Litcius/Paper detail

Cloneable inorganic nanoparticles

Alexander Hendricks, Bradley F. Guilliams, Rachel Silliman Cohen, Tony Tien, Gavin A. McEwen, Kanda Borgognoni, Christopher J. Ackerson

2023Chemical Communications12 citationsDOIOpen Access PDF

Abstract

) can select and reduce specific inorganic oxyanions and coordination complexes, creating zerovalent precipitates. Other proteins/peptides (often genetically concatenated to the parent oxidoreductase) serve as ligands, directing the size, shape, crystal structure and other properties of the nanoparticle. The DNA encoding a cNP can be recombinantly transferred into any organism. Ideally, this enables recombinant production of cNPs with the same defined physiochemical properties. Such cNPs are of interest for applications ranging from molecular imaging, bio-remediation, catalysis, and biomining. In this Feature Article we detail and define the cNP concept, and retrace the story of our creation of a cloneable Se NanoParticle (cSeNP). We also describe our more preliminary work that we expect to result in cloneable semiconductor quantum dots, cloneable Te nanoparticles, and other cNP formulations. We highlight the application of cNPs in cellular electron microscopy and compare this approach to other cloneable imaging contrast approaches.

Topics & Concepts

NanoparticleNanotechnologyPeptideChemistryChemical engineeringMaterials scienceBiochemistryEngineeringAdvanced biosensing and bioanalysis techniquesSupramolecular Self-Assembly in MaterialsDiatoms and Algae Research
Cloneable inorganic nanoparticles | Litcius