The approach we are developing in this project aims to change how spatial molecular information can be acquired and interpreted. Rather than relying on direct optical observation or predefined spatial indexing schemes, we explore a strategy in which spatial relationships are encoded into molecular interaction networks and recovered through computational analysis. This introduces a new measurement paradigm that separates the physical process of information capture from the reconstruction of spatial organization. Current spatial transcriptomics technologies are typically limited by trade-offs between resolution, field of view, and cost, particularly when extending to three-dimensional samples. By contrast, a sequencing-based network approach has the potential to scale more naturally with sample size and complexity, while maintaining high spatial fidelity. If successfully implemented, this could allow volumetric mapping of biological systems that are currently difficult to access, such as large tissue sections or organoid models, without reliance on complex imaging infrastructure.
The results so far indicate that key components of this paradigm are feasible. In particular, the establishment of controlled, spatially localized molecular amplification and the demonstration of computational reconstruction from network-like data provide early evidence that spatial information can be encoded and recovered in this manner. While these elements are not yet integrated into a complete system, they indicate a route toward developing this new class of spatial measurement technologies. Beyond immediate applications, our project contributes to a broader conceptual advancement that frames spatial inference as a problem of network reconstruction. This creates opportunities to apply and further develop methods from graph theory and machine learning in the context of molecular data, and to explore hybrid experimental–computational and AI/ML-enabled systems where measurement and inference are tightly coupled.
To ensure further uptake and success, we will need integration of subcomponents into an end-to-end workflow, validation in biological samples, and demonstration of reproducibility and scalability. In addition, translation to practical use will require consideration of manufacturability, protocol standards, and compatibility with existing sequencing infrastructures. This line of work could support tools for studying biological systems, enable accessible spatial analysis across research and clinical settings, and contribute to the development of scalable molecular technologies aligned with emerging needs in data-driven life sciences.