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. 2020 Aug 27;61:63–70. doi: 10.1016/j.jcrc.2020.08.018

Awake prone positioning for COVID-19 hypoxemic respiratory failure: A rapid review

Jason Weatherald a,1, Kevin Solverson b,1, Danny J Zuege b,c, Nicole Loroff a, Kirsten M Fiest b,d, Ken Kuljit S Parhar b,
PMCID: PMC7450241  PMID: 33096347

1. Background

Infection with SARS-CoV-2 can result in Coronavirus Disease–19 (COVID-19) [[1], [2]]. While the majority of patients are asymptomatic or have mild disease [3], approximately 14% develop more severe disease including hypoxemic respiratory failure and/or Acute Respiratory Distress Syndrome (ARDS) [3]. Prone positioning is a life-saving intervention for mechanically ventilated patients with moderate-severe ARDS [4]. Based on this, the World Health Organization (WHO) guidelines recommend these patients be considered for a trial of prone positioning [5].

Recently the use of prone positioning in awake non-intubated COVID-19 patients has been recommended by several notable organizations with the goal of preventing intubation and potentially improving patient-oriented outcomes [[6], [7]]. In contrast to prone positioning for intubated mechanically ventilated patients with ARDS, there have been no randomized control trials examining the role of awake prone positioning for non-intubated patients with hypoxemic respiratory failure. To further explore this question we used rapid review methodology Tricco et al. [8] to quickly identify and synthesize studies examining the effect of awake prone positioning on patients with hypoxemic respiratory failure (including those with ARDS and/or COVID-19).

2. Methods

We have elected to use “rapid review” methodology rather than “systematic review” methodology primarily due to the speed and efficiency through which we are able to conduct this review, as previously described [8]. In the absence of an EQUATOR guidance document, we used PRISMA guidelines where applicable [9].

Studies were included if they met the following criteria 1) population – non-intubated patients with hypoxemic respiratory failure, 2) intervention – prone positioning, 3) comparator – usual management, 4) outcomes – intubation, survival, change in respiratory parameters, adverse events, 5) setting – hospitalized patients 6) study design – observational or randomized control trial. Studies were not limited to ARDS or COVID-19 patients.

The search strategy was developed by a critical care physician (KP), a critical care epidemiologist (KF) and a medical librarian (NL) (See search details in Online Supplement). Briefly, the search strategy involved combinations of keywords and subject headings relating to the concepts of, 1) SARS-Cov-2 or COVID-19 or coronavirus, 2) awake prone positioning, and 3) hypoxemic respiratory failure, including but not limited to ARDS and other potentially relevant conditions. The search was conducted on May 19, 2020 and was updated on August 7, 2020 with no restrictions on publication language or date. Databases and grey literature sources searched included: MEDLINE (Ovid), PubMed, Trip PRO, Cochrane Library, LitCOVID, WHO COVID-19 Research Database, Centre for Evidence-Based Medicine (CEBM), National Institute for Health and Care Excellence (NICE), medRxiv, BMJ Best Practice, Cambridge Coronavirus Free Access Collection, and Google Scholar. Titles and abstracts were reviewed independently and in duplicate (KP and JW) for selection for full text review. Disagreements were resolved through discussion or with a third reviewer (KS). Full text review and data abstraction was conducted independently and in duplicate (KP, KS, JW). Data abstracted included study characteristics, participant demographics, and outcomes.

