Corroborating the Subjective Classification of Ultrasound Images of Normal and Fatty Human Livers by the Radiologist through Texture Analysis and SOM

The objective of this study is to establish that subjective evaluation of fatty as well as normal ultrasound human liver images based on echotexture (spatial pattern of echoes) and echogenicity by visual inspection can be corroborated by Haralick's statistical texture analysis. Seventy-six ultrasound scan images of human normal livers and twenty-four ultrasound images of fatty livers as identified by the radiologist on the basis of echotexture and echogenecity, have been collected from hospital for this study. An unsupervised neural network learning technique, namely, Self Organising Map (SOM) has been employed to generate profile plots. Using Student's t like statistic for each feature as a measure of distinction between normal and fatty livers, two most appropriate features, namely, maximum probability (Maxp) and uniformity (Uni) are selected from this profile plots. These two features are found to form clusters with little overlap for normal and fatty livers. Thus statistical texture analysis of the ultrasound human images using 'Maxp" and "Uni" presented the best results for corroborating the classification as made the radiologist by visual inspection. This work may be a humble beginning to model the radiologists' perceptual findings that may emerge in future as a new tool with respect to 'ultrasonic biopsy'.

[1]  Mitsuru Ishizuka,et al.  A creative abduction approach to scientific and knowledge discovery , 2005, Knowl. Based Syst..

[2]  Maguelonne Teisseire,et al.  Mining spatio-temporal data , 2006, Journal of Intelligent Information Systems.

[3]  John McCarthy,et al.  Circumscription - A Form of Non-Monotonic Reasoning , 1980, Artif. Intell..

[4]  Béla Julesz,et al.  Visual Pattern Discrimination , 1962, IRE Trans. Inf. Theory.

[5]  Haim Azhari,et al.  Feasibility study of ultrasonic fatty liver biopsy: texture vs. attenuation and backscatter. , 2004, Ultrasound in medicine & biology.

[6]  Anthony G. Cohn,et al.  Multi-Dimensional Modal Logic as a Framework for Spatio-Temporal Reasoning , 2002, Applied Intelligence.

[7]  Antonis C. Kakas,et al.  ACLP: Abductive Constraint Logic Programming , 2000, J. Log. Program..

[8]  Ramakrishnan Srikant,et al.  Mining sequential patterns , 1995, Proceedings of the Eleventh International Conference on Data Engineering.

[9]  Philippe Muller,et al.  Topological Spatio–Temporal Reasoning and Representation , 2002, Comput. Intell..

[10]  Donna L. Hudson,et al.  Neural networks and artificial intelligence for biomedical engineering , 1999 .

[11]  Jian Pei,et al.  Mining changing regions from access-constrained snapshots: a cluster-embedded decision tree approach , 2006, Journal of Intelligent Information Systems.

[12]  Linda G. Shapiro,et al.  Computer and Robot Vision , 1991 .

[13]  Robert M. Haralick,et al.  Textural Features for Image Classification , 1973, IEEE Trans. Syst. Man Cybern..

[14]  Teuvo Kohonen,et al.  Self-organized formation of topologically correct feature maps , 2004, Biological Cybernetics.

[15]  Murray Shanahan,et al.  Perception as Abduction: Turning Sensor Data Into Meaningful Representation , 2005, Cogn. Sci..

[16]  Dimitrios Gunopulos,et al.  Efficient Mining of Spatiotemporal Patterns , 2001, SSTD.

[17]  T H Shawker,et al.  Quantitative estimation of liver attenuation and echogenicity: normal state versus diffuse liver disease. , 1987, Radiology.