Title :
CRF-driven multi-compartment geometric model
Author :
Farhand, S. ; Andreopoulos, F.M. ; Tsechpenakis, G.
Author_Institution :
Comput. & Inf. Sci. Dept., Indiana Univ.-Purdue Univ., Indianapolis, IN, USA
Abstract :
We present a hybrid framework for segmenting structures consisting of distinct inter-connected parts. We combine the robustness of Conditional Random Fields in appearance classification with the shape constraints of geometric models and the relative part topology constraints that multi-compartment modeling provides. We demonstrate the performance of our method in cell segmentation from fluorescent microscopic images, where the compartments of interest are the cell nucleus, cytoplasm, and the negative hypothesis (background). We compare our results with the most relevant model- and appearance-based segmentation methods.
Keywords :
biological techniques; biology computing; cellular biophysics; fluorescence spectroscopy; image classification; image segmentation; optical microscopy; CRF driven multicompartment geometric model; appearance based segmentation methods; appearance classification; cell nucleus; cell segmentation; conditional random fields; cytoplasm; distinct interconnected parts; fluorescent microscopic images; geometric models; hybrid framework; model based segmentation methods; multicompartment modeling; negative hypothesis; relative part topology constraints; shape constraints; structure segmentation; Deformable models; Educational institutions; Image segmentation; Level set; Microscopy; Shape; Topology; Cell segmentation; conditional random fields; deformable models; multi-compartment segmentation;
Conference_Titel :
Biomedical Imaging (ISBI), 2013 IEEE 10th International Symposium on
Conference_Location :
San Francisco, CA
Print_ISBN :
978-1-4673-6456-0
DOI :
10.1109/ISBI.2013.6556669
