Effect of the Use of Metronome Feedback on the Quality of Pediatric Cardiopulmonary Resuscitation

Although the use of audio feedback with devices such as metronomes during cardiopulmonary resuscitation (CPR) is a simple method for improving CPR quality, its effect on the quality of pediatric CPR has not been adequately evaluated. In this study, 64 healthcare providers performed CPR (with one- and two-handed chest compression (OHCC and THCC, respectively)) on a pediatric resuscitation manikin (Resusci Junior QCPR), with and without audio feedback using a metronome (110 beats/min). CPR was performed on the floor, with a compression-to-ventilation ratio of 30:2. For both OHCC and THCC, the rate of achievement of an adequate compression rate during CPR was significantly higher when performed with metronome feedback than that without metronome feedback (CPR with vs. without feedback: 100.0% (99.0, 100.0) vs. 94.0% (69.0, 99.0), p < 0.001, for OHCC, and 100.0% (98.5, 100.0) vs. 91.0% (34.5, 98.5), p < 0.001, for THCC). However, the rate of achievement of adequate compression depth during the CPR performed was significantly higher without metronome feedback than that with metronome feedback (CPR with vs. without feedback: 95.0% (23.5, 99.5) vs. 98.5% (77.5, 100.0), p = 0.004, for OHCC, and 99.0% (95.5, 100.0) vs. 100.0% (99.0, 100.0), p = 0.003, for THCC). Although metronome feedback during pediatric CPR could increase the rate of achievement of adequate compression rates, it could cause decreased compression depth.

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Metronome Use Positively Affect Cardiopulmonary Resuscitation Parameters: Prospective Observational Multicenter Manikin Study

10.22514/sv.2020.16.0005 ◽

2020 ◽

Keyword(s):

Cardiopulmonary Resuscitation ◽

Minute Ventilation ◽

Heart Association ◽

High Volume ◽

Compression Rate ◽

Compression Depth ◽

Manikin Study ◽

Volume Ventilation ◽

Cpr Quality

Objective: Clinical studies have shown that eliminating performer errors is important to ensure high quality cardiopulmonary resuscitation (CPR). Literature on the effects of metronome use on the quality of CPR is scarce. This study aimed to investigate the effect of metronome use on the quality of cardiopulmonary resuscitation. Methods: Thirty volunteer emergency physicians who were divided into 15 groups participated in this prospective, observational, multi-center, manikin study. Firstly, each participant performed conventional CPR on a manikin, and then performed metronome-guided CPR after a short break. Parameters affecting CPR quality were evaluated based on the recommendations of the 2015 American Heart Association CPR and Emergency Cardiovascular Care Guideline. In addition, the fatigue levels of participants were evaluated using the Borg Fatigue Index. Results: Metronome-guided CPR significantly improved the chest compression rate (median (Interquartile Range-IQR); 128 (22) compressions/min vs. 110 (2) compressions/min; 95%CI, p < 0.001), deep compression rate (median (IQR); 95.25 (80) compressions/min vs. 72.63 (105) compressions/min; 95%CI, p < 0.001), compression depth (median (IQR); 62.50 (11) mm vs. 60.25 (14) mm; 95%CI, p = 0.016), ventilation number (median (IQR); 11.25 (6) ventilations/min vs. 9.50 (1) ventilations/min; 95%CI, p = 0.001), high-volume ventilation count (median (IQR); 10.13 (6) ventilations/min vs. 9.50 (1) ventilations/min; 95%CI, p = 0.026), minute ventilation volume (median (IQR); 11.75 (10) L/min vs. 8.03 (3) L/min; 95%CI, p < 0.05), and fatigue levels (median (IQR); 3 (2) vs. 2 (2); in 95%CI, p < 0.05). Conclusions: Our study showed that metronome is a useful device for reaching effective CPR. Metronome guidance may change the CPR parameters positively. This study is in accordance with previous studies which have investigated the effect of metronome-guided CPR on survival.

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Effect of Acute Exposure to Altitude on the Quality of Chest Compression‐Only Cardiopulmonary Resuscitation in Helicopter Emergency Medical Services Personnel: A Randomized, Controlled, Single‐Blind Crossover Trial

Journal of the American Heart Association ◽

10.1161/jaha.121.021090 ◽

2021 ◽

Author(s):

Anna Vögele ◽

Michiel Jan van Veelen ◽

Tomas Dal Cappello ◽

Marika Falla ◽

Giada Nicoletto ◽

...

