This work may not be copied, distributed, displayed, published, reproduced, transmitted, modified, posted, sold, licensed, or used for commercial purposes. By downloading this file, you are agreeing to the publisher’s Terms & Conditions.

Rounds in the General Hospital

Weaning From Exogenous Sedation in the Era of COVID-19 Infection: Recommendations for Sedation and Its Discontinuation

Shixie Jiang, MD; Aldis H. Petriceks, BA; Heather Burke, MD; and Theodore A. Stern, MD

Published: July 16, 2020

Weaning From Exogenous Sedation in the Era of COVID-19 Infection:

Recommendations for Sedation and Its Discontinuation

LESSONS LEARNED AT THE INTERFACE OF MEDICINE AND PSYCHIATRY

The Psychiatric Consultation Service at Massachusetts General Hospital sees medical and surgical inpatients with comorbid psychiatric symptoms and conditions. During their twice-weekly rounds, Dr Stern and other members of the Consultation Service discuss diagnosis and management of hospitalized patients with complex medical or surgical problems who also demonstrate psychiatric symptoms or conditions. These discussions have given rise to rounds reports that will prove useful for clinicians practicing at the interface of medicine and psychiatry.

Prim Care Companion CNS Disord 2020;22(4):20f02686

To cite: Jiang S, Petriceks AH, Burke H, et al. Weaning from exogenous sedation in the era of COVID-19 infection: recommendations for sedation and its discontinuation. Prim Care Companion CNS Disord. 2020;22(4):20f02686.

To share: https://doi.org/10.4088/PCC.20f02686

aDepartment of Psychiatry and Behavioral Neurosciences, University of South Florida, Tampa, Florida

bHarvard Medical School, Boston, Massachusetts

cDepartment of Psychiatry, Massachusetts General Hospital, Boston, Massachusetts

*Corresponding author: Shixie Jiang, MD, University of South Florida, 3515 E Fletcher Ave, MDC 14, Tampa, FL 33613 ([email protected]).

Have you ever wondered what types of sedating medications are available for use in those who require ventilatory support during the management of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)/coronavirus disease 2019 (COVID-19) infection? Have you been uncertain while caring for critically ill individuals about which agents to use and how much you can give, as well as how quickly those medications can be tapered and discontinued? Have you wondered what complications might arise with a rapid taper and how those manifestations can be managed effectively? If you have, then the following case vignette and discussion should prove useful.

CASE VIGNETTE

Mr A, a 35-year-old man with an unremarkable psychiatric and medical history, presented to a local emergency department (ED) with 2 days of fever, chills, and shortness of breath. He had not traveled outside of the city recently nor had he interacted with anyone known to have SARS-CoV-2/COVID-19 infection. His only outpatient medication was low-dose ibuprofen, as needed, for musculoskeletal pain. He was a married, hard-working, chef with 2 school-aged children. He drank alcohol socially and denied use of other substances. His physical examination revealed a temperature of 102°F, respiratory rate of 20 breaths/minute, blood pressure of 136/84 mm Hg, pulse of 102 beats/minute, and oxygen saturation of 87%. His cardiopulmonary examination was remarkable for bilateral inspiratory crackles. A computed tomography (CT) scan (without contrast) of his chest showed bilateral ground-glass opacities in the upper lobes with rounded morphology. He required immediate supplemental oxygenation, which briefly improved his respiratory status. Shortly after his ED evaluation, he decompensated further and developed respiratory distress, leading to endotracheal intubation. Mr A was admitted to the hospital’s intensive care unit (ICU) and placed on mechanical ventilation. A nasopharyngeal swab for SARS-CoV-2 RT-PCR was positive.

Dr B, a middle-aged family medicine physician, was recently redeployed from his outpatient clinic to care for patients in the ICU. Although his team leader was a critical care physician, Dr B had not worked in such a setting since his years of residency training, and he was assigned the task of caring for Mr A, among others. Mr A was placed on synchronized intermittent mandatory ventilation with a 60% fraction of inspired oxygen, a pressure support of 10, a positive end-expiratory pressure of 5, and a tidal volume of 550 mL. A dexmedetomidine infusion was initiated at 0.4 mcg/kg/h and titrated to 0.8 mcg/kg/h. Throughout his hospitalization, Mr A was monitored regularly with arterial blood gases and chest X-rays along with sedation holidays to assess his neurologic and unassisted respiratory status.

Once Mr A was able to oxygenate well on his own on minimal ventilatory settings (positive end-expiratory pressure of 5, pressure support of 10, and 40% fraction of inspired oxygen; on pressure support ventilator settings), weaning parameters were obtained. He achieved a tidal volume > 700 mL, a rapid shallow breathing index of 64, and a negative inspiratory force of −30 cm H2O. Therefore, he was considered ready for extubation. Subsequently, his dexmedetomidine infusion was rapidly discontinued. Four hours later, Mr A became acutely anxious and restless; he became hypertensive, diaphoretic, and tachycardic.

DISCUSSION

How Often Do Those With SARS-CoV-2/COVID-19 Infection Require Hospitalization and ICU Care?

Several studies1-3 have indicated that individuals with COVID-19 infections fall into 1 of 4 severity categories: asymptomatic, mild, severe, and critically ill. Those who are asymptomatic or who have mild manifestations (eg, with pneumonia and little to no hypoxemia) comprise most cases—approximately 80%.1-3 Those with severe disease account for 14% to 15% of cases and have shortness of breath, hypoxemia, and greater pulmonary involvement on chest X-rays. They typically require hospitalization but not ICU care. However, those with critical illness are likely to develop respiratory failure, multiple organ dysfunction, stroke, or septic shock and require ICU care, often with mechanical ventilation.2,4 This group accounts for roughly 5% of confirmed COVID-19 cases. According to the World Health Organization,5 individuals with mild illness tend to recover within 2 weeks of symptom onset, while those with more severe manifestations typically require 3 to 6 weeks of care.

clinical points

  • During the COVID-19 crisis, career intensive care unit (ICU) physicians and redeployed staff have struggled with the necessary, but novel, challenge of managing critically ill patients while maintaining their safety and the capacity for human compassion.
  • Sedation of patients on mechanical ventilation is a balance, as oversedation is associated with longer time spent on the ventilator and a longer ICU stay and undersedation is associated with worsening stress, insomnia, delirium, and development of posttraumatic stress disorder.
  • Neurologic assessment is recommended daily and during sedation interruption because it allows for the monitoring of baseline neurologic function and better detection of secondary cerebral illness, as patients are at higher risk for neurologic dysfunction when critically ill even if they are admitted to the ICU for nonneurologic etiologies.
  • During the reduction of sedative-analgesic medications, patients should be closely monitored for acute withdrawal phenomenon.

