Abstract
The acquisition of high quality maps of gene expression in the rodent brain is of fundamental importance to the neuroscience community. The generation of such datasets relies on registering individual gene expression images to a reference volume, a task encumbered by the diversity of staining techniques employed, and by deformations and artifacts in the soft tissue. Recently, deep learning models have garnered particular interest as a viable alternative to traditional intensity-based algorithms for image registration. In this work, we propose a supervised learning model for general multimodal 2D registration tasks, trained with a perceptual similarity loss on a dataset labeled by a human expert and augmented by synthetic local deformations. We demonstrate the results of our approach on the Allen Mouse Brain Atlas (AMBA), comprising whole brain Nissl and gene expression stains. We show that our framework and design of the loss function result in accurate and smooth predictions. Our model is able to generalize to unseen gene expressions and coronal sections, outperforming traditional intensity-based approaches in aligning complex brain structures.
Highlights
Mouse brain atlases are an essential tool used by neuroscientists to investigate relationships between structural and functional properties of different brain regions
In order to utilize the information provided by the different markers, gene expressions must be aligned to the reference Nissl atlas, so that all the data can be put into a common coordinate system
We presented a supervised deep learning model with perceptual similarity for the 2D registration of gene expressions to Nissl stains of the Allen Mouse Brain Atlas
Summary
Mouse brain atlases are an essential tool used by neuroscientists to investigate relationships between structural and functional properties of different brain regions. In order to utilize the information provided by the different markers, gene expressions must be aligned to the reference Nissl atlas, so that all the data can be put into a common coordinate system To this end, the Allen Mouse Brain Atlas (AMBA) includes an alignment module, but this module is limited to non-deformable transformations (Sunkin et al, 2012). The Allen Mouse Brain Atlas (AMBA) includes an alignment module, but this module is limited to non-deformable transformations (Sunkin et al, 2012) For this reason, previous works (Erö et al, 2018) have had to resort to a manual landmark-based non-rigid approach to correct inaccuracies. This solution is not scalable to the whole genomic database
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