3. Results

The search yielded 181 unique articles. From this, 162 articles were selected for full text review and 35 articles met inclusion criteria and were included in the final rapid review synthesis. A total of 35 studies (including 12 prospective cohorts, 18 retrospective cohorts, and 5 case reports) with 414 patients were synthesized (see Table 1 for COVID-19 studies and Table 2 for non-COVID-19 studies) [[10], [11], [12], [13], [14], [15], [16], [17], [18], [19], [20], [21], [22], [23], [24], [25], [26], [27], [28], [29], [30], [31], [32], [33], [34], [35], [36], [37], [38], [39], [40], [41], [42], [43], [44]]. Twenty-nine of these studies (n = 364 patients; 11 prospective cohorts, 13 retrospective cohorts, 5 case reports) report on the use of awake prone positioning in COVID-19 patients [[10], [11], [12], [13], [14], [15], [16], [17],[19], [20], [21],[24], [25], [26], [27], [28], [29],[31], [32], [33],[35], [36], [37], [38], [39],[41], [42], [43], [44]]. Only one study included data from a control group [44]. Seventeen studies (128 patients) were conducted exclusively within the ICU [12,[16], [17], [18], [19],22,23,25,[29], [30], [31],34,35,37,[40], [41], [42]], two in the emergency department (60 patients) [10,13], eight exclusively on a non-ICU hospital ward (104 patients) [14,20,21,27,28,32,33,38], and two studies included patients in multiple settings (73 patients) [15,36]. The setting was not reported in 6 studies (49 patients) [11,24,26,39,43,44]. The frequency and duration of prone positioning was protocolized in only 15 studies (223 patients) [10,[14], [15], [16],18,19,25,26,28,30,31,38,39,43,44]. The duration of prone positioning sessions varied from <1 h to >18 h (Tables 1 and 2) and was not reported in three studies [13,26,27]. All studies demonstrated improvements in oxygenation while patients were in the prone position except one [17]. When reported, improvements in oxygenation were generally not sustained after returning to the supine position, [15,20,31,[34], [35], [36]] except in two studies in which patients were receiving NIV [33,40]. One hundred twenty-one patients (29%) of the 414 patients (35 studies) required invasive mechanical ventilation. Adverse events were variably reported and included 42 deaths among the 414 patients (10.1% of all patients), discomfort, nosebleeds, sternal pain, back pain, and intolerance of awake prone positioning. Follow-up duration was variably reported (Table 1, Table 2) and was not reported in eight studies [17,18,[22], [23], [24], [25],30,31].

Table 1.

Characteristics of studies examining awake prone positioning in non-intubated patients with hypoxemic respiratory failure due to COVID-19.