Excluding young children, it appears that individuals of all ages can fall into any of the 4 categories of COVID-19 severity, and those who begin in a less severe category can fall to a more severe state. Nevertheless, COVID-19 infects people in an age-dependent manner. In 1 report,6 the Centers for Disease Control and Prevention (CDC) analyzed 4,226 cases of confirmed COVID-19 infection in its associated surveillance sites in the US territories. The CDC confirmed the age of 2,449 of these individuals who were distributed as follows: 0-19 years (5%), 20-44 years (29%), 45-54 years (18%), 55-64 years (18%), 65-84 years (25%), and over 85 years (6%). Among patients with age data available, 12% required hospitalization in the 6-week period. Adults 65 or older comprised 31% of cases but experienced 45% of hospitalizations, 53% of ICU admissions, and 80% of deaths. The total hospitalization rate—among all patients with and without age data—was between 20.7% and 30.4%, the total ICU rate was 4.9%-11.5%, and the case fatality rate was 1.8%-3.8%.6 Research conducted over similar time periods in China reported that between 7% and 26% of laboratory-confirmed COVID-19 infections required ICU care.7 In concordance with these data, researchers8,9 in Italy reported ICU admission rates between 5% and 12% among those with laboratory-confirmed COVID-19 infection, and 16% among patients already hospitalized with COVID-19 infection. These rates have remained more or less consistent among infected patients over time, though infection rates have evolved across the world. A wide disparity of figures has been proposed for the overall case fatality rate, which has been difficult to calculate due to the large proportion of asymptomatic cases. It has also remained difficult to track changes in rates of hospitalization, ICU use, and mortality due to inherent delays in recording, analysis, interpretation, and reporting of data.

Older adults are not the only group who are at increased risk for severe illness, hospitalization, and death. Those with hypertension, chronic lung disease, diabetes mellitus, cardiovascular disease, cancer, chronic kidney disease, or any combination of these conditions are at increased risk for negative outcomes.1,2,10-12 In addition, the CDC added immunocompromised individuals (eg, those with HIV/AIDS), severe obesity, and liver disease to the list of risk factors for severe COVID-19-related illness.13 Among 355 COVID-19-related deaths analyzed in 1 Italian research study,14 patients had an average of 2.7 preexisting conditions, with only 3 patients devoid of any significant comorbidity. This disparity is especially accentuated when combined with age. In a Washington State chronic care facility, 101 residents showed symptoms from the virus, with an average age of 83 years, and 94% had a chronic medical condition.15 A stunning 55% of those residents required hospitalization, and 34% died of their infection.15

What Is It Like for Staff Caring for Critically Ill Individuals With COVID-19 Infection?

During this pandemic, health care staff have documented their responses to this unprecedented situation. For example, in an essay in the Annals of Internal Medicine published in mid-April 2020, a group of physicians in a New York City hospital reported a collective sense of purpose, certainly, but also fear, uncertainty, and stress.16 "While providing care in an urban academic medical center’s medical wards," they wrote, "we have lost the intimate connection with our patients at their most vulnerable points; felt powerless in the face of the very real fear."16(p1) Worst of all, they felt unprotected. The lack of intimate connection came as the result of distancing measures (staff were advised to remain at least 2 m away from infected patients when possible and to use personal protective equipment [PPE] constantly), restrictions on visits by family and friends, time constraints associated with high patient demand, and limited history taking and physical examination.16,17 The authors wrote, "Instead of taking a comprehensive history, we focus only on the aspects relevant to COVID-19. And instead of conducting full physical examinations, we focus on the portions of the examination that could reveal respiratory problems to come. Wearing masks, face shields, gowns, and gloves all the time is foreign, awkward, and cumbersome. Though critical to our safety, this physical barrier of personal protective equipment impedes the intimate interactions that we and our patients are accustomed to having."16(p1)

Career ICU physicians and redeployed staff have struggled with the necessary, but utterly novel, challenge of managing critically ill patients while maintaining their safety and the capacity for human compassion. In many institutions, patients who required mechanical ventilation were isolated while the ventilators remained in the hallway, allowing staff to manage ventilation without increasing exposure or using excess amounts of PPE. Routine practices, such as placing a hand on the patient’s chest to feel for breathing, were restricted in many hospitals. In addition, staff and administrators remained concerned that the national supply of PPE was insufficient to protect health care workers, and this led to consternation on the part of those at risk.16,18

In addition, a moral dilemma arose while reconciling professional and societal duties with the safety, assurance, and well-being of family and loved ones. "I feel an immense guilt at having burdened [my family] with this horrible disease because of my career choices," a pediatric otolaryngologist wrote.19(p2) Another physician, a resident in internal medicine, wrote, "I am intentionally shifting my responsibilities in the face of this new viral menace," to protect herself from severe asthma exacerbations.20(p1) Systemic challenges were also faced by most ICU staff, regardless of personal circumstances. These challenges included limited space and supplies, a lack of effective COVID-19-specific medications, and the need to regularly adapt to constant changes in practice and patient demands.21

While one cannot predict everyone’s critical caregiving experience—particularly in a rapidly evolving pandemic—these challenges appear to form a meaningful pattern. ICU staff in the COVID-19 era are faced with new and foreign standards of patient interactions, moral and personal distress regarding risk of infection and spread among family and loved ones, adjustments to new forms of treatment and caregiving, concern over a lack of personal protection, and uncertainty due to a constantly evolving situation and set of clinical guidelines. While many staff have managed these challenges with poise and resolve, the process of caring for patients infected with COVID-19 has been trivial for no one.

How Can Recently Redeployed Providers Be Effectively Supported When Working in ICUs Rather Than in Their Primary Discipline?

Support for non-ICU physicians who have been redeployed to caring for critically ill individuals infected with COVID-19 generally fall into 2 categories: professional and personal. Both are important to maintain a well-prepared and mentally healthy workforce throughout the pandemic.

Professional support is perhaps the most intuitive need for providers redeployed from non-ICU specialties. Whether one is a surgeon, a radiologist, a psychiatrist, or a practitioner from another specialty, specific learning and assessment materials are required to prepare for critical care in general and COVID-19-related care specifically. Preparatory materials for general critical care can be found in the "COVID-19 Resources for Non-ICU Clinicians" resource collection developed by the Society for Critical Care Medicine.22 This collection includes brief overviews on topics ranging from mechanical ventilation to medication dosage and drip rate calculation, as well as a self-assessment knowledge check for physicians preparing to care for patients with COVID-19 in the ICU. In addition, repositories of the most relevant and up-to-date literature regarding COVID-19-specific critical care (and other aspects of the pandemic) can be found in the online versions of most major medical journals.23,24 Among this pertinent literature, clinical guidelines and synopses may be especially helpful, given their concise and evidence-based nature. As just 2 examples, Poston et al25 recently published a selection of clinical recommendations for management of critically ill patients with COVID-19, alongside detailed guideline ratings and analyses of the evidence base. Phua et al26 published a thorough review of the same topic, delineating, describing, and concisely illustrating (in flowcharts and diagrams) pertinent challenges and recommendations to COVID-19-related intensive care. Taken together, such professional resources may help ensure that each redeployed provider is well prepared for his/her new role.

