Miniature Force Sensing System for Monitoring of Optimal Cricoid Pressure for Airway Protection

Application of correct force on cricoid cartilage is an effective approach to prevent the regurgitation of gastric contents. However, the force applied by nurses varies widely, resulting in a proportion of patients remaining at high risk of gastric aspiration due to inadequate force. To guide the nu...

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Bibliographic Details
Published inIEEE sensors journal Vol. 18; no. 10; pp. 4303 - 4310
Main Authors Xue, Ning, Liu, Chunxiu, Sun, Jianhai, Li, Tong, Chi, Cheng, Hee, Hwan-Ing, Wang, Yu-Shun
Format Journal Article
LanguageEnglish
Published New York IEEE 15.05.2018
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Accuracy
Anesthesia
Biocompatibility
biomedical sensors
Calibration
Cartilage
Cricoid force sensing
Curvature
Electrodes
flexible printed board
flexible sensor
Force
Human subjects
Multiplexing
Nurses
Organic light emitting diodes
Read out systems
Sensor arrays
Sensors
Substrates
wearable sensor
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Summary:Application of correct force on cricoid cartilage is an effective approach to prevent the regurgitation of gastric contents. However, the force applied by nurses varies widely, resulting in a proportion of patients remaining at high risk of gastric aspiration due to inadequate force. To guide the nurses to exert consistent and accurate target cricoid force with real time feedback, a flexible, wearable and biocompatible polymer-based force sensor patch was developed, the sensor patch is able to attach on the cricoid cartilage surface. A force readout system based on printed circuit board was also developed. The light-emitting diodes on the circuit are to indicate the force range. The force sensing system with two sensor patterns (3 × 5 and 10 × 10 array) were measured on the flat surface, and curved manikin surface. Human subject was involved in the device experimental calibration and verification. The results show that the surface curvature and testing subject are related to the calibration data and measurement accuracy. The measured force accuracy is within ±2.5 N on the manikin surface, and within ±4.0 N on human subject. As a guided fixture was introduced on the sensor patch, the accuracy of the sensor increased to ±1.5 N.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2018.2821697