FormalPara Take-home message

Critical care patients with COVID-19 were disproportionately non-white, from more deprived areas and more likely to be male and obese. Conventional severity scoring appeared not to adequately reflect their acute severity, with the distribution across PaO2/FiO2 ratio categories indicating acutely severe respiratory disease. Critical care patients with COVID-19 experience high mortality and place a great burden on critical care services.

Introduction

Since originating in late 2019, in Wuhan China, severe acute respiratory syndrome coronavirus 2, the virus associated with coronavirus disease 2019 (COVID-19), has rapidly spread across the world [1]. As of 16 September 2020, almost 30 million cases were reported, associated with approaching one million deaths [2], including 41,664 in the United Kingdom (UK), representing unprecedented numbers of critically ill patients and intense demand on critical care services, globally [3, 4].

Accurate and reliable analyses of the epidemiology of COVID-19 in critical care are essential for monitoring patient outcomes and informing planning for future service provision [5]. In the UK, prior to the epidemic, as COVID-19 was a new disease, planning for service provision was informed by recent historic data on a likely similar condition and by emerging data from international cohorts of critical care patients with COVID-19. As the epidemic emerged, the Intensive Care National Audit & Research Centre (ICNARC), through its national clinical audit (the Case Mix Programme—CMP) was well placed to rapidly collate, analyse and report data on critical care patients with COVID-19.

Now, as the first wave of the epidemic is waning, the primary aim of this study was to describe the epidemiology of COVID-19 in critical care across the UK (England, Wales and Northern Ireland—the remit of the CMP). Our first objective was to describe the patient characteristics, acute illness severity, organ support and outcomes of critical care patients with COVID-19. Our second objective was to compare critical care patients with COVID-19 to a recent historic cohort of critical care patients with other viral pneumonias (non-COVID-19). Our third objective was to compare critical care patients with COVID-19 across reported international cohorts.

Methods

Data sources

Two cohorts of critical care patients admitted to critical care units participating in the CMP—one, prospective, of patients with confirmed COVID-19 (Objective 1) and one, recent but retrospective, of patients with other viral pneumonias (non-COVID-19) (Objective 2) and international cohorts of critical care patients with COVID-19 from published reports (Objective 3).

Data

For Objective 1, consecutive patients, from 1 February to 31 August, 2020, identified from their first admission with confirmed COVID-19 (confirmed either at or after the start of critical care) to one of 289 National Health Service (NHS) adult critical care units (standalone and combined intensive care/high dependency units) in England, Wales and Northern Ireland (100% coverage) routinely submitting data to the CMP. Comprehensive testing for COVID-19 was mandated in all NHS critical care units from 2 March 2020 [6]. Critical care patients with COVID-19 were defined as either those with a positive test (according to local practice) or those with a clinical diagnosis of COVID-19 in the context of a negative test where the treating clinical team were strongly convinced that the test was a false negative and the patient was treated as a confirmed COVID-19 patient.

For Objective 2, data for a historic cohort of critical care patients, between 1 January 2017 and 31 December 2019, with other viral pneumonias (non-COVID-19) were extracted from the CMP database. Other viral pneumonias (non-COVID-19) were identified where the primary reason for admission to critical care was coded as viral pneumonia using the ICNARC Coding Method (ICM) [7]. The ICM generates a hierarchical code based on selection of body system (respiratory), anatomical site (lungs), physiological/pathological process (infection), and final condition (viral pneumonia). Viral pneumonia could be influenza or non-influenza related. Codes for pneumonia of non-viral origin (e.g. bacterial, parasitic, etc.) or where no organism was isolated were excluded.

CMP data included a unique national patient identifier; patient characteristics, type and duration of organ support and outcome. Patient characteristics included date of birth; usual residential postcode; sex; ethnicity (using NHS ethnicity codes); height; weight; duration of hospital stay prior to critical care admission; source of admission to critical care; past medical history; level of care (intensive or high dependency) at admission; and lowest and highest values for specific physiological parameters during the first 24 h of admission. Past medical history data covered: prior dependency (based on levels of assistance with daily activities); and serious morbidities (cardiovascular, respiratory, renal, liver, metastatic disease, haematological malignancy and immunocompromise) evident in the prior 6 months.

At acute hospital discharge, data submitted included dates and times of critical care admission and discharge (including those for readmissions during the same acute hospital stay); calendar days (00:00 to 23:59) of organ support in critical care (respiratory, cardiovascular, renal, neurological), as defined by the NHS Critical Care Minimum Data Set (CCMDS) [8]; date of acute hospital discharge; and status at critical care unit and acute hospital discharge. The CMP has support for the collection and use of patient-identifiable data without consent under Section 251 of the NHS Act 2006 (approval number PIAG 2–10(f)/2005). As a service evaluation, approval from a Research Ethics Committee was not required (UK Health Research Authority).