Keyword(s):

Emergency Medical Services ◽

Chest Compression ◽

Acute Exposure ◽

Medical Services ◽

Compression Depth ◽

Helicopter Emergency Medical Services ◽

Emergency Medical ◽

Emergency Medical Services Personnel ◽

Cpr Quality

Background Helicopter emergency medical services personnel operating in mountainous terrain are frequently exposed to rapid ascents and provide cardiopulmonary resuscitation (CPR) in the field. The aim of the present trial was to investigate the quality of chest compression only (CCO)‐CPR after acute exposure to altitude under repeatable and standardized conditions. Methods and Results Forty‐eight helicopter emergency medical services personnel were divided into 12 groups of 4 participants; each group was assigned to perform 5 minutes of CCO‐CPR on manikins at 2 of 3 altitudes in a randomized controlled single‐blind crossover design (200, 3000, and 5000 m) in a hypobaric chamber. Physiological parameters were continuously monitored; participants rated their performance and effort on visual analog scales. Generalized estimating equations were performed for variables of CPR quality (depth, rate, recoil, and effective chest compressions) and effects of time, altitude, carryover, altitude sequence, sex, qualification, weight, preacclimatization, and interactions were analyzed. Our trial showed a time‐dependent decrease in chest compression depth ( P =0.036) after 20 minutes at altitude; chest compression depth was below the recommended minimum of 50 mm after 60 to 90 seconds (49 [95% CI, 46–52] mm) of CCO‐CPR. Conclusions This trial showed a time‐dependent decrease in CCO‐CPR quality provided by helicopter emergency medical services personnel during acute exposure to altitude, which was not perceived by the providers. Our findings suggest a reevaluation of the CPR guidelines for providers practicing at altitudes of 3000 m and higher. Mechanical CPR devices could be of help in overcoming CCO‐CPR quality decrease in helicopter emergency medical services missions. Registration URL: https://www.clinicaltrials.gov ; Unique identifier: NCT04138446.

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Abstract 133: Electrical Insulating Gloves for Safe Hands-on Defibrillation Do Not Compromise the Quality of Chest Compressions

Circulation ◽

10.1161/circ.130.suppl_2.133 ◽

2014 ◽

Vol 130 (suppl_2) ◽

Author(s):

Jakob E Thomsen ◽

Martin Harpsø ◽

Graham W Petley ◽

Svend Vittinghus ◽

Charles D Deakin ◽

...

Keyword(s):

Clinical Examination ◽

Chest Compression ◽

Electrical Insulation ◽

Compression Rate ◽

Chest Compressions ◽

Compression Depth ◽

Resuscitation Guidelines ◽

Hands On ◽

Class 1

Introduction: We have recently shown that Class 1 electrical insulating gloves are safe for hands-on defibrillation. Continuous chest compressions during defibrillation reduce the peri-shock pauses and increase the subsequent chance of successful defibrillation. In this study we have investigated the effect of these electrical insulation gloves on the quality of chest compressions, compared with normal clinical examination gloves. Methods: Emergency medical technicians trained in 2010 resuscitation guidelines delivered uninterrupted chest compressions for 6 min on a manikin, whilst wearing Class 1 electrical insulating gloves or clinical examination gloves. The order of gloves was randomized and each session of chest compressions was separated by at least 30 min to avoid fatigue. Data were collected from the manikin. Compression depth and compression rate were compared. Results: Data from 35 participants are shown in Figure 1. There was no statistically significant difference between Class 1 electrical insulating gloves in chest compression depth (median±range: 45 (28-61) vs 43 (28-61) p=0.69) and chest compression rate (113 (67-150) vs 113(72-145), p=0.87) when compared to clinical examination cloves. Conclusion: These preliminary data suggest that the use of Class 1 electrical insulation gloves does not reduce the quality of chest compressions during simulated CPR compared to clinical examination gloves.

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Abstract 240: Smartphone Application to Provide Real-Time Cardiopulmonary Resuscitation Quality Feedback

Circulation ◽

10.1161/circ.140.suppl_2.240 ◽

2019 ◽

Vol 140 (Suppl_2) ◽

Author(s):

Emily Stumpf ◽

Ravi Ambati ◽

Raj Shekhar ◽

Steven Staffa ◽

David Zurakowski ◽

...

