Title :
A unified geometric model for 3D confocal image analysis in cytology
Author :
Sarti, A. ; Ortiz, C. ; Lockett, S. ; Malladi, R.
Author_Institution :
Lawrence Berkeley Nat. Lab., California Univ., Berkeley, CA, USA
Abstract :
In this paper, we use partial differential equation based analysis as a methodology for computer-aided cytology. We wish to accurately extract and classify the shapes of nuclei from noisy confocal microscopy images. This is a prerequisite to an accurate quantitative intranuclear (genotypic and phenotypic) and internuclear (tissue structure) analysis of cancerous and pre-cancerous specimens. We study the use of a geometric-driven scheme for improving the results obtained by a nuclear segmentation method, based on automatic segmentation, followed by object reconstruction and interactive classification. We build a chain of methods that includes an edge-preserving image smoothing mechanism, an automatic (albeit non-regularized) segmentation method, a geometry-driven scheme to regularize the shapes and improve edge fidelity, and an interactive method to split shape clusters and reclassify them
Keywords :
cellular biophysics; differential geometry; image segmentation; medical image processing; 3D confocal image analysis; cytology; edge-preserving image smoothing mechanism; geometric-driven scheme; geometry-driven scheme; interactive method; noisy confocal microscopy images; nuclear segmentation method; partial differential equation based analysis; shape clusters; tissue structure; unified geometric model; Image analysis; Image edge detection; Image reconstruction; Image segmentation; Microscopy; Noise shaping; Partial differential equations; Shape; Smoothing methods; Solid modeling;
Conference_Titel :
Computer Graphics, Image Processing, and Vision, 1998. Proceedings. SIBGRAPI '98. International Symposium on
Conference_Location :
Rio de Janeiro
Print_ISBN :
0-8186-9215-4
DOI :
10.1109/SIBGRA.1998.722735