At the same time, personal and social support is also necessary to maintain an effective critical care workforce. Organizations such as the American Medical Association (AMA) have recognized the importance of this support and have collated "practical strategies for health system leadership to consider in support of their physicians and care teams during COVID-19."27(p1) The AMA collection, in particular, includes recommendations for institutional policy (eg, workload redistribution, paid sick leave) as well as examples of and online links to initiatives taken by specific companies, hospitals, and organizations for the support of health care workers during the pandemic. The collection lists several food companies offering contact-free and reduced-pricing meal deliveries to hospitals and clinicians, mentions child and pet services and emotional and mental health services, and provides links to the COVID-19 resource pages of other prominent academic medical organizations and institutions.

Which Medication Classes Are Typically Used to Sedate Intubated Patients in the ICU?

Management of intubated patients in the ICU typically includes sedation and analgesia. Sedation reduces stress and anxiety while facilitating mechanical ventilation. The most commonly used medications for sedation include propofol, dexmedetomidine, and benzodiazepines.28

Propofol is a sedative with increasing popularity when compared to rates of benzodiazepine or dexmedetomidine use.29 It is typically preferred if a patient requires periodic neurologic assessments, as it has a rapid onset, short-half life, and inactive metabolites. Notable adverse effects of propofol include hypotension as well as prolonged emergence from sedation, particularly if propofol has been dosed to provide deeper sedation, as it can lead to saturation of peripheral tissues.30 Practitioners should also be aware that propofol has been related to higher rates of self-extubation.28

Dexmedetomidine was initially considered for short-term use (< 24 hours) in ICU patients; however, it has been well tolerated and effective for longer periods. Dexmedetomidine is metabolized in the liver; patients with liver failure or cirrhosis require smaller doses and have a longer emergence from sedation.30 Notable adverse effects of dexmedetomidine include bradycardia, with a higher risk of hemodynamic instability when given in a loading dose.31

Benzodiazepines including lorazepam, midazolam, and diazepam have a place in continuous ICU sedation, particularly when managing agitation or anxiety.30 However, propofol and dexmedetomidine have been recommended over the use of benzodiazepines for sedation, as they have been found to improve time spent on the ventilator, decrease risk of delirium, and cause less hemodynamic instability.31,32 Additionally, adverse effects of benzodiazepines (including decreased respiratory drive, hypotension, and development of tolerance if used consistently) should be considered.30 This recommendation has been reflected in the PADIS guidelines (Pain, Agitation/Sedation, Delirium, Immobility, and Sleep) of the Society of Critical Care Medicine since 2013.28 However, benzodiazepines continue to have a place in ICU sedation when managing agitation, anxiety, or accompanying seizures or withdrawal.30

Adjunctive options for sedative therapy include use of clonidine, which has a similar mechanism of action to dexmedetomidine but provides a lower level of sedation. Clonidine should be tapered, as abrupt discontinuation can lead to hypertension.33

Analgesia is often undertreated due to adverse effects of pain medications that include respiratory depression, hemodynamic changes, and addiction potential.33 Analgesia can be measured by standardized scales, such as the Behavioral Pain Scale and the Critical Care Pain Observational Tool.34 Options for analgesia include morphine, hydromorphone, fentanyl, and remifentanil. Morphine and hydromorphone are typically administered as intermittent intravenous (IV) injections, whereas fentanyl and remifentanil are administered as a continuous infusion, as they have a faster onset and can be titrated.33

Adjunctive options for analgesia include continuous infusion of ketamine, which has been shown in retrospective studies to decrease utilization of analgesic and sedation medications in mechanically ventilated patients35; however, further prospective studies are needed to confirm its utility. Use of ketamine requires close monitoring for adverse effects, such as hallucinations or other psychological disturbances.28

How Deep Should Sedation Be for Intubated Patients and How Often Should Sedation Be Lightened to Complete a Neurologic Examination?

Sedation of patients on mechanical ventilation is a balance, as oversedation is associated with longer time spent on the ventilator and a longer ICU stay and undersedation is associated with worsening stress, insomnia, delirium, and development of posttraumatic stress disorder (PTSD).28,33 Therefore, scales such as the Sedation Agitation Scale,36 the Motor Activity Assessment Scale,37 and the Richmond Agitation-Sedation Scale (RASS)38 are used to establish a goal level of sedation and to monitor sedation in a standardized way.34Light sedation is preferred to deep sedation in ICU patients who are being mechanically ventilated, as it shortens time to extubation and decreases the tracheostomy rate.28 Older studies sided toward a target RASS score of −2.39 However, more recent studies have shown that a RASS score between −1 and + 1 led to significantly shorter ICU length of stays and decreased cost.40 For this reason, target RASS scores have trended toward lighter and lighter sedation levels, with the most recent PADIS 2018 guidelines defining light sedation as a RASS score of −2 to + 1.28

Sedation protocols can be classified as protocol-directed sedation management (or a protocol carried out by the ICU nurse) versus non-protocol-directed management. Review of randomized controlled trials showed no significant difference between outcomes of either of these management options.41 However, the heterogeneity of the studies on this topic, the nurse-to-patient ratio, and the experience of the individual performing the protocol should be considered.41 Sedation of patients can also be classified by continuous sedation versus intermittent sedation (typically a daily interruption of sedation). Daily interruption of sedation had multiple benefits, as it shortened mechanical ventilation by 2 days and length of ICU stay by 3.5 days and decreased the total amount of benzodiazepines used.39 Additionally, it reduced the complications that can accompany prolonged intubation, including ventilator-associated pneumonia, barotrauma, venous thromboembolic disease, upper gastrointestinal bleeding, and cholestasis.42

Neurologic assessment is recommended daily and during sedation interruption, as it allows for the monitoring of baseline neurologic function and better detection of secondary cerebral illness. Patients are at higher risk for neurologic dysfunction when critically ill, even if they are admitted to the ICU for nonneurologic etiologies.43

The decision to use prone positioning during mechanical ventilation can influence the level of sedation. Particularly in patients with severe acute respiratory distress syndrome (ARDS), keeping the patient in prone position for at least 12 hours a day showed a decrease in mortality and is suspected to decrease risk of ventilator-related lung injury.44 Patients in the prone position typically require increased sedation and neuromuscular blockade to better tolerate this position.45 For management of patients with COVID-19, guidelines from the European Society of Intensive Medicine recommend intermittent use of neuromuscular blockers unless the patient requires deeper sedation or prone ventilation, in which case a continuous infusion of neuromuscular blockers would be recommended.46

What Do Withdrawal Syndromes From These Medication Classes Look Like and When Do They Appear?

