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SBIR Based Screening for Lung Cancer


Affiliations
1 Department of ETCE, Sathyabama Institute of Science and Technology, Chennai, Tamilnadu, India
     

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Lung cancer is the most dangerous type of cancer in the world. Early detection can save the life and increase the survivability of patients. In this project we obtain a solution for lung cancer symptom detection by applying Shape based image retrieval (SBIR). Our algorithm is broadly divided into three parts, at first part we accept the data set of cancer symptoms which is a generalized way for creating the patterns for Lung Cancer Framework, and in the second part we find the relevant data from the patterns using segmentation approach. We can choose the frequent symptoms only by using the threshold value. Based on the threshold value we decide whether it’s a cancer cell or non-cancer cell. We initialize the cancer cell value to support the pattern of cancer symptoms. It is updated in each trial. By updating the cancer cell value in each step we can check the symptom precision which either increases the accuracy or decreases it. Finally, result analysis can be proved by the appropriately using artificial neural network algorithm.

Keywords

Dicom, SVM, ANN, k-NN, Accuracy, Sensitivity, Precision and Specificity.
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  • Cancer Facts and Figure 2009 by American Cancer Society, http://www.cancer.org
  • Anthony V D’Antoni, Genevieve Pinto Zipp, Valerie G Olson and Terrence F Cahill, “Does the mind map learning strategy facilitate information retrieval and critical thinking in medical students?", BMC Med Educ. 2010.
  • Stefan Diederich et al., “Screening for early lung cancer with lowdose spiral CT: prevalence in 817 asymptomatic smokers", Radiology, vol. 222, no.3, pp. 773-781, 2002.
  • Ichiro Yoshino, Masafumi Yamaguchi, Testuzo Tagawa, Seiichi Fukuyama, Toshifumi Kameyama, Atsushi Osoegawa and Yoshihiko Maehara, “Operative results of clinical stage I nonsmall cell lung cancer", Lung Cancer, vol. 42, no. 11, May 2003.
  • Austin et al., “Glossary of terms for CT of lungs; recommendations of the Nomenclature Committee of the Fleischner Society", Thoracic Radiology, vol. 200, pp. 327-331, April 1996.
  • Y. Kawata, N. Niki, H. Ohmatsu, M. Kusumoto, R. Kakinuma, K. Yamada, K. Mori, H. Nishiyama, K. Eguchi, M. Kaneko, and N. Moriyama, “Pulmonary nodule classification based on nodule retrieval from 3-D thoracic CT image database”, Medical Image Computing and Computer-Assisted Intervention (MICCAI 2004).
  • Michael O. Lam, Tim Disney, Daniela S. Raicu, Jacob Furst and David S. Channin, “BRISC-An Open Source Pulmonary Nodule Image Retrieval Framework", Journal of digital imaging, 2007.
  • Arimura, S. Katsuragawa and K. Suzuki, “Computerized scheme for automated detection of lung nodules in low-dose computed tomography images for lung cancer screening”, Acad. Radiol., Vol. 11, pp. 617629, 2004.
  • Ambrosini,S. Nicolini, P. Carolia, C. Nannia, A. Massarob, M.-C. Marzolab, D. Rubellob and S. Fantia, “PET/CT imaging in di_erent types of lung cancer: An overview”, European Journal of Radiology, Vol. 81, pp. 988-1001, 2013.
  • El-Bazl, A. Farag, R. Falk and R. LaRocca, Automatic identification of lung abnormalities in chest spiral CT scans, In proc. of the international conference on Acoustics, Speech, and Signal Processing (ICASSP '03), Vol.2, pp. 261-264, 2003.
  • El-Baz, A. Farag, G. Gimelfarb, R. Falk, M.-A. El-Ghar and T. Eldiasty, “A framework for automatic segmentation of lung nodules from low dose chest CT scans”, in Proc. of the 18th International Conference on Pattern Recognition (ICPR 06), Vol. 3, pp. 611614, 2006.
  • El-Baz, G. Gimelfarb, R. Falk and M. Abo El-Ghar, “3D MGRFbased appearance modelling for robust segmentation of pulmonary nodules in 3D LDCT chest images, in Lung Imaging and Computer Aided Diagnosis”, chapter 3, pp. 5163, Taylor and Francis edition, 2011.
  • J.-P. Kockelkorn, E.-M. Van Rikxoort, J.-C. Grutters and B. Van Ginneken, Interactive lung segmentation in CT scans with severe abnormalities, In Proc. of the 7th IEEE International Symposium on Biomedical Imaging: From Nano to Macro (ISBI '10), pp. 564567, 2010.
  • Ashwin, S.-A. Kumar, J. Ramesh and K. Gunavathi, “E_cient and Reliable Lung Nodule Detection using a Neural Network Based Computer Aided Diagnosis System”, In Proc. of the International Conference on Emerging Trends in Electrical Engineering and Energy Management (ICETEEEM'2012), pp. 135-142, Chennai, 13-15 Dec. 2012.
  • Farag, J Graham, A. Farag and R. Falk, “Lung Nodule Modelling A Data-Driven approach”, Advances in Visual Computing, Vo. 5875, pp 347-356, 2009.
  • Haussecker and B. Jahne, “A tensor approach for local structure analysis in multidimensional images in 3-D”, Image Anal. Synthesis, pp.171178, 1996.
  • Frangi, W. Niessen, K. Vincken, and M. Viergever, “Multiscale vessel enhancement filtering”, Med. Image Computing Computer Assisted Intervention, vol. 1496, pp. 130137, 1998
  • Zhao, A.-P. Reeves, D.-F. Yankelevitz and C.-I. Henschke, “Three-dimensional multicriterion automatic segmentation of pulmonary nodules of helical computed tomography images”, Optical Engineering, Vol. 38, No. 8, pp. 13401347,1999

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  • SBIR Based Screening for Lung Cancer

Abstract Views: 257  |  PDF Views: 0

Authors

G. Mary Valantina
Department of ETCE, Sathyabama Institute of Science and Technology, Chennai, Tamilnadu, India
Z. Mary Livinsa
Department of ETCE, Sathyabama Institute of Science and Technology, Chennai, Tamilnadu, India

Abstract


Lung cancer is the most dangerous type of cancer in the world. Early detection can save the life and increase the survivability of patients. In this project we obtain a solution for lung cancer symptom detection by applying Shape based image retrieval (SBIR). Our algorithm is broadly divided into three parts, at first part we accept the data set of cancer symptoms which is a generalized way for creating the patterns for Lung Cancer Framework, and in the second part we find the relevant data from the patterns using segmentation approach. We can choose the frequent symptoms only by using the threshold value. Based on the threshold value we decide whether it’s a cancer cell or non-cancer cell. We initialize the cancer cell value to support the pattern of cancer symptoms. It is updated in each trial. By updating the cancer cell value in each step we can check the symptom precision which either increases the accuracy or decreases it. Finally, result analysis can be proved by the appropriately using artificial neural network algorithm.

Keywords


Dicom, SVM, ANN, k-NN, Accuracy, Sensitivity, Precision and Specificity.

References