For Objective 3, a literature search for international cohorts of critical care patients with COVID-19 was conducted. Reports including more than 5 sites and more than 200 patients were included.

Statistical analysis

For Objectives 1 and 2, multiple admissions for the same patient were linked using the unique national identifier (NHS number) and combined into a single patient record. Patient characteristics presented derive from the first critical care admission.

Age was derived from dates of birth and admission to critical care and categorised in three groups (< 50, 50–69, 70+). Recorded ethnicity codes were grouped into five categories (White, Asian, Black, Mixed/other and not stated). Patients' residential postcodes were linked to the index of multiple deprivation (IMD), assigned at the level of Lower Layer Super Output Area according to the 2019 Indices of Multiple Deprivation for England and Wales and the 2017 Multiple Deprivation Measure for Northern Ireland, and categorised at quintiles of the national distribution. Body mass index (BMI), calculated as weight (kg) divided by height (m) squared (where actual values not available, estimated values were used) was categorised into standard NHS BMI categories.

Prior dependency in relation to daily activities was considered in three categories: independent (no assistance); some dependency (minor or major assistance); and dependent (total assistance).

Prior hospital stay was calculated from dates of admission to acute hospital and to critical care. Source of admission to critical care was categorised into four groups (emergency department, ward, other hospital location or not in hospital).

The PaO2/FiO2 ratio (P/F ratio), derived from the arterial blood gas with the lowest PaO2 during the first 24 h, was categorised to reflect mild [> 200 mmHg (> 26.7 kPa)], moderate [> 100 and ≤ 200 mmHg (> 13.3 and ≤ 26.7 kPa)] and severe [≤ 100 mmHg (≤ 13.3 kPa)] acute respiratory distress syndrome (ARDS) [9].

Lowest and highest values for physiological parameters during the first 24 h of admission were used to calculated the Acute Physiology and Chronic Health Evaluation (APACHE) II [10] acute physiology score and the APACHE II score. The former (0–60) is based on weighting any deviation from the normal range for twelve physiological parameters [temperature, heart rate, respiratory rate, arterial pH, serum sodium, serum creatinine, white blood cell count, Glasgow Coma Score, mean arterial pressure, A-aDO2 (if FiO2 ≥ 0.5) or PaO2 (if FiO2 < 0.5), serum potassium and haematocrit (estimated from haemoglobin)]. The latter (0–71) adds additional weights for age and for serious comorbidities to the APACHE II acute physiology score.

Total duration of stay in critical care was calculated in calendar days from the dates of admission to and discharge from critical care, excluding any periods in the acute hospital stay outside critical care. In survival analyses, patients discharged from acute hospital prior to 90 days were assumed to be alive at 90 days.

Analyses used all available data and were conducted using Stata/SE version 16.1 (StataCorp LP). Levels of missing data are presented in eFigure 1. Descriptive statistics were used to summarise data, with results reported as means with standard deviations (SD), medians with interquartile ranges (IQRs), or counts and percentages, as appropriate. Results for age, sex, ethnicity and BMI were contextualised using general population data from the 2011 National UK censuses [11] and 2018 Health Survey for England [12]. For Objective 3, reported data were extracted from published reports and tabulated using a standardized data extraction form.

Results

Patient characteristics, acute illness severity, organ support and outcomes of critical care patients with COVID-19 (Objective 1)

Of 289 critical care units, 258 had at least one admission with COVID-19. In total, between 1 February and 31 August 2020, 10,834 patients with COVID-19 were admitted: 41% presenting as high dependency and 59% as intensive care patients. Patient characteristics, acute illness severity, organ support and outcomes are presented in Table 1. Patients had a median (IQR) age of 60 (51–68); just over 21% were aged under 50, with a similar proportion aged 70 or more. Over two-thirds (70.1%) were male and one-third (32.6%) were of non-white ethnicity. The median (IQR) BMI for the cohort was 28.3 (24.8–33) kg/m2; almost 40% were considered obese (BMI ≥ 30). Prior to admission, most (89.4%) were reported as being able to live independently and 8.2% had at least one documented serious comorbidity.

Table 1 Characteristics, acute illness severity, outcomes and organ support of critical care patients with COVID-19 compared with critical care patients with other viral pneumonias (non-COVID-19)

Males aged 50–79 years appeared over-represented, when compared with the age/sex distribution for the general population (Fig. 1A), while those of white ethnicity appeared under-represented, when matched on residential location for the general population (Fig. 1B). Critical care patients with COVID-19 were more likely to derive from deprived areas and more likely to be severely obese (BMI ≥ 40) compared with the general population (Fig. 1C, D).

