TY  - JOUR
AU  - Berlet, Maximilian
AU  - Vogel, Thomas
AU  - Gharba, Mohamed
AU  - Eichinger, Joseph
AU  - Schulz, Egon
AU  - Friess, Helmut
AU  - Wilhelm, Dirk
AU  - Ostler, Daniel
AU  - Kranzfelder, Michael
PY  - 2022
DA  - 2022/5/26
TI  - Emergency Telemedicine Mobile Ultrasounds Using a 5G-Enabled Application: Development and Usability Study
JO  - JMIR Form Res
SP  - e36824
VL  - 6
IS  - 5
KW  - 5G
KW  - telemedicine
KW  - telehealth
KW  - eHealth
KW  - digital health
KW  - digital medicine
KW  - mobile ultrasound
KW  - ultrasound
KW  - imaging
KW  - digitalized medicine
KW  - emergency care
KW  - emergency
KW  - ambulance
KW  - slicing
KW  - diagnostic
KW  - diagnosis
KW  - image quality
KW  - field test
AB  - Background: Digitalization affects almost every aspect of modern daily life, including a growing number of health care services along with telemedicine applications. Fifth-generation (5G) mobile communication technology has the potential to meet the requirements for this digitalized future with high bandwidths (10 GB/s), low latency (<1 ms), and high quality of service, enabling wireless real-time data transmission in telemedical emergency health care applications. Objective: The aim of this study is the development and clinical evaluation of a 5G usability test framework enabling preclinical diagnostics with mobile ultrasound using 5G network technology. Methods: A bidirectional audio-video data transmission between the ambulance car and hospital was established, combining both 5G-radio and -core network parts. Besides technical performance evaluations, a medical assessment of transferred ultrasound image quality and transmission latency was examined. Results: Telemedical and clinical application properties of the ultrasound probe were rated 1 (very good) to 2 (good; on a 6 -point Likert scale rated by 20 survey participants). The 5G field test revealed an average end-to-end round trip latency of 10 milliseconds. The measured average throughput for the ultrasound image traffic was 4 Mbps and for the video stream 12 Mbps. Traffic saturation revealed a lower video quality and a slower video stream. Without core slicing, the throughput for the video application was reduced to 8 Mbps. The deployment of core network slicing facilitated quality and latency recovery. Conclusions: Bidirectional data transmission between ambulance car and remote hospital site was successfully established through the 5G network, facilitating sending/receiving data and measurements from both applications (ultrasound unit and video streaming). Core slicing was implemented for a better user experience. Clinical evaluation of the telemedical transmission and applicability of the ultrasound probe was consistently positive. 
SN  - 2561-326X
UR  - https://formative.jmir.org/2022/5/e36824
UR  - https://doi.org/10.2196/36824
UR  - http://www.ncbi.nlm.nih.gov/pubmed/35617009
DO  - 10.2196/36824
ID  - info:doi/10.2196/36824
ER  -