Based on the Watson-Crick base pairing principle, precisely programmable metal-framework nucleic acids (mFNA) have evolved from one-dimensional to three-dimensional nanoscale structures, a technological advancement attributed to progress in DNA nanotechnology. mFNA are a new type of nanomaterial formed by using framework nucleic acids (FNAs) as precise templates to guide the ordered assembly and self-assembly of metal ions, metal salts (such as calcium phosphate, calcium carbonate, etc.), metal nanoclusters, metal nanoparticles, or metal oxide nanoparticles. Compared to traditional FNAs, mFNA not only inherits the powerful programmed self-assembly capabilities of nucleic acids but also incorporates the unique physicochemical properties of inorganic metal nanomaterials. This intersection of organic and inorganic chemistry presents broad application prospects in fields such as biology, chemistry, materials science, and energy science. This review, based on the principles related to FNAs, introduces the concept of mFNA for the first time, aiming to explore the fundamental connections between nanoscale FNAs and metal materials. Additionally, the article focuses on the construction methods and functional characteristics of mFNA. Finally, the current challenges faced by mFNA are reviewed, and their future development is anticipated, providing detailed information for a comprehensive understanding of the research progress in mFNA.
Keywords: DNA; DNA self-assembly; framework nucleic acids (FNAs); metal; metal-framework nucleic acids (mFNA).
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