Fig. 1
figure 1

Critical care patients with COVID-19 compared to the UK general population for age/sex, ethnicity, level of deprivation and body mass index

Over one-third of patients (36.9%) had a P/F ratio, derived from the arterial blood gas with the lowest PaO2 during the first 24 h, of ≤ 13.3 kPa (≤ 100 mmHg) consistent with severe ARDS. During the critical care unit stay, advanced respiratory support (invasive ventilation) was received by 72% of patients for a median (IQR) duration of 13 (7–23) calendar days. Advanced cardiovascular and renal support were received by 30.4% and 26.7% of patients for a median (IQR) of 3 (2–6) and 8 (3–15) days, respectively.

By critical care unit discharge, 4240 (39.1%) died and 6464 (59.7%) survived (with 1.2% still in critical care at database lock). By acute hospital discharge, 4554 (42%) died and 5868 (54.2%) survived (with 3.8% still in acute hospital at database lock). Critical care survivors stayed longer in the unit than non-survivors (median duration 12 versus 9 days). Outcomes, stratified by age/sex, P/F ratio categories, APACHE II acute physiology score and type and combinations of organ support received are presented in Fig. 2. Mortality increased with increasing age and severity of illness (either decreasing P/F ratio category or increasing acute physiology score). Most deaths (88.7%) and critical care unit discharges (79.6%) occurred before day 30 and most acute hospital discharges (90.2%) occurred before day 60 (Fig. 3).

Fig. 2
figure 2

Outcomes for critical care patients with COVID-19 by age/sex, P/F ratio categories (ventilated or not in the first 24 h), APACHE II acute physiology score and type and combinations of organ support received

Fig. 3
figure 3

Survival to acute hospital discharge for critical care patients with COVID-19. aPatients are included in this survival analysis at day 0 if they were admitted at least two weeks prior to data extraction and censored on subsequent days after reaching either their last known follow-up date, or at two weeks prior to data extraction (whichever was earliest)

Patient characteristics, acute illness severity, organ support and outcomes of critical care patients with COVID-19, stratified by P/F ratio category and by receipt (or not) of advanced respiratory support (invasive ventilation), are presented in eTables 1 and 2.

Comparison of critical care patients with COVID-19 to critical care patients with other viral pneumonias (non-COVID-19) (Objective 2)

In total, between 1 January 2017 and 31 December 2019, 5782 patients with other viral pneumonias (non-COVID-19) were admitted; 56.5% presenting as high dependency and 43.5% as intensive care patients. Patient characteristics, acute illness severity, organ support and outcomes are also presented in Table 1. Compared with critical care patients with COVID-19, median age was similar but a smaller proportion were male (54.3% versus 70.1%) and of non-white ethnicity (11.2% versus 32.6%). Critical care patients with other viral pneumonias (non-COVID-19) were more likely to have needed assistance with daily activities or to have severe conditions prior to hospitalisation than those with COVID-19. While the generic score (APACHE II) indicated slightly higher acute severity of illness for other viral pneumonias (non-COVID-19), lower P/F ratios derived from the arterial blood gas with the lowest PaO2 during the first 24 h, indicated greater severity of illness for critical care patients with COVID-19.

In-hospital mortality, whether in the critical care unit or in acute hospital, was lower for critical care patients with other viral pneumonias (non-COVID-19) compared with COVID-19, both overall and when stratified by age/sex, P/F ratio category, APACHE II acute physiology score and type and combinations of organ support received (Fig. 4). Duration of stay in critical care and in acute hospital was shorter for other viral pneumonias (non-COVID-19). A greater proportion of critical care patients with COVID-19 received organ support over a greater number of calendar days, in combinations similar to critical care patients with other viral pneumonias (eFigure 2).

Fig. 4
figure 4

Acute hospital mortality for critical care patients with COVID-19 compared with other viral pneumonias (non-COVID-19) by age/sex, P/F ratio category (ventilated or not in the first 24 h), APACHE II acute physiology score and type and combinations of organ support received

Comparison of critical care patients with COVID-19 across international cohorts (Objective 3)

With regard to international comparisons, 9 studies fulfilled the a priori inclusion criteria (5 sites, 200 patients) applied to indicate some degree of representativeness [13,14,15,16,17,18,19,20,21]. Meaningful comparisons were limited due to lack of standardised reporting (Supplement page 2 and eTable 3).

Discussion

In this manuscript, we set out to describe the epidemiology of COVID-19 in critical care. In our large, representative cohort (10,834 critical care patients with COVID-19 admitted across 289 critical care units) from England, Wales and Northern Ireland, critical care patients with COVID-19 were disproportionately from non-white ethnic groups, from more deprived areas and were more likely to be male and obese, relative to both the general population and to a historic cohort of critical care patients with other viral pneumonias (non-COVID-19). Additionally, relative to critical care patients with other viral pneumonias (non-COVID-19), patients with COVID-19 reported lower prior levels of dependency and of serious comorbidities.

