Part 12: Education, implementation, and teams: 2010 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science with Treatment Recommendations

Jasmeet Soar; Mary E Mancini; Farhan Bhanji; John E Billi; Jennifer Dennett; Judith Finn; Matthew Huei-Ming Ma; Gavin D Perkins; David L Rodgers; Mary Fran Hazinski; Ian Jacobs; Peter T Morley

doi:10.1016/j.resuscitation.2010.08.030

. 2010 Oct 16;81(1):e288–e332. doi: 10.1016/j.resuscitation.2010.08.030

Part 12: Education, implementation, and teams^☆^☆☆

2010 International Consensus on Cardiopulmonary Resuscitation and Emergency Cardiovascular Care Science with Treatment Recommendations

Jasmeet Soar ^1,^⁎, Mary E Mancini ¹, Farhan Bhanji, John E Billi, Jennifer Dennett, Judith Finn, Matthew Huei-Ming Ma, Gavin D Perkins, David L Rodgers, Mary Fran Hazinski, Ian Jacobs, Peter T Morley; , on behalf of the Education, Implementation, and Teams Chapter Collaborators

PMCID: PMC7184565 PMID: 20956038

Application of resuscitation science to improve patient care and outcomes requires effective strategies for education and implementation. Systematic reviews suggest that there are significant opportunities to improve education, enhance individual and team performance, and avoid delays in implementation of guidelines into practice. It is within this context that the International Liaison Consensus on Resuscitation (ILCOR) Education, Implementation, and Teams (EIT) Task Force was established and addressed 32 worksheet topics. Reviewers selected topics from the 2005 International Consensus on Cardiopulmonary Resuscitation (CPR) and Emergency Cardiovascular Care (ECC) Science With Treatment Recommendations ¹ and new topics identified by an expert group.

One challenge for the EIT Task Force was extrapolating outcomes from simulation studies to actual patient outcomes. During the evidence evaluation, if the PICO (Population, Intervention, Comparator, Outcome) question outcomes were limited to training outcomes such as improved performance on a manikin or simulator, studies were classified to a level of evidence (LOE) according to study design (e.g., a randomised controlled trial [RCT] on a manikin would be LOE 1). Manikin or simulator studies were labeled as LOE 5 irrespective of the study design if the PICO question also included patient outcomes.

The following is a summary of key 2010 recommendations or changes related to EIT:

•
Efforts to implement new resuscitation guidelines are likely to be more successful if a carefully planned, multifaceted implementation strategy is used. Education, while essential, is only one element of a comprehensive implementation strategy.
•
All courses should be evaluated to ensure that they reliably achieve the program objectives. Training should aim to ensure that learners acquire and retain the skills and knowledge that will enable them to act correctly in actual cardiac arrests.
•
Life support knowledge and skills, both basic and advanced, can deteriorate in as little as 3–6 months. Frequent assessments and, when needed, refresher training are recommended to maintain knowledge and skills.
•
Short video/computer self-instruction courses with minimal or no instructor coaching, combined with hands-on practice (practice-while-you-watch), can be considered as an effective alternative to instructor-led basic life support (cardiopulmonary resuscitation [CPR] and automated external defibrillator [AED]) courses.
•
Laypeople and healthcare providers (HCPs) should be trained to start CPR with chest compressions for adult victims of cardiac arrest. If they are trained to do so, they should perform ventilations. Performing chest compressions alone is reasonable for trained individuals if they are incapable of delivering airway and breathing maneuvers to cardiac arrest victims.
•
AED use should not be restricted to trained personnel. Allowing use of AEDs by individuals without prior formal training can be beneficial and may be lifesaving. Since even brief training improves performance (e.g., speed of use, correct pad placement), it is recommended that training in the use of AEDs be provided.
•
CPR prompt or feedback devices improve CPR skill acquisition and retention and may be considered during CPR training for laypeople and healthcare professionals. These devices may be considered for clinical use as part of an overall strategy to improve the quality of CPR.
•
It is reasonable to wear personal protective equipment (PPE) (e.g., gloves) when performing CPR. CPR should not be delayed or withheld if PPE is not available unless there is a clear risk to the rescuer.
•
Manual chest compressions should not continue during the delivery of a shock because safety has not been established.

Several important knowledge gaps were identified during the evidence review process:

•
The optimal duration and type of initial training to acquire resuscitation knowledge and skills.
•
The optimal frequency and type of refresher training required to maintain resuscitation knowledge and skills.
•
The optimal use of assessment as a tool to promote the learning of resuscitation knowledge and skills.
•
The impact of experience in actual resuscitation attempts on skill decay and the need for refresher training.
•
The impact of specific training interventions on patient outcomes.
•
A standardised nomenclature and definitions for different types of simulation training and terms such as ‘high fidelity simulation,’ ‘feedback,’ ‘briefing’ and ‘debriefing.’
•
The most effective and efficient methods of disseminating information about new resuscitation interventions or guidelines to reduce time to implementation.
•
For cardiac resuscitation centres (facilities providing a comprehensive package of post resuscitation care), the optimal emergency medical services (EMS) system characteristics, safe patient transport interval (time taken to travel from scene to hospital), optimal mode of transport (e.g., ground ambulance, helicopter), and role of secondary transport (transfer from receiving hospital to a resuscitation centre).

The EIT Task Force organised its work into five major sections:

•
Education—including who should be trained and how to prepare for training, the use of specific instructional strategies and techniques, retraining intervals, retention of knowledge and skills, and assessment methods.
•
Risks and effects on the rescuer of CPR training and actual CPR performance.
•
Rescuer willingness to respond.
•
Implementation and teams—including a framework for implementation efforts as well as individual and team factors associated with success.
•
Ethics and outcomes.

Education

Effective and efficient resuscitation education is one of the essential elements in the translation of guidelines into clinical practice. Educational interventions need to be population specific (e.g., lay rescuers, HCPs) and evaluated to ensure that they achieve the desired educational outcomes—not just at the end of the course but also during actual resuscitation events. Retention of knowledge and skills should be confirmed through assessment and not be assumed to persist for pre-established time intervals.

Populations

Who should be trained and how should they prepare for training?

Focused training^EIT-012A^,^EIT-012B

For lay providers requiring basic life support training, does focusing training on high-risk populations, compared with no such targeting improve outcomes (e.g., bystander CPR, survival)?

Consensus on science

In three studies (LOE 1²; LOE 23, 4), people reported that they would be more willing to perform bystander CPR on family members than on nonrelatives.

One LOE 2 study⁵ of people who called 911 found that unless family members had received CPR training, they were less likely to perform CPR than unrelated bystanders. Computer modeling (LOE 5)⁶ suggested that very large numbers of older adults would need to be trained to achieve a sufficient increase in private residence bystander CPR rates to improve survival. Twelve studies (LOE 12, 7, 8, 9, 10, 11; LOE 23, 12; LOE 413, 14; LOE 515, 16) reported that training of patients and family members in CPR provided psychological benefit. Two LOE 1 studies7, 17 reported that negative psychological effects on patients can be avoided by providing social support.

Treatment recommendation

There is insufficient evidence to support or refute the use of training interventions that focus on high-risk populations. Training with social support reduces family member and patient anxiety, improves emotional adjustment, and increases feelings of empowerment.

Focused trainingEIT-012A, EIT-012B

EIT-012A

mmc22.pdf^{(59.4KB, pdf)}

EIT-012B

mmc23.pdf^{(64.6KB, pdf)}

For lay providers requiring basic life support training, does focusing training on high-risk populations, compared with no such targeting improve outcomes (e.g., bystander CPR, survival)?

Consensus on science

In three studies (LOE 1²; LOE 23, 4), people reported that they would be more willing to perform bystander CPR on family members than on nonrelatives.

One LOE 2 study⁵ of people who called 911 found that unless family members had received CPR training, they were less likely to perform CPR than unrelated bystanders. Computer modeling (LOE 5)⁶ suggested that very large numbers of older adults would need to be trained to achieve a sufficient increase in private residence bystander CPR rates to improve survival. Twelve studies (LOE 12, 7, 8, 9, 10, 11; LOE 23, 12; LOE 413, 14; LOE 515, 16) reported that training of patients and family members in CPR provided psychological benefit. Two LOE 1 studies7, 17 reported that negative psychological effects on patients can be avoided by providing social support.

Treatment recommendation

There is insufficient evidence to support or refute the use of training interventions that focus on high-risk populations. Training with social support reduces family member and patient anxiety, improves emotional adjustment, and increases feelings of empowerment.

Precourse preparation^EIT-018A

For advanced life support providers undergoing advanced life support courses, does the inclusion of specific precourse preparation (e.g., e-learning and pretesting), as opposed to no such preparation, improve outcomes (e.g., same skill assessment but with less face-to-face [instructor] hands-on training)?

Consensus on science

Eight studies (LOE 1¹⁸; LOE 4¹⁹; LOE 520, 21, 22, 23, 24, 25) reported that a diverse range of precourse preparatory actions (e.g., computer-assisted learning, pretests, video-based learning, textbook reading) improved learner outcomes in advanced life support courses.

One large LOE 1 RCT²⁶ of use of a commercially available e-learning simulation program before attending an advanced life support course, compared with standard preparation with a course manual, did not improve either cognitive or psychomotor skill performance during cardiac arrest simulation testing.

Eighteen studies (LOE 2²⁷; LOE 419, 28; LOE 520, 25, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41) showed that alternative course delivery formats such as electronically delivered (CD or Internet-based) courses produced as good or better learner outcomes compared with traditional courses, and also reduced instructor-to-learner face-to-face time.

Treatment recommendation

Precourse preparation including, but not limited to, use of computer-assisted learning tutorials, written self-instruction materials, video-based learning, textbook reading, and pretests are recommended as part of advanced life support courses. Any method of precourse preparation that is aimed at improving knowledge and skills or reducing instructor-to-learner face-to-face time should be formally assessed to ensure equivalent or improved learning outcomes compared with standard instructor-led courses.

Precourse preparationEIT-018A

EIT-018A

mmc30.pdf^{(109.5KB, pdf)}

For advanced life support providers undergoing advanced life support courses, does the inclusion of specific precourse preparation (e.g., e-learning and pretesting), as opposed to no such preparation, improve outcomes (e.g., same skill assessment but with less face-to-face [instructor] hands-on training)?

Consensus on science

Eight studies (LOE 1¹⁸; LOE 4¹⁹; LOE 520, 21, 22, 23, 24, 25) reported that a diverse range of precourse preparatory actions (e.g., computer-assisted learning, pretests, video-based learning, textbook reading) improved learner outcomes in advanced life support courses.

One large LOE 1 RCT²⁶ of use of a commercially available e-learning simulation program before attending an advanced life support course, compared with standard preparation with a course manual, did not improve either cognitive or psychomotor skill performance during cardiac arrest simulation testing.

Eighteen studies (LOE 2²⁷; LOE 419, 28; LOE 520, 25, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41) showed that alternative course delivery formats such as electronically delivered (CD or Internet-based) courses produced as good or better learner outcomes compared with traditional courses, and also reduced instructor-to-learner face-to-face time.

Treatment recommendation

Precourse preparation including, but not limited to, use of computer-assisted learning tutorials, written self-instruction materials, video-based learning, textbook reading, and pretests are recommended as part of advanced life support courses. Any method of precourse preparation that is aimed at improving knowledge and skills or reducing instructor-to-learner face-to-face time should be formally assessed to ensure equivalent or improved learning outcomes compared with standard instructor-led courses.