Author Study Type N Inclusion Criteria Exclusion Criteria Setting Oxygen Delivery Mode Prone Positioning Protocol Study Outcome Duration of Follow-up Duration of Prone Positioning Supine Oxygenation and Resp Rate (if available)
mean (SD), median [IQR]		 Prone Position Oxygenation and Resp Rate (if available) mean (SD), median [IQR] Intubation Rate, No. (%) Adverse Event Reporting
Coppo (2020) PC 56 Age 18–75, confirmed COVID-19, hypoxemia consent Pregnant, uncollaborative, altered mental status, NYHA < II, increased BNP, COPD on home NIV or O2, impending intubation Non-ICU Medical units, ED, ICU Helmet CPAP, Reservoir mask, Venturi mask Assisted proning, encouraged to maintain x 3 h, Repeat up to 8 h/d PaO2:FiO2 Hospital discharge Median 3 h [3, 4]
Up to 7 sessions.		 PaO2:FiO2 180.5 (76.6)
RR 24.5 (5.5)		 PaO2:FiO2 285.5 (112.9)
RR 24.5 (6.9)		 18/56 (32) 9% discomfort
4% worsening oxygenation
2% coughing
5 deaths (9%)
Golestani-Eraghi (2020) PC 10 COVID-19, not mech ventilated, PaO2:FiO2 < 150 Not reported ICU Helmet NIV 2 h sessions Not reported Not reported Mean 9 h PaO2 46.3 (5.2) PaO2 62.5 (4.6) 2/10 (20%) None reported
2 deaths (20%)
Moghadam (2020) PC 10 COVID-19, not mech ventilated Not reported Non-ICU Medical unit Not reported Not reported SpO2, RR, auxiliary muscle use Hospital discharge Not reported SpO2 86% (0.7) SpO2 96% (2.2) 0/10 (0) Not reported
Elharrar (2020) PC 24 Hypoxemia, CT chest with COVID-19 and posterior lesions Requiring intubation, altered consciousness Non-ICU Medical unit NP, facemask, HFNC Single episode, no goal duration Proportion of patients with PaO2 increase ≥20%from supine to PP 10 days 17% <1 h
21% 1–3 h
63% >3 h		 PaO2 72.8 (14.2) PaO2 91 (27.3)
25% had ≥20% increase PaO2		 5/24 (20.8) 42% backpain
17% tolerated <1 h
17% required intubation within 72 h
Ng (2020) PC 10 Hypoxemia Drowsy, uncooper-ative, ophthalmic or cervical pathology, pregnancy, hemodyn-amic instability, FiO2 > 0.5 Non-ICU Medical unit NP, HFNC, or Venturi mask 1 h sessions, 5 sessions/d
spaced 3 h apart. Continued until on RA x 24 h		 Not reported Median 8 days (range 2–19) Median total duration 21 h (range 2–58) SpO2 91.5 (range 88–95) Not reported 1/10 (10) Discomfort, nausea, vomiting reported
1 death (10%)
Retucci (2020) PC 26 COVID-19, spontane-ous breathing, GCS = 15, PaO2:FiO2 < 250 after 48 h Helmet CPAP Requiring intubation, GCS < 15, SBP < 90, SpO2 < 90% on FiO2 > 0.8 ICU Helmet CPAP Prone/lateral positioning based on CXR or CT scan, 1 h sessions.
39 sessions:
12 prone, 27 lateral		 Successful trial, defined as all 4 of:
1. decrease A-aO2 gradient ≥20%, 2. equal or reduced RR, 3. equal or reduced dyspnea
4. SBP ≥ 90 mmHg		 Not reported 1 h PaO2:FiO2 182.9 (43)
A-aO2 207.1 [160.7–251.3]
RR 23.7 (4.7)		 PaO2:FiO2 220 (64.5)
A-aO2 184.3 [141.4–246.8]
RR 23.1 (4.5)		 7/26 (27) 39% of trials did not meet primary outcome.
25% of prone position trials failed
40% of lateral position trials failed
8% did not tolerate (both in lateral position)
5% discomfort
3% SBP < 90 mmHg
8% increased RR
2 deaths (8%)
Sartini (2020) PC 15 Hypoxemia (SpO2 < 94%), FiO2 > 0.6 and CPAP 10 cm H2O Non-ICU Medical Unit NIV Not reported PaO2:FiO2, RR, patient comfort with NIV 14 days Median 3 h (IQR 1–6) PaO2:FiO2 58–117**
Supine RR: 21–31**		 PaO2:FiO2 114–122**
PP: 18–27**		 1/15 (6.6) 1 death (7%)
Thompson (2020) PC 29 Confirmed COVID-19, Severe hypoxemia (RR > 30 and SpO2 < 93% on 6 L O2 by NP and 15 L by NRB Altered mental status, inability to turn without help, immediate intubation needed, mild hypoxemia. Step-down unit (interme-diate) NP or NRB Repeated episodes, up to 24 h per day, use a pillow under hips/pelvis. Change in SpO2 at 1 h Up to 49 days or to hospital discharge Median 4 h (range 1–24) in not-intubated group, Median 6 h (range 1–24) in intubated group.
 SpO2 65–95%** SpO2 90–100%**