Conventional severity scoring (APACHE II acute physiology score) appeared not to adequately reflect the acute severity of critical care patients with COVID-19. The distribution of critical care patients with COVID-19 across the more severe P/F ratio categories appeared to indicate a high degree of acute severity of respiratory disease and much higher than for critical care patients with other viral pneumonias (non-COVID-19), not captured by the APACHE II acute physiology score. Acute severity was also reflected in the high mortality for critical care patients with COVID-19, much higher than for critical care patients with other viral pneumonias (non-COVID-19)—both overall and when stratified by age/sex, P/F ratio category, APACHE II acute physiology score and by type and combinations of organ support received. Overall, critical care patients with COVID-19 placed a greater burden on critical care services when compared with critical care patients with other viral pneumonias (non-COVID-19), with higher proportions receiving organ support and for longer durations.

Clearly, any direct comparisons with critical care patients with other viral pneumonias (non-COVID-19) are challenging as the historic (2017–2019) cohort derived from a non-pandemic period. It is possible that when considering the cohort of critical care patients with COVID-19 admitted during the UK epidemic wave, perceived and/or actual health care system strain and availability of beds may have led to changing triage criteria for critical care admission. This said, at the peak of the epidemic, critical care bed capacity in England was expanded from a pre-pandemic total of 4122 critical care beds (7.4 beds per 100,000 population) to 7560 beds equipped for invasive ventilation and 3405 beds equipped for non-invasive ventilation (19.6 beds per 100,000 population) and reported occupancy of these expanded beds never exceeded 60%, nationally.

Comparison of summary statistics across reported international studies was challenging. Where comparisons were possible, available patient characteristics appeared similar but there was variation in rates of invasive ventilation and mortality. Our figures, however, are in line with a recent meta-analysis [22]. Even after considering the inherent difficulties of international comparisons, per se (e.g. system-level differences, beds per capita, staff to patient ratios, etc.) [23,24,25], there remains a need for greater standardisation in reporting of patient characteristics, acute illness severity, organ support and outcomes for critical care cohorts, particularly in the context of a global pandemic.

This study has strengths. A major one is the 100% coverage of critical care units across three nations of the UK (Scotland reports separately) across the whole epidemic wave. We built on the lessons learned from the H1N1 pandemic where our response was too slow [26, 27]. We expedited data collection, leveraging the existing high-quality clinical database of the CMP, for which data are prospectively defined and collected nationally by trained data collectors to precise rules and definitions, to which they were already familiar prior to the epidemic. The CMP database readily enabled comparison to recent historic data for patients with a relevant comparative condition [e.g. other viral pneumonias (non-COVID-19)]. We had a high level of completeness of outcome data (with only 3.8% still in acute hospital at database lock), comparing favourably with other reports [28,29,30] and we did not restrict our analyses to select groups.

This study has limitations. While comprehensive formal testing for COVID-19 was introduced in critical care units on 2 March 2020, it should be noted that, in an attempt to address the potential for false negatives, those patients with a clinical diagnosis of COVID-19 in the context of a negative test (less than 1%), where the treating clinical team were convinced that the test was a false negative, were included. Our historic cohort of other viral pneumonias (non-COVID-19) were those coded with a primary reason for admission to critical care for viral pneumonia and, as such, should be regarded solely as a presumptive diagnosis of viral pneumonia. While there were strengths in adhering to the well-known dataset of the CMP, this translated into not having certain key variables that emerged as being important as knowledge around COVID-19 developed (including more specific detail on use of treatments, such as specific types of respiratory support and pharmacologic agents received as others have reported [31, 32]). Additional data were not requested to minimize the demands on staff during the pandemic. We chose to publicly report the emerging data, weekly [33], to inform our health care providers, policy-makers and the public, and waiting to the end of the epidemic wave to describe the full cohort in its entirety.

In conclusion, our cohort of 10,834 critical care patients with COVID-19 were disproportionately from non-white ethnic groups, from more deprived areas and were more likely to be male and obese. Conventional severity scoring appeared not to adequately reflect their acute severity, with the distribution across P/F ratio categories appearing to indicate a high degree of acute severity of respiratory disease. Critical care patients with COVID-19 experience high mortality and place a great burden on critical care services. The observed differences when comparing critical care patients with COVID-19 to those with other viral pneumonias (non-COVID-19) demonstrated the difficulty of selecting a likely similar condition when service planning for an impending pandemic of a new disease. Thus, any service planning for a second wave should use accurate and reliable population-level data on patients with COVID-19. To support this, there is a need for greater standardisation in reporting of critical care cohorts internationally.