Abstract
The segmentation of structures in electron microscopy (EM) images is very important for neurobiological research. The low resolution neuronal EM images contain noise and generally few features are available for segmentation, therefore application of the conventional approaches to identify the neuron structure from EM images is not successful. We therefore present a multi-scale fused structure boundary detection algorithm in this study. In the algorithm, we generate an EM image Gaussian pyramid first, then at each level of the pyramid, we utilize Laplacian of Gaussian function (LoG) to attain structure boundary, we finally assemble the detected boundaries by using fusion algorithm to attain a combined neuron structure image. Since the obtained neuron structures usually have gaps, we put forward a reinforcement learning-based boundary amendment method to connect the gaps in the detected boundaries. We use a SARSA (λ)-based curve traveling and amendment approach derived from reinforcement learning to repair the incomplete curves. Using this algorithm, a moving point starts from one end of the incomplete curve and walks through the image where the decisions are supervised by the approximated curve model, with the aim of minimizing the connection cost until the gap is closed. Our approach provided stable and efficient structure segmentation. The test results using 30 EM images from ISBI 2012 indicated that both of our approaches, i.e., with or without boundary amendment, performed better than six conventional boundary detection approaches. In particular, after amendment, the Rand error and warping error, which are the most important performance measurements during structure segmentation, were reduced to very low values. The comparison with the benchmark method of ISBI 2012 and the recent developed methods also indicates that our method performs better for the accurate identification of substructures in EM images and therefore useful for the identification of imaging features related to brain diseases.
Highlights
The brain is the center of the nervous system in all vertebrates and most invertebrate animals [1], and it comprises a vast number of interconnected neurons, which are the basic building blocks of the nervous system
There are many competitions in biomedical imaging processing, such as the International Symposium on Biomedical Imaging (ISBI) [43], which focuses on the presentation of technological advances in theoretical and applied biomedical imaging and image computing
ISBI 2012 presented the challenge of automatically segmenting neural structures from electron microscopy (EM) images
Summary
The brain is the center of the nervous system in all vertebrates and most invertebrate animals [1], and it comprises a vast number of interconnected neurons, which are the basic building blocks of the nervous system. To produce connectomes based on EM, we need to identify each synapse and trace the axons and dendrites in the brain using images, which technologically is an image segmentation task with the goal of segmenting neuronal structures. The neuronal structure segmentation task is especially challenging because neurons contain many intracellular organelles such as mitochondria and endosomes. Neuronal EM images are generally low resolution gray images that contain numerous kinds of noise. The results are usually dissatisfactory when conventional image segmentation approaches are applied to the identification of neuronal structures [10]
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