Median SpO2 improvement 7% [4.6–9.4]		 16/29 (55) 13% refused
3 deaths (10%)
Tu (2020) PC 9 COVID-19 confirmed, HFNC >2 days, PaO2:FiO2 < 150 Not reported HFNC Repeated episodes, as long as tolerated SpO2
PaO2 		Hospital discharge, mean LOS 28 (10) d Median 2 h [1–4] per session, median 5 [3–8] sessions SpO2 90% (2)
PaO2 69 (10)		 SpO2 96% (3)
PaO2 108 (14)		 2/9 (22) None reported
1 intubated patient required ECMO
0 deaths (0%)
Caputo (2020) PC 50 Hypoxemia (SpO2 < 90%) NIV use, DNR order ED NP or facemask Not reported SpO2 5 min after PP, intubation rate within 24 h 3 days Not reported SpO2 84% [75–90] SpO2 94% [90–95] 13/50 (26.0) 22% required intubation within 60 min
Zhang (2020) PC 23 COVID-19, Hypoxemia (SpO2 < 90%), Age 18–80, consent Need for intubation, inability to self position, basal lung disease, unstable spine, high ICP, severe burns, abdo surgery, abdo HTN, cranial injury, tracheotomy, immuno-suppresion, pregnant, imminent death. Not reported NP, HFNC, NIV Evaluated muscle strength first, self position prone, 1-2 h sessions 3–4 times/day for 5 days. Vitals measured at 10 min and 30 min in PP SpO2, RR, ROX 90 days Median 9 h [8–22] SpO2 91.1 (1.5), RR 28.2 (3.1)
ROX 3.35 (0.46)		 SpO2 95.5 (1.7)
RR 24.9 (1.8)
ROX 3.96 (0.45)		 8/23 (35) 10 deaths (43%)
Bastoni (2020) RC 10 Receiving helmet NIV, awake & able to prone Need for rapid intubation & ICU, End-stage comorbid disease ED Helmet CPAP 10–20 cmH2O Nurse assisted, Morphine infusion for sedation. PaO2:FiO2, Lung US signs Hospital discharge 1 h PaO2:FiO2 68 (5) PaO2:FiO2 97 (8)
No change in lung US findings		 6/10 (60) 40% did not tolerate or refused.
4 deaths (40%)
Burton-Papp (2020) RC 20 COVID-19, Hypoxemia, received CPAP or NIV ICU CPAP or NIV Not described ΔP/F Hospital discharge Median 3 [2]
Median 5 cycles per patient [6.25]		 ΔPaO2/FiO2 + 28.7 [95%CI 18.7–38.6]
ΔRR −0.98 [95%CI -2-0.04]		 7/20 (35) None reported
2 intubated patients required ECMO
0 deaths
Cohen (2020) RC 2 52 Female
40 Male		 Non-ICU Medical unit HFNC, NP Self-prone as long as possible Discharge from unit 2–4 h per day Patient 1. SpO2 90% on HFNC FiO2 1.0, RR 45
Patient 2. SpO2 92% on 4 L		 Patient 1. SpO2 100% on HFNC FiO2 1.0, RR 25
Patinet 2. SpO2 96% on 2 L		 0/2 (0) None reported
Damarla (2020) RC 10 Confirmed COVID-19, rapidly increasing O2 requiring ICU Requiring intubation ICU NP or HFNC Alternate prone/supine every 2 h, supervised first episode SpO2, RR at 1 h 28 d 2 h SpO2 94% [91–95]
RR 31 [28–39]		 SpO2 98 [97–99]
RR 22 [18–25]		 2/10 (20) None
0 deaths
Despres (2020) RC 6 COVID-19, PaO2:FiO2 ≤ 300 Requiring intubation ICU NP, HFNC As long as tolerated PaO2:FiO2 Not reported Median 2 h [1–7] PaO2:FiO2 183 [144–212] PaO2:FiO2 168 [156–225] 3/6 (50%) Not reported
Dong (2020) RC 25 COVID-19, Severe disease (RR ≥ 30, SpO2 ≤ 93% or PaO2:FiO2 〈300), or critical disease (Requiring ventilation, shock, organ failure) Excluded patients who received PP but rapidly improved or who did not tolerate first session. ICU NP, Mask, HFNC, NIV Daily session >4 h, nurse instructions, lateral positioning if PP not tolerated Survival, intubation, PaO2:FiO2 Hospital discharge Mean 4.9 h (SD 3.1) PaO2:FiO2 194 [164–252]
RR 27 [26–30]		 PaO2:FiO2 348 [288–390]
RR 22 [20−22]		 0/25 16% Sternal pain
4% Scrotal pain
4% Lumbago
4% Pruritis
0 deaths
Froelich (2020) RC 3 Confirmed COVID-19 Not reported NP. Face Mask, HFNC Varied positions, supine, lateral, prone, ergonomic prone. SpO2 Not reported <30 min Patient 1. SpO2 94% on 4 L
Patient 2. SpO2 95% on 6 L
Patient 3. SpO2 91% on 15 L		 Patient 1. SpO2 97% on 4 L
Patient 2. SpO2 97% on 6 L
Patient 3. SpO2 95% on 15 L (lateral position only)		 0/3 (0) 33% Hip and back pain
33% Inability to maintain prone position due to jaw dislocation
