Yüksek Başlangiç İvmeli Göǧüs Kompresyon Cihazi

Ahmet Kagizman; Volkan Sezer

doi:10.1109/ELECO64362.2024.10847220

Yüksek Başlangiç İvmeli Göǧüs Kompresyon Cihazi

Translated title of the contribution: High Initial Acceleration Chest Compression Device

Ahmet Kagizman, Volkan Sezer

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The primary intervention in cardiac arrest is chest compression-based cardiopulmonary resuscitation (CPR). While the American Heart Association (AHA) recommends standard manual CPR, various CPR devices have been developed to deliver more consistent compressions. However, clinical data suggest these devices do not improve survival rates as effectively as manual CPR. This may be because manual compressions produce higher initial momentum, making blood circulation more efficient. However, due to the limitations of piston technologies, current CPR devices cannot fully mimic this impulsive compression. In this study, a new CPR device that provides effective chest compressions with high initial acceleration thanks to the patented piston mechanism has been developed. The device's performance has been compared with the widely used LUCAS 3 device, and instantaneous acceleration data have been obtained through sensors integrated into the pistons of both devices.

Translated title of the contribution	High Initial Acceleration Chest Compression Device
Original language	Turkish
Title of host publication	Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9798331518035
DOIs	https://doi.org/10.1109/ELECO64362.2024.10847220
Publication status	Published - 2024
Event	2024 Electrical, Electronics and Biomedical Engineering Conference at 15th National Conference on Electrical and Electronics Engineering, ELECO 2024 - Bursa, Turkey Duration: 28 Nov 2024 → 30 Nov 2024

Publication series

Name	Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings

Conference

Conference	2024 Electrical, Electronics and Biomedical Engineering Conference at 15th National Conference on Electrical and Electronics Engineering, ELECO 2024
Country/Territory	Turkey
City	Bursa
Period	28/11/24 → 30/11/24

Bibliographical note

Publisher Copyright:
© 2024 IEEE.

Access to Document

10.1109/ELECO64362.2024.10847220

Cite this

Kagizman, A., & Sezer, V. (2024). Yüksek Başlangiç İvmeli Göǧüs Kompresyon Cihazi. In Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings (Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ELECO64362.2024.10847220

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abstract = "The primary intervention in cardiac arrest is chest compression-based cardiopulmonary resuscitation (CPR). While the American Heart Association (AHA) recommends standard manual CPR, various CPR devices have been developed to deliver more consistent compressions. However, clinical data suggest these devices do not improve survival rates as effectively as manual CPR. This may be because manual compressions produce higher initial momentum, making blood circulation more efficient. However, due to the limitations of piston technologies, current CPR devices cannot fully mimic this impulsive compression. In this study, a new CPR device that provides effective chest compressions with high initial acceleration thanks to the patented piston mechanism has been developed. The device's performance has been compared with the widely used LUCAS 3 device, and instantaneous acceleration data have been obtained through sensors integrated into the pistons of both devices.",

author = "Ahmet Kagizman and Volkan Sezer",

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Kagizman, A & Sezer, V 2024, Yüksek Başlangiç İvmeli Göǧüs Kompresyon Cihazi. in Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings. Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings, Institute of Electrical and Electronics Engineers Inc., 2024 Electrical, Electronics and Biomedical Engineering Conference at 15th National Conference on Electrical and Electronics Engineering, ELECO 2024, Bursa, Turkey, 28/11/24. https://doi.org/10.1109/ELECO64362.2024.10847220

Yüksek Başlangiç İvmeli Göǧüs Kompresyon Cihazi. / Kagizman, Ahmet ; Sezer, Volkan.
Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings. Institute of Electrical and Electronics Engineers Inc., 2024. (Electrical-Electronics and Biomedical Engineering Conference, ELECO 2024 - Proceedings).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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N2 - The primary intervention in cardiac arrest is chest compression-based cardiopulmonary resuscitation (CPR). While the American Heart Association (AHA) recommends standard manual CPR, various CPR devices have been developed to deliver more consistent compressions. However, clinical data suggest these devices do not improve survival rates as effectively as manual CPR. This may be because manual compressions produce higher initial momentum, making blood circulation more efficient. However, due to the limitations of piston technologies, current CPR devices cannot fully mimic this impulsive compression. In this study, a new CPR device that provides effective chest compressions with high initial acceleration thanks to the patented piston mechanism has been developed. The device's performance has been compared with the widely used LUCAS 3 device, and instantaneous acceleration data have been obtained through sensors integrated into the pistons of both devices.

AB - The primary intervention in cardiac arrest is chest compression-based cardiopulmonary resuscitation (CPR). While the American Heart Association (AHA) recommends standard manual CPR, various CPR devices have been developed to deliver more consistent compressions. However, clinical data suggest these devices do not improve survival rates as effectively as manual CPR. This may be because manual compressions produce higher initial momentum, making blood circulation more efficient. However, due to the limitations of piston technologies, current CPR devices cannot fully mimic this impulsive compression. In this study, a new CPR device that provides effective chest compressions with high initial acceleration thanks to the patented piston mechanism has been developed. The device's performance has been compared with the widely used LUCAS 3 device, and instantaneous acceleration data have been obtained through sensors integrated into the pistons of both devices.

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Yüksek Başlangiç İvmeli Göǧüs Kompresyon Cihazi

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