During the reduction of sedative-analgesic medications, patients should be closely monitored for acute withdrawal phenomenon. In this setting, withdrawal is quite common and can be induced by abruptly interrupting or rapidly decreasing doses and blood drug concentrations. In an observation study47 of 28 mechanically ventilated patients in an ICU for more than 1 week, 32% experienced an acute withdrawal syndrome. This syndrome manifests with variable symptoms depending on the sedative-analgesic class of medication used. Additionally, monitoring for emergence delirium after weaning of sedation is a crucial task, as it may occur in 68%-87% of medical ICU patients. Prominent risk factors include age > 65 years, prolonged ventilation (more than 3 days) and immobility, continued nutritional and electrolyte deficiencies in the setting of COVID-19 infection, and organ failure. The hallmarks of this syndrome are impaired attention, disorientation, and problems with cognition, language, visuospatial ability, or perception.48 It should be differentiated from more common agent-specific withdrawal features by persistence of altered mentation and confusion, as it can also occur in roughly the same time period.

Opiate withdrawal occurs in approximately 16.7% of patients receiving mechanical ventilation for more than 72 hours. Symptoms include anxiety, agitation, tachypnea, tachycardia, fever/chills, hypertension, mydriasis, rhinorrhea, lacrimation, nausea/vomiting, abdominal cramps, diarrhea, tremor, and piloerection. Opioid withdrawal onset varies depending on the agent used and symptom cluster; however, it typically occurs within 7-12 hours of medication dose reduction.49 Benzodiazepine withdrawal is characterized by similar features, including agitation, anxiety, tremors, autonomic hyperactivity, and fever. More dangerously, these features may also precipitate seizures. Its prevalence has not been characterized due to the heterogeneity of drugs used and concurrent opioid administration. The onset is typically within 4-10 hours, with a more rapid precipitation if midazolam was used.50

Withdrawal from propofol has been noted as "propofol infusion syndrome." Its overall epidemiology, pathophysiology, and diagnostic criteria are not well studied or understood. Propofol withdrawal syndrome has been precipitated by reducing anesthesia after administration of high doses (> 5 mg/kg/h) or prolonged duration (> 48 hours). Its presentation is highly variable and can involve fever and hypotension, accompanied by metabolic acidosis, rhabdomyolysis, hyperkalemia, or elevated lactate and liver enzymes. Propofol infusion syndrome onset occurs within 24 hours of any reduction in its dose or frequency.51

Considering the increasingly widespread use of dexmedetomidine, withdrawal after prolonged infusions has been documented. Its incidence is relatively understudied; however, 1 recent prospective observational study52 reported that 64% of the 42-patient cohort experienced symptoms. Additionally, withdrawal was found to be more likely to occur in those receiving high cumulative daily doses or elevated peak rates (> 12.9 µg/kg/d or 0.8 µg/kg/h) for more than 3 days. Withdrawal signs include hypertension, tachycardia, diaphoresis, and anxiety. The time to onset of these symptoms is currently not well studied but estimated to be within 8 hours of discontinuation.52

Compared to the other sedative agents, symptoms of ketamine withdrawal are less often associated with hemodynamic effects and cardiorespiratory events and more so with dysphoric emergence phenomenon. Ketamine withdrawal occurs in 10%-20% of patients and involves depersonalization, dreams, hallucinations, and a general state of distress. The time frame in which this occurs is within minutes to hours of removal of sedation.53

How Can Withdrawal Syndromes From These Medication Classes Be Managed?

The first and pivotal question for sedation weaning is to assess readiness by considering improvement of the underlying etiology that resulted in continuous sedation, hemodynamic stability, appropriate neurologic status (RASS score of −2 to 0 with minimal sedation), and adequate gas exchange (partial pressure of oxygen: fraction of inspired oxygen ratio > 200 with a positive end-expiratory pressure of 5 cm H2O). For any pharmacologic agent used for continuous sedation, the sequence and rate of discontinuation should be individualized and optimized. Abrupt or rapid discontinuation is more likely to precipitate withdrawal phenomenon, particularly in those who have been receiving sedation for more than 7 days. A gradual reduction (of 10%-25% per day) is prudent.54

For opiate withdrawal secondary to infusions in the critically ill, several strategies have been proposed; unfortunately, controlled trials on this are lacking. These regimens include conversion to a longer-acting oral equivalent (eg, methadone) or augmentation with a α-2 agonist such as dexmedetomidine or clonidine. Dosing varies tremendously if oral equivalents are utilized and depend on the amount and frequency used for continuous sedation. One study31 of 20 patients used an average of 48 mg of methadone to transition from fentanyl infusions. In the case of dexmedetomidine, doses of 0.7 mcg/kg/h with or without loading doses of approximately 1 µg/kg have been implemented.55 Clonidine has been administered via a transdermal patch (50-100 µg/d or 4.2-8.5 µg/kg/d) or an oral formulation of 3-6 µg/kg/d divided every 4 to 6 hours.55,56 Benzodiazepine withdrawal has also been managed with α-2 agonists, as described above. Additionally, IV or oral lorazepam (0.5-1 mg every 6-12 hours) has been used simultaneously as weaning ensues to prevent and alleviate withdrawal symptoms that arise.57

There are no established guidelines for treatment of propofol infusion syndrome. The overall success is more likely to depend on early diagnosis and prevention. These approaches involve avoiding infusion rates > 5 mg/kg/h for more than 48 hours, using propofol in combination with other sedatives, and monitoring pH, lactate, and creatine kinase if prolonged administration is required. Otherwise, acute management is centered on treatment of the ensuing metabolic acidosis by increasing minute ventilation or even using extracorporeal membrane oxygenation in some cases.51

Dexmedetomidine withdrawal is a documented yet poorly understood syndrome. As such, there are no specific treatments reported specifically for these cases. Symptomatic treatment of autonomic hyperactivity can be managed with cardiovascular agents, along with a brief course of benzodiazepines for acute anxiety or agitation that arises (lorazepam 0.5-1 mg every 6 hours as needed). With ketamine emergence phenomenon, reactions are often quite frightening or distressful but not particularly dangerous. Calming environmental techniques (eg, music, isolated recovery area) may be utilized. Otherwise, single administration of benzodiazepines has been efficacious shortly before weaning or as needed upon emergence.53 Propofol has also been combined with ketamine (0.75 mg/kg, ranging from 0.2 to 2.05 mg/kg for each agent) with an observed lower occurrence rate of this withdrawal syndrome.58

Are There Long-Term Consequences From Prolonged Ventilatory Support?