Instructional methods

There are multiple methods to deliver course content. This section examines specific instructional methods and strategies that may have an impact on course outcomes.

Alternative instructor methods^EIT-002A^,^EIT-002B

For lay rescuers and HCPs, does the use of specific instructional methods (video/computer self-instruction), compared with traditional instructor-led courses, improve skill acquisition and retention?

Consensus on science

Twelve studies (LOE 142, 43, 44, 45, 46, 47; LOE 2 or 348, 49, 50, 51, 52, 53) demonstrated that basic life support skills can be acquired and retained at least as well and, in some cases, better using video-based self-instruction (practice-while-you-watch) compared with traditional instructor-led courses. Video-based self-instruction lasted from 8 to 34 min, whereas instructor-led courses were usually 4–6 h in duration. One LOE 1 study⁵⁴ demonstrated that prior viewing of a video on infant CPR before an instructor-led course improved skill acquisition.

When compared with traditional instructor-led CPR courses, various self-instructional and shortened programs have been demonstrated to be efficient (from the perspective of time) and effective (from the perspective of skill acquisition) in teaching CPR skills to various populations.

Treatment recommendation

Short video/computer self-instruction (with minimal or no instructor coaching) that includes synchronous hands-on practice (practice-while-you-watch) in basic life support can be considered as an effective alternative to instructor-led courses.

Alternative instructor methodsEIT-002A, EIT-002B

EIT-002A

mmc8.pdf^{(49KB, pdf)}

EIT-002B

mmc9.pdf^{(62.7KB, pdf)}

For lay rescuers and HCPs, does the use of specific instructional methods (video/computer self-instruction), compared with traditional instructor-led courses, improve skill acquisition and retention?

Consensus on science

Twelve studies (LOE 142, 43, 44, 45, 46, 47; LOE 2 or 348, 49, 50, 51, 52, 53) demonstrated that basic life support skills can be acquired and retained at least as well and, in some cases, better using video-based self-instruction (practice-while-you-watch) compared with traditional instructor-led courses. Video-based self-instruction lasted from 8 to 34 min, whereas instructor-led courses were usually 4–6 h in duration. One LOE 1 study⁵⁴ demonstrated that prior viewing of a video on infant CPR before an instructor-led course improved skill acquisition.

When compared with traditional instructor-led CPR courses, various self-instructional and shortened programs have been demonstrated to be efficient (from the perspective of time) and effective (from the perspective of skill acquisition) in teaching CPR skills to various populations.

Treatment recommendation

Short video/computer self-instruction (with minimal or no instructor coaching) that includes synchronous hands-on practice (practice-while-you-watch) in basic life support can be considered as an effective alternative to instructor-led courses.

AED training interventions^>EIT-013A^,^EIT-013B

For basic life support providers (lay or HCP) requiring AED training, are there any specific training interventions, compared with traditional lecture/practice sessions, that increase outcomes (e.g., skill acquisition and retention, actual AED use)?

Consensus on science

One LOE 2 study⁵⁵ demonstrated that training delivered by laypeople is as effective as training by HCPs. One LOE 1 study⁵⁶ reported that instruction by nurses, as compared with physicians, resulted in better skill acquisition. Four studies (LOE 246, 51, 57; LOE 4⁵⁸) reported that the use of computer-based AED training improved skill acquisition and retention, particularly when combined with manikin practice. One LOE 1 study⁴⁷ supported the use of video-self instruction when compared with instructor-led training. Three LOE 1 studies59, 60, 61 showed that the use of video self-instruction was less effective for some elements when compared with instructor-led training. One LOE 1 study⁶² supported the use of a training poster and manikin for learning AED skills. Three studies (LOE 246, 63; LOE 4⁶⁴) reported that laypeople and HCPs could use an AED without training. Three LOE 2 studies65, 66, 67 reported that untrained individuals could deliver a shock with an AED. However, even minimal training (15-min lecture, 1-h lecture with manikin practice, or reading instructions) improved performance (e.g., time to shock delivery, correct pad placement, safety).

Treatment recommendation

AED use should not be restricted to trained personnel. Allowing use of AEDs by individuals without prior formal training can be beneficial and may be lifesaving. Since even brief training improves performance (e.g., speed of use, correct pad placement), it is recommended that training in the use of AEDs be provided. Laypeople can be used as AED instructors. Short video/computer self-instruction (with minimal or no instructor coaching) that includes synchronous hands-on practice in AED use (practice-while-you-watch) may be considered as an effective alternative to instructor-led AED courses.

AED training interventionsEIT-013A, EIT-013B

EIT-013A

mmc24.pdf^{(153.8KB, pdf)}

EIT-013B

mmc25.pdf^{(105.7KB, pdf)}

For basic life support providers (lay or HCP) requiring AED training, are there any specific training interventions, compared with traditional lecture/practice sessions, that increase outcomes (e.g., skill acquisition and retention, actual AED use)?

Consensus on science

One LOE 2 study⁵⁵ demonstrated that training delivered by laypeople is as effective as training by HCPs. One LOE 1 study⁵⁶ reported that instruction by nurses, as compared with physicians, resulted in better skill acquisition. Four studies (LOE 246, 51, 57; LOE 4⁵⁸) reported that the use of computer-based AED training improved skill acquisition and retention, particularly when combined with manikin practice. One LOE 1 study⁴⁷ supported the use of video-self instruction when compared with instructor-led training. Three LOE 1 studies59, 60, 61 showed that the use of video self-instruction was less effective for some elements when compared with instructor-led training. One LOE 1 study⁶² supported the use of a training poster and manikin for learning AED skills. Three studies (LOE 246, 63; LOE 4⁶⁴) reported that laypeople and HCPs could use an AED without training. Three LOE 2 studies65, 66, 67 reported that untrained individuals could deliver a shock with an AED. However, even minimal training (15-min lecture, 1-h lecture with manikin practice, or reading instructions) improved performance (e.g., time to shock delivery, correct pad placement, safety).

Treatment recommendation

AED use should not be restricted to trained personnel. Allowing use of AEDs by individuals without prior formal training can be beneficial and may be lifesaving. Since even brief training improves performance (e.g., speed of use, correct pad placement), it is recommended that training in the use of AEDs be provided.

Laypeople can be used as AED instructors

Short video/computer self-instruction (with minimal or no instructor coaching) that includes synchronous hands-on practice in AED use (practice-while-you-watch) may be considered as an effective alternative to instructor-led AED courses.

Advanced life support leadership/team training^EIT-017A

For advanced life support providers undergoing advanced life support courses, does the inclusion of specific leadership/team training, as opposed to no such specific training, improve outcomes (e.g., performance during cardiac arrest)?

Consensus on science

Four studies (LOE 168, 69; LOE 270, 71) of advanced life support in simulated in-hospital cardiac arrest and seven LOE 5 studies72, 73, 74, 75, 76, 77, 78 of actual and simulated arrest demonstrated improved resuscitation team performance when specific team and/or leadership training was added to advanced life support courses.

Treatment recommendation

Specific teamwork training, including leadership skills, should be included in advanced life support courses.

Advanced life support leadership/team trainingEIT-017A

EIT-017A

mmc29.pdf^{(85.6KB, pdf)}

For advanced life support providers undergoing advanced life support courses, does the inclusion of specific leadership/team training, as opposed to no such specific training, improve outcomes (e.g., performance during cardiac arrest)?

Consensus on science

Four studies (LOE 168, 69; LOE 270, 71) of advanced life support in simulated in-hospital cardiac arrest and seven LOE 5 studies72, 73, 74, 75, 76, 77, 78 of actual and simulated arrest demonstrated improved resuscitation team performance when specific team and/or leadership training was added to advanced life support courses.

Treatment recommendation

Specific teamwork training, including leadership skills, should be included in advanced life support courses.

Teaching chest compressions to achieve recoil^EIT-032

Is there a method for teaching chest compressions, compared with current teaching, to achieve full chest recoil (complete release) after each compression?

Consensus on science

One LOE 5 clinical case series⁷⁹ documented a 46% incidence of incomplete chest recoil by professional rescuers using the 2005-recommended CPR technique. One LOE 4 study⁸⁰ electronically recorded chest recoil during in-hospital paediatric cardiac arrests, and found that leaning on the chest (>2.5 kg; an adult feedback threshold) occurred in 50% of chest compressions/decompressions using the recommended hand position, and that incomplete recoil was reduced with real-time automated feedback. Another LOE 4 in-hospital paediatric study⁸¹ demonstrated a 23.4% incidence of incomplete recoil. One LOE 5 study⁸² has shown that without specific training in complete chest recoil technique, 22% of trained rescuers leaned on the chest when performing CPR. Two LOE 5 studies79, 83 demonstrated that incomplete chest recoil was significantly reduced with three techniques (i.e., ‘two-finger fulcrum,’ ‘five-finger fulcrum,’ and ‘hands-off’) of lifting the heel of the hand slightly but completely off the chest during CPR in a manikin model. However, duty cycle and compression depth were reduced when professional and lay rescuers applied these techniques.

Treatment recommendation

There is insufficient evidence to recommend teaching any specific technique to optimise complete chest recoil during actual CPR.

Teaching chest compressions to achieve recoilEIT-032

EIT-032

mmc49.pdf^{(59.2KB, pdf)}

Is there a method for teaching chest compressions, compared with current teaching, to achieve full chest recoil (complete release) after each compression?

Consensus on science

One LOE 5 clinical case series⁷⁹ documented a 46% incidence of incomplete chest recoil by professional rescuers using the 2005-recommended CPR technique. One LOE 4 study⁸⁰ electronically recorded chest recoil during in-hospital paediatric cardiac arrests, and found that leaning on the chest (>2.5 kg; an adult feedback threshold) occurred in 50% of chest compressions/decompressions using the recommended hand position, and that incomplete recoil was reduced with real-time automated feedback. Another LOE 4 in-hospital paediatric study⁸¹ demonstrated a 23.4% incidence of incomplete recoil. One LOE 5 study⁸² has shown that without specific training in complete chest recoil technique, 22% of trained rescuers leaned on the chest when performing CPR. Two LOE 5 studies79, 83 demonstrated that incomplete chest recoil was significantly reduced with three techniques (i.e., ‘two-finger fulcrum,’ ‘five-finger fulcrum,’ and ‘hands-off’) of lifting the heel of the hand slightly but completely off the chest during CPR in a manikin model. However, duty cycle and compression depth were reduced when professional and lay rescuers applied these techniques.

Treatment recommendation

There is insufficient evidence to recommend teaching any specific technique to optimise complete chest recoil during actual CPR.

Use of CPR prompt/feedback devices^EIT-005A^,^EIT-005B

For lay rescuers and HCPs performing CPR, does the use of CPR prompt/feedback devices, compared with no device, improve acquisition, retention, and actual performance of CPR skills?

Consensus on science

Most devices considered in this review combine prompting (a signal to perform an action, e.g., metronome for compression rate) with feedback (after-event information about the effect of an action, e.g., visual display of compression depth). The effects have been considered together in this question and devices are referred to as prompt/feedback devices.

Seven LOE 5 manikin studies84, 85, 86, 87, 88, 89, 90 demonstrated that CPR prompt/feedback devices either in addition to or in place of instructor-led training improved basic CPR skill acquisition (tested without use of the device). Another LOE 5 manikin study⁸⁵ showed that automated feedback might be less effective than instructor feedback for more complex skills (e.g., bag-mask ventilation).

