Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection

Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection

Breast cancer is one of the leading causes of cancer death among women; to decrease the death rate for this disease, early detection plays a key role. Recently, microwave imaging systems have been proposed as an alternative to the current techniques, but they suffer from poor resolution due to the l...

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Main Authors: Simona Di Meo, Giulia Matrone, Marco Pasian
Format: Article
Language:English
Published: MDPI AG 2021-01-01
Series:Applied Sciences
Subjects:
breast cancer detection
early diagnosis
microwave imaging
millimeter-wave imaging
tissue-mimicking phantoms
Online Access:https://www.mdpi.com/2076-3417/11/1/432
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spelling doaj-f3940eb5ecec48489671df631bc7fb062021-01-05T00:03:29ZengMDPI AGApplied Sciences2076-34172021-01-011143243210.3390/app11010432Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer DetectionSimona Di Meo0Giulia Matrone1Marco Pasian2Department of Electrical, Computer and Biomedical Engineering, University of Pavia, Via Ferrata 5, 27100 Pavia, ItalyDepartment of Electrical, Computer and Biomedical Engineering, University of Pavia, Via Ferrata 5, 27100 Pavia, ItalyDepartment of Electrical, Computer and Biomedical Engineering, University of Pavia, Via Ferrata 5, 27100 Pavia, ItalyBreast cancer is one of the leading causes of cancer death among women; to decrease the death rate for this disease, early detection plays a key role. Recently, microwave imaging systems have been proposed as an alternative to the current techniques, but they suffer from poor resolution due to the low frequencies involved. In this paper, for the first time, an innovative millimeter-wave imaging system for early-stage breast cancer detection is proposed and experimentally verified on different breast phantoms. This has the potential to achieve superior resolution for breasts with a high volumetric percentage of adipose tissue, and the merit to overcome the common misconception that millimeter-waves cannot achieve useful penetration depths for biological applications. Three phantoms were prepared according to the dielectric properties of human breast <i>ex vivo</i> tissues in the frequency range [0.5–50] GHz. Two cylindrical inclusions made by water and gelatin or agar, mimicking dielectric properties of neoplastic tissues, were embedded in the phantom at different depths up to 3 cm. Two double ridge waveguides, with mono-modal frequency band equal to [<sup>18</sup>,<sup>19</sup>,<sup>20</sup>,<sup>21</sup>,<sup>22</sup>,<sup>23</sup>,<sup>24</sup>,<sup>25</sup>,<sup>26</sup>,<sup>27</sup>,<sup>28</sup>,<sup>29</sup>,<sup>30</sup>,<sup>31</sup>,<sup>32</sup>,<sup>33</sup>,<sup>34</sup>,<sup>35</sup>,<sup>36</sup>,<sup>37</sup>,<sup>38</sup>,<sup>39</sup>,<sup>40</sup>] GHz, were used to synthetize a linear array of 24 elements in 28 positions, acquiring signals with a Vector Network Analyzer. The images were reconstructed by applying the Delay and Sum algorithm to calibrated data. The feasibility of a new imaging system with a central working frequency of about 30 GHz is experimentally demonstrated for the first time, and a target detection capability up to 3 cm within the phantom is shown. The presented results pave the way for a possible use of millimeter-waves to image non-superficial neoplasms in the breast.https://www.mdpi.com/2076-3417/11/1/432breast cancer detectionearly diagnosismicrowave imagingmillimeter-wave imagingtissue-mimicking phantoms
collection DOAJ
language English
format Article
sources DOAJ
author Simona Di Meo
Giulia Matrone
Marco Pasian
spellingShingle Simona Di Meo
Giulia Matrone
Marco Pasian
Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection
Applied Sciences
breast cancer detection
early diagnosis
microwave imaging
millimeter-wave imaging
tissue-mimicking phantoms
author_facet Simona Di Meo
Giulia Matrone
Marco Pasian
author_sort Simona Di Meo
title Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection
title_short Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection
title_full Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection
title_fullStr Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection
title_full_unstemmed Experimental Validation on Tissue-Mimicking Phantoms of Millimeter-Wave Imaging for Breast Cancer Detection
title_sort experimental validation on tissue-mimicking phantoms of millimeter-wave imaging for breast cancer detection
publisher MDPI AG
series Applied Sciences
issn 2076-3417
publishDate 2021-01-01
description Breast cancer is one of the leading causes of cancer death among women; to decrease the death rate for this disease, early detection plays a key role. Recently, microwave imaging systems have been proposed as an alternative to the current techniques, but they suffer from poor resolution due to the low frequencies involved. In this paper, for the first time, an innovative millimeter-wave imaging system for early-stage breast cancer detection is proposed and experimentally verified on different breast phantoms. This has the potential to achieve superior resolution for breasts with a high volumetric percentage of adipose tissue, and the merit to overcome the common misconception that millimeter-waves cannot achieve useful penetration depths for biological applications. Three phantoms were prepared according to the dielectric properties of human breast <i>ex vivo</i> tissues in the frequency range [0.5–50] GHz. Two cylindrical inclusions made by water and gelatin or agar, mimicking dielectric properties of neoplastic tissues, were embedded in the phantom at different depths up to 3 cm. Two double ridge waveguides, with mono-modal frequency band equal to [<sup>18</sup>,<sup>19</sup>,<sup>20</sup>,<sup>21</sup>,<sup>22</sup>,<sup>23</sup>,<sup>24</sup>,<sup>25</sup>,<sup>26</sup>,<sup>27</sup>,<sup>28</sup>,<sup>29</sup>,<sup>30</sup>,<sup>31</sup>,<sup>32</sup>,<sup>33</sup>,<sup>34</sup>,<sup>35</sup>,<sup>36</sup>,<sup>37</sup>,<sup>38</sup>,<sup>39</sup>,<sup>40</sup>] GHz, were used to synthetize a linear array of 24 elements in 28 positions, acquiring signals with a Vector Network Analyzer. The images were reconstructed by applying the Delay and Sum algorithm to calibrated data. The feasibility of a new imaging system with a central working frequency of about 30 GHz is experimentally demonstrated for the first time, and a target detection capability up to 3 cm within the phantom is shown. The presented results pave the way for a possible use of millimeter-waves to image non-superficial neoplasms in the breast.
topic breast cancer detection
early diagnosis
microwave imaging
millimeter-wave imaging
tissue-mimicking phantoms
url https://www.mdpi.com/2076-3417/11/1/432
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AT giuliamatrone experimentalvalidationontissuemimickingphantomsofmillimeterwaveimagingforbreastcancerdetection
AT marcopasian experimentalvalidationontissuemimickingphantomsofmillimeterwaveimagingforbreastcancerdetection
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