MuViT: Multi-Resolution Vision Transformers for Learning Across Scales in Microscopy
This addresses the problem of multi-scale analysis in large-scale microscopy for biomedical researchers, representing a novel method for a known bottleneck.
The paper tackles the challenge of analyzing gigapixel microscopy images with structures across multiple spatial scales by introducing MuViT, a transformer architecture that fuses true multi-resolution observations. The results show consistent improvements over strong ViT and CNN baselines across synthetic benchmarks, kidney histopathology, and high-resolution mouse-brain microscopy.
Modern microscopy routinely produces gigapixel images that contain structures across multiple spatial scales, from fine cellular morphology to broader tissue organization. Many analysis tasks require combining these scales, yet most vision models operate at a single resolution or derive multi-scale features from one view, limiting their ability to exploit the inherently multi-resolution nature of microscopy data. We introduce MuViT, a transformer architecture built to fuse true multi-resolution observations from the same underlying image. MuViT embeds all patches into a shared world-coordinate system and extends rotary positional embeddings to these coordinates, enabling attention to integrate wide-field context with high-resolution detail within a single encoder. Across synthetic benchmarks, kidney histopathology, and high-resolution mouse-brain microscopy, MuViT delivers consistent improvements over strong ViT and CNN baselines. Multi-resolution MAE pretraining further produces scale-consistent representations that enhance downstream tasks. These results demonstrate that explicit world-coordinate modelling provides a simple yet powerful mechanism for leveraging multi-resolution information in large-scale microscopy analysis.