Nagma Vohra scite author profile

Terahertz imaging and spectroscopy has demonstrated a potential for differentiating tissue types of excised breast cancer tumors. Pulsed terahertz technology provides a broadband frequency range from 0.1 THz to 4 THz for detecting cancerous tissue. Tumor tissue types of interest include cancer typically manifested as infiltrating ductal or lobular carcinomas, fibro-glandular (healthy connective tissues) and fat. In this work, images of breast tumors excised from human and animal models are reviewed. In addition to alternate fresh tissues, breast cancer tissue phantoms are developed to further evaluate terahertz imaging and the potential use of contrast agents. Terahertz results are successfully validated with pathology images, showing strong differentiation between cancerous and healthy tissues for all freshly excised tissues and types. The advantages, challenges and limitations of THz imaging of breast cancer are discussed.

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Pulsed terahertz reflection imaging of tumors in a spontaneous model of breast cancer

Vohra

Bowman

Díaz

et al. 2018

Biomed. Phys. Eng. Express

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We report the use of reflection-mode terahertz (THz) imaging in a transgenic mouse model of breast cancer. Unlike tumor xenografts that are grown from established cell lines, these tumors were spontaneously generated in the mammary fat pad of mice, and are a better representation of human breast cancer. THz imaging results from 7 tumors that recapitulate the compartmental complexity of breast cancer are presented here. Imaging was first performed on freshly excised tumors within an hour of excision and then repeated after fixation with formalin and paraffin. These THz images were then compared with histopathology to determine reflection-mode signals from specific regions within tumor. Our results demonstrate that the THz signal was consistently higher in cancerous tissue compared with fat, muscle, and fibrous tissue. Almost all tumors presented in this work demonstrated advanced stages where cancer infiltrated other tissues like fat and fibrous stroma. As the first known THz investigation in a transgenic model, these results hold promise for THz imaging at different stages of breast cancer.

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Deep Learning Classification of Breast Cancer Tissue from Terahertz Imaging Through Wavelet Synchro-Squeezed Transformation and Transfer Learning

Liu

Vohra

Bailey

et al. 2022

J Infrared Milli Terahz Waves

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K- and W-Band Free-Space Characterizations of Highly Conductive Radar Absorbing Materials

Vohra

El-Shenawee

2021

IEEE Trans. Instrum. Meas.

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Supervised Bayesian learning for breast cancer detection in terahertz imaging

Chavez

Vohra

Bailey

et al. 2021

Biomedical Signal Processing and Control

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Nagma Vohra

Cancer detection in excised breast tumors using terahertz imaging and spectroscopy

Pulsed terahertz reflection imaging of tumors in a spontaneous model of breast cancer

Deep Learning Classification of Breast Cancer Tissue from Terahertz Imaging Through Wavelet Synchro-Squeezed Transformation and Transfer Learning

K- and W-Band Free-Space Characterizations of Highly Conductive Radar Absorbing Materials

Supervised Bayesian learning for breast cancer detection in terahertz imaging

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