Numerous studies have addressed the neurologic, neurocognitive, psychiatric, and functional sequelae of prolonged mechanical ventilation (PMV). In 1 study,59 comparing outcomes of patients discharged from a Canadian ICU, 47.2% of patients who received PMV were rehospitalized within 1 year, while only 37.7% of those who did not receive PMV were rehospitalized over an equivalent timeframe. Rates of 1-year ICU readmission (19.0% vs 11.6%) and total health care costs (Can $32,526 vs Can $13,657) were significantly increased in those who received PMV. In a separate study conducted in the United States, the authors60 reported a 56% 1-year mortality rate among patients discharged from the hospital after receiving PMV. Of those who survived beyond 1 year, 62% reported that their health status was better after 1 year than it had been prior to hospitalization, 23% reported worse health, and 15% reported no change. Among the survivors, 28% reported no dependencies for their instrumental activities of daily living (IADLs), 57% were dependent on caregiver support for at least 1 IADL, and 7% were dependent on others for every IADL.60

Behind these broad functional deficits lies a list of neurologic and pathophysiologic sequelae associated with PMV. According to a consensus statement from the National Association for Medical Direction of Respiratory Care (NAMDRC), these sequelae include "late mortality, ongoing morbidity, neurocognitive defects, impaired mental health. . . . These stresses, physical and emotional, associated with continued weaning efforts, complications, worsened comorbidities . . . add to the continuum of late sequelae."61(p3,951) In a review article62 developed from the 2002 Brussels Roundtable, the authors noted that these issues are often present at discharge and continue beyond the 1-year follow-up. One study,63 conducted in the ICU of a large US medical school found that, of 96 patients who underwent PMV during their ICU stay, 44.8% tested as "cognitively impaired" at hospital discharge. In addition, 10.4% of patients met criteria for delirium at discharge and 20.5% met criteria for subsyndromal delirium.63Another study64 conducted among patients with ARDS weaned from PMV and discharged from the ICU found that neurocognitive sequelae can persist long after discharge. After 1 year, 30% of patients in the study64 experienced global cognitive deficits, and 78% experienced impairment in at least 1 cognitive function, including concentration, attention, and memory. Generally speaking, patients may also experience general constitutive symptoms (eg, weakness, fatigue) as part of the long-term sequelae of PMV and appear to be at increased risk for PTSD and depression.62,65 Beyond the effects of PMV itself, conditions such as ARDS are associated with their own independent consequences of central nervous system dysfunction. Reviews of ARDS and its neurocognitive sequelae can be found in the literature.66,67

One question may be to what extent PMV itself—as opposed to chronic conditions or patient characteristics—is responsible for morbidity in patients receiving this intervention. While the literature has yet to provide compelling or consistent answers to this particular inquiry, recent developments in quality assessment and critical care have provided a framework that may enable clinician researchers to do so. In 2013, the CDC organized a working group that defined ventilator-associated events (VAEs) as a quality benchmark for measuring ventilator-related morbidity and mortality. Prior to this definition, ventilator-associated pneumonia served as the only benchmark of quality for ventilated patients and a relatively unreliable one at that. Its replacement, VAE, stands as a "surveillance definition algorithm," used to "identify a broad range of conditions and complications occurring in mechanically ventilated adult patients," and is broken into 4 definition tiers. The first of these are ventilation-associated conditions (VACs), defined as at least 2 calendar days of stable or decreasing ventilator setting followed by consistently higher settings for at least 2 additional calendar days.68 In other words, a "new respiratory deterioration."68,69 The second is infection-related ventilation-associated complication (IVAC), meaning essentially VAC with evidence of infection. The third is possible pneumonia, defined as IVAC with possible evidence of pulmonary infection. Finally, the fourth is probable pneumonia, defined as IVAC with probable evidence of pulmonary infection. Details can be found in CDC documents and explanatory articles.68,70,71

These definitions are important to the question of PMV-related morbidity and mortality because without them, clinicians and researchers would be unable to standardize their classifications of what precisely qualifies as a condition for which PMV can be said to be responsible for. Since the CDC established these surveillance definitions, studies have suggested that most VACs, for instance, are attributable to pneumonia, pulmonary edema, atelectasias, or acute respiratory distress syndrome and are not unavoidable consequences of caring for critically ill patients.68,70,71 Furthermore, these studies68,70-72 have demonstrated a strong association between VACs and length of stay in the ICU, as well as between VACs and mortality. In 1 single-center retrospective cohort study, IVACs were independently and significantly associated with hospital mortality, and VACs were independently and near significantly associated with the same measure.73 This study,73 and the others referenced,68,70-72 accounted for confounding traits such as age, sex, height, weight, and comorbidities, thus suggesting that while the literature provides little evidence as to what proportion of overall morbidity and mortality in patients receiving PMV is caused by the PMV itself, there is reliable evidence that is indeed independently associated with morbidity and mortality through both infectious and noninfectious complications.

In essence, PMV is associated with a wide range of physiologic, neurocognitive, and functional deficits that can be seen at hospital discharge, and many of these deficits may persist. Given this reality, and that of increasing use of PMV worldwide, ongoing research is being devoted to understanding these sequelae, their treatment, and their prevention.61

How Do Critically Ill Patients With SARS-CoV-2/COVID-19 Infection Do After Receiving Intensive Care?

Retrospective observational studies74 of ICU patients in Lombardy, Italy reported 88% of patients in the ICU required mechanical ventilation. Of the 1,581 patients recorded on March 25, 2020, 920 patients were still in the ICU, 256 patients had been discharged from the ICU, and 405 patients had died in the ICU, with a notable difference in mortality between patients > 64 years old (35%) and patients < 64 years old (15%).74 Early case series75 of COVID-19 outcomes in patients in New York City showed 14.2% of patients required ICU-level care and 12.2% of patients required mechanical ventilation. By April 4, 2020, 3.3% of patients requiring mechanical ventilation had been discharged from the hospital, 72.2% were still in the hospital, and 24.5% had died.75 Median hospitalization was found to be 10 days, 12 days, and 13 days, respectively.76-78

How Was Mr A Managed After His Extubation?

