Microwave bone imaging: a preliminary scanning system for proof-of-concept

Giuseppe Ruvio; Antonio Cuccaro; Raffaele Solimene; Adriana Brancaccio; Bruno Basile; Max J. Ammann

Microwave bone imaging: a preliminary scanning system for proof-of-concept

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Author(s): Giuseppe Ruvio ¹ ; Antonio Cuccaro ² ; Raffaele Solimene ² ; Adriana Brancaccio ² ; Bruno Basile ³ ; Max J. Ammann ¹
- Affiliations: 1: Antenna and High Frequency Research Centre, Dublin Institute of Technology, Kevin Street, Dublin 8, Ireland ;
  2: Dipartimento di Ingegneria Industriale e dell'Informazione, Seconda Università di Napoli, Via Roma 29, 81031 Aversa (CE), Italy ;
  3: B&B Sas, Strada Fienile 1, Napoli 80013, Casalnuovo di Napoli (NA), Italy
Source: Volume 3, Issue 3, September 2016, p. 218 – 221
DOI: 10.1049/htl.2016.0003 , Online ISSN 2053-3713

This is an open access article published by the IET under the Creative Commons Attribution -NonCommercial License (http://creativecommons.org/licenses/by-nc/3.0/)

Received 11/01/2016, Accepted 31/05/2016, Revised 21/05/2016, Published 30/06/2016

This Letter introduces a feasibility study of a scanning system for applications in biomedical bone imaging operating in the microwave range 0.5–4 GHz. Mechanical uncertainties and data acquisition time are minimised by using a fully automated scanner that controls two antipodal Vivaldi antennas. Accurate antenna positioning and synchronisation with data acquisition enables a rigorous proof-of-concept for the microwave imaging procedure of a multi-layer phantom including skin, fat, muscle and bone tissues. The presence of a suitable coupling medium enables antenna miniaturisation and mitigates the impedance mismatch between antennas and phantom. The three-dimensional image of tibia and fibula is successfully reconstructed by scanning the multi-layer phantom due to the distinctive dielectric contrast between target and surrounding tissues. These results show the viability of a microwave bone imaging technology which is low cost, portable, non-ionising, and does not require specially trained personnel. In fact, as no a-priori characterisation of the antenna is required, the image formation procedure is very conveniently simplified.

References

1. 1)
  - 7. Meaney, P.M., Goodwin, D., Golnabi, A., et al: ‘3D Microwave Bone Imaging’. Proc. Sixth European Conf. on Antennas and Propagation (EUCAP), 2011, pp. 1170–1171.
2. 2)
  - 14. Coincecao, R.C., O'Halloran, M., Glavin, M., et al: ‘Comparison of planar and circular antenna configurations for breast cancer detection using microwave imaging’, Progr. Electromagn. Res., 2009, 99, pp. 1–20 (doi: 10.2528/PIER09100204).
3. 3)
  - 12. Gabriel, S., Lau, R.W., Gabriel, C.: ‘The dielectric properties of biological tissues: II. Measurements in the frequency range 10 Hz to 20 GHz’, Phys. Med. Biol., 1996, 41, 2251–2269.
4. 4)
  - 2. Fear, E.C., Meaney, P.M., Stuchly, M.A.: ‘Microwaves for breast cancer detection?’, IEEE Potentials, 2003, 22, (1), pp. 12–18 (doi: 10.1109/MP.2003.1180933).
5. 5)
  - 23. Gabriel, C., Gabriely, S., Corthout, E.: ‘The dielectric properties of various tissues’, Phys. Med. Biol., 1996, 41, pp. 2231–2249 (doi: 10.1088/0031-9155/41/11/001).
6. 6)
  - 8. Solimene, R., Ruvio, G., Dell'Aversano, A., et al: ‘Detecting point-like sources of unknown frequency spectra’, Prog. Electromagn. Res., 2013, B, (50), pp. 347–364 (doi: 10.2528/PIERB13030414).
7. 7)
  - 6. Flores-Tapia, D., Pistorius, S.: ‘Real time breast microwave radar image reconstruction using circular holography: a study of experimental feasibility’, Med. Phys., 2011, 38, pp. 5420–5431 (doi: 10.1118/1.3633922).
8. 8)
  - 3. Nikolova, N.K.: ‘Microwave imaging for breast cancer’, IEEE Microw. Mag., 2011, 12, (7), pp. 78–94 (doi: 10.1109/MMM.2011.942702).
9. 9)
  - 4. Tian, Z., Meaney, P.M., Pallone, M.J., et al: ‘Microwave tomographic imaging for osteoporosis screening: a pilot clinical study’. Conf. Proc. IEEE Engineering in Medical and Biology Society, 2010, pp. 1218–1221.
10. 10)
  - 13. Solimene, R., Cuccaro, A.: ‘Front wall clutter rejection methods in TWI’, IEEE Geosci. Remote Sens. Lett., 2013, 11, pp. 1158–1162 (doi: 10.1109/LGRS.2013.2288491).
11. 11)
  - 10. Gabriel, C.: ‘Compilation of the dielectric properties of body tissues at RF and microwave frequencies’. Report N.AL/OE-TR- 1996-0037, Occupational and Environmental Health Directorate, Radiofrequency Radiation Division, Brooks Air Force Base, Texas (USA), June 1996.
12. 12)
  - 5. Jafari, H.M., Deen, M.J., Hranilovic, S., et al: ‘A study of ultrawideband antennas for near-field imaging’, IEEE Trans. Antennas Propag., 2007, 55, (4), pp. 1184–1188 (doi: 10.1109/TAP.2007.893405).
13. 13)
  - 9. Ruvio, G., Solimene, R., Cuccaro, A., et al: ‘Breast cancer detection using interferometric MUSIC: experimental and numerical assessment’, Med. Phys., 2014, 41, (10), pp. 103101/1–103101/11 (doi: 10.1118/1.4892067).
14. 14)
  - 3. Fhager, A., Persson, M.: ‘A microwave measurement system for stroke detection’. Seventh Loughborough Antennas and Propagation Conf., LAPC 2011, Loughborough, 14–15 November 2011.

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