Combinatorial Nanoparticle-Bound ssDNA Oligonucleotide Library Synthesized by Split-and-Pool Synthesis

Synthetic ssDNA oligonucleotides hold great potential for various applications, including DNA aptamers, DNA digital data storage, DNA origami, and synthetic genomes. In these contexts, precise control over the synthesis of the ssDNA strands is essential for generating combinatorial sequences with user-defined parameters. Desired features for creating synthetic DNA oligonucleotides include easy manipulation of DNA strands, effective detection of unique DNA sequences, and a straightforward mechanism for strand elongation and termination. In this study, we present a split-and-pool method for generating synthetic DNA oligonucleotides on nanoparticles, enabling the creation of scalable combinatorial libraries. Our approach involves coupling DNA to nanoparticles, ligating double-digested fragments for orientation-specific synthesis, and attaching a final single-digested fragment to ensure strand termination. We assess the quality of our method by characterizing both the DNA and the nanoparticles used as solid supports, confirming that our method produces scalable, combinatorial nanoparticle-bound ssDNA libraries with controllable strand lengths.