key: cord-0024593-yani8te6
authors: Hsu, Cindy H.; Considine, Julie; Pawar, Rahul D.; Cellini, Jacqueline; Schexnayder, Stephen M.; Soar, Jasmeet; Olasveengen, Theresa M.; Berg, Katherine M.
title: Cardiopulmonary resuscitation and defibrillation for cardiac arrest when patients are in the prone position: A systematic review
date: 2021-12-04
journal: Resusc Plus
DOI: 10.1016/j.resplu.2021.100186
sha: d23e9edc2c6be6ae6f1461523a69a9e1959646ea
doc_id: 24593
cord_uid: yani8te6

AIM: To perform a systematic review of cardiopulmonary resuscitation (CPR) and/or defibrillation in the prone position compared to turning the patient supine prior to starting CPR and/or defibrillation. METHODS: The search included PubMed, Embase, Web of Science, Cochrane, CINAHL Plus, and medRxiv on December 9, 2020. The population included adults and children in any setting with cardiac arrest while in the prone position. The outcomes included arterial blood pressure and end-tidal capnography during CPR, time to start CPR and defibrillation, return of spontaneous circulation, survival and survival with favorable neurologic outcome to discharge, 30 days or longer. ROBINS-I was performed to assess risk of bias for observational studies. RESULTS: The systematic review identified 29 case reports (32 individual cases), two prospective observational studies, and two simulation studies. The observational studies enrolled 17 patients who were declared dead in the supine position and reported higher mean systolic blood pressure from CPR in prone position (72 mmHg vs 48 mmHg, p < 0.005; 79 ± 20 mmHg vs 55 ± 20 mmHg, p = 0.028). One simulation study reported a faster time to defibrillation in the prone position. Return of spontaneous circulation, survival to discharge or 30 days were reported in adult and paediatric case reports. Critical risk of bias limited our ability to perform pooled analyses. CONCLUSIONS: We identified a limited number of observational studies and case reports comparing prone versus supine CPR and/or defibrillation. Prone CPR may be a reasonable option if immediate supination is difficult or poses unacceptable risks to the patient.

Prone positioning is recommended for severe hypoxemic respiratory failure, based on clinical trial data showing decreased mortality with this treatment. 1 It has been utilized increasingly since the COVID-19 pandemic for patients with acute respiratory distress syndrome (ARDS) and severe hypoxemia. Multiple investigators have reported improvements in hypoxemia related to COVID-19 with prone positioning in patients being treated with invasive mechanical ventilation, extracorporeal life support, and those on noninvasive respiratory support (e.g. high-flow nasal cannula or continuous positive airway pressure). [2] [3] [4] [5] Due to this increased use of prone positioning, the question of how to proceed when a patient has a cardiac arrest while in the prone position has become increasingly relevant. Patients who are prone when they experience a cardiac arrest, especially if intubated and sedated, can be challenging to turn supine quickly. Furthermore, turning such a patient supine prior to starting cardiopulmonary resuscitation (CPR) will necessarily lead to some delay in chest compressions. The prior recommendation from the American Heart Association (AHA) has been to perform CPR in the supine position whenever possible, only performing CPR with a patient in the prone position if supination is not feasible or safe. 6, 7 Interim COVID-19 guidance for cardiac arrest from the AHA states that leaving patients with an advanced airway in the prone position for CPR with hands in the standard position over the T7/10 vertebral bodies should be considered unless they can safely and rapidly be turned supine. 8, 9 The interim guidance on COVID-19 from the International Liaison Committee on Resuscitation (ILCOR) did not provide any treatment recommendations regarding CPR in the prone position. 10 In 2020, the ILCOR Advanced Life Support (ALS) and Basic Life Support (BLS) Task Forces determined that there was sufficient need for guidance on the best approach to initiating CPR in prone patients, and that a new Consensus on Science and Treatment Recommendations (CoSTR) should be developed. ILCOR generates CoSTRs, based on systematic reviews, to provide some guidance that can then be used for regional and national councils to develop their own guidelines as they deem appropriate. Two scoping reviews and one systematic review have been published recently on the topic of CPR in the prone position. [11] [12] [13] However, the previous systematic review 11 did not include patients who suffered from cardiac arrest while prone and were turned supine prior to initiation of CPR, limiting any ability to compare the two approaches. The scoping reviews 12,13 did not include bias assessments or certainty of evidence, and therefore cannot be used to generate new ILCOR treatment recommendations.