Two LOE 5 manikin studies84, 87 showed improved skill retention when a CPR prompt/feedback device was used during initial training. An additional LOE 5 manikin study⁸⁹ showed that unsupervised refresher training with a CPR prompt/feedback device, compared with no refresher training, also improved skill retention. The LOE 5 follow-up arm of the manikin study of bag-mask ventilation/CPR⁸⁵ continued to show poorer ventilation skills in the voice-activated manikin-feedback arm compared with the instructor-feedback arm.

Evidence from 21 manikin studies (LOE 5)84, 86, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107 consistently demonstrated that CPR prompt/feedback devices used during CPR improved the quality of CPR performance on manikins. Three additional manikin studies (LOE 5) examined the utility of video/animations on mobile-phone devices: two studies showed improved checklist scores and quality of CPR92, 95 and faster initiation of CPR,⁹² while the third study showed that participants using multimedia phone CPR instruction took longer to complete tasks than dispatcher-assisted CPR.¹⁰³ Two manikin studies (LOE 5)108, 109 that used two-way video communication to enable the dispatcher to review and comment on CPR in real time produced equivocal findings.

There are no studies demonstrating improved patient outcomes with CPR prompt/feedback devices. One study each in children (LOE 2)¹¹⁰ and adults (LOE 2)¹¹¹ showed that metronomes improved chest compression rate and increased end-tidal carbon dioxide (thought to correlate with improved cardiac output and blood flow to the lungs). Five studies evaluating the introduction of CPR prompt/feedback devices in clinical practice (pre/post comparisons) found improved CPR performance (LOE 3)80, 112, 113, 114, 115.

There may be some limitations to the use of CPR prompt/feedback devices. Two LOE 5 manikin studies116, 117 reported that chest-compression devices may overestimate compression depth if CPR is being performed on a compressible surface such as a mattress on a bed. One LOE 5 study¹⁰⁰ reported harm to a single participant when a hand got stuck in moving parts of the CPR feedback device. Another LOE 5 manikin study¹¹⁸ demonstrated that additional mechanical work from the CPR provider was required to compress the spring in one of the pressure-sensing feedback devices. One case report (LOE 5)¹¹⁹ documented soft tissue injury to a patient's chest when an accelerometer device was used for prolonged CPR.

Treatment recommendation

CPR prompt/feedback devices may be considered during CPR training for laypeople and HCPs. CPR prompt/feedback devices may be considered for clinical use as part of an overall strategy to improve the quality of CPR. Instructors and rescuers should be made aware that a compressible support surface (e.g., mattress) may cause a feedback device to overestimate depth of compression.

Use of CPR prompt/feedback devicesEIT-005A, EIT-005B

EIT-005A

mmc12.pdf^{(240.1KB, pdf)}

EIT-005B

mmc13.pdf^{(94.8KB, pdf)}

For lay rescuers and HCPs performing CPR, does the use of CPR prompt/feedback devices, compared with no device, improve acquisition, retention, and actual performance of CPR skills?

Consensus on science

Most devices considered in this review combine prompting (a signal to perform an action, e.g., metronome for compression rate) with feedback (after-event information about the effect of an action, e.g., visual display of compression depth). The effects have been considered together in this question and devices are referred to as prompt/feedback devices.

Seven LOE 5 manikin studies84, 85, 86, 87, 88, 89, 90 demonstrated that CPR prompt/feedback devices either in addition to or in place of instructor-led training improved basic CPR skill acquisition (tested without use of the device). Another LOE 5 manikin study⁸⁵ showed that automated feedback might be less effective than instructor feedback for more complex skills (e.g., bag-mask ventilation).

Two LOE 5 manikin studies84, 87 showed improved skill retention when a CPR prompt/feedback device was used during initial training. An additional LOE 5 manikin study⁸⁹ showed that unsupervised refresher training with a CPR prompt/feedback device, compared with no refresher training, also improved skill retention. The LOE 5 follow-up arm of the manikin study of bag-mask ventilation/CPR⁸⁵ continued to show poorer ventilation skills in the voice-activated manikin–feedback arm compared with the instructor-feedback arm.

Evidence from 21 manikin studies (LOE 5)84, 86, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107 consistently demonstrated that CPR prompt/feedback devices used during CPR improved the quality of CPR performance on manikins. Three additional manikin studies (LOE 5) examined the utility of video/animations on mobile-phone devices: two studies showed improved checklist scores and quality of CPR92, 95 and faster initiation of CPR,⁹² while the third study showed that participants using multimedia phone CPR instruction took longer to complete tasks than dispatcher-assisted CPR.¹⁰³ Two manikin studies (LOE 5)108, 109 that used two-way video communication to enable the dispatcher to review and comment on CPR in real time produced equivocal findings.

There are no studies demonstrating improved patient outcomes with CPR prompt/feedback devices. One study each in children (LOE 2)¹¹⁰ and adults (LOE 2)¹¹¹ showed that metronomes improved chest compression rate and increased end-tidal carbon dioxide (thought to correlate with improved cardiac output and blood flow to the lungs). Five studies evaluating the introduction of CPR prompt/feedback devices in clinical practice (pre/post comparisons) found improved CPR performance (LOE 3)80, 112, 113, 114, 115.

There may be some limitations to the use of CPR prompt/feedback devices. Two LOE 5 manikin studies116, 117 reported that chest-compression devices may overestimate compression depth if CPR is being performed on a compressible surface such as a mattress on a bed. One LOE 5 study¹⁰⁰ reported harm to a single participant when a hand got stuck in moving parts of the CPR feedback device. Another LOE 5 manikin study¹¹⁸ demonstrated that additional mechanical work from the CPR provider was required to compress the spring in one of the pressure-sensing feedback devices. One case report (LOE 5)¹¹⁹ documented soft tissue injury to a patient's chest when an accelerometer device was used for prolonged CPR.

Treatment recommendation

CPR prompt/feedback devices may be considered during CPR training for laypeople and HCPs. CPR prompt/feedback devices may be considered for clinical use as part of an overall strategy to improve the quality of CPR. Instructors and rescuers should be made aware that a compressible support surface (e.g., mattress) may cause a feedback device to overestimate depth of compression.

Training interventions^EIT-009A

For adult and paediatric advanced life support providers, are there any specific training interventions (e.g., duration of session, interactive computer programs, e-learning, video self-instruction) compared with traditional lecture/practice sessions that increase outcomes (e.g., skill acquisition and retention)?

Consensus on science

There is limited evidence about interventions that enhance learning and retention from advanced life support courses. One LOE 3 study¹²⁰ suggested that the 2005 Guidelines have helped to improve “no-flow” fraction (i.e., percent of total resuscitation time that compressions are not performed) but not other elements of quality of CPR performance. One LOE 1 study¹²¹ demonstrated that clinical training before an advanced life support (ALS) course might improve long-term retention of ALS knowledge and skills. One LOE 5 advanced trauma life support (ATLS) study¹²² suggested that postcourse experience might play a role in knowledge and skill retention. In one LOE 3 study¹²³ unscheduled mock-codes improved mock-code performance in hospital personnel. One LOE 2 study¹²⁴ found no difference in knowledge retention when live actors were used in ALS course training compared with manikins.

Treatment recommendation

There is insufficient evidence to recommend any specific training intervention, compared with traditional lecture/practice sessions, to improve learning, retention, and use of advanced life support skills.

Training interventionsEIT-009A

EIT-009A

mmc18.pdf^{(71.3KB, pdf)}

For adult and paediatric advanced life support providers, are there any specific training interventions (e.g., duration of session, interactive computer programs, e-learning, video self-instruction) compared with traditional lecture/practice sessions that increase outcomes (e.g., skill acquisition and retention)?

Consensus on science

There is limited evidence about interventions that enhance learning and retention from advanced life support courses. One LOE 3 study¹²⁰ suggested that the 2005 Guidelines have helped to improve “no-flow” fraction (i.e., percent of total resuscitation time that compressions are not performed) but not other elements of quality of CPR performance. One LOE 1 study¹²¹ demonstrated that clinical training before an advanced life support (ALS) course might improve long-term retention of ALS knowledge and skills. One LOE 5 advanced trauma life support (ATLS) study¹²² suggested that postcourse experience might play a role in knowledge and skill retention. In one LOE 3 study¹²³ unscheduled mock-codes improved mock-code performance in hospital personnel. One LOE 2 study¹²⁴ found no difference in knowledge retention when live actors were used in ALS course training compared with manikins.

Treatment recommendation

There is insufficient evidence to recommend any specific training intervention, compared with traditional lecture/practice sessions, to improve learning, retention, and use of advanced life support skills.

Realistic training techniques^EIT-019A^,^EIT-019B

For participants undergoing basic or advanced life support courses, does the inclusion of more realistic techniques (e.g., high-fidelity manikins, in situ training), as opposed to standard training (e.g., low-fidelity manikins, education centre), improve outcomes (e.g., skill performance on manikins, skill performance in an actual arrest, willingness to perform)?

Consensus on science

Studies report conflicting data on the effect of increasing realism (e.g., use of actual resuscitation settings, high-fidelity manikins) on learning, and few data on patient outcomes. Two studies (LOE 1¹²⁵; LOE 2¹²⁶) supported an improvement in performance of skills in actual arrest, but were underpowered to identify improved survival rate. One small LOE 1 study¹²⁷ showed no overall effect on performance, although the simulation-trained group demonstrated superior teamwork skills. Thirteen studies (LOE 1125, 128, 129, 130, 131, 132; LOE 2133, 134, 135; LOE 3136, 137; LOE 4138, 139) reported an improvement in skills assessed using a manikin. Seven LOE 1 studies140, 141, 142, 143, 144, 145, 146 reported no effect on skills assessed using a manikin. Eleven LOE 1 studies tested the effect of simulation fidelity on the participants’ knowledge using multiple-choice questions; nine of these studies found no effect124, 127, 128, 130, 140, 141, 143, 144, 147 and two of the 11 studies demonstrated an improvement in participant knowledge with the more realistic techniques.148, 149

Two studies (LOE 3¹³⁶; LOE 4¹³⁸) that focused on resuscitation in trauma reported improved skill performance (on a manikin) with higher-fidelity simulation. One LOE 1 study¹⁴⁰ found no difference in skill performance or knowledge in advanced trauma life support (ATLS) with the use of high-fidelity simulation. One LOE 1 study¹⁴⁸ reported a significant increase in knowledge when using manikins or live patient models for trauma teaching compared with no manikins or no live models. In this study there was no difference in knowledge acquisition between using manikins or live patient models, although learners preferred using the manikins.

Four studies (LOE 1128, 140, 141; LOE 2¹⁴⁸) reported that higher fidelity simulation was associated with improved learner satisfaction rate compared with a traditional curriculum. One LOE 1 study¹⁴⁴ questioned the cost-effectiveness of higher fidelity approaches compared with standard manikins.

Three studies (LOE 1¹²⁵; LOE 2¹³⁴; LOE 3¹³⁷) reported that requiring learners to perform all of the steps of psychomotor skills in simulation as they would in an actual clinical situation could reveal inadequacies in training.

Treatment recommendation

There is insufficient evidence to support or refute the use of more realistic techniques (e.g., high-fidelity manikins, in situ training) to improve outcomes (e.g., skill performance on manikins, skill performance in actual arrest, willingness to perform) compared with standard training (e.g., low-fidelity manikins, education centre) in basic and advanced life support courses.

