Rajwar, A.; Eichhorn, L.; Palacka, J.; Ly, S.; Benson, E.

DNA nanotechnology offers precise, biocompatible structures with strong potential for targeted drug delivery, yet current discovery approaches rely on testing individual designs, limiting exploration of structural diversity. Here, we introduce an evolutionary selection strategy that screens large libraries of DNA nanostructures, each folded from a single-stranded structure genome compatible with amplification and sequencing. Cellular internalization is used as the selection pressure: libraries are incubated with mammalian cells, internalized structures are recovered from lysates, and the process is iterated across multiple rounds in HEK293T and RAW264.7 cells. High-throughput sequencing of recovered structure genomes reveals cell-type-specific enrichment patterns, enabling the identification of individual nanostructures with preferential uptake. Selected candidates were synthesized and evaluated as purified structures, confirming differential internalization by quantitative flow cytometry and microscopy. Turning DNA nanostructure discovery into a selection-based process, could enable high-throughput exploration of structural diversity and provide an alternative route to identify nanostructures with cell-specific uptake properties for biomedical applications.