The ILCOR ALS and BLS Task Forces, together with the Paediatric Life Support Task Force, therefore proceeded with the following systematic review to determine whether performing CPR and/or defibrillation while the cardiac arrest patient remains in the prone position as compared to turning the patient supine prior to initiation of CPR and/or defibrillation improve clinical outcomes to inform the 2021 ILCOR CoSTR. 14 

The protocol for this review was prospectively submitted to the International Prospective Register of Systematic Reviews (PROSPERO) on January 11, 2021 (registration number CRD42021230691). The protocol is provided in the Supplemental contents. This systematic review followed the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines. 15 The PRISMA checklist is provided in the Supplementary contents. This review was commissioned at no cost by ILCOR and was carried out by ILCOR Task Force (unpaid) members and other volunteers.

The study question was framed using the PICOST (Population, Intervention, Comparison, Outcome, Study Design, Time frame) format: in adults and children in any setting (in-hospital or out-of-hospital) with cardiac arrest occurring while in the prone position (P), does performing CPR and/or defibrillation while the patient remains in the prone position (I) as compared to turning the patient supine prior to initiation of CPR and/or defibrillation (C) improve clinical outcomes (O).

Relevant outcomes were prioritized by the ILCOR ALS and BLS Task Forces and based on the available literature. We included arterial blood pressure during CPR, time to initiation of CPR, time to defibrillation for shockable rhythms during CPR, end-tidal carbon dioxide (ETCO2) during CPR, return of spontaneous circulation (ROSC), survival and survival with favorable neurologic outcome to discharge, 30 days or longer.

Randomized controlled trials (RCTs) and non-randomized studies (non-randomized controlled trials, interrupted time series, controlled before-and-after studies, cohort studies), case series, case reports, simulation studies, and animal studies were eligible for inclusion. Case series and case reports were included as the writing group was aware that the human data on prone CPR are extremely limited, consisting primarily of case reports. Unpublished studies (e.g., conference abstracts, trial protocols) and editorials were excluded, although case reports published in letter form were included. Scoping reviews and systematic reviews were included for discussion and to assure no primary papers were missed, but data were not extracted from these reviews.

All years and languages were included as long as there was an English abstract. The search was conducted on December 9, 2020 and included the databases of PubMed, Embase, Web of Science, Cochrane, CINAHL Plus, and medRxiv. Clinicaltrials.gov and PROS-PERO were searched for ongoing or other completed studies. The search strategy is provided in the Supplemental content.

Two reviewers, using pre-defined screening criteria, independently screened all titles and abstracts retrieved from the systematic search. Any disagreements regarding inclusion or exclusion were resolved by discussion between the reviewers and with two additional reviewers as needed. The Kappa-values for interobserver variance were calculated. The two reviewers then reviewed the full textreports of all potentially relevant publications passing the first level of screening. Any disagreement regarding eligibility was resolved by discussion.

Two reviewers, using a pre-defined standardized data extraction form, extracted data from individual studies. Any discrepancies in the extracted data were identified and resolved by discussion and consensus.

Four investigators (working in pairs of two) independently assessed risk of bias using the ROBINS-I tool for observational studies 16 and a tool adapted from Murad et al. to assess the methodological quality of case reports. 17 For ROBINS-I, risk of bias is assessed within domains including: (1) bias due to confounding, (2) bias in selection of participants into the study, (3) bias in classification of interventions, (4) bias due to deviations from intended interventions (5) bias due to missing data, (6) bias in measurement of outcomes, (7) bias in selection of the reported result, and (8) overall bias. 16 The methodological quality of case reports was assessed using four domains: selection, ascertainment, causality, and reporting. 17 Disagreements were resolved by discussion. Risk of bias was assessed by outcome but reported by study, as the risk of bias was similar across outcomes.

From the writing group's knowledge of the evidence, it was thought that the risk of bias in the available evidence, consisting primarily of case reports and small observational studies, would be too high to allow for meta-analysis. A narrative synthesis was therefore the primary plan, but the approach to meta-analysis and assessment of heterogeneity in the case of evidence being more robust than anticipated was detailed in the protocol, which is provided in the Supplemental content. If feasible, we planned to provide the narrative synthesis for adult and paediatric studies separately, medical and surgical cases separately, as well as for the entire group.