Given his underlying illness, critical condition, and prolonged sedation, Mr A likely suffered an acute withdrawal syndrome secondary to dexmedetomidine. He was managed symptomatically with lorazepam 1 mg every 6 hours as needed for anxiety and restlessness, and his vital signs were monitored regularly. The nursing team and staff members were instructed to maintain a quiet and structured environment, with carefully scheduled times for laboratory draws, interviews, and assessments. He improved significantly within the next 36 hours, and his acute withdrawal-related symptoms were alleviated. His respiratory status continued to remain stable and improve. He underwent regular physical therapy and other rehabilitation services to regain his previous functional status.

CONCLUSION

Here, we presented a case vignette highlighting a SARS-CoV-2/COVID-19-positive patient to discuss basic principles of sedation, weaning from sedation, and management of agent-specific acute withdrawal syndromes that may arise. Further studies will be required to determine optimal parameters and treatment regimens for these patients; however, in terms of the sedation weaning and withdrawal management, we anticipate that this information will still be relevant. Given the ongoing and ever-developing pandemic and influx of patients in ICUs, practitioners being enlisted temporarily as intensivists need to be guided by practical information. Finally, note that over the course of the COVID-19 pandemic, a number of organizations have provided online guidelines for managing COVID in the ICU, including the American Thoracic Society,79 the National Institute for Health Care Excellence,80 the Intensive Care Society,81 and the Society of Critical Care Medicine.22 Many of these societies also provide resources targeted toward non-ICU clinicians.

Submitted: May 18, 2020; accepted May 29, 2020.

Published online: July 16, 2020.

Potential conflicts of interest: Dr Stern is an employee of the Academy of Consultation-Liaison Psychiatry (as editor of Psychosomatics). Drs Jiang and Burke and Mr Petriceks report no conflicts of interest related to the subject of this article.

Funding/support: None.

REFERENCES

1.McIntosh K. Coronavirus disease 2019 (COVID-19). UpToDate website. https://www.uptodate.com/contents/coronavirus-disease-2019-covid-19. Published 2020. Accessed April 5, 2020.

2.Wu Z, McGoogan JM. Characteristics of and important lessons from the Coronavirus Disease 2019 (COVID-19) outbreak in China: summary of a report of 72,314 cases from the Chinese Center for Disease Control and Prevention. JAMA. 2020;323(13):1239-1242. PubMed CrossRef

3.Guan W-J, Ni Z-Y, Hu Y, et al; China Medical Treatment Expert Group for Covid-19. Clinical characteristics of Coronavirus Disease 2019 in China. N Engl J Med. 2020;382(18):1708-1720. PubMed CrossRef

4.Cascella M, Rajnik M, Cuomo A, et al. Features, evaluation and treatment coronavirus (COVID-19). In: StatPearls [Internet]. Treasure Island, FL: StatPearls Publishing, LLC; 2020. http://www.ncbi.nlm.nih.gov/pubmed/32150360.

5.WHO Director-General’s Opening Remarks at the Media Briefing on COVID-19-24 February 2020. WHO website. https://www.who.int/dg/speeches/detail/who-director-general-s-opening-remarks-at-the-media-briefing-on-covid-19-24-February-2020. Accessed May 22, 2020.

6.Bialek S, Boundy E, Bowen V, et al; CDC COVID-19 Response Team. Severe outcomes among patients with coronavirus disease 2019 (COVID-19)—United States, February 12-March 16, 2020. MMWR Morb Mortal Wkly Rep. 2020;69(12):343-346. PubMed

7.Anesi GL. Coronavirus disease 2019 (COVID-19): critical care and airway management issues. UpToDate website. https://www.uptodate.com/contents/coronavirus-disease-2019-covid-19-critical-care-and-airway-management-issues. Published 2020. Accessed May 10, 2020.

8.Grasselli G, Pesenti A, Cecconi M. Critical care utilization for the COVID-19 outbreak in Lombardy, Italy: early experience and forecast during an emergency response. JAMA. 2020;323(16):1545. PubMed CrossRef

9.Livingston E, Bucher K. Coronavirus disease 2019 (COVID-19) in Italy. JAMA. 2020;323(14):1335. PubMed CrossRef

10.CDC COVIDView. Centers for Disease Control and Prevention. https://www.cdc.gov/coronavirus/2019-ncov/covid-data/covidview.html. Published 2020. Accessed April 5, 2020.

11.Zhou F, Yu T, Du R, et al. Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study. Lancet. 2020;395(10229):1054-1062. PubMed CrossRef

12.Chow N, Fleming-Dutra K, Gierke R, et al; CDC COVID-19 Response Team. Preliminary estimates of the prevalence of selected underlying health conditions among patients with coronavirus disease 2019—United States, February 12-March 28, 2020. MMWR Morb Mortal Wkly Rep. 2020;69(13):382-386. PubMed

13.People Who Are at Higher Risk for Severe Illness. CDC website. https://www.cdc.gov/coronavirus/2019-ncov/need-extra-precautions/people-at-higher-risk.html. Accessed May 22, 2020.

14.Onder G, Rezza G, Brusaferro S. Case-fatality rate and characteristics of patients dying in relation to COVID-19 in Italy [published online ahead of print March 23, 2020]. JAMA. PubMed CrossRef

15.McMichael TM, Currie DW, Clark S, et al; Public Health-Seattle and King County, EvergreenHealth, and CDC COVID-19 Investigation Team. Epidemiology of Covid-19 in a long-term care facility in King County, Washington. N Engl J Med. 2020;382(21):2005-2011. PubMed CrossRef

16.Cunningham CO, Diaz C, Slawek DE. COVID-19: the worst days of our careers. Ann Intern Med. 2020;172(11):764-765. PubMed CrossRef

17.Murthy S, Gomersall CD, Fowler RA. Care for critically ill patients with COVID-19. JAMA. 2020;323(15):1499-1500. PubMed CrossRef

18.Ranney ML, Griffeth V, Jha AK. Critical supply shortages—the need for ventilators and personal protective equipment during the Covid-19 pandemic. N Engl J Med. 2020;382(18):e41. PubMed CrossRef

19.Jayawardena A. Waiting for something positive [published online ahead of print April 22, 2020]. N Engl J Med. PubMed CrossRef

20.Tsai C. Personal risk and societal obligation amidst COVID-19. JAMA. 2020;323(16):1555. PubMed CrossRef

21.Qiu H, Tong Z, Ma P, et al; China Critical Care Clinical Trials Group (CCCCTG). Intensive care during the coronavirus epidemic. Intensive Care Med. 2020;46(4):576-578. PubMed CrossRef

22.Critical care for the non-ICU Clinician. Society of Critical Care Medicine website. https://covid19.sccm.org/nonicu.htm. Published 2020. Accessed May 3, 2020.

23.Coronavirus Disease 2019 (COVID-19). JAMA Network website. https://jamanetwork.com/journals/jama/pages/coronavirus-alert. Published 2020. Accessed May 3, 2020.