Realistic training techniquesEIT-019A, EIT-019B

EIT-019A

mmc31.pdf^{(116.1KB, pdf)}

EIT-019B

mmc32.pdf^{(210.4KB, pdf)}

For participants undergoing basic or advanced life support courses, does the inclusion of more realistic techniques (e.g., high-fidelity manikins, in situ training), as opposed to standard training (e.g., low-fidelity manikins, education centre), improve outcomes (e.g., skill performance on manikins, skill performance in an actual arrest, willingness to perform)?

Consensus on science

Studies report conflicting data on the effect of increasing realism (e.g., use of actual resuscitation settings, high-fidelity manikins) on learning, and few data on patient outcomes. Two studies (LOE 1¹²⁵; LOE 2¹²⁶) supported an improvement in performance of skills in actual arrest, but were underpowered to identify improved survival rate. One small LOE 1 study¹²⁷ showed no overall effect on performance, although the simulation-trained group demonstrated superior teamwork skills. Thirteen studies (LOE 1125, 128, 129, 130, 131, 132; LOE 2133, 134, 135; LOE 3136, 137; LOE 4138, 139) reported an improvement in skills assessed using a manikin. Seven LOE 1 studies140, 141, 142, 143, 144, 145, 146 reported no effect on skills assessed using a manikin. Eleven LOE 1 studies tested the effect of simulation fidelity on the participants’ knowledge using multiple-choice questions; nine of these studies found no effect124, 127, 128, 130, 140, 141, 143, 144, 147 and two of the 11 studies demonstrated an improvement in participant knowledge with the more realistic techniques.148, 149

Two studies (LOE 3¹³⁶; LOE 4¹³⁸) that focused on resuscitation in trauma reported improved skill performance (on a manikin) with higher-fidelity simulation. One LOE 1 study¹⁴⁰ found no difference in skill performance or knowledge in advanced trauma life support (ATLS) with the use of high-fidelity simulation. One LOE 1 study¹⁴⁸ reported a significant increase in knowledge when using manikins or live patient models for trauma teaching compared with no manikins or no live models. In this study there was no difference in knowledge acquisition between using manikins or live patient models, although learners preferred using the manikins.

Four studies (LOE 1128, 140, 141; LOE 2¹⁴⁸) reported that higher fidelity simulation was associated with improved learner satisfaction rate compared with a traditional curriculum. One LOE 1 study¹⁴⁴ questioned the cost-effectiveness of higher fidelity approaches compared with standard manikins.

Three studies (LOE 1¹²⁵; LOE 2¹³⁴; LOE 3¹³⁷) reported that requiring learners to perform all of the steps of psychomotor skills in simulation as they would in an actual clinical situation could reveal inadequacies in training.

Treatment recommendation

There is insufficient evidence to support or refute the use of more realistic techniques (e.g., high-fidelity manikins, in situ training) to improve outcomes (e.g., skill performance on manikins, skill performance in actual arrest, willingness to perform) compared with standard training (e.g., low-fidelity manikins, education centre) in basic and advanced life support courses.

Course format and duration

Resuscitation training courses vary widely in their duration and how different elements of the curriculum are taught. This section examines the effect of course format and duration on learning outcomes.

Course duration^EIT-029A^,^EIT-029B

For basic life support providers (lay or HCP), does a longer duration instructor-led course, compared with a shorter course, improve skill acquisition and retention?

Consensus on science

A single, randomised manikin LOE 1 study¹⁵⁰ demonstrated that a 7-h basic life support (with AED) instructor-led course resulted in better initial skill acquisition than a 4-h instructor-led course; and a 4-h instructor-led course resulted in better skill acquisition than a 2-h course. Retesting at 6 months after a 2-h course resulted in skill retention at 12 months that was equivalent to a 7-h course with no intermediate testing. This study¹⁵⁰ along with two LOE 2 manikin studies151, 152 demonstrated that for periods between 4 and 12 months, skill retention is higher for longer courses, but deterioration is at similar rates. The differences in learning outcomes for courses of different durations may not be significant, particularly if assessment and refresher training are undertaken.

Treatment recommendation

It is reasonable to consider shortening the duration of traditional instructor-led basic life support courses. Brief reassessment (e.g., at 6 months) should be considered to improve skills and retention. The optimal duration of an instructor-led basic life support course has not been determined. New course formats should be assessed to ensure that they achieve their objectives.

Course durationEIT-029A, EIT-029B

EIT-029A

mmc44.pdf^{(47.8KB, pdf)}

EIT-029B

mmc45.pdf^{(41.3KB, pdf)}

For basic life support providers (lay or HCP), does a longer duration instructor-led course, compared with a shorter course, improve skill acquisition and retention?

Consensus on Science

A single, randomised manikin LOE 1 study¹⁵⁰ demonstrated that a 7-h basic life support (with AED) instructor-led course resulted in better initial skill acquisition than a 4-h instructor-led course; and a 4-h instructor-led course resulted in better skill acquisition than a 2-h course. Retesting at 6 months after a 2-h course resulted in skill retention at 12 months that was equivalent to a 7-h course with no intermediate testing. This study¹⁵⁰ along with two LOE 2 manikin studies151, 152 demonstrated that for periods between 4 and 12 months, skill retention is higher for longer courses, but deterioration is at similar rates. The differences in learning outcomes for courses of different durations may not be significant, particularly if assessment and refresher training are undertaken.

Treatment recommendation

It is reasonable to consider shortening the duration of traditional instructor-led basic life support courses. Brief reassessment (e.g., at 6 months) should be considered to improve skills and retention. The optimal duration of an instructor-led basic life support course has not been determined. New course formats should be assessed to ensure that they achieve their objectives.

Nontraditional scheduling formats^EIT-020

For participants undergoing advanced life support courses, does the use of nontraditional scheduling formats such as random scheduling (introducing station cases in a random manner) or modular courses, as opposed to traditional scheduling, improve outcomes (e.g., skills performance)?

Consensus on science

There are no published studies addressing the impact of different ALS course scheduling formats, compared with the traditional 2-day course format, that demonstrated improved learning outcomes (knowledge and skill acquisition and/or retention).

Treatment recommendation

There is insufficient evidence to support or refute the use of alternative advanced life support course scheduling formats compared with the traditional 2-day course format.

Nontraditional scheduling formatsEIT-020

EIT-020

mmc33.pdf^{(55.6KB, pdf)}

For participants undergoing advanced life support courses, does the use of nontraditional scheduling formats such as random scheduling (introducing station cases in a random manner) or modular courses, as opposed to traditional scheduling, improve outcomes (e.g., skills performance)?

Consensus on science

There are no published studies addressing the impact of different ALS course scheduling formats, compared with the traditional 2-day course format, that demonstrated improved learning outcomes (knowledge and skill acquisition and/or retention).

Treatment recommendation

There is insufficient evidence to support or refute the use of alternative advanced life support course scheduling formats compared with the traditional 2-day course format.

Retraining intervals

It is recognised that knowledge and skill retention declines within weeks after initial resuscitation training. Refresher training is invariably required to maintain knowledge and skills; however, the optimal frequency for refresher training is unclear. This section examines the evidence addressing the optimal frequency for refresher training to maintain adequate knowledge and skills.

Specific intervals for basic life support^EIT-010

For basic life support providers (lay and HCP), are there any specific intervals for update/retraining, compared with standard practice (i.e., 12 or 24 monthly), that increase outcomes (e.g., skill acquisition and retention)?

Consensus on science

Six studies (LOE 144, 87; LOE 2¹⁵⁰; LOE 447, 153, 154) using different training approaches demonstrated that CPR skills (e.g., alerting EMS, chest compressions, ventilations) decay rapidly (within 3–6 months) after initial training. Two studies (LOE 1¹⁵⁵; LOE 4¹⁵⁶) reported skill decay within 7–12 months after initial training. Four studies (LOE 2¹⁵⁰; LOE 4157, 158, 159) demonstrated that CPR performance was retained or improved with reevaluation, refresher, and/or retraining after as little as three months. Three LOE 2 studies66, 150, 160 demonstrated that AED skills are retained longer than CPR skills. One LOE 2 study¹⁶⁰ reported higher levels of retention from a program that achieved initial training to a high (mastery) level. However, deterioration of CPR skills was still reported at three months.

Treatment recommendation

For basic life support providers (lay and HCP), skills assessment and, if required, a skills refresher should be undertaken more often than the current commonly recommended training interval of 12–24 months.

Specific intervals for basic life supportEIT-010

EIT-010

mmc19.pdf^{(62.7KB, pdf)}

For basic life support providers (lay and HCP), are there any specific intervals for update/retraining, compared with standard practice (i.e., 12 or 24 monthly), that increase outcomes (e.g., skill acquisition and retention)?

Consensus on science

Six studies (LOE 144, 87; LOE 2¹⁵⁰; LOE 447, 153, 154) using different training approaches demonstrated that CPR skills (e.g., alerting EMS, chest compressions, ventilations) decay rapidly (within 3–6 months) after initial training. Two studies (LOE 1¹⁵⁵; LOE 4¹⁵⁶) reported skill decay within 7–12 months after initial training. Four studies (LOE 2¹⁵⁰; LOE 4157, 158, 159) demonstrated that CPR performance was retained or improved with reevaluation, refresher, and/or retraining after as little as three months. Three LOE 2 studies66, 150, 160 demonstrated that AED skills are retained longer than CPR skills. One LOE 2 study¹⁶⁰ reported higher levels of retention from a program that achieved initial training to a high (mastery) level. However, deterioration of CPR skills was still reported at three months.

Treatment recommendation

For basic life support providers (lay and HCP), skills assessment and, if required, a skills refresher should be undertaken more often than the current commonly recommended training interval of 12–24 months.

Specific intervals for advanced life support^EIT-011A^,^EIT-011B

For adult and paediatric advanced life support providers, do any specific intervals for update/retraining, compared with standard practice (i.e., 12 or 24 months), increase outcomes (e.g., skill acquisition and retention)?

Consensus on science

One LOE 1 trial¹⁶¹ and one LOE 3 study¹⁶² suggested that refresher training may enhance resuscitation knowledge retention but did not maintain motor skills. Two RCTs (LOE 1)163, 164 showed no benefit of refresher training.

Nine studies (LOE 3¹⁶⁵; LOE 4153, 166, 167, 168, 169, 170, 171, 172) reported decreased resuscitation knowledge and/or skills performance when tested 3–6 months after initial training. Two LOE 4 studies173, 174 reported decreased performance when tested 7–12 months following training. One LOE 4 study¹⁷⁵ reported decay of practical skill performance when participants were tested 18 months after training.

Treatment recommendation

For advanced life support providers there should be more frequent assessment of skill performance and/or refresher training than is currently recommended in established advanced life support programs. There is insufficient evidence to recommend an optimal interval and form of assessment and/or refresher training.

Specific intervals for advanced life supportEIT-011A, EIT-011B

EIT-011A

mmc20.pdf^{(107.1KB, pdf)}

EIT-011B

mmc21.pdf^{(201.2KB, pdf)}

For adult and paediatric advanced life support providers, do any specific intervals for update/retraining, compared with standard practice (i.e., 12 or 24 months), increase outcomes (e.g., skill acquisition and retention)?

Consensus on science

One LOE 1 trial¹⁶¹ and one LOE 3 study¹⁶² suggested that refresher training may enhance resuscitation knowledge retention but did not maintain motor skills. Two RCTs (LOE 1)163, 164 showed no benefit of refresher training.