Keyword(s):

Cardiopulmonary Resuscitation ◽

Real Time ◽

Mobile Application ◽

Sensor Data ◽

Smart Device ◽

Compression Rate ◽

Acceleration Sensor ◽

Compression Depth ◽

Quality Feedback ◽

Cpr Quality

Introduction: Quality of cardiopulmonary resuscitation (CPR) contributes significantly to morbidity and mortality in both in-hospital and out-of-hospital cardiac arrest. Key parameters that determine the CPR quality are compression rate, compression depth, duration of interruptions, chest recoil factor and respiratory rate. Several studies have demonstrated that real-time audiovisual feedback improves CPR quality in both bystanders and hospital staff. This study aims to develop and validate a smart device (phones and wearable technology) application to provide real-time audiovisual and haptic feedback to optimize CPR quality, by calculating aforementioned chest compression parameters. Hypothesis: A mobile application using acceleration sensor data from smart devices can provide accurate real time CPR quality feedback. Methods: A mobile application was developed to track the compression depth, compression rate and pause duration in real time using the data captured from the on-device accelerometer. The mobile device was placed on an adult manikin’s chest along the midline close to the point of compressions. Data from the application was compared directly to data obtained from a validated clinical standard CPR quality tool. Results: CPR quality parameters were obtained from the app and the standard for 60, 10-second-long sessions. Bland-Altman plot analysis for compression depth showed agreement between the app measurements and standard within +/-3.5mm (Figure 1). The intraclass correlation for agreement in the measurement of compression count was 0.92 (95% CI: 0.88-0.95), indicative of very strong agreement. Conclusions: Smart device (phones and wearable technology) applications using acceleration sensor data can accurately provide real-time CPR quality feedback. With further development and validation they can provide a ubiquitous CPR feedback tool valuable for out of hospital arrests and in under-privileged areas worldwide.

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Evaluation of the quality of cardiopulmonary resuscitation according to vehicle driving pattern, using a virtual reality ambulance driving system: a prospective, cross-over, randomised study

BMJ Open ◽

10.1136/bmjopen-2018-023784 ◽

2018 ◽

Vol 8 (9) ◽

pp. e023784 ◽

Cited By ~ 3

Author(s):

Jin Ho Beom ◽

Min Joung Kim ◽

Je Sung You ◽

Hye Sun Lee ◽

Ji Hoon Kim ◽

...

Keyword(s):

Chest Compression ◽

Fire Service ◽

Quality Parameters ◽

Hand Position ◽

Sudden Stop ◽

Compression Depth ◽

Randomised Study ◽

Cpr Quality ◽

Service Academy

ObjectivesTo analyse changes in the quality of cardiopulmonary resuscitation (CPR) according to driving patterns encountered during ambulance transport, using a virtual reality simulator.DesignProspective, cross-over, randomised study.SettingThis study was conducted at the National Fire Service Academy, Cheonan-si, Korea.ParticipantsEmergency medical technicians (39 men and 9 women) attending the National Fire Service Academy for clinical training with ≥6 months field experience or having performed ≥10 CPR. Individuals who withdrew consent were excluded.Outcome measuresCPR quality parameters (eg, chest compression depth and its variability).ResultsChest compressions were performed for 8 min each in a stationary and driving state. The mean chest compression depths were 54.8 mm and 55.3 mm during these two states, respectively (p=0.41). The SD of the chest compression depth was significantly higher while in the driving (7.6 mm) than in the stationary state (6.5 mm; p=0.04). The compression depths in the speed bump and sudden stop sections were 51.5 mm and 50.6 mm, respectively, which was shallower than those in all other sections (p<0.001). The correct hand position rate was low in the speed bump, sudden stop and right-hand cornering sections (65.4%, 71.5% and 72.5%, respectively; p=0.001)ConclusionsAlthough we found no differences in chest compression quality parameters between the stationary and driving states, the variability in the chest compression depth increased in the driving state. When comparing CPR quality parameters according to driving patterns, we noted a shallower compression depth, increased variability and decreased correct hand position rate in the speed bump, sudden stop and right-hand cornering sections. The clinical significance of these changes in CPR quality during ambulance transport remains to be determined. Future studies on how to reduce changes in the quality of CPR (including research on equipment development) are needed.

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A Feasibility Study for Measuring Accurate Chest Compression Depth and Rate on Soft Surfaces Using Two Accelerometers and Spectral Analysis

BioMed Research International ◽

10.1155/2016/6596040 ◽

2016 ◽

Vol 2016 ◽

pp. 1-7 ◽

Cited By ~ 5

Author(s):

Sofía Ruiz de Gauna ◽

Digna M. González-Otero ◽

Jesus Ruiz ◽

J. J. Gutiérrez ◽

James K. Russell

Keyword(s):