Huang (2020) RC 3 SpO2 < 92% on ≥6 L or PaO2:FiO2 < 200, bilateral opacities, RR < 30 Accessory muscle use, Contraindic-ations (cervical instability, pregnancy) Not reported HFNC, Venturi mask Four 2 h sessions daily PaO2:FiO2 Up to 6 days Not reported Patient 1. PaO2:FiO2 84.8
Patient 2. PaO2:FiO2 160
Patient 3. PaO2:FiO2 60.6		 Patient 1. PaO2:FiO2 114
Patient 2. PaO2:FiO2 169
Patient 3. PaO2:FiO2 133		 1/3 (33) Not reported
Paul (2020) RC 2 42 Male
35 Male		 ICU HFNC, NIV Not reported Hospital discharge 2–3 h sessions, over 3 days Patient 1. SpO2 92% on FiO2 0.7
Patient 2. FiO2 0.8		 Patient 1. SpO2 98% on FiO2 0.5
Patient 2. FiO2 0.4		 0/2 (0) Anxiety and discomfort in both patients
Ripoll-Gallardo (2020) RC 13 PaO2:FiO2 < 150 Requiring intubation, hemodyn-amic instability, multiorgan failure Non-ICU Medical unit Helmet CPAP Encouraged as long as possible PaO2:FiO2 Hospital discharge Mean 2.4 h (SD 0.87) PaO2:FiO2 113 [108–121] PaO2:FiO2 138 [126–178] 9/13 (69) No complications
7 deaths (54%)
Solverson (2020) RC 17 Suspected or confirmed COVID-19, ICU consult, Hypoxemia (5 L to maintain SpO2 ≥ 90%), at least 1 prone session ICU, non-ICU medical ward NP, HFNC Encouraged as long as possible SpO2
Tolerability		 Hospital discharge 35% < 1 h
Median 75 min (range 30–480), Median 2 sessions (range 1–6) per day		 SpO2 91% (range 84–95)
RR 28 (range 18–38)
SpO2:FiO2 152 (range 97–233)		 SpO2 98% (range 92–100)
RR 22 (range 15–33)
SpO2:FiO2 165 (range 106–248)		 7/17 (41) 47% pain/discomfort
6% delirium
2 deaths (12%)
Sztajnbok (2020) RC 2 43 Male
37 Male		 ICU NRB Encouraged as long as possible ICU discharge 8–10 h, single sessions Patient 1. SpO2 100% on 10 L, RR 30
Patient 2. SpO2 94% on 10 L, RR 28		 Patient 1. Decreased to 5 L
Patient 2. SpO2 96% on 3 L, RR 22		 0/2 (0) Not reported
Xu (2020) RC 10 COVID-19 confirmed, Not reported Target 16 h/d, target SpO2 > 90% PaO2:FiO2 Hospital discharge, mean LOS 17.7 d 4–6 h sessions PaO2:FiO2 89–228 PaO2:FiO2 200–325** on day 3 of PP 0/10 (0) 0 deaths
Cascella (2020) CR 1 54 Male
Received tocilizumab		 Not reported NIV 3 sessions per day PaO2:FiO2 Hospital discharge Mean 90 min per session PaO2:FiO2 150 PaO2:FiO2 300 0/1 (0) Not reported
Vibert (2020) CR 1 23 Female
pregnant
Hypoxemia		 ICU HFNC and NIV Not reported Hospital discharge 2 h periods SpO2 89%, FiO2 0.6, 60 L/min SpO2 96%, FiO2 0.6, 60 L/min 0/1 (0) No adverse patient or fetal events
Elkattawy (2020) CR 1 36 Male Hypoxemia Non-ICU Medical unit NP Not reported 1 day >12 h per day SpO2 94%, 4 L/min NP SpO2 95%, room air 0/1 (0) Not reported
Slessarev (2020) CR 1 68 Male Hypoxemia ICU HFNC Not reported 4 days 16–18 h per day PaO2:FiO2 100** PaO2:FiO2 250** 0/1 (0) 1 Nosebleed
Whittemore (2020) CR 1 60 Male Hypoxemia ICU NRB Not reported SpO2 Hospital discharge >18 h per day SpO2 82% on 12 L NRB SpO2 94% on 12 L NRB 0/1 Not reported
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* High flow nasal cannula success/failure, ** Range, estimated from a figure. Abbreviations: ARDS, acute respiratory distress syndrome; BNP, B-type natriuretic peptide; CPAP, continuous positive airway pressure; CR, case report; CT, computed tomography; DNR, do not resuscitate; ECMO, extracorporeal membrane oxygenation; ED, emergency department; FiO2, fraction of inhaled oxygen; GCS, Glasgow Coma Scale; HFNC, high-flow nasal cannula; HFPV, high-frequency percussive ventilation; HTN, hypertension; ICP, intracranial pressure; ICU, intensive care unit; IQR, interquartile range; LOS, length of stay; NIV, non-invasive ventilation; NP, nasal prongs; NRB, non-rebreather face mask; NYHA, New York Heart Association; PaO2, partial pressure of arterial oxygen; PC, prospective cohort; PP, prone position; RC, retrospective cohort; RA, room air; ROX, ROX index = SpO2/FiO2 x 1/respiratory rate; RR, respiratory rate; SBP, systolic blood pressure; SD, standard deviation; SpO2, oxygen saturation; US, ultrasound.

