Monitoring chest compression rate in automated external defibrillators using the autocorrelation of the transthoracic impedance

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.

Download Full-text

Robust real-time chest compression rate detection from smartphone video

Proceedings of the 10th International Symposium on Image and Signal Processing and Analysis ◽

10.1109/ispa.2017.8073560 ◽

2017 ◽

Author(s):

Oyvind Meinich-Bache ◽

Kjersti Engan ◽

Tonje S. Birkenes ◽

Helge Myklebust

Keyword(s):

Real Time ◽

Chest Compression ◽

Compression Rate

Download Full-text

Leg-heel chest compression as an alternative for medical professionals in times of COVID-19

10.1101/2021.03.09.21253220 ◽

2021 ◽

Author(s):

Matthias Ott ◽

Alexander Krohn ◽

Laurence H. Bilfield ◽

F. Dengler ◽

C. Jaki ◽

...

Keyword(s):

Chest Compression ◽

Effective Alternative ◽

Medical Professionals ◽

Compression Rate ◽

Compression Depth ◽

Significant Difference ◽

Manual Chest Compression ◽

Special Circumstances ◽

Previous Training

AbstractObjectiveTo evaluate leg-heel chest compression without previous training as an alternative for medical professionals and its effects on distance to potential aerosol spread during chest compression.Methods20 medical professionals performed standard manual chest compression followed by leg-heel chest compression after a brief instruction on a manikin. We compared percentage of correct chest compression position, percentage of full chest recoil, percentage of correct compression depth, average compression depth, percentage of correct compression rate and average compression rate between both methods. In a second approach, potential aerosol spread during chest compression was visualized.ResultsThere was no significant difference between manual and leg-heel compression. The distance to potential aerosol spread could have been increased by leg-heel method.ConclusionUnder special circumstances like COVID-19-pandemic, leg-heel chest compression may be an effective alternative without previous training compared to manual chest compression while markedly increasing the distance to the patient.

Download Full-text

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.

Download Full-text