A Radiological Clip Design Using Ultrasound Identification to Improve Localization

Overview

Journal IEEE Trans Biomed Eng

Specialties Biomedical Engineering
Biophysics

Date 2024 Apr 12

PMID 38607722

Authors

Jenna Cario

Zhengchang Kou

Rita J Miller

April Dickenson

Christine U Lee

Michael L Oelze

Affiliations

Soon will be listed here.

Abstract

Objective: We demonstrate the use of ultrasound to receive an acoustic signal transmitted from a radiological clip designed from a custom circuit. This signal encodes an identification number and is localized and identified wirelessly by the ultrasound imaging system.

Methods: We designed and constructed the test platform with a Teensy 4.0 microcontroller core to detect ultrasonic imaging pulses received by a transducer embedded in a phantom, which acted as the radiological clip. Ultrasound identification (USID) signals were generated and transmitted as a result. The phantom and clip were imaged using an ultrasonic array (Philips L7-4) connected to a Verasonics Vantage 128 system operating in pulse inversion (PI) mode. Cross-correlations were performed to localize and identify the code sequences in the PI images.

Results: USID signals were detected and visualized on B-mode images of the phantoms with up to sub-millimeter localization accuracy. The average detection rate across 30,400 frames of ultrasound data was 98.1%.

Conclusion: The USID clip produced identifiable, distinguishable, and localizable signals when imaged.

Significance: Radiological clips are used to mark breast cancer being treated by neoadjuvant chemotherapy (NAC) via implant in or near treated lesions. As NAC progresses, available marking clips can lose visibility in ultrasound, the imaging modality of choice for monitoring NAC-treated lesions. By transmitting an active signal, more accurate and reliable ultrasound localization of these clips could be achieved and multiple clips with different ID values could be imaged in the same field of view.

Citing Articles

Underlying factors that affect ultrasound conspicuity of breast biopsy markers: an exploratory study.

Cario J, Lee C, Oelze M Transl Breast Cancer Res. 2025; 6:2.

PMID: 39980808 PMC: 11836746. DOI: 10.21037/tbcr-24-48.

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