24.Coronavirus (Covid-19). NEJM website. https://www.nejm.org/coronavirus?query=main_nav_lg. Published 2020. Accessed May 3, 2020.

25.Poston JT, Patel BK, Davis AM. Management of critically ill adults with COVID-19. JAMA. 2020;323(18)1839-1841. PubMed

26.Phua J, Weng L, Ling L, et al; Asian Critical Care Clinical Trials Group. Intensive care management of coronavirus disease 2019 (COVID-19): challenges and recommendations. Lancet Respir Med. 2020;8(5):506-517. PubMed

27.Caring for our caregivers during COVID-19. American Medical Association website. https://www.ama-assn.org/delivering-care/public-health/caring-our-caregivers-during-covid-19. Published 2020. Accessed May 3, 2020.

28.Devlin JW, Skrobik Y, Gélinas C, et al. Clinical Practice Guidelines for the Prevention and Management of Pain, Agitation/Sedation, Delirium, Immobility, and Sleep Disruption in Adult Patients in the ICU. Crit Care Med. 2018;46(9):e825-e873. PubMed CrossRef

29.Wunsch H, Kahn JM, Kramer AA, et al. Use of intravenous infusion sedation among mechanically ventilated patients in the United States. Crit Care Med. 2009;37(12):3031-3039. PubMed CrossRef

30.Barr J, Fraser GL, Puntillo K, et al; American College of Critical Care Medicine. Clinical practice guidelines for the management of pain, agitation, and delirium in adult patients in the intensive care unit. Crit Care Med. 2013;41(1):263-306. PubMed CrossRef

31.Riker RR, Shehabi Y, Bokesch PM, et al; SEDCOM (Safety and Efficacy of Dexmedetomidine Compared With Midazolam) Study Group. Dexmedetomidine vs midazolam for sedation of critically ill patients: a randomized trial. JAMA. 2009;301(5):489-499. PubMed CrossRef

32.Carson SS, Kress JP, Rodgers JE, et al. A randomized trial of intermittent lorazepam versus propofol with daily interruption in mechanically ventilated patients. Crit Care Med. 2006;34(5):1326-1332. PubMed CrossRef

33.Hughes CG, McGrane S, Pandharipande PP. Sedation in the intensive care setting. Clin Pharmacol. 2012;4:53-63. PubMed

34.Sessler CN, Grap MJ, Ramsay MA. Evaluating and monitoring analgesia and sedation in the intensive care unit. Crit Care. 2008;12(suppl 3):S2. PubMed CrossRef

35.Garber PM, Droege CA, Carter KE, et al. Continuous infusion ketamine for adjunctive analgosedation in mechanically ventilated, critically ill patients. Pharmacotherapy. 2019;39(3):288-296. PubMed CrossRef

36.Riker RR, Picard JT, Fraser GL. Prospective evaluation of the Sedation-Agitation Scale for adult critically ill patients. Crit Care Med. 1999;27(7):1325-1329. PubMed CrossRef

37.Devlin JW, Boleski G, Mlynarek M, et al. Motor Activity Assessment Scale: a valid and reliable sedation scale for use with mechanically ventilated patients in an adult surgical intensive care unit. Crit Care Med. 1999;27(7):1271-1275. PubMed CrossRef

38.Sessler CN, Gosnell MS, Grap MJ, et al. The Richmond Agitation-Sedation Scale: validity and reliability in adult intensive care unit patients. Am J Respir Crit Care Med. 2002;166(10):1338-1344. PubMed CrossRef

39.Kress JP, Pohlman AS, O’ Connor MF, et al. Daily interruption of sedative infusions in critically ill patients undergoing mechanical ventilation. N Engl J Med. 2000;342(20):1471-1477. PubMed CrossRef

40.Taran Z, Namadian M, Faghihzadeh S, et al. The effect of sedation protocol using Richmond Agitation-Sedation Scale (RASS) on some clinical outcomes of mechanically ventilated patients in intensive care units: a randomized clinical trial. J Caring Sci. 2019;8(4):199-206. PubMed CrossRef

41.Aitken LM, Bucknall T, Kent B, et al. Protocol-directed sedation versus non-protocol-directed sedation in mechanically ventilated intensive care adults and children. Cochrane Database Syst Rev. 2018;11:CD009771. PubMed CrossRef

42.Schweickert WD, Gehlbach BK, Pohlman AS, et al. Daily interruption of sedative infusions and complications of critical illness in mechanically ventilated patients. Crit Care Med. 2004;32(6):1272-1276. PubMed CrossRef

43.Stocchetti N, Le Roux P, Vespa P, et al. Clinical review: neuromonitoring—an update. Crit Care. 2013;17(1):201. PubMed CrossRef

44.Munshi L, Del Sorbo L, Adhikari NKJ, et al. Prone position for acute respiratory distress syndrome. a systematic review and meta-analysis. Ann Am Thorac Soc. 2017;14(suppl 4):S280-S288. PubMed CrossRef

45.Guérin C, Reignier J, Richard JC, et al; PROSEVA Study Group. Prone positioning in severe acute respiratory distress syndrome. N Engl J Med. 2013;368(23):2159-2168. PubMed CrossRef

46.Tezcan B, Turan S, Özgök A. Current use of neuromuscular blocking agents in intensive care units. Turk J Anaesthesiol Reanim. 2019;47(4):273-281. PubMed CrossRef

47.Cammarano WB, Pittet JF, Weitz S, et al. Acute withdrawal syndrome related to the administration of analgesic and sedative medications in adult intensive care unit patients. Crit Care Med. 1998;26(4):676-684. PubMed CrossRef

48.Maldonado JR. Acute brain failure: Pathophysiology, diagnosis, management, and sequelae of delirium. Crit Care Clin. 2017;33(3):461-519. PubMed CrossRef

49.Hyun DG, Huh JW, Hong SB, et al. Iatrogenic opioid withdrawal syndrome in critically ill patients: a retrospective cohort study. J Korean Med Sci. 2020;35(15):e106. PubMed CrossRef

50.Shafer A. Complications of sedation with midazolam in the intensive care unit and a comparison with other sedative regimens. Crit Care Med. 1998;26(5):947-956. PubMed CrossRef

51.Hemphill S, McMenamin L, Bellamy MC, et al. Propofol infusion syndrome: a structured literature review and analysis of published case reports. Br J Anaesth. 2019;122(4):448-459. PubMed CrossRef

52.Bouajram RH, Bhatt K, Croci R, et al. Incidence of dexmedetomidine withdrawal in adult critically ill patients: a pilot study. Crit Care Explor. 2019;1(8):e0035. PubMed CrossRef

53.Strayer RJ, Nelson LS. Adverse events associated with ketamine for procedural sedation in adults. Am J Emerg Med. 2008;26(9):985-1028. PubMed CrossRef

