive immunity).

Weakness is the predominant clinical finding (most often ascending paralysis). Dysautonomia doesn't seem to be a prominent issue.

Guillain-Barre Syndrome may tend to blend in with critical illness neuropathy & myopathy, which may be more frequent (especially among intubated patients).

The diagnosis may be supported by neuroimaging (excluding other lesions) and bedside electrophysiologic studies.

Intravenous immune globulin (IVIG) is generally the front-line therapy for Guillain-Barre Syndrome (with equal efficacy compared to plasmapheresis and superior tolerability).

More on GBS in the IBCC chapter on this here.

Acute Disseminated Encephalomyelitis (ADEM)

This has been reported only in a single patient with COVID-19, so its incidence remains unclear (Zhang et al.).

Acute Disseminated Encephalomyelitis is often seen after viral illnesses. It causes multifocal demyelinating lesions scattered throughout the white matter within the brain, spinal cord, and optic nerves.

A variety of symptoms may occur, depending on the location of the lesions (e.g., confusion, coma, seizure, weakness, sensory abnormality).

The diagnosis is based largely on neuroimaging (with multiple lesions present, resembling those of multiple sclerosis).

This may be treated with steroid.

Acute necrotizing encephalopathy

This is a rare disorder caused by various viral infections. It has been reported in only a single patient with COVID-19, so its incidence in this situation remains unclear (Poyiadji et al.).

The pathogenesis seems to involve a systemic cytokine storm, which damages the blood-brain barrier (Wu et al. 2015).

Clinical features may include confusion, seizure, or focal neurologic deficits.

Radiographically this causes multi-focal, symmetric lesions on CT scan and MRI involving the thalami, brainstem, cerebral white matter, and cerebellum (with involvement of the bilateral thalami being the most consistent finding). At various stages, there may be edema, petechial hemorrhages, or eventually necrosis.

There is no established therapy. Steroids have been utilized with mixed results.

Cerebrovascular disease

Overview: Ischemic stroke can occur to any cohort of patients under physiologic stress. However, it seems that COVID-19 causes an unusually large number of ischemic strokes (including in patients with otherwise mild disease manifestations). This is likely a manifestation of hypercoagulability due to COVID-19.

A report of 221 patients with COVID-19 detected acute ischemic stroke in 11/221 patients (5%), cerebral venous sinus thrombosis in one patient (0.5%), and intracranial hemorrhage in one patient (0.5%)(Li et al 3/13). Notably, 12/13 patients with cerebrovascular complications from COVID-19 had extremely high levels of D-dimer (with an average level of 6,900 ug/L).

Oxley et al. reported a series of five patients <50 YO with COVID-19 who presented to medical care due to symptoms of large-vessel occlusive stroke. Aside from stroke, these patients had either none or mild symptoms from COVID-19. Three of the patients had D-dimer levels over 1,500 ng/mL, suggesting that COVID-19 is capable of inducing a hypercoagulable state even in the absence of severe hypoxemic respiratory failure.

Viral encephalitis

COVID-19 can invade the brain and directly cause a viral encephalitis. Fortunately this seems to be rare. To date, only one case of encephalitis is reported (Moriguchi et al).

Patients with COVID-19 can be relatively young and suffering from single-organ failure due to a reversible etiology, so many would be excellent candidates for ECMO. VV ECMO could be used for respiratory failure (although it's unclear how common true refractory hypoxemia is). VA ECMO could be useful in patients with fulminant cardiomyopathy and cardiogenic shock

Exact indications and timing are unclear.

In an epidemic, ECMO capabilities would probably rapidly become saturated. Very thorny ethical issues could arise (e.g. how long of an ECMO run is one patient allowed to have before the withdrawal of life-sustaining therapy, in order to allow the circuit to be used for another patient).

going further

Infographics on ECMOed by M Velia Antonini

prognostication of individual patients (back to contents)

overview: three general domains

Epidemiological risk factors Age above ~55-60 years old Diabetes Hypertension Morbid obesity Chronic kidney disease Coronary artery disease, heart failure Chronic pulmonary disease Transplant or other form of immunosuppression HIV

Vital signs Respiratory rate >24 breaths/min Heart rate > 125 b/m Oxygen saturation <90% on room air

Labs (rough cutoffs only; greater elevations are worse prognostically and individual studies vary regarding cutoff values) D-dimer > 1000 ng/ml Ferritin >300 ug/L LDH >245 IU/L Absolute lymphocyte count < 0.8 C-reactive protein >100 mg/L



more on laboratory prognostication

additional information

Preliminary indicators of mortality based on data from China and South Korea (MDCalc, Shahriar Zehtabchi and Joe Habboushe).

(1) It remains unclear what fraction of patients are hospitalized. There may be lots of patients with mild illness who don't present to medical attention and aren't counted. The vast majority of infected patients (e.g. >80%) don't get significantly ill and don't require hospitalization.

(2) Among hospitalized patients ( Guan et al 2/28 ~10-20% of patients are admitted to ICU (note – as the pandemic progresses and fewer patients present to hospital, this percentage is growing). ~3-10% require intubation. ~2-5% die.

(3) Longer term outcomes: Prolonged ventilator dependency ? Patients who survive the initial phases of the illness may still require prolonged ventilator support (possibly developing some radiographic elements of fibrosis)(Zhang 2020). As the epidemic progresses, an issue which may arise is a large volume of patients unable to wean from mechanical ventilation.

Overall mortality The largest series of mortality data comes from the Chinese CDC (table below). The absolute numbers may vary depending on whether some cases were missed, but the relative impact of various risk factors is probably accurate. 👁 Image of mortality related to age and comorbidity.

(Caveat: There are numerous sets of numbers published and they vary a lot. However, from the clinician's standpoint the precise numbers don't really matter.)

avoidance of unnecessary emergency department or clinic visits

Health systems should ideally be put in place to dissuade patients from presenting to the clinic or emergency department for testing to see if they have COVID-19 (e.g. if they have mild constitutional symptoms and don't otherwise require medical attention).

Many centers have developed drive-thru testing, which avoids exposure of other patients in the emergency department. Outdoor testing also ensures ongoing circulation of fresh air.

home disposition

The vast majority of patients with coronavirus will recover spontaneously, without requiring any medical attention (perhaps >80% of patients).

Patients with mild symptoms can generally be discharged home, with instructions to isolate themselves. These decisions should be made in coordination with local health departments, who can assist in follow-up.

Features favoring home discharge may include: Ability to understand and comply with self-isolation (e.g. separate bedroom and bathroom). Ability to call for assistance if they are deteriorating. Having household members who aren't at increased risk of complications from COVID-19 (e.g. elderly, pregnant women, or people with significant medical comorbidities). Lack of hypoxemia, marked chest infiltrates, or other features that would generally indicate admission.

If possible, discharge home with a pulse oximeter may improve detection of silent hypoxemia, potentially allowing patients to re-present to medical attention before developing advanced organ failures.

For more, see CDC interim guidance for disposition of patients with COVID-19 here and here.

Update #6, 5/17:

Update #5, 5/6:

Update #4, 4/21:

Update #3, 4/13:

Update #2, 3/30:

Update #1, 3/22:

First COVID cast, 3/11:

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