Nine studies (LOE 3¹⁶⁵; LOE 4153, 166, 167, 168, 169, 170, 171, 172) reported decreased resuscitation knowledge and/or skills performance when tested 3–6 months after initial training. Two LOE 4 studies173, 174 reported decreased performance when tested 7–12 months following training. One LOE 4 study¹⁷⁵ reported decay of practical skill performance when participants were tested 18 months after training.

Treatment recommendation

For advanced life support providers there should be more frequent assessment of skill performance and/or refresher training than is currently recommended in established advanced life support programs. There is insufficient evidence to recommend an optimal interval and form of assessment and/or refresher training.

Assessment

Written examination^EIT-004

For students of adult and paediatric advanced level courses, does success in the written examination, compared with lack of success, predict success in completing the practical skills testing associated with the course or in cardiac arrest management performance in actual or simulated cardiac arrest events?

Consensus on science

Four observational studies (LOE P4)176, 177, 178, 179 did not support the ability of a written test to predict clinical skill performance in an advanced life support course. Twelve LOE P5 studies180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191 supported using written tests as a predictor of nonresuscitation clinical skills, with variable levels of correlation ranging from 0.19 to 0.65. Three LOE P5 studies192, 193, 194 were either neutral or did not support the ability of a written test to predict clinical skill performance.

Treatment recommendation

A written test in an advanced life support course should not be used as a substitute for demonstration of clinical skill performance.

Written examinationEIT-004

EIT-004

mmc11.pdf^{(63.5KB, pdf)}

For students of adult and paediatric advanced level courses, does success in the written examination, compared with lack of success, predict success in completing the practical skills testing associated with the course or in cardiac arrest management performance in actual or simulated cardiac arrest events?

Consensus on science

Four observational studies (LOE P4)176, 177, 178, 179 did not support the ability of a written test to predict clinical skill performance in an advanced life support course. Twelve LOE P5 studies180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 191 supported using written tests as a predictor of nonresuscitation clinical skills, with variable levels of correlation ranging from 0.19 to 0.65. Three LOE P5 studies192, 193, 194 were either neutral or did not support the ability of a written test to predict clinical skill performance.

Treatment recommendation

A written test in an advanced life support course should not be used as a substitute for demonstration of clinical skill performance.

Testing versus continuous assessment^EIT-021A

For participants undergoing basic or advanced life support courses, does end-of-course testing, as opposed to continuous assessment and feedback, improve outcomes (e.g., improve learning/performance)?

Testing versus continuous assessmentEIT-021A

EIT-021A

mmc34.pdf^{(42.8KB, pdf)}

For participants undergoing basic or advanced life support courses, does end-of-course testing, as opposed to continuous assessment and feedback, improve outcomes (e.g., improve learning/performance)?

Assessment versus no assessment^EIT-030A

For lay and HCP, does the use of assessment, as opposed to no such assessment, improve CPR knowledge, skills, and learning/retention?

Consensus on science

No studies have compared outcomes of continuous versus end-of-course assessments for resuscitation training.

One LOE 1 manikin study¹⁹⁵ showed that including assessment during advanced life support training, compared with a control group without assessment, moderately improved performance at the 2-week postcourse scenario assessment. In another LOE 1 study¹⁹⁵ performance assessment after 6 months in the “testing” group compared with the control group failed to show a statistically significant improvement.

Treatment recommendation

Summative assessment at the end of advanced life support training should be considered as a strategy to improve learning outcomes. There is insufficient evidence to recommend an optimal method of assessment during life support training.

Assessment versus no assessmentEIT-030A

EIT-030A

mmc46.pdf^{(52.9KB, pdf)}

For lay and HCP, does the use of assessment, as opposed to no such assessment, improve CPR knowledge, skills, and learning/retention?

Consensus on science

No studies have compared outcomes of continuous versus end-of-course assessments for resuscitation training.

One LOE 1 manikin study¹⁹⁵ showed that including assessment during advanced life support training, compared with a control group without assessment, moderately improved performance at the 2-week postcourse scenario assessment. In another LOE 1 study¹⁹⁵ performance assessment after 6 months in the “testing” group compared with the control group failed to show a statistically significant improvement.

Treatment recommendation

Summative assessment at the end of advanced life support training should be considered as a strategy to improve learning outcomes. There is insufficient evidence to recommend an optimal method of assessment during life support training.

Education knowledge gaps

•
Effect of targeting training to family and friends of those at “high risk” of cardiac arrest.
•
Potential for tailoring preparation and training to individual learning styles.
•
Optimal assessment tools and strategy to promote learning resuscitation skills.
•
Optimal format and duration of self-instruction.
•
Impact of resuscitation training on performance in actual cardiac arrest.
•
Motivating bystanders to use AEDs.
•
Optimal training (alternative, minimal, no training, standardised instructor-led training) for use of AEDs in actual events.
•
Governmental, social, and political measures needed to improve public participation in life support programs.
•
Optimal ways to teach and assess leadership and team skills.
•
Specific techniques to optimise complete chest recoil during CPR without impacting depth, rate, and duty cycle of compression, including the use of prompt and feedback devices to acheive this.
•
Optimal method for implementing feedback devices into practice.
•
Specific advantages of prompt devices versus feedback devices and feedback timing (real time or immediately post-event).
•
Optimal method for learning and retention of knowledge/skills.
•
Standardization in simulation nomenclature and research methods.
•
Influence of equipment or manikin fidelity, environmental fidelity, and psychological fidelity on learning outcomes.
•
Optimal length of an instructor-led course.
•
Comparison of different course formats (e.g., a 2-day course versus four half-day modules).
•
Effect of ongoing clinical experience on retention of skills and need for assessment and/or refresher training.
•
Optimal interval and form for assessment.
•
Optimal format for refresher training when the need is identified.
•
Effect of type of measurement/assessment.
•
Effect of complexity on retention.
•
Optimal intervals and strategies for refresher courses for various populations.
•
Levels of knowledge/skill deterioration tolerable (clinically significant) before a refresher course is needed.
•
Correlation between rescuer knowledge/skill competencies and patient survival.
•
Modalities to increase knowledge/skill retention (clinical exposure, simulation, video learning).
•
Economy and logistics of shorter intervals for update/retraining.
•
Optimal form and timing of assessment to optimise learning, retention, and application of resuscitation skills.

Risks and effects on the rescuer of CPR training and actual CPR performance

The safety of rescuers is essential during training and actual CPR performance.

CPR and AED training and experience^EIT-014A^,^BLS-002A

For providers (lay or HCP), does undertaking training/performing actual CPR or use of a defibrillator (manual or AED), compared with no such training/performance, increase harm to the rescuer?

CPR and AED training and experienceEIT-014A, BLS-002A

EIT-014A

mmc26.pdf^{(267.6KB, pdf)}

BLS-002A

mmc3.pdf^{(74.7KB, pdf)}

For providers (lay or HCP), does undertaking training/performing actual CPR or use of a defibrillator (manual or AED), compared with no such training/performance, increase harm to the rescuer?

Compression-only CPR^BLS-005A^,BLS-005B

For rescuers performing CPR on adults or children, does compression-only CPR, compared with traditional CPR, result in an increase in adverse outcomes (e.g., fatigue)?

Compression-Only CPRBLS-005A^,BLS-005B

BLS-005A

mmc5.pdf^{(59.7KB, pdf)}

For rescuers performing CPR on adults or children, does compression-only CPR, compared with traditional CPR, result in an increase in adverse outcomes (e.g., fatigue)?

Use of barrier devices^BLS-002A

For rescuers performing CPR on adults or children (out-of-hospital and in-hospital), does the use of a barrier device, as opposed to no such use, improve outcomes (e.g., lower infection risk)?

Use of barrier devicesBLS-002A

BLS-002A

mmc3.pdf^{(74.7KB, pdf)}

For rescuers performing CPR on adults or children (out-of-hospital and in-hospital), does the use of a barrier device, as opposed to no such use, improve outcomes (e.g., lower infection risk)?

Physical effects

Consensus on science

CPR is very rarely associated with adverse events to the rescuer during training or actual performance. An observational study (LOE 4)¹⁹⁶ reported one muscle strain during a large public access defibrillation trial.¹⁹⁷ One prospective observational study (LOE 4)¹⁹⁸ described five musculoskeletal injuries (four back-related) associated with performing chest compressions in 1265 medical emergency team (MET) call participants. Two retrospective surveys of nurses and ambulance officers (LOE 4)199, 200 reported a high incidence of back symptoms attributed to performing CPR.

Three small simulation studies (LOE 4)201, 202, 203 using a greater number of ventilations per minute than those provided with the currently recommended compression-ventilation ratio (30:2) described hyperventilation-related symptoms during rescue breathing. Five single or small case series (LOE 5)204, 205, 206, 207, 208 described isolated adverse events from training or performing actual CPR (myocardial infarction, pneumothorax, chest pain, shortness of breath, nerve injury, allergy, vertigo). In one case report (LOE 5)²⁰⁹ a rescuer suffered a puncture wound to her left hand from a victim's sternotomy wires when performing chest compressions.

One simulation study (LOE 5)²¹⁰ of six physicians (aged 25–40 years) and another study (LOE 5)²¹¹ of 10 healthy medical students showed that performing chest compressions increased rescuer oxygen consumption. The authors considered that this increase in oxygen consumption was sufficient to cause myocardial ischaemia in individuals with coronary heart disease. A small randomised trial of cardiac rehabilitation patients (LOE 5)⁹, however, reported no adverse physical events during CPR training.

Treatment recommendation

CPR training and actual performance is safe in most circumstances. Learners and rescuers should consider personal and environmental risks before starting CPR. Individuals undertaking CPR training should be advised of the nature and extent of the physical activity required during the training program. Learners who develop significant symptoms (e.g., chest pain, severe shortness of breath) during CPR should be advised to stop. Rescuers who develop significant symptoms during actual CPR should consider stopping CPR.

Rescuer fatigue

A single LOE 4 in-hospital patient study²¹² of 3 min of continuous chest compressions with real-time feedback to the rescuer showed that the mean depth of compression deteriorated between 90 and 180 s, but compression rate was maintained. Three LOE 5 studies showed that some rescuers were unable to complete 5 min (laypeople),²¹³ 5–6 min (lay females),²¹⁴ or 18 min (HCPs)²¹⁵ of continuous chest compressions because of physical exhaustion. Two manikin studies (LOE 5)215, 216 demonstrated that performing chest compressions increases heart rate and oxygen consumption in HCPs. Two randomised manikin studies (LOE 5)213, 214 demonstrated that >5 to 10 min of continuous chest compressions by laypeople resulted in significantly less compression depth compared with standard 30:2 CPR, and no difference in compression rate. In one LOE 5 manikin study²¹⁷ experienced paramedics demonstrated no decline in chest compression quality below guideline recommendations during 10 min of BLS with any of three different compression–ventilation ratios (15:2, 30:2, and 50:2).

Four manikin studies (LOE 5)218, 219, 220, 221 showed a time-related deterioration in chest compression quality (mainly depth) during continuous compressions by HCPs. A single manikin study (LOE 5)²²² demonstrated that medical students performed better-quality chest compressions during the first 2 min of continuous chest compressions compared with 15:2 CPR, although there was deterioration in quality after 2 min. An LOE 5 manikin study²²³ of HCPs showed that the number of effective compressions (depth >38 mm) was the same if the rescuer changed every minute or every 2 min during 8 min of continuous chest compressions. Fatigue was reported more frequently after a 2-min period of compressions.