Spectral Analysis ◽

Cardiopulmonary Resuscitation ◽

Feasibility Study ◽

Chest Compression ◽

Compression Rate ◽

Compression Depth ◽

Test Conditions ◽

Median Error

Background. Cardiopulmonary resuscitation (CPR) feedback devices are being increasingly used. However, current accelerometer-based devices overestimate chest displacement when CPR is performed on soft surfaces, which may lead to insufficient compression depth. Aim. To assess the performance of a new algorithm for measuring compression depth and rate based on two accelerometers in a simulated resuscitation scenario. Materials and Methods. Compressions were provided to a manikin on two mattresses, foam and sprung, with and without a backboard. One accelerometer was placed on the chest and the second at the manikin’s back. Chest displacement and mattress displacement were calculated from the spectral analysis of the corresponding acceleration every 2 seconds and subtracted to compute the actual sternal-spinal displacement. Compression rate was obtained from the chest acceleration. Results. Median unsigned error in depth was 2.1 mm (4.4%). Error was 2.4 mm in the foam and 1.7 mm in the sprung mattress (p<0.001). Error was 3.1/2.0 mm and 1.8/1.6 mm with/without backboard for foam and sprung, respectively (p<0.001). Median error in rate was 0.9 cpm (1.0%), with no significant differences between test conditions. Conclusion. The system provided accurate feedback on chest compression depth and rate on soft surfaces. Our solution compensated mattress displacement, avoiding overestimation of compression depth when CPR is performed on soft surfaces.

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Advantage and Limitation of Using a Visual Feedback Device during Cardiopulmonary Resuscitation Training

Prehospital and Disaster Medicine ◽

10.1017/s1049023x19005223 ◽

2020 ◽

Vol 35 (1) ◽

pp. 104-108

Author(s):

Chan Woong Kim ◽

Je Hyeok Oh

Keyword(s):

Cardiopulmonary Resuscitation ◽

Visual Feedback ◽

Chest Compression ◽

Educational Strategy ◽

Compression Depth ◽

Trade Off ◽

Resuscitation Training ◽

Before And After ◽

Cpr Training

AbstractIntroduction:Recent cardiopulmonary resuscitation (CPR) guidelines recommend the use of CPR prompt/feedback devices during CPR training because it can improve the quality of CPR.Problem:Chest compression depth and full chest recoil show a trade-off relationship. Therefore, achievement of both targets (adequate chest compression depth and full chest recoil) simultaneously is a difficult task for CPR instructors. This study hypothesized that introducing a visual feedback device to the CPR training could improve the chest compression depth and ratio of full chest recoil simultaneously.Methods:The study investigated the effects of introducing a visual feedback device during CPR training by comparing the results of skill tests before and after introducing a visual feedback device. The results of skill tests from 2016 through 2018 were retrospectively reviewed. The strategy of emphasizing chest compression depth was implemented during the CPR training in 2017, and a visual feedback device was introduced in 2018. The interval between the CPR training and skill tests was seven days. Feedback was not provided during the skill tests.Results:In total, 159 students completed skill tests. Although the chest compression depth increased significantly from 50 mm (42–54) to 60 mm (59–61) after emphasizing chest compression depth (P < .001), the ratio of full chest recoil decreased simultaneously from 100% (100–100) to 81% (39–98; P < .001). The ratio of full chest recoil increased significantly from 81% (39–98) to 95% (77–100) after introducing a visual feedback device (P = .018). However, the students who did not achieve 80% of the ratio of full chest recoil remained significantly higher than in 2016 (1% in 2016, 49% in 2017, and 27% in 2018; P < .001).Conclusions:Although introducing a visual feedback device during CPR training resulted in increasing the ratio of full chest recoil while maintaining the adequacy of chest compression depth, 27% of the students still did not achieve 80% of the ratio of full chest recoil. Another educational strategy should be considered to increase the qualities of CPR more completely.

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Abstract 1806: End-tidal Carbon Dioxide as a Measure of Cardiopulmonary Resuscitation Efficacy during Human Cardiac Arrest

Circulation ◽

10.1161/circ.116.suppl_16.ii_385 ◽

2007 ◽

Vol 116 (suppl_16) ◽

Author(s):

Joshua L Wallbrecht ◽

Dana P Edelson ◽

Barbara Litzinger ◽

Deborah Walsh ◽

Terry L Vanden Hoek ◽

...