54.Conti G, Mantz J, Longrois D, et al. Sedation and weaning from mechanical ventilation: time for ‘ best practice’ to catch up with new realities? Multidiscip Respir Med. 2014;9(1):45. PubMed CrossRef

55.Honey BL, Benefield RJ, Miller JL, et al. Alpha2-receptor agonists for treatment and prevention of iatrogenic opioid abstinence syndrome in critically ill patients. Ann Pharmacother. 2009;43(9):1506-1511. PubMed CrossRef

56.Al-Qadheeb NS, Roberts RJ, Griffin R, et al. Impact of enteral methadone on the ability to wean off continuously infused opioids in critically ill, mechanically ventilated adults: a case-control study. Ann Pharmacother. 2012;46(9):1160-1166. PubMed CrossRef

57.van der Vossen AC, van Nuland M, Ista EG, et al. Oral lorazepam can be substituted for intravenous midazolam when weaning paediatric intensive care patients off sedation. Acta Paediatr. 2018;107(9):1594-1600. PubMed CrossRef

58.Willman EV, Andolfatto G. A prospective evaluation of "ketofol" (ketamine/propofol combination) for procedural sedation and analgesia in the emergency department. Ann Emerg Med. 2007;49(1):23-30. PubMed CrossRef

59.Hill AD, Fowler RA, Burns KEA, et al. Long-term outcomes and health care utilization after prolonged mechanical ventilation. Ann Am Thorac Soc. 2017;14(3):355-362. PubMed CrossRef

60.Chelluri L, Im KA, Belle SH, et al. Long-term mortality and quality of life after prolonged mechanical ventilation. Crit Care Med. 2004;32(1):61-69. PubMed CrossRef

61.MacIntyre NR, Epstein SK, Carson S, et al; National Association for Medical Direction of Respiratory Care. Management of patients requiring prolonged mechanical ventilation: report of a NAMDRC consensus conference. Chest. 2005;128(6):3937-3954. PubMed CrossRef

62.Angus DC, Carlet J; 2002 Brussels Roundtable Participants. Surviving intensive care: a report from the 2002 Brussels Roundtable. Intensive Care Med. 2003;29(3):368-377. PubMed CrossRef

63.Ely EW, Inouye SK, Bernard GR, et al. Delirium in mechanically ventilated patients: validity and reliability of the confusion assessment method for the intensive care unit (CAM-ICU). JAMA. 2001;286(21):2703-2710. PubMed CrossRef

64.Hopkins RO, Weaver LK, Pope D, et al. Neuropsychological sequelae and impaired health status in survivors of severe acute respiratory distress syndrome. Am J Respir Crit Care Med. 1999;160(1):50-56. PubMed CrossRef

65.Angus DC, Musthafa AA, Clermont G, et al. Quality-adjusted survival in the first year after the acute respiratory distress syndrome. Am J Respir Crit Care Med. 2001;163(6):1389-1394. PubMed CrossRef

66.Giordano G, Pugliese F, Bilotta F. Mechanical ventilation and long-term neurocognitive impairment after acute respiratory distress syndrome. Crit Care. 2020;24(1):30. PubMed CrossRef

67.Bilotta F, Giordano G, Sergi PG, et al. Harmful effects of mechanical ventilation on neurocognitive functions. Crit Care. 2019;23(1):273. PubMed CrossRef

68.Klompas M. Complications of mechanical ventilation-the CDC’s new surveillance paradigm. N Engl J Med. 2013;368(16):1472-1475. PubMed CrossRef

69.Centers for Disease Control and Prevention (CDC). Ventilator-Associated Event. VAE; 2017. https://www.cdc.gov/nhsn/pdfs/pscmanual/10-vae_final.pdf. Accessed July 5, 2020.

70.Hayashi Y, Morisawa K, Klompas M, et al. Toward improved surveillance: the impact of ventilator-associated complications on length of stay and antibiotic use in patients in intensive care units. Clin Infect Dis. 2013;56(4):471-477. PubMed CrossRef

71.Klompas M, Khan Y, Kleinman K, et al; CDC Prevention Epicenters Program. Multicenter evaluation of a novel surveillance paradigm for complications of mechanical ventilation. PLoS One. 2011;6(3):e18062. PubMed CrossRef

72.Klompas M, Magill S, Robicsek A, et al; CDC Prevention Epicenters Program. Objective surveillance definitions for ventilator-associated pneumonia. Crit Care Med. 2012;40(12):3154-3161. PubMed CrossRef

73.Kobayashi H, Uchino S, Takinami M, et al. The impact of ventilator-associated events in critically 111 subjects with prolonged mechanical ventilation. Respir Care. 2017;62(11):1379-1386. PubMed CrossRef

74.Grasselli G, Zangrillo A, Zanella A, et al; COVID-19 Lombardy ICU Network. Baseline characteristics and outcomes of 1591 patients infected with SARS-CoV-2 admitted to ICUs of the Lombardy Region, Italy. JAMA. 2020;323(16):1574-1581. PubMed CrossRef

75.Richardson S, Hirsch JS, Narasimhan M, et al; and the Northwell COVID-19 Research Consortium. Presenting characteristics, comorbidities, and outcomes among 5700 patients hospitalized with COVID-19 in the New York City Area. JAMA. 2020;323(20):2052. PubMed CrossRef

76.Wu C, Chen X, Cai Y, et al. Risk factors associated with acute respiratory distress syndrome and death in patients with Coronavirus disease 2019 pneumonia in Wuhan, China. JAMA Intern Med. 2020. PubMed CrossRef

77.Wang D, Hu B, Hu C, et al. Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected pneumonia in Wuhan, China. JAMA. 2020;323(11):1061-1069. PubMed CrossRef

78.Guan WJ, Zhong NS. Clinical characteristics of Covid-19 in China: reply. N Engl J Med. 2020;382(19):1861-1862. PubMed

79.COVID-19: interim guidance on management pending empirical evidence. American Thoracic Society. https://www.thoracic.org/covid/covid-19-guidance.pdf. Published 2020. Accessed May 22, 2020.

80.COVID-19 rapid guideline: critical care in adults. National Institute for Health and Care Excellence website. https://www.nice.org.uk/guidance/ng159. Published 2020. Accessed May 22, 2020.

81.ICS guidance for prone positioning of the conscious COVID patient 2020. Intensive Care Society website. https://icmanaesthesiacovid-19.org/news/ics-guidance-for-prone-positioning-of-the-conscious-covid-patient-2020. Published 2020. Accessed May 22, 2020.

Related Articles

Volume: 22

Quick Links: COVID-19

$40.00

Buy this Article as a PDF