PT  - JOURNAL ARTICLE
AU  - Sukhendu Das
AU  - Jaikishan Jayakumar
AU  - Samik Banerjee
AU  - Janani Ramaswamy
AU  - Venu Vangala
AU  - Keerthi Ram
AU  - Partha Mitra
TI  - High precision automated detection of labeled nuclei in Gigapixel resolution image data of Mouse Brain
AID  - 10.1101/252247
DP  - 2019 Jan 01
TA  - bioRxiv
PG  - 252247
4099  - http://biorxiv.org/content/early/2019/03/25/252247.short
4100  - http://biorxiv.org/content/early/2019/03/25/252247.full
AB  - There is a need in modern neuroscience for accurate and automated image processing techniques for analyzing the large volume of neuroanatomical imaging data. Even at light microscopic levels, imaging mouse brains produces individual data volumes in the TerraByte range. A fundamental task involves the detection and quantification of objects of a given type, e.g. neuronal nuclei or somata, in brain scan dataset. Traditionally this quantification has been performed by human visual inspection with high accuracy, that is not scalable. When modern automated CNN and SVM-based methods are used to solve this classification problem, they achieve accuracy levels that range between 85 – 92%. However, higher rates of precision and recall that are close to that of human performance are necessary. In this paper, we describe an unsupervised, iterative algorithm, which provides a high performance for a specific problem of detecting Green Fluorescent Protein labeled nuclei in 2D scans of mouse brains. The algorithm judiciously combines classical computer vision techniques and is focused on the complex problem of decomposing strong overlapped objects of interest. Our proposed technique uses feature detection methods on ridge lines over distance transformation of the image and an arc based iterative spatial-filling method to solve the problem. We demonstrate our results on mouse brain dataset of Gigabyte resolution and compare it with manual annotation of the brains. Our results show that an aptly designed CV algorithm with classical feature extractors when tailored to this problem of interest achieves near-ideal human-like performance. Quantitative comparative analysis, using manually annotated ground truth, reveals that our approach performs better on mouse brain scans than general purpose machine learning (including deep CNN) methods.