Portable Ultrasound Research System for Use in Automated Bladder Monitoring with Machine-Learning-Based Segmentation

Portable Ultrasound Research System for Use in Automated Bladder Monitoring with Machine-Learning-Based Segmentation

We developed a new mobile ultrasound device for long-term and automated bladder monitoring without user interaction consisting of 32 transmit and receive electronics as well as a 32-element phased array 3 MHz transducer. The device architecture is based on data digitization and rapid transfer to a c...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Vol. 21; no. 19; p. 6481
Main Authors: Fournelle, Marc, Grün, Tobias, Speicher, Daniel, Weber, Steffen, Yilmaz, Mehmet, Schoeb, Dominik, Miernik, Arkadiusz, Reis, Gerd, Tretbar, Steffen, Hewener, Holger
Format: Journal Article
Language:English
Published: Basel MDPI AG 28-09-2021
MDPI
Subjects:
Automation
Beamforming
Bladder
bladder monitoring
channel data
Communication
Computer architecture
Digitization
Electronics
Image processing
machine-learning
Monitoring
multichannel system
Phased arrays
Plane waves
POCUS
POUR
Power supply
Qualitative analysis
Signal reconstruction
Software
Ultrasonic imaging
United States > US
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Summary:We developed a new mobile ultrasound device for long-term and automated bladder monitoring without user interaction consisting of 32 transmit and receive electronics as well as a 32-element phased array 3 MHz transducer. The device architecture is based on data digitization and rapid transfer to a consumer electronics device (e.g., a tablet) for signal reconstruction (e.g., by means of plane wave compounding algorithms) and further image processing. All reconstruction algorithms are implemented in the GPU, allowing real-time reconstruction and imaging. The system and the beamforming algorithms were evaluated with respect to the imaging performance on standard sonographical phantoms (CIRS multipurpose ultrasound phantom) by analyzing the resolution, the SNR and the CNR. Furthermore, ML-based segmentation algorithms were developed and assessed with respect to their ability to reliably segment human bladders with different filling levels. A corresponding CNN was trained with 253 B-mode data sets and 20 B-mode images were evaluated. The quantitative and qualitative results of the bladder segmentation are presented and compared to the ground truth obtained by manual segmentation.
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ISSN:1424-8220
1424-8220
DOI:10.3390/s21196481