Abstract
Analysing biological images coming from the microscope is challenging; not only is it complex to acquire the images, but also the three-dimensional shapes found on them. Thus, using automatic approaches that could learn and embrace that variance would be highly interesting for the field. Here, we use an evolutionary algorithm to obtain the 3D cell shape of curve epithelial tissues. Our approach is based on the application of a 3D segmentation algorithm called LimeSeg, which is a segmentation software that uses a particle-based active contour method. This program needs the fine-tuning of some hyperparameters that could present a long number of combinations, with the selection of the best parametrisation being highly time-consuming. Our evolutionary algorithm automatically selects the best possible parametrisation with which it can perform an accurate and non-supervised segmentation of 3D curved epithelial tissues. This way, we combine the segmentation potential of LimeSeg and optimise the parameters selection by adding automatisation. This methodology has been applied to three datasets of confocal images from Drosophila melanogaster, where a good convergence has been observed in the evaluation of the solutions. Our experimental results confirm the proper performing of the algorithm, whose segmented images have been compared to those manually obtained for the same tissues.
Highlights
Nowadays, image processing is used in many different fields such as medical images, object detection and face recognition
We summarise the results on Salivary glands, Embryo and Egg chamber in separate sections, depicting for each tissue three different graphical representations:
This section has presented the experimental results for an automatic optimisation of LimeSeg 3D image segmentation process for three different tissues of Drosophila melanogaster
Summary
Image processing is used in many different fields such as medical images, object detection and face recognition. This discipline focuses on the analysis and treatment of images to improve their quality and extract information from them [1]. Pixels are categorised in different connecting regions depending on their grey scale. The methods to detect edges use properties of the grey scale of pixels related with differences colour distinctness and texture variation [3]. These characteristics describe objects which are in boundaries of regions
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