Our search identified 823 unique titles/abstracts, of which 738 were excluded based on initial review of the abstracts (Kappa = 0.66). After full-text review of 85 papers, an additional 60 studies were excluded, and 7 were added after review of bibliographies of prior review papers identified, leaving 32 studies for inclusion (Kappa for full text review = 0.94; Fig. 1 PRISMA) . In total, 29 case reports (describing 32 individual cases), 2 prospective nonrandomized studies, one simulation study, and one simulation study reported in conjunction with one of the 29 case reports were included. A tabulated overview of these studies is provided in the Supplemental content.

We identified only two human observational studies, enrolling a total of 17 patients in the intensive care unit who had already been declared dead due to failure to achieve ROSC with conventional CPR in the supine position. 9, 18 These studies were deemed at critical risk of bias due primarily to confounding and, in the case of one study, 18 incomplete reporting of the outcome (Table 1 ). Due to the critical risk of bias, no meta-analysis was performed. Certainty of evidence assessed as very low for both studies due to risk of bias, indirectness, and imprecision (Table 1 ). Blood pressure during CPR was the only reported outcome, and the investigators compared blood pressure achieved with prone compressions to blood pressure during compressions delivered with the patient supine. Both studies reported significantly higher mean systolic blood pressure during prone compressions (72 mmHg vs 48 mmHg, p < 0.005 9 , 79 ± 20 mmHg vs 55 ± 20 mmHg, p = 0.028 18 , while only one found a significant increase in mean diastolic pressure with prone compressions (34 mmHg vs 24 mmHg, NS 9 , 17 ± 10 mmHg vs 13 ± 7 mmHg, p = 0.028 18 . Supine data were missing in 3/11 patients from one study. 18 

All case reports were considered at critical risk of bias. Of the twenty adult case reports (Table 2) , twelve had CPR commenced in prone position [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] and eight were supinated prior to commencement of CPR. [31] [32] [33] [34] [35] [36] [37] Of the 12 paediatric case reports (Table 3) , 11 had CPR commenced prone position 29,38-46 while one was supinated prior to initiation of CPR. 47 Of the 32 case reports (20 adult and 12 paediatric), 31 cases (19 adult and 12 paediatric) were of patients in a prone position in the operating room, most often with head fixation or ongoing surgery or instrumentation that could considerably hinder the ability to safely and quickly turn the patients to supine position. Only one adult case was a patient in the prone position in the intensive care unit. 22 

Comparison of commonly reported outcomes from prone vs supine CPR are shown in Table 2 (adult case reports) and 3 (paediatric case reports). The critical outcome of time to CPR was reported in eight adult cases 19, 22, 24, 27, 29, 30, 32, 35 and seven paediatric cases. 29, [38] [39] [40] 43, 44 Time to CPR for all except for one adult case report 35 were only reported qualitatively or not reported at all. 'Immediate' prone CPR was reported in six adult cases 19, 22, 24, 27, 29, 30 and seven paediatric cases. 29, [38] [39] [40] 43, 44 One adult case reported CPR 'immediately' after supination 32 and one adult case reported CPR commenced after supination 6 min following cardiac arrest. 35 Two simulation studies reported that the time to supinate the patient was 50 ± 34 s 48 and 110 s. 21 The mean time to start chest compressions in supine position was 77 ± 31 s in one simulation study. 48 We identified one simulation study that reported time to prone defibrillation without chest compressions of 22 s (1 group) compared with a mean time of 108 ± 61 s (13 groups) when the patient was supinated for CPR and defibrillation. 48 Time to defibrillation was not reported in any adult or paediatric case report.

Return of spontaneous circulation was reported in all studies. Occurrence of ROSC in those with CPR started prone vs supine is presented in Tables 2 and 3 . ETCO2 during CPR in the prone position was reported in five adult cases, [23] [24] [25] 30, 34 with values ranging from 15 mmHg 30 to 33 mmHg 25 ; and two paediatric cases both of which reported ETCO2 10 mmHg with prone compressions. 44, 46 Outcomes at hospital discharge Survival to hospital discharge with favourable neurological outcome was not explicitly reported in any adult or paediatric case. There were implicit reports of survival to hospital discharge with favourable neurological outcome in eight adult cases ('without neurologic deficit' 21 ; 'no cerebral injury' 20 ; 'recovered uneventfully' 23 ; 'without deficits' 33 ; 'awake and well oriented at 7 days' 22 ; 'without sequelae' 24 ; 'could carry out simple tasks' 25 ; and 'discharged from hospital in a stable neurological condition' 30 ) and seven paediatric cases ('no evidence of significant cerebral dysfunction' 38 ; 'returned to baseline over two weeks' 39 ; 'recovered without sequelae' 40 ; 'no adverse neurological sequelae' 41 ; 'in good condition' 47 ; 'made an uneventful recovery' 29 ; and 'unchanged from preoperative status' 42 ).