Table 2.

Characteristics of Studies Examining Awake Prone Positioning in Non-intubated Patients with Hypoxemic Respiratory Failure not due to COVID-19.

Author Study Type N Inclusion Criteria Exclusion Criteria Setting Oxygen Delivery Mode Prone Positioning Protocol Study Outcome Duration of Follow-up Duration of Prone Positioning Supine Oxygenation and Resp Rate (if available)
mean (SD), median [IQR]		 Prone Position Oxygenation and Resp Rate (if available)
mean (SD), median [IQR]		 Intubation Rate, No. (%) Adverse Event Reporting
Ding (2020) PC 20 ARDS (Berlin) on NIV with CPAP 5 cm H2O and PaO2:FiO2 < 200 Requiring intubation ICU HFNC or NIV >30 min, 2 times daily for 3 days Intubation rate, change in PaO2:FiO2 Not reported Mean 2 h PaO2:FiO2 95 (22) / 102 (15)* PaO2:FiO2 130 (35) / 113 (25)* 9/20 (45.0) 2 non-tolerant
1 death (5%)
Perez-Nieto (2020) RC 6 ARDS (Berlin criteria) non-infections ARDS, and PaO2:FiO2 < 100 ICU HFNC or NIV 2–3 h, 2 times daily for 2 days Not reported 2–3 h every 12 h PaO2:FiO2 80
[67–91]		 PaO2:FiO2 116
[101−131]		 2/6 (33.3) 1 death (17%)
Scaravilli (2015) RC 15 PaO2:FiO2 < 300, and undergone one PP without intubation ICU NP, HFNC or NIV Not reported Change in PaO2:FiO2 Hospital discharge Median 3 (IQR 2–4) PaO2:FiO2 127(49)
RR: 26 (10)		 PaO2:FiO2 186 (72)
RR: 25 (11)		 2/15 (13.3) No displaced catheters, pressure sores, neuropathy, vomiting, change in hemodynamics or vasopressors
2 patients non-tolerant, 3 patients died without intubation: 2 patients put on ECMO before intubation, and 1 patient changed goals of care
Feltracco (2012) RC 3 Post lung transplant, and hypoxemia ICU HFPV Not reported Not reported 1–3 h 5–6 times per day, 1 h 3–4 times per
Day		 0/1 (0) Not reported
Feltracco (2009) RC 2 Post lung transplant, and hypoxemia ICU NIV Not reported Not reported 6-8 h per day FiO2 0.80 FiO2 0.60 0/1 (0) Not reported
Valter (2003) RC 4 Hypoxemia ICU NIV Not reported Hospital discharge 1–5 h FiO2 0.70 [0.60–0.70]
RR: 31 (26–38)		 FiO2 0.40 [0.30–0.50]
RR: 20 (18–21)		 0/1 (0) Not reported
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4. Discussion

