Complex silica composite nanomaterials templated with DNA origami

With the development of structural DNA nanotechnology, DNA has now far exceeded its original function: as a genetic code. It can, in principle, self‐assemble into desired shapes with accurate size. Moreover, it can perform as a functional linker to program other materials by grafting DNA onto these materials. Nanoparticles, both inorganic and organic, can now be programmatically assembled into complex 3D superlattices with high order when guided by DNA. By encoding functions into the as‐assembled nanoparticles, materials with excellent collective effects may be invented. Here, how nanoparticles with different shapes or functions are successfully fabricated into 3D lattices with the help of DNA shells coated on the surface and how scientists can produce desired lattices by design are reviewed. The cases to achieve dynamic superlattices of nanoparticles by affecting the environment where DNA survives are also discussed.

Section: Discussionmentioning

confidence: 96%

3D Lattice Engineering of Nanoparticles by DNA Shells

Tian

2019

“…In this work, DNA modified 2,5‐dialkoxy paraphenylenevinylene (APPV) brush polymer was synthesized and immobilized precisely on DNA origami through complementary ssDNA that extends out from the DNA origami. Notably, another novel use of DNA origami as a template has been reported by Fan and co‐workers to create biomimetic silica nanostructures (Figure H) . This methodology offered the possibility of transferring nanoscale geometric information from designer DNA origami to inorganic materials.…”

Section: Fabrication Of Nanoscale Patterns On Dna Origamimentioning

confidence: 96%

Section: Fabrication Of Nanoscale Patterns On Dna Origamimentioning

confidence: 99%

Create Nanoscale Patterns with DNA Origami

Fan

Wang

Kenaan

et al. 2019

Structural deoxyribonucleic acid (DNA) nanotechnology offers a robust platform for diverse nanoscale shapes that can be used in various applications. Among a wide variety of DNA assembly strategies, DNA origami is the most robust one in constructing custom nanoshapes and exquisite patterns. In this account, the static structural and functional patterns assembled on DNA origami are reviewed, as well as the reconfigurable assembled architectures regulated through dynamic DNA nanotechnology. The fast progress of dynamic DNA origami nanotechnology facilitates the construction of reconfigurable patterns, which can further be used in many applications such as optical/plasmonic sensors, nanophotonic devices, and nanorobotics for numerous different tasks.

“…Growth of SiO 2 by gas phase chemical vapor deposition was developed to produce both positive‐tone and negative‐tone patterns . Recently, Fan and his coworker have demonstrated the overcoating of silica onto 2D and 3D DNA nanostructures using a solution process (Figure B) . The formed inorganic shell significantly improves the mechanical strength of the DNA nanostructure.…”

Section: Dna‐based Nanofabricationmentioning

confidence: 99%

DNA‐Based Nanofabrication: Pathway to Applications in Surface Engineering

Hui

Zhang

Deng

et al. 2019

This Concept provides an overview of recent developments of DNA‐based nanofabrication and discusses its potential applications in the area of surface engineering. The first part of the paper discusses the strength and limitations of existing DNA‐based nanofabrication methods. The second part highlights several examples of surface engineering applications involving nano‐ and microscale surface textures. It finishes with a discussion of the opportunities and remaining challenges of applying DNA‐based nanofabrication in surface engineering applications.