Survival to hospital discharge was explicitly reported in 13 adult cases 20,21,23,24,28,30-36 and 11 paediatric cases. 29, [38] [39] [40] [41] [42] [43] [44] [45] 47 Survival to 30 days or longer was reported in only one adult case where CPR was initiated prone 25 and six adult cases 31-34 supinated before CPR started. Five paediatric cases reported the outcome of survival to 30 days or longer. 38, 40, 43, 44 Outcomes by prone/supine CPR initiation are summarized in Tables 2 and 3 .

Survival with favourable neurological outcome at 30 days or longer was not explicitly reported in any adult or paediatric case. There were implicit reports of survival with favourable neurological outcome at 30 days or longer in two adult cases ('without deficits' 33 ; 'able to perform his work and activities of daily living independently' 35 ) and two paediatric cases ('no abnormal neurological signs . . . within accepted limits for achondroplasia' 38 ; 'recovered without sequelae' 40 ).

In this systematic review on prone vs supine CPR/defibrillation, only a limited number of prospective nonrandomized studies, case reports, and simulation studies were identified. The lack of comparative studies examining any clinical outcomes leaves us without any real evidence for whether immediate supination or provision of chest compressions and/or defibrillation in the prone position is most beneficial. Supine CPR remains best practice and is known to be effective. However, the very limited evidence available suggests that prone CPR can produce adequate hemodynamics and may be a reasonable option if immediate supination is difficult or poses unacceptable risks to the patient.

The aetiology of cardiac arrest may also influence the urgency of supination. For example, a primary airway problem such as a dislodged tracheal tube may require immediate supination, whereas the need for haemorrhage control during surgery in the prone position may necessitate CPR in the prone position. The difficulty of supinating a patient will vary widely based on patient size, personnel immediately available, and interventions in place such as chest tubes, advanced airways, intravenous lines, personal protective equipment and isolation requirements, and potentially open wounds/exposed hardware (in the case of patients in the operating room). The relative risk of delaying the initiation of CPR and defibrillation vs the possible risk of prone CPR/defibrillation being less effective remains unclear. In many intensive care units, patients who are prone and on mechanical ventilation are likely to already have continuous arterial blood pressure and ETCO2 monitoring, thus allowing for the rapid assessment of the effectiveness of prone compressions. These patients also often have severe hypoxemia and may have had tracheal tubes in place for prolonged periods, raising the possibility of airway dislodgement or blockage as a contributing factor to the cardiac arrest. Additional studies could include larger observational studies or case series representing the total experience of a center or centers, simulation studies, or even additional case reports that report quantitative metrics such as time to initiation of CPR/defibrillation in the prone position and ETCO2 and arterial blood pressure during prone compressions. More data on patients in intensive care units are especially needed as the vast majority of published case reports on prone CPR are from patients in a prone position for spinal or brain surgery in the operating room.

This systematic review has several limitations. The lack of randomized controlled studies limited our ability to definitively compare the efficacy of prone vs supine chest compression or defibrillation. With one exception, 22 the identified case reports described events and outcomes of operating room patients, thereby limiting our ability to extrapolate these findings to patients proned for hypoxemic respiratory failure in the emergency department or inpatient settings or outof-hospital cardiac arrest patients found in a prone position. Finally, the significant risk of bias from the observational studies limited our ability to perform meta-analyses.

We identified a limited number of observational studies and case reports comparing prone vs supine CPR and defibrillation. Prone CPR may be a reasonable option if immediate supination is difficult or poses unacceptable risks to the patient.