Treatment recommendation

When performing chest compressions, if feasible, it is reasonable to consider changing rescuers after about 2 min to prevent rescuer fatigue (demonstrated by deterioration in chest compression quality—in particular, depth of compressions). The change of rescuers performing chest compressions should be done with minimum interruption to the compressions.

Risks during defibrillation attempts

Consensus on science

Harm to the rescuer or a bystander is extremely rare during defibrillation attempts. A large randomised trial of public access defibrillation (LOE 1)¹⁹⁷ and four prospective studies of first-responder AED use (LOE 4224, 225, 226; LOE 5²²⁷) demonstrated that AEDs can be used safely by laypeople and first responders. One LOE 4 manikin study²²⁸ observed that laypeople using an AED touched the manikin during shock delivery in one third of defibrillation attempts.

An observational study (LOE 4)²²⁹ of 43 patients undergoing cardioversion measured only a small current leakage through “mock rescuers” wearing polyethylene gloves and simulating chest compression during shock delivery. One LOE 5 systematic review²³⁰ identified eight articles that reported a total of 29 adverse events associated with defibrillation. Only one case (LOE 5)²³¹ has been published since 1997. A 150-J biphasic shock was delivered during chest compressions. The rescuer doing chest compressions felt the electric discharge and did not suffer any harm. Seven cases were due to accidental or intentional defibrillator misuse (LOE 5)232, 233, 234, 235, 236, one was due to device malfunction (LOE 5)²³⁷, and four occurred during training/maintenance procedures (LOE 5)237, 238. A case series (LOE 5)²³⁷ identified 14 adverse events during actual resuscitation; all caused only minor harm.

The risks to individuals in contact with a patient during implanted cardioverter defibrillator (ICD) discharge are difficult to quantify. Four single case reports (LOE 5)239, 240, 241, 242 described shocks to the rescuer from discharging ICDs. ICD discharge was associated with a significant jolt to rescuers and in one case resulted in a peripheral nerve injury.²⁴²

Three animal studies suggested that the use of defibrillators in wet environments is safe (LOE 5)243, 244, 245.

There are no reports of harm to rescuers from attempting defibrillation in wet environments.

Treatment recommendation

The risks associated with defibrillation are less than previously thought. There is insufficient evidence to recommend that continuing manual chest compressions during shock delivery for defibrillation is safe. It is reasonable for rescuers to wear gloves when performing CPR and attempting defibrillation (manual and/or AED) but resuscitation should not be delayed/withheld if gloves are not available.

There is insufficient evidence to make a recommendation about the safety of contacting a patient during ICD discharge. There is insufficient evidence to make a recommendation about the best method of avoiding shocks to the rescuer from an ICD discharge during CPR.

Although there are no reports of harm to rescuers, there is insufficient evidence to make a recommendation about the safety of defibrillation in wet environments.

Psychological effects

Consensus on science

One large prospective trial of PAD (LOE 4)¹⁹⁶ reported a few adverse psychological effects requiring intervention that were associated with CPR or AED use. One prospective analysis of stress reactions associated with a trial of public access defibrillation (LOE 4)²⁴⁶ reported low levels of stress in those responding to an emergency in this setting. One prospective observational study of 1265 MET calls (LOE 4)¹⁹⁸ described “psychological injury” related to CPR performance in one rescuer. Two large retrospective questionnaire-based reports relating to performance of CPR by a bystander (LOE 4)247, 248 reported that nearly all respondents regarded their intervention as a positive experience. Two small retrospective studies of nurses involved in delivery of CPR (LOE 4²⁴⁹; LOE 5²⁵⁰) noted the stress involved and the importance of recognition and management of this stress.

Treatment recommendation

There are few reports of psychological harm to rescuers after involvement in a resuscitative attempt. There is insufficient evidence to support or refute any recommendation about minimizing the incidence of psychological harm to rescuers.

Disease transmission

Consensus on science

There are only a very few cases reported (LOE 5) where performing CPR has been implicated in disease transmission. Salmonella infantis,²⁵¹ panton-valentine leucocidin staphylococcus aureus,²⁵² severe acute respiratory syndrome (SARS),²⁵³ meningococcal meningitis,²⁵⁴ helicobacter pylori,²⁵⁵ herpes simplex virus,256, 257 cutaneous tuberculosis,²⁵⁸ stomatitis,²⁵⁹ tracheitis,²⁶⁰ shigella,²⁶¹ and streptococcus pyogenes²⁶² have been implicated. One report described herpes simplex virus infection as a result of training in CPR (LOE 5)²⁶³. One systematic review found that in the absence of high-risk activities, such as intravenous cannulation, there were no reports of transmission of hepatitis B, hepatitis C, human immunodeficiency virus (HIV), or cytomegalovirus during either training or actual CPR (LOE 5)²⁶⁴.

Treatment recommendation

The risk of disease transmission during training and actual CPR performance is very low. Rescuers should take appropriate safety precautions, especially if a victim is known to have a serious infection (e.g., HIV, tuberculosis, hepatitis B virus, or SARS).

Barrier devices

Consensus on science

No human studies have addressed the safety, effectiveness, or feasibility of using barrier devices to prevent patient contact during rescue breathing. Nine clinical reports (LOE 5)257, 258, 264, 265, 266, 267, 268 proposed or advocated the use of barrier devices to protect the rescuer from transmitted disease. Three LOE 5 studies269, 270, 271 showed that barrier devices can decrease transmission of bacteria in controlled laboratory settings.

Treatment recommendation

The risk of disease transmission is very low and initiating rescue breathing without a barrier device is reasonable. If available, rescuers may consider using a barrier device. Safety precautions should be taken if the victim is known to have a serious infection (e.g., HIV, tuberculosis, hepatitis B virus, or SARS).

Knowledge gaps

•
Actual incidence of disease transmission and other harm during CPR
•
Safety of hands-on defibrillation
•
Safest type of glove
•
CPR in patients with ICDs
•
Role of barrier devices

Rescuer willingness to respond

Increasing the willingness of individuals to respond to a cardiac arrest with early recognition, calling for help, and initiation of CPR is essential to improve survival rates.

Factors that increase outcomes^EIT-008A^,^EIT-008B

Among bystanders (lay or HCP), are there any specific factors, compared with standard interventions, that increase outcomes (e.g., willingness to provide CPR or the actual performance of CPR [standard or chest compression only]) in adults or children with cardiac arrest (prehospital)?

Consensus on science

Sixteen LOE 4 studies5, 246, 272, 273, 274, 275, 276, 277, 278, 279, 280, 281, 282, 283, 284, 285 have suggested that many factors decrease the willingness of bystanders to start CPR, including bystander characteristics (panic, fear of disease or harming the victim or performing CPR incorrectly) and victim characteristics (stranger, being unkempt, evidence of drug use, blood, or vomit).

Two studies (LOE 1¹³¹; LOE 4²⁸⁶) have suggested that training rescuers to recognise gasping as a sign of cardiac arrest improves identification of cardiac arrest victims. Ten studies (LOE 2¹⁰; LOE 45, 272, 274, 280, 281, 282, 287, 288, 289) showed increased bystander CPR rate in those trained in CPR, especially if training had occurred within five years. Three LOE 5 studies272, 275, 290 showed that willingness to perform CPR was increased when emergency dispatchers provided telephone CPR instructions. Eight LOE 4 studies273, 277, 280, 284, 285, 287, 291, 292 provided evidence that potential rescuers would be more likely to start CPR if they had the option to use compression-only CPR.

Treatment recommendation

To increase willingness to perform CPR
- •
  Laypeople should receive training in CPR. This training should include the recognition of gasping or abnormal breathing as a sign of cardiac arrest when other signs of life are absent.
- •
  Laypeople should be trained to start resuscitation with chest compressions in adult and paediatric victims.
- •
  If unwilling or unable to perform ventilations, rescuers should be instructed to continue compression-only CPR.
- •
  EMS dispatchers should provide CPR instructions to callers who report cardiac arrest.
- •
  When providing CPR instructions, EMS dispatchers should include recognition of gasping and abnormal breathing.

Knowledge gaps

•
Optimal method for teaching recognition of cardiac arrest including gasping, agonal, and abnormal breathing.
•
Optimal method for laypeople to recognise return of spontaneous circulation (ROSC).
•
Optimal methods for mass education of laypeople.

Factors that increase outcomesEIT-008A, EIT-008B

EIT-008A

mmc16.pdf^{(106.6KB, pdf)}

EIT-008B

mmc17.pdf^{(134.7KB, pdf)}

Among bystanders (lay or HCP), are there any specific factors, compared with standard interventions, that increase outcomes (e.g., willingness to provide CPR or the actual performance of CPR [standard or chest compression only]) in adults or children with cardiac arrest (prehospital)?

Consensus on science

Sixteen LOE 4 studies5, 246, 272, 273, 274, 275, 276, 277, 278, 279, 280, 281, 282, 283, 284, 285 have suggested that many factors decrease the willingness of bystanders to start CPR, including bystander characteristics (panic, fear of disease or harming the victim or performing CPR incorrectly) and victim characteristics (stranger, being unkempt, evidence of drug use, blood, or vomit).

Two studies (LOE 1¹³¹; LOE 4²⁸⁶) have suggested that training rescuers to recognise gasping as a sign of cardiac arrest improves identification of cardiac arrest victims. Ten studies (LOE 2¹⁰; LOE 45, 272, 274, 280, 281, 282, 287, 288, 289) showed increased bystander CPR rate in those trained in CPR, especially if training had occurred within five years. Three LOE 5 studies272, 275, 290 showed that willingness to perform CPR was increased when emergency dispatchers provided telephone CPR instructions. Eight LOE 4 studies273, 277, 280, 284, 285, 287, 291, 292 provided evidence that potential rescuers would be more likely to start CPR if they had the option to use compression-only CPR.

Treatment recommendation

To increase willingness to perform CPR
- •
  Laypeople should receive training in CPR. This training should include the recognition of gasping or abnormal breathing as a sign of cardiac arrest when other signs of life are absent.
- •
  Laypeople should be trained to start resuscitation with chest compressions in adult and paediatric victims.
- •
  If unwilling or unable to perform ventilations, rescuers should be instructed to continue compression-only CPR.
- •
  EMS dispatchers should provide CPR instructions to callers who report cardiac arrest.
- •
  When providing CPR instructions, EMS dispatchers should include recognition of gasping and abnormal breathing.

Knowledge gaps

•
Optimal method for teaching recognition of cardiac arrest including gasping, agonal, and abnormal breathing
•
Optimal method for laypeople to recognise return of spontaneous circulation (ROSC)
•
Optimal methods for mass education of laypeople

Implementation and teams

The best scientific evidence for resuscitation will have little impact on patient outcomes if it is not effectively translated into clinical practice. Successful implementation is dependent on effective educational strategies to ensure that resuscitation providers have the necessary knowledge and skills in combination with the provision of necessary infrastructure and resources.²⁹³ Education itself is only one strategy for implementing changes. This section addresses the need for a framework for successful implementation of guidelines, including broad implementation strategies that include educational activities.

Implementation strategies

Little is known about what strategies work best for implementing evidence-based guidelines in communities, institutions, or units. Implementation of the 2005 resuscitation guidelines in emergency medical services agencies was reported to take a mean of 416 ± 172 days in the Resuscitation Outcomes Consortium (ROC) sites²⁹⁴ and 18 months in the Netherlands.²⁹⁵ Identified barriers to rapid implementation included delays in getting staff trained, equipment delays, and organisational decision making.294, 295 This section provides insight into several elements that appear to facilitate successful implementation.