In this rapid review, we present a synthesis of 35 studies (414 patients) that examined the use of awake prone positioning for non-intubated patients with hypoxemic respiratory failure. There has been significant attention on its use as a potential treatment for COVID-19 through news organizations, social media, and institutional guidelines. However, the evidence to support prone positioning in this population is limited to uncontrolled prospective or retrospective cohorts and case reports with small sample sizes and limited follow-up.

The cohorts and case studies in this rapid review describe an improvement in oxygenation while patients were in the prone position. The impact of improved oxygenation on clinical outcomes such as survival remains unclear. In contrast to non-intubated patients, prone positioning invasively ventilated patients with moderate-severe ARDS within an ICU is a proven life-saving intervention and is supported by meta-analyses of randomized control trials [4,45,46]. Although many invasively ventilated patients improve their oxygenation when in the prone position, these changes are not associated with survival [47]. The survival benefit is more likely mediated through a reduction in ventilator induced lung injury and not improved oxygenation [47]. Given that non-intubated patients are not at risk for ventilator induced lung injury, potential clinical benefits may be mediated through improved oxygenation, preventing intubation (which can be influenced by clinician decision making and bias), reduced respiratory work, or a reduction in patient self-inflicted lung injury [48].

In this synthesis, many patients receiving awake prone positioning were treated in monitored settings and not general wards (182 of 414 patients, 44%). Key details to offer this intervention safely such as the frequency, duration and adverse events were often not described or provided in limited detail. In six studies, awake prone positioning was not tolerated by some patients for even short durations [10,18,20,24,34,36]. Invasively ventilated patients with ARDS require greater than 12 h of prone positioning to receive a mortality benefit from prone positioning, which often requires sedation and paralysis to be tolerated [45,46]. Furthermore, patients included in this rapid review were heterogeneous in terms of hypoxemia severity. Prone positioning invasively ventilated patients is only beneficial in moderate-severe ARDS, not all severities of hypoxemia [45].

In summary, although awake prone positioning may be a promising therapy for patients with hypoxemic respiratory failure (including those with COVID-19), the supporting evidence is limited to case reports and cohort studies. These studies, when synthesized, highlight the lack of key details to inform clinicians and trialists. Many questions remain unanswered when considering the use of awake prone positioning. What are the effects on patient outcomes? What is the optimal frequency and duration? What are the criteria for stopping prone positioning? Which patients are most likely to benefit and which ones should be excluded? What are the potential adverse events that could occur? Ongoing randomized controlled trials (NCT04402879, NCT04383613, NCT04383613, NCT04350723, NCT04365959, NCT04347941) will be crucial in answering these questions.

Funding

None.

Declaration of Competing Interest

Authors do not report any conflicts of interest.

Appendix A. Supplementary data

Supplementary material

mmc1.pdf (144.9KB, pdf)

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