Keyword(s):

Carbon Dioxide ◽

Cardiac Arrest ◽

Chest Compression ◽

Compression Rate ◽

Medical Systems ◽

Compression Depth ◽

Mean Values ◽

End Tidal Carbon Dioxide ◽

Cpr Quality ◽

End Tidal

Background: End-tidal carbon dioxide (EtCO 2 ) is a physiologic measure that has potential to serve as an indicator of chest compression efficacy, with higher EtCO 2 values during CPR correlating with improved hemodynamics during prior laboratory studies. EtCO 2 measurement could therefore guide resuscitation efforts and help optimize CPR performance. Objective: To test the hypothesis that EtCO 2 levels positively correlate with improved chest compression rate and depth during human cardiac arrest. Methods: A prospective, observational study was conducted using a commercially available monitor/defibrillator with CPR quality and EtCO 2 sensing capabilities (MRx-QCPR, Philips Medical Systems) during in-hospital cardiac arrests at one hospital from 4/2006 until 8/2006. Resuscitation transcripts were divided into 30-second segments and mean values of chest compression rate and depth and EtCO 2 were derived for each segment. Regression analysis, with cluster-adjustment for individual patients, was used to correlate compression rate and depth with EtCO 2 . Results: Data were collected and analyzed from 281 30-second segments with a median of 12 (interquartile range: 8–33) segments per arrest from 13 consecutive patients for whom EtCO 2 and chest compression data were simultaneously available. Mean EtCO 2 was 19±7 mmHg. After adjusting for compression rate and clustering, there was a positive correlation between compression depth and EtCO 2 (regression coefficient 0.20; 95%CI [−0.01 – 0.42]). There was no significant correlation between compression rate and EtCO 2 after adjusting for compression depth and cluster, nor between survival and EtCO 2 levels. Conclusion: We found that deeper chest compressions correlated with higher EtCO 2 levels. Based on this relationship, changes in EtCO 2 during the actual resuscitation event may be reflective of the CPR quality being delivered. This work also suggests the feasibility of continuous monitoring of physiology during CPR to ensure resuscitation quality.

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Abstract 17534: The Most Appropriate Number of Personnel Needed for Chest Compressions for In-hospital Cardiac Arrest: A Randomized, Crossover Manikin Study

Circulation ◽

10.1161/circ.132.suppl_3.17534 ◽

2015 ◽

Vol 132 (suppl_3) ◽

Author(s):

Shunsuke Yamanaka ◽

Kei Nishiyama ◽

Hiroyuki Hayashi ◽

Ji Young Huh

Keyword(s):

Cardiac Arrest ◽

Cardiopulmonary Resuscitation ◽

Chest Compression ◽

Healthcare Providers ◽

Preliminary Evaluation ◽

Chest Compressions ◽

Rescue Team ◽

Manikin Study ◽

Hospital Cardiac Arrest

Background: Effective chest compression (CC) is vital in cardiopulmonary resuscitation (CPR), and rescuer’s fatigue negatively affects quality of CPR. However, there is no consensus on the appropriate number of personnel needed for CC to avoid rescuer’s fatigue. Objective: We determined the appropriate number of personnel needed for 30-min CPR in a rescue-team in a hospital. Methods: We conducted a preliminary randomized, crossover, manikin trial on healthcare providers. We divided them into Groups A to D according to the intervals between the 2-min CC and assigned a different interval to each group. Groups A, B, C, and D performed CCs at 2-, 4-, 6-, and 8-min intervals as in 2, 3, 4, and 5 personnel, respectively. All participants performed CCs for 30 min with different intervals depending on the assigned group; participants allocated to Groups A, B, C, and D performed 8, 5, 4, and 3 cycles, respectively. We compared the differences between first cycle and the second to the last cycle Results: We enrolled 42 participants (age: 25.2±4.2, men 47.6%) for the preliminary evaluation. We used Kruskal-Wallis for the analysis. Participants in the less interval Groups A and B performed faster (A: -24.28±15.18, B: -7.90±13.49, C: -11.27±17.01, D: -2.38±3.31, P=0.03) and shallower CCs (A: -4.42±6.92, B: -3.18±5.43, C: -0.18±5.74, D: -1.23±4.10, P=0.62). Women-rescuers performed faster (A: -27.25±12.23, B: -7.00±13.97, C: -8.16±19.26, D: 3.16±4.66, P= 0.05) and shallower CCs (A: -6.25±7.54, B: -3.00±6.89, C: -3.66±3.32, D: -0.16±4.35, P=0.58). However, CCs of men-rescuers were not faster (A: -20.33±20.65, B: -9.00±14.44, C: -15.00±15.11, D: -7.14±16.70, P= 0.60) or shallower (A: -2.00±6.55 B: -3.40±3.78, C: 4.00±5.33, D: -2.14±3.98, P=0.06). Conclusion: At least four rescuers (Group C) may be needed to reduce rescuer’s fatigue for 30-min CPR. If the team only includes women, more personnel would be needed as women experience fatigue faster.

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