Implementation factors^EIT-022^,^EIT-022B

In communities where processes/guidelines are being implemented, does the use of any specific factors, compared with no such use, improve outcomes (e.g., success of implementation)?

Consensus on science

Using the implementation of therapeutic hypothermia as an example, two LOE 3296, 297 and one LOE 5²⁹⁸ single-institution interventional studies supported the use of a written protocol, pathway, or standard operating procedure as part of a comprehensive approach to implementing the therapeutic hypothermia guideline. One LOE 2 survey²⁹⁹ and one LOE 3 single-institution intervention³⁰⁰ also supported the use of written protocols, although Hay³⁰⁰ only briefly described cointerventions used.

A wide spectrum of evidence supports the use of a comprehensive, multifaceted approach to guideline implementation, including identification and use of clinical champions, a consensus-building process, multidisciplinary involvement, written protocols, detailed process descriptions, practical logistic support, multimodality/multilevel education, and rapid cycle improvement (e.g., Plan, Do, Study, Act) to respond to problems as they arise. The evidence supporting this multifaceted approach includes one LOE 3 study,²⁹⁶ one LOE 5 intervention description,²⁹⁸ two LOE 5 theoretical reviews,301, 302 and four LOE 5 studies extrapolated from nonhypothermia nonarrest settings (2 RCTs,303, 304 one concurrent controlled trial,³⁰⁵ and one retrospective controlled trial³⁰⁶).

Treatment recommendation

Institutions or communities planning to implement complex guidelines such as therapeutic hypothermia should consider using a comprehensive, multifaceted approach including clinical champions, a consensus-building process, multidisciplinary involvement, written protocols, detailed process description, practical logistic support, multimodality/multilevel education, and rapid cycle improvement methods.

Investigators studying implementation of guidelines should consider using a framework for implementing guidelines (e.g., Brach-AHRQ, 2008)³⁰² and report whether results were measured or estimated, and whether they were sustained.

Knowledge gaps

•
Which specific factors (such as consensus-building, logistic support, rapid cycle improvement) are most critical for successful guidelines implementation?
•
Differences between in-hospital and EMS implementations.
•
Effectiveness of a multilevel approach (country, community, organisation, unit, individual).
•
Importance of describing all cointerventions during implementation studies.
•
Repeat surveys over time with same population to assess progress in implementation and to identify success factors and barriers.

Implementation factorsEIT-022, EIT-022B

EIT-022

mmc2.pdf^{(109.7KB, pdf)}

EIT-022B

mmc2.pdf^{(109.7KB, pdf)}

In communities where processes/guidelines are being implemented, does the use of any specific factors, compared with no such use, improve outcomes (e.g., success of implementation)?

Consensus on science

Using the implementation of therapeutic hypothermia as an example, two LOE 3296, 297 and one LOE 5²⁹⁸ single-institution interventional studies supported the use of a written protocol, pathway, or standard operating procedure as part of a comprehensive approach to implementing the therapeutic hypothermia guideline. One LOE 2 survey²⁹⁹ and one LOE 3 single-institution intervention³⁰⁰ also supported the use of written protocols, although Hay³⁰⁰ only briefly described cointerventions used.

A wide spectrum of evidence supports the use of a comprehensive, multifaceted approach to guideline implementation, including identification and use of clinical champions, a consensus-building process, multidisciplinary involvement, written protocols, detailed process descriptions, practical logistic support, multimodality/multilevel education, and rapid cycle improvement (e.g., Plan, Do, Study, Act) to respond to problems as they arise. The evidence supporting this multifaceted approach includes one LOE 3 study,²⁹⁶ one LOE 5 intervention description,²⁹⁸ two LOE 5 theoretical reviews,301, 302 and four LOE 5 studies extrapolated from nonhypothermia nonarrest settings (2 RCTs,303, 304 one concurrent controlled trial,³⁰⁵ and one retrospective controlled trial³⁰⁶).

Treatment recommendation

Institutions or communities planning to implement complex guidelines such as therapeutic hypothermia should consider using a comprehensive, multifaceted approach including clinical champions, a consensus-building process, multidisciplinary involvement, written protocols, detailed process description, practical logistic support, multimodality/multilevel education, and rapid cycle improvement methods.

Investigators studying implementation of guidelines should consider using a framework for implementing guidelines (e.g., Brach-AHRQ, 2008)³⁰² and report whether results were measured or estimated, and whether they were sustained.

Knowledge gaps

•
Which specific factors (such as consensus-building, logistic support, rapid cycle improvement) are most critical for successful guidelines implementation?
•
Differences between in-hospital and EMS implementations.
•
Effectiveness of a multilevel approach (country, community, organisation, unit, individual).
•
Importance of describing all cointerventions during implementation studies.
•
Repeat surveys over time with same population to assess progress in implementation and to identify success factors and barriers.

Individual and team factors

Individual and team factors impact performance during resuscitative attempts. This section describes specific factors that have an impact on performance during simulated or actual cardiac arrest.

Prehospital physicians^ALS-SC-077

In adult cardiac arrest (prehospital), does the performance of advanced life support procedures by experienced physicians, as opposed to standard care (without physicians), improve outcomes (e.g., ROSC, survival)?

Consensus on science

In adult cardiac arrest, physician presence during resuscitation, compared with paramedics alone, has been reported to increase compliance with guidelines (LOE 2³⁰⁷; LOE 4³⁰⁸) and physicians in some systems can perform advanced resuscitation procedures more successfully (LOE 2307, 309; LOE 4310, 311, 312).

When compared within individual systems, four studies suggested improved survival to hospital discharge when physicians were part of the resuscitation team (LOE 2313, 314; LOE 3315, 316) and 10 studies suggested no difference in survival of the event (LOE 2)307, 313 or survival to hospital discharge (LOE 2)307, 315, 317, 318, 319, 320, 321, 322, 323. One study found lower survival of the event when physicians were part of the resuscitation team (LOE 2)³²³.

Studies indirectly comparing resuscitation outcomes between physician-staffed and other systems are difficult to interpret because of the heterogeneity among systems, independent of physician-staffing (LOE 5)³²⁴. High survival rates after cardiac arrest have been reported from systems that employ experienced physicians as part of the EMS response (LOE 3325, 326; LOE 4310, 312, 327) and these survival rates may be higher than in systems that rely on nonphysician providers (LOE 2³²⁸; LOE 3325, 326, 329). Other comparisons noted no difference in survival between systems using paramedics or physicians as part of the response (LOE 3)330, 331. Well-organised nonphysician systems with highly trained paramedics also reported high survival rates (LOE 5)³²⁴. There are no RCTs to address this question.

Treatment recommendation

There is insufficient evidence to make a recommendation for or against physician versus nonphysician providers of ALS during out-of-hospital CPR.

Knowledge gaps

More data are required to determine the training required to achieve best outcomes, the level of training and experience required to maintain competence in procedural skills, and the cost-effectiveness of physicians compared with nonphysicians.

Prehospital physiciansALS-SC-077

ALS-SC-077

mmc2.pdf^{(109.7KB, pdf)}

In adult cardiac arrest (prehospital), does the performance of advanced life support procedures by experienced physicians, as opposed to standard care (without physicians), improve outcomes (e.g., ROSC, survival)?

Consensus on science

In adult cardiac arrest, physician presence during resuscitation, compared with paramedics alone, has been reported to increase compliance with guidelines (LOE 2³⁰⁷; LOE 4³⁰⁸) and physicians in some systems can perform advanced resuscitation procedures more successfully (LOE 2307, 309; LOE 4310, 311, 312).

When compared within individual systems, four studies suggested improved survival to hospital discharge when physicians were part of the resuscitation team (LOE 2313, 314; LOE 3315, 316) and 10 studies suggested no difference in survival of the event (LOE 2)307, 313 or survival to hospital discharge (LOE 2)307, 315, 317, 318, 319, 320, 321, 322, 323. One study found lower survival of the event when physicians were part of the resuscitation team (LOE 2)³²³.

Studies indirectly comparing resuscitation outcomes between physician-staffed and other systems are difficult to interpret because of the heterogeneity among systems, independent of physician-staffing (LOE 5)³²⁴. High survival rates after cardiac arrest have been reported from systems that employ experienced physicians as part of the EMS response (LOE 3325, 326; LOE 4310, 312, 327) and these survival rates may be higher than in systems that rely on nonphysician providers (LOE 2³²⁸; LOE 3325, 326, 329). Other comparisons noted no difference in survival between systems using paramedics or physicians as part of the response (LOE 3)330, 331. Well-organised nonphysician systems with highly trained paramedics also reported high survival rates (LOE 5)³²⁴. There are no RCTs to address this question.

Treatment recommendation

There is insufficient evidence to make a recommendation for or against physician versus nonphysician providers of ALS during out-of-hospital CPR.

Knowledge gaps

More data are required to determine the training required to achieve best outcomes, the level of training and experience required to maintain competence in procedural skills, and the cost-effectiveness of physicians compared with nonphysicians.

Advanced life support checklists^EIT-031A^,^EIT-031B

Does the use of a checklist during adult and paediatric advanced life support as opposed to no checklist, improve outcomes (e.g., compliance with guidelines, other outcomes)?

Consensus on science

Four LOE 5 randomised trials of cognitive aids/checklists for simulated basic life support,92, 95, 332, 333 three LOE 5 randomised trials of cognitive aids in simulated anaesthetic emergency or advanced resuscitation,334, 335, 336 and one LOE 5 observational study³³⁷ showed improvement in proxy outcomes (e.g., proper dosing of medications or performance of correct CPR procedures). One randomised³³⁸ and one nonrandomised³³⁹ trial (LOE 5) of cognitive aids showed improved recall of factual information important for effective advanced life support. Two LOE 4 surveys340, 341 on the use of checklists in actual resuscitations reported that physicians perceived cognitive aids to be useful. One LOE 5 retrospective analysis of actual anaesthesia emergency³⁴² suggested that a cognitive aid algorithm might be helpful in diagnosis and management. One LOE 5, three-armed study of simulated basic life support³³³ demonstrated no difference in CPR performance between the short-checklist arm and the no-checklist arm, but a positive outcome in the long-checklist arm. One LOE 5 study of neonatal resuscitation³⁴³ did not demonstrate any benefit from using a poster prompt.

Potential harm was found in one LOE 5 randomised trial of simulated basic life support¹⁰³ in which participants with a mobile-phone cognitive aid had >1-min delay in starting CPR. An LOE 5 simulated PALS study³⁴⁴ showed potential harm because a significant portion of hand-held cognitive aid users applied the wrong algorithm. The outcome of using a cognitive aid such as a checklist may be specific to the aid or the situation.

Treatment recommendation

It is reasonable to use cognitive aids (e.g., checklists) during resuscitation, provided that they do not delay the start of resuscitative efforts. Aids should be validated using simulation or patient trials, both before and after implementation, to guide rapid cycle improvement.

Knowledge gaps

•
The value of cognitive aids in simulated and actual resuscitation.
•
Potential for unintended consequences associated with the use of a cognitive aid (especially delay to initiation of intervention or use of incorrect algorithm).
•
Utility of specific cognitive aids with specific providers or in specific situations.
•
Human factors issues in solo and team resuscitation.
•
Optimal model for follow-up quality assurance (assessment of efficacy and rapid cycle improvement) after introduction of a cognitive aid.
•
Transferability or generalizability of cognitive aids across settings.
•
Can cognitive aids such as simple checklists be used without training?

