NADINE: new approaches to detecting breast cancer by sequential μm-wavelength imaging with the aid of novel frequency analysis techniques

References

• American Cancer Society, Breast Cancer. Available online at: http://www.cancer.org/Cancer/BreastCancer/index?ssSourceSiteId=null (accessed 24 February 2012).
   Google Scholar
• Button, T.M., Li, H., Fisher, P., Rosenblatt, R., Dulaimy, K., Li, S., O’Hea, B., Salvitti, M., Geronimo, V., Geronimo, C., Jambawalikar, S., Carvelli, P., Weiss, R., 2004, Dynamic infrared imaging for the detection of malignancy. Physics in Medicine and Biology, 49, 3105–3116.
   PubMed Web of Science ®Google Scholar
• Janicek, M.J., Demetri, G., Janicek, M.R., Shaffer, K. and Fauci, M.A., 2003, Dynamic infrared imaging of newly diagnosed malignant lymphoma compared with gallium-67 and fluorine-18 fluorodeoxyglucose (FDG) positron emission tomography. Technology in Cancer Research and Treatment, 2, 571–577.
   PubMedGoogle Scholar
• Joro, R., Lääperi, A.L., Dastidar, P., Soimakallio, S., Kuukasjärvi, T., Toivonen, T., Saaristo, R. and Järvenpää, R., 2008, Imaging of breast cancer with mid- and long-wave infrared camera. Journal of Medical Engineering & Technology, 32, 189–197.
   Google Scholar
• Joro, R., Läperi, A.L., Soimakallio, S., Järvenpää, R., Kuukasjärvi, T., Toivonen T., Saaristo, R. and Dastidar, P., 2008, Dynamic infrared imaging in identification of breast cancer tissue with combined image processing and frequency analysis. Journal of Medical Engineering & Technology, 32, 325–335.
   PubMedGoogle Scholar
• Agostini, V., Knaflitz, M. and Molinari, F., 2007, Evaluation of different marker sets for motion artefact reduction in breast dynamic infrared imaging. Conference Proceedings of the IEEE Engineering in Medicine and Biology Society, 22–26 Aug. 2007, Lyon France. 3377–3379.
   Google Scholar
• Joro, R., Läperi, A.L., Dastidar, P., Järvenpää, R., Kuukasjärvi, T., Toivonen, T., Saaristo, R. and Soimakallio, S., 2009, A dynamic infrared imaging-based diagnostic process for breast cancer. Acta Radiologica, 50, 860–869.
   Web of Science ®Google Scholar
• Thomsen, L.L. and Miles, D.W., 1998, Role of nitric oxide in tumour progression: lessons from human tumours. Cancer Metastasis Reviews, 17, 107–118.
   PubMed Web of Science ®Google Scholar
• Thomsen, L.L., Miles, D.W., Happerfield, L., Bobrov, L.G., Knowles, R.G. and Moncada, S., 1995, Nitric oxide synthase activity in human breast cancer. British Journal of Cancer, 72, 41–44.
   PubMed Web of Science ®Google Scholar
• Rogalski, A., 1995, Infrared Photon Detectors. Institute of Technical Physics, WAT, SPIE Optical Engineering Press, 1995, Washington, USA 1, pp. 21, 61–63, 302, 351–475.
   Google Scholar
• Rogatto, W.D., 1993, The infrared & electro-optical systems handbook/electro-optical components. SPIE Optical Engineering Press, 1993, Michigan USA 3, 177–273.
   Google Scholar
• The MathWorks, 2005, Image Processing Toolbox, User’s Guide version 5 (Natick: The MathWorks), pp. 50–150.
   Google Scholar
• Gonzales, R.C., Woods, R.E. and Eddins, S.L., 2004, Digital Image Processing using Matlab®. (New Jersey: Pearson Education), pp. 65–193.
   Google Scholar
• Cabanski, W, Breiter, R, Rode, W, Ziegler, J, Schneider, H, Walther, M, Fauci, M, QWIP LWIR cameras with NETD<10mK and improved low Frequency Drift for long Observation Time in Medicine and Research. Proceedings of SPIE 2002, Vol. 4721, 165–173.
   Google Scholar
• Joro, R., 2009, Exploitation of dynamic infrared technology in radiology and breast cancer research (Licentiate Thesis). Tampere University of Technology/Department of Automation Science and Engineering, 09/2009, pp. 77–77; 90–98.
   Google Scholar
• Joro, R. and Iivonen, V., 2010, Menetelmä syöpäkasvaimen ja sitä ympäröivän kudoksen lämpödynamiikan identifioimiseksi ja erottamiseksi kehittyneellä kuvauspeti-kamerajärjestelmällä ja taajuusanalyysillä. European patent (Finland) ID: FI120959, 31 May 2010.
   Google Scholar
• Anbar, M., Milescu, L., Naumov, A., Brown, C., Button, T., Carty, C. and Dulaimy, K., 2001, Detection of cancerous breasts by dynamic area telethermometry. IEEE Engineering in Medicine and Biology Magazine, 20, 80–91.
   PubMedGoogle Scholar
• Janesick, J., 2003, Charge coupled CMOS and hybrid detector arrays. Proceedings of SPIE, Focal Plane Arrays, SPIE paper #5167-1, Aug 2003, San Diego.
   Google Scholar
• Janesick, J.R., 2001, Scientific charge-coupled devices. Proceedings of SPIE, 1, 489–530, 582–602, 605–649.
   Google Scholar
• Friedman, C., Arbel, A. and Ginosar, R., 1999, Current skimming-based CMOS readout architectures for quantum well infrared photo detectors. IEEE Workshop on Charge-Coupled Devices and Advanced Image Sensors, Kanagawa, Japan, June 1999.
   Google Scholar
• Janesick, J.R. and Putnam, G., 2003, Developments and applications of high-performance CCD and CMOS imaging arrays. Annual Review of Nuclear Science, 53, 263–300.
   Google Scholar
• Button, T.M., Li, H., Fisher, P., Rosenblatt, R., Dulaimy, K., Li, S., O’Hea, B., Salvitti, M., Geronimo, V., Geronimo, C., Jambawalikar, S. and Weiss, R., 2004, Dynamic infrared imaging for the detection of malignancy. Physics in Medicine and Biology, 49, 3105–3116.
   PubMed Web of Science ®Google Scholar
• Janicek, M.J., Demetri, G., Janicek, M.R., Shaffer, K. and Fauci, M.A., 2003, Dynamic infrared imaging of newly diagnosed malignant lymphoma compared with gallium-67 and fluorina-18 fluorodeoxyglucose (FDG) positron emission tomography. Technology in Research & Treatment, 2, 571–577.
   PubMed Web of Science ®Google Scholar