Pilot Study of Freshly Excised Breast Tissue Response in the 300-600 GHz Range

Overview

Journal Biomed Opt Express

Specialty Radiology

Date 2018 Jul 10

PMID 29984076

Citations 11

Authors

Quentin Cassar

Amel Al-Ibadi

Laven Mavarani

Philipp Hillger

Janusz Grzyb

Gaetan MacGrogan

Thomas Zimmer

Ullrich R Pfeiffer

Jean-Paul Guillet

Patrick Mounaix

Affiliations

Soon will be listed here.

Abstract

The failure to accurately define tumor margins during breast conserving surgery (BCS) results in a 20% re-excision rate. The present paper reports the investigation to evaluate the potential of terahertz imaging for breast tissue recognition within the under-explored 300 - 600 GHz range. Such a frequency window matches new BiCMOS technology capabilities and thus opens up the opportunity for near-field terahertz imaging using these devices. To assess the efficacy of this frequency band, data from 16 freshly excised breast tissue samples were collected and analyzed directly after excision. Complex refractive indices have been extracted over the as-mentioned frequency band, and amplitude frequency images show some contrast between tissue types. Principal component analysis (PCA) has also been applied to the data in an attempt to automate tissue classification. Our observations suggest that the dielectric response could potentially provide contrast for breast tissue recognition within the 300 - 600 GHz range. These results open the way for silicon-based terahertz subwavelength near field imager design, efficient up to 600 GHz to address ex vivo life-science applications.

Citing Articles

Biomedical application of terahertz imaging technology: a narrative review.

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Terahertz Imaging and Spectroscopy in Cancer Diagnostics: A Technical Review.

Peng Y, Shi C, Wu X, Zhu Y, Zhuang S BME Front. 2023; 2020:2547609.

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Measurement and Modeling of the Optical Properties of Adipose Tissue in the Terahertz Range: Aspects of Disease Diagnosis.

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