Flexible large-area ultrasound arrays for medical applications made using embossed polymer structures-Reference-Cited by-同舟云学术

Flexible large-area ultrasound arrays for medical applications made using embossed polymer structures

Published:2024-03-30 Issue:1 Volume:15 Page:
ISSN:2041-1723
Container-title:Nature Communications
language:en
Short-container-title:Nat Commun

Author:

van Neer Paul L. M. J.,Peters Laurens C. J. M.,Verbeek Roy G. F. A.,Peeters Bart,de Haas Gerard,Hörchens Lars^ORCID,Fillinger Laurent^ORCID,Schrama Thijs,Merks-Swolfs Egon J. W.,Gijsbertse Kaj,Saris Anne E. C. M.,Mozaffarzadeh Moein,Menssen Jan M.,de Korte Chris L.^ORCID,van der Steen Jan-Laurens P. J.,Volker Arno W. F.,Gelinck Gerwin H.^ORCID

Abstract

AbstractWith the huge progress in micro-electronics and artificial intelligence, the ultrasound probe has become the bottleneck in further adoption of ultrasound beyond the clinical setting (e.g. home and monitoring applications). Today, ultrasound transducers have a small aperture, are bulky, contain lead and are expensive to fabricate. Furthermore, they are rigid, which limits their integration into flexible skin patches. New ways to fabricate flexible ultrasound patches have therefore attracted much attention recently. First prototypes typically use the same lead-containing piezo-electric materials, and are made using micro-assembly of rigid active components on plastic or rubber-like substrates. We present an ultrasound transducer-on-foil technology based on thermal embossing of a piezoelectric polymer. High-quality two-dimensional ultrasound images of a tissue mimicking phantom are obtained. Mechanical flexibility and effective area scalability of the transducer are demonstrated by functional integration into an endoscope probe with a small radius of 3 mm and a large area (91.2×14 mm2) non-invasive blood pressure sensor.

Publisher

Springer Science and Business Media LLC

Link

https://www.nature.com/articles/s41467-024-47074-1.pdf

Reference41 articles.

1. Cobbold, R. S. C. Foundations Of Biomedical Ultrasound (Oxford Univ. Press, 2007).

2. Szabo, T. L. Diagnostic Ultrasound Imaging: Inside Out (Academic Press, 2014).

3. Global Business Intelligence. Ultrasound systems market to 2019—Technological advancements, wide applications and device portability to drive future growth. https://www.gbiresearch.com/report-store/market-reports/medtech/ultrasound-systems-market-to-2019-technologicaladvancements-wide-applications-and-device-portability-to-drive-future growth (2013).

4. Wang, C. et al. Bioadhesive ultrasound for long-term continuous imaging of diverse organs. Science 377, 517–523 (2022).

5. Omidvar, A., Cretu, E., Rohling, R., Cresswell, M. & Hodgson, A. J. Flexible polyCMUTs: fabrication and characterization of a flexible polymer-based capacitive micromachined ultrasonic array for conformal ultrasonography. Adv. Mater. Technol. 8, 2201316 (2023).

Cited by 4 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Patient-centric care: Unveiling the potential of wearable electronics in clinical practice;Wearable Electronics;2024-12

2. Flexible ultrasound arrays with embossed polymer structures for medical imaging;Journal of Semiconductors;2024-08-01

3. Toward soft robotic inspection for aircraft: An overview and perspective;MRS Communications;2024-07-03

4. An Exploration into the Structuring of Soft Piezoelectric Transducers for Wearable Applications;2024 IEEE International Symposium on Medical Measurements and Applications (MeMeA);2024-06-26