Ultrahigh-Capacity Vertical Encoded Micro-Spherical Nucleic Acids for Multiplexed Detection

Here, we report a DNA-programmable microsphere encoding platform using spatially organized fluorophores on magnetic cores with elongated DNA scaffolds. By engineering vertically stratified DNA scaffolds on paramagnetic microspheres, we achieved orthogonal spectral separation of 2-3 fluorophores through spatial confinement, generating 96 distinct two-color and 536 three-color barcodes via tunable stoichiometric control. We validated the platform's utility for nucleic acid multiplexing by demonstrating simultaneous detection of multiple targets, establishing a foundation for scalable high-order multiplexing. The system circumvents material compatibility restrictions inherent to conventional approaches, resolves spatial encoding conflicts through programmable DNA nanostructures, and achieves exponential encoding scalability. By synergizing the operational advantages of liquid-phase microsphere assays with the precision of DNA nanotechnology, this work establishes a new paradigm for high-throughput multiplexed diagnostics, offering unprecedented potential for precision medicine and large-scale biomedical analysis.