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. Adult: CPR commenced prone (n = 12) [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] Adult: patient supinated before CPR (n = 8) 31 

Prone positioning in severe acute respiratory distress syndrome

Feasibility and physiological effects of prone positioning in non-intubated patients with acute respiratory failure due to COVID-19 (PRON-COVID): a prospective cohort study

Early conscious prone positioning in patients with COVID-19 receiving continuous positive airway pressure: a retrospective analysis

Prone positioning in moderate to severe acute respiratory distress syndrome due to COVID-19: A cohort study and analysis of physiology

Awake prone positioning for COVID-19 acute hypoxaemic respiratory failure: a randomised, controlled, multinational, open-label meta-trial

CPR techniques and devices

Adult Basic and Advanced Life Support: 2020 American Heart Association Guidelines for Cardiopulmonary Resuscitation and Emergency Cardiovascular Care

Interim Guidance for Basic and Advanced Life Support in Adults, Children, and Neonates With Suspected or Confirmed COVID-19: From the Emergency Cardiovascular Care Committee and Get With The Guidelines-Resuscitation Adult and Pediatric Task Forces of the American Heart Association

Reverse CPR: a pilot study of CPR in the prone position

International Liaison Committee on Resuscitation: COVID-19 consensus on science, treatment recommendations and task force insights

Rodríguez-Pé rez A. Cardiopulmonary resuscitation in the prone position in the operating room or in the intensive care unit: A systematic review

Cardiopulmonary resuscitation in prone position: A scoping review

Prone cardiopulmonary resuscitation: A scoping and expanded grey literature review for the COVID-19 pandemic

on behalf of the Advanced Life Support, Basic Life Support and Paediatric Life Support Task Forces at the International Liaison Committee on Resuscitation

Cardiopulmonary Resuscitation and Defibrillation for Cardiac Arrest when Patients are in the Prone Position Consensus on Science with Treatment Recommendations. ILCOR Consensus on Science with Treatment Recommendations (CoSTR)

The PRISMA 2020 statement: an updated guideline for reporting systematic reviews

ROBINS-I: a tool for assessing risk of bias in non-randomised studies of interventions

Methodological quality and synthesis of case series and case reports

Cardiopulmonary resuscitation in prone position: a simplified method for outpatients

Prone cardiopulmonary resuscitation in elderly undergoing posterior spinal fusion with laminectomy

Cardiac arrest during surgery and ventilation in the prone position: a case report and systematic review

Optimizing patient access during an emergency while using intraoperative computed tomography

Cardiopulmonary resuscitation in the prone position: Kouwenhoven revisited

Prone CPR for transient asystole during lumbosacral spinal surgery

Cardiopulmonary resuscitation in the prone position

Successful cardiopulmonary resuscitation in prone position

Efficacy of external cardiac massage in a patient in the prone position

Cardiac arrest in the prone position caused by central venous cannulation-induced cardiac tamponade

Successful defibrillation in the prone position

Successful cardiopulmonary resuscitation of two patients in the prone position using reversed precordial compression

Cardiac arrest during craniotomy in prone position

Venous air embolism during lumbar laminectomy in the prone position: report of three cases

A lethal pulmonary embolism during percutaneous vertebroplasty

Venous air embolism: an unusual complication of atlantoaxial arthrodesis: case report

Intraoperative death during lumbar discectomy

Intraoperative Visible Air Bubbling Recorded as a Sign of Massive Venous Air Embolism During Prone Position Surgery for Extensive Ossification of Spinal Ligaments: A Case Report with a Video Clip

Fatal air embolism during endoscopic retrograde cholangio-pancreatography (ERCP): a case report

Cardiac arrest after epidural anesthesia for a esthetic plastic surgery: a case report

Cardiac arrest and resuscitation of a 6-month old achondroplastic baby undergoing neurosurgery in the prone position

Air Embolism During Posterior Spinal Fusion in a 10-Year-Old Girl: A Case Report

Cardiac pulmonary resuscitation in prone position. The best option for posterior fossa neurosurgical patients

A case of ventricular fibrillation in the prone position during back stabilisation surgery in a boy with Duchenne's muscular dystrophy

Intraoperative cardiopulmonary resuscitation in the prone position

Two cases of fatal air embolism in children undergoing scoliosis surgery

CPR in prone position during neurosurgery

Venous air embolism during removal of bony spur in a child of split cord malformation: A case report. 18th Annual Conference of Indian Society of Neuroanaesthesiology and Critical Care

Non-invasive continuous haemodynamic andPetCO2 monitoring during peroperative cardiac arrest

Cardiac arrest during desflurane anaesthesia in a patient with Duchenne's muscular dystrophy

Performance of anesthesia residents during a simulated prone ventricular fibrillation arrest in an anesthetized pediatric patient

The authors would like to thank Claudio Sandroni and Takahiro Nakashima for assistance with translation of non-English articles. 

Supplementary data to this article can be found online at https://doi. org/10.1016/j.resplu.2021.100186.