Advanced life support checklistsEIT-031A, EIT-031B

EIT-031A

mmc47.pdf^{(74.3KB, pdf)}

EIT-031B

mmc48.pdf^{(59.7KB, pdf)}

Does the use of a checklist during adult and paediatric advanced life support as opposed to no checklist, improve outcomes (e.g., compliance with guidelines, other outcomes)?

Consensus on science

Four LOE 5 randomised trials of cognitive aids/checklists for simulated basic life support,92, 95, 332, 333 three LOE 5 randomised trials of cognitive aids in simulated anaesthetic emergency or advanced resuscitation,334, 335, 336 and one LOE 5 observational study³³⁷ showed improvement in proxy outcomes (e.g., proper dosing of medications or performance of correct CPR procedures). One randomised³³⁸ and one nonrandomised³³⁹ trial (LOE 5) of cognitive aids showed improved recall of factual information important for effective advanced life support. Two LOE 4 surveys340, 341 on the use of checklists in actual resuscitations reported that physicians perceived cognitive aids to be useful. One LOE 5 retrospective analysis of actual anaesthesia emergency³⁴² suggested that a cognitive aid algorithm might be helpful in diagnosis and management. One LOE 5, three-armed study of simulated basic life support³³³ demonstrated no difference in CPR performance between the short-checklist arm and the no-checklist arm, but a positive outcome in the long-checklist arm. One LOE 5 study of neonatal resuscitation³⁴³ did not demonstrate any benefit from using a poster prompt.

Potential harm was found in one LOE 5 randomised trial of simulated basic life support¹⁰³ in which participants with a mobile-phone cognitive aid had >1-min delay in starting CPR. An LOE 5 simulated PALS study³⁴⁴ showed potential harm because a significant portion of hand-held cognitive aid users applied the wrong algorithm. The outcome of using a cognitive aid such as a checklist may be specific to the aid or the situation.

Treatment recommendation

It is reasonable to use cognitive aids (e.g., checklists) during resuscitation, provided that they do not delay the start of resuscitative efforts. Aids should be validated using simulation or patient trials, both before and after implementation, to guide rapid cycle improvement.

Knowledge gaps

•
The value of cognitive aids in simulated and actual resuscitation.
•
Potential for unintended consequences associated with the use of a cognitive aid (especially delay to initiation of intervention or use of incorrect algorithm).
•
Utility of specific cognitive aids with specific providers or in specific situations.
•
Human factors issues in solo and team resuscitation.
•
Optimal model for follow-up quality assurance (assessment of efficacy and rapid cycle improvement) after introduction of a cognitive aid.
•
Transferability or generalizability of cognitive aids across settings.
•
Can cognitive aids such as simple checklists be used without training?

Team briefings/debriefings^EIT-001A^,^EIT-001B

For resuscitation teams, do briefings/debriefings, when compared to no briefings/debriefings, improve performance or outcomes?

Team briefings/debriefingsEIT-001A, EIT-001B

EIT-001A

mmc6.pdf^{(57.1KB, pdf)}

EIT-001B

mmc7.pdf^{(101.4KB, pdf)}

For resuscitation teams, do briefings/debriefings, when compared to no briefings/debriefings, improve performance or outcomes?

HCP briefings/debriefings^NRP-033A^,^NRP-033B

For HCPs, do briefings (before a learning or patient-care experience) and/or debriefings (after a learning or patient care experience), when compared to no briefings or debriefings, improve the acquisition of content knowledge, technical skills and behavioral skills required for effective and safe resuscitation?

Consensus on science

The terms ‘briefing,’ ‘debriefing,’ and ‘feedback’ are often used interchangeably in studies and have therefore been grouped as ‘briefings/debriefings’ in the Consensus on Science. Debriefings tend to occur after the event. Debriefing is an integral part of the actual training intervention in many studies. This makes it difficult to measure the effect of the debriefing.

Evidence from one LOE 1 prospective RCT³⁴⁵ and 16 other studies (LOE 3–4)71, 73, 93, 125, 126, 132, 346, 347, 348, 349, 350, 351, 352, 353, 354, 355 documented improvement with briefings/debriefings in the acquisition of the content knowledge, technical skills, and/or behavioral skills required for effective and safe resuscitation. One LOE 4 study³⁵⁶ revealed no effect of briefings/debriefings on performance. No studies indicated that the use of briefings/debriefings had any negative effect.

Treatment recommendation

It is reasonable to recommend the use of briefings and debriefings during both learning and actual clinical activities.

Knowledge gaps

•
Relative benefits of team versus individual briefings/debriefings.
•
Differential effectiveness of video, verbal, and other measures of feedback.
•
Effects of briefings/debriefings on technical versus nontechnical skills.

HCP briefings/debriefingsNRP-033A, NRP-033B

NRP-033A

mmc50.pdf^{(71.7KB, pdf)}

NRP-033B

mmc51.pdf^{(56.1KB, pdf)}

For HCPs, do briefings (before a learning or patient-care experience) and/or debriefings (after a learning or patient care experience), when compared to no briefings or debriefings, improve the acquisition of content knowledge, technical skills and behavioral skills required for effective and safe resuscitation?

Consensus on science

The terms ‘briefing,’ ‘debriefing,’ and ‘feedback’ are often used interchangeably in studies and have therefore been grouped as ‘briefings/debriefings’ in the Consensus on Science. Debriefings tend to occur after the event. Debriefing is an integral part of the actual training intervention in many studies. This makes it difficult to measure the effect of the debriefing.

Evidence from one LOE 1 prospective RCT³⁴⁵ and 16 other studies (LOE 3–4)71, 73, 93, 125, 126, 132, 346, 347, 348, 349, 350, 351, 352, 353, 354, 355 documented improvement with briefings/debriefings in the acquisition of the content knowledge, technical skills, and/or behavioral skills required for effective and safe resuscitation. One LOE 4 study³⁵⁶ revealed no effect of briefings/debriefings on performance. No studies indicated that the use of briefings/debriefings had any negative effect.

Treatment recommendation

It is reasonable to recommend the use of briefings and debriefings during both learning and actual clinical activities.

Knowledge gaps

•
Relative benefits of team versus individual briefings/debriefings.
•
Differential effectiveness of video, verbal, and other measures of feedback.
•
Effects of briefings/debriefings on technical versus nontechnical skills.

System factors

This section describes broader resuscitation programs and implementation strategies that have an impact at a system level.

AED program factors^EIT-015

In AED programs, what specific factors when included (e.g., linkage to 911 registries, location of program [including home]), compared with not included predict an effective outcome for the program?

AED program factorsEIT-015

EIT-015

mmc27.pdf^{(125.1KB, pdf)}

In AED programs, what specific factors when included (e.g., linkage to 911 registries, location of program [including home]), compared with not included predict an effective outcome for the program?

Outcomes of AED programs^BLS-004B

In adults and children with out-of-hospital cardiac arrest (including residential settings), does implementation of a public access AED program, as opposed to traditional EMS response, improve successful outcomes (e.g., ROSC)?

Consensus on science

One RCT (LOE 1)¹⁹⁷, four prospective controlled cohort studies (LOE 2)357, 358, 359, 360, one study using historical controls (LOE 3)³⁶¹, nine observational studies (LOE 4)226, 227, 362, 363, 364, 365, 366, 367, 368, and one mathematical modeling study (LOE 5)³⁶⁹ showed that AED programs are safe and feasible and significantly increase survival of out-of-hospital ventricular fibrillation (VF) cardiac arrest if the emergency response plan is effectively implemented and sustained.

For EMS programs, 10 studies (LOE 1³⁷⁰; LOE 2³⁵⁸; LOE 3224, 371, 372; LOE 4373, 374, 375, 376, 377) supported AED use; 11 studies (LOE 2378, 379; LOE 3380, 381, 382, 383; LOE 4384, 385, 386, 387, 388) were neutral, and two meta-analyses359, 389 suggested benefit.

For first-responder use, two studies (LOE 2³⁹⁰; LOE 3³⁹¹) supported use of AEDs by fire or police first responders, but six studies (LOE 1³⁹²; LOE 2³⁹³; LOE 3394, 395, 396; LOE 4³⁹⁷) were neutral.

In public access trials, six studies (LOE 1¹⁹⁷; LOE 2³⁵⁷; LOE 3361, 362; LOE 4365, 367) supported PAD. Two studies (LOE 3³⁹⁸; LOE 5³⁹⁹) were neutral. Five LOE 4 studies226, 363, 364, 400, 401 demonstrated survival attributed to AED programs in casinos, airplanes, or airports. One LOE 4 study⁴⁰² was neutral.

For home AED deployment, three studies (LOE 1197, 403; LOE 2⁴⁰⁴) showed that home AED programs are safe and feasible but were unlikely to result in a significant increase in survival of out-of-hospital VF cardiac arrest.

For on-site AEDs in public places, 11 studies (LOE 1¹⁹⁷; LOE 2³⁵⁷; LOE 3224, 361, 362; LOE 4226, 363, 364, 365, 366, 405) supported on-site AEDs. This approach demonstrates high survival at low deployment rates. Four studies (LOE 1³⁹²; LOE 2⁴⁰⁶; LOE 3395, 398) did not demonstrate improvement in survival to discharge compared with EMS, despite better response time.

For mobile AEDs, three studies (LOE 2357, 358; LOE 3³⁹¹) reported that community first responders (CFRs) equipped with AEDs achieved improvement in survival when they arrived at the patient's side sooner than traditional EMS responders.

In one LOE 2 study³⁵⁸ first responders were trained only in AED use; however, most survivors received CPR and AED, suggesting a role for CPR. There is no evidence to support a specific type of rescuer as better than another. One LOE 3 study³⁶¹ noted that even untrained bystanders achieved good results.

One LOE 3 study³⁹⁸ reported that use of a restrictive dispatch protocol (unresponsive and not breathing) to summon first responders reduced the frequency of deployment, by reducing not only false alarms (false-positives) but also legitimate calls (true positives). In contrast, in one LOE 2 study³⁵⁸ a less-restrictive dispatch protocol (unresponsive patient) yielded more false-positives as part of a wider involvement of first responders and increased survival. No difference in response interval appeared to be related to instrument of dispatch (telephone compared with pager).

Treatment recommendation

Implementation of AED programs in public settings should be based on the characteristics of published reports of successful programs in similar settings.

Home AED use for high-risk individuals who do not have an ICD is safe and feasible and may be considered on an individual basis, but has not been shown to change overall survival rates.

Because population-specific (e.g., rate of witnessed arrest) and program-specific (e.g., response time) characteristics affect survival, when implementing an AED program, community and program leaders should consider factors such as location, development of a team with responsibility for monitoring and maintaining the devices, training and retraining programs for those who are likely to use the AED, coordination with the local EMS agency, and identification of a group of paid or volunteer individuals who are committed to using the AED for victims of arrest.

Knowledge gaps

•
Community or program characteristics of effective AED programs

Other specific worksheets that would be helpful are:

•
Evaluating AED deployment strategies
•
Should communities perform cardiac arrest surveillance to inform placement of public AEDs?

Outcomes of AED programsBLS-004B

BLS-004B

mmc4.pdf^{(99KB, pdf)}