Mapping the brain structures in three-dimensional accurately is critical for an in-depth understanding of the brain functions. By using the brain atlas as a hub, mapping detected datasets into a standard brain space enables efficiently use of various datasets.
However, because of the heterogeneous and non-uniform characteristics of the brain structures at cellular level brought with the recently developed high-resolution whole-brain microscopes, traditional registration methods are difficult to apply to the robust mapping of various large volume datasets.
Here, we proposed a robust Brain Spatial Mapping Interface BrainsMapi to address the registration of large volume datasets at cellular level by introducing the extract regional features of the anatomically invariant method and a strategy of parameter acquisition and large volume transformation.
By performing validation on model data and biological images, BrainsMapi can not only achieve robust registration on sample tearing and streak image datasets, different individual and modality datasets accurately, but also are able to complete the registration of large volume dataset at cellular level which dataset size reaches 20 TB. Besides, it can also complete the registration of historical vectorized dataset.
BrainsMapi would facilitate the comparison, reuse and integration of a variety of brain datasets. Mapping brain structures in three-dimensional is necessary to thoroughly understand of the brain functions Huang and Luo, Creating a comprehensive space to map various brains will encompasses complex spatiotemporal information that can greatly facilitate the comparison Badea et al. Drawing a stereotaxic brain atlas Dong, ; Goldowitz, provides a unified spatial reference for addressing this issue.
