Bionanofabrication of Ordered Nanoparticle Arrays:  Effect of Particle Properties and Adsorption Conditions

Bergkvist, Magnus; Mark, Sonny S.; Yang, Xin; Angert, Esther R.; Batt, Carl A.

doi:10.1021/jp049280l

Cited by 53 publications

(78 citation statements)

References 45 publications

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“…[168][169][170][171] These arrays have been used as a template for the organization of nanoparticles and biotinylated ferritin into organized arrays. [172][173][174][175] Self-assembly has been combined with a "top-down" approach to organize protein-cage arrays at planar interfaces. The molecular combing method has been used to create inplane order.…”

Section: Hierarchical Assemblymentioning

confidence: 99%

Biological Containers: Protein Cages as Multifunctional Nanoplatforms

Uchida¹,

Klem²,

Allen³

et al. 2007

Advanced Materials

536

518

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Materials scientists increasingly draw inspiration from the study of how biological systems fabricate materials under mild synthetic conditions by using self‐assembled macromolecular templates. Containerlike protein architectures such as viral capsids and ferritin are examples of such biological templates. These protein cages have three distinct interfaces that can be synthetically exploited: the interior, the exterior, and the interface between subunits. The subunits that comprise the building blocks of these structures can be modified both chemically and genetically in order to impart designed functionality to different surfaces of the cage. Therefore, the cages possess a great deal of synthetic flexibility, which allows for the introduction of multifunctionality in a single cage. In addition, hierarchical assembly of the functionalized cages paves the way for development of a new class of materials with a wide range of applications from electronics to biomedicine.

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Section: Hierarchical Assemblymentioning

confidence: 99%

Biological Containers: Protein Cages as Multifunctional Nanoplatforms

Uchida¹,

Klem²,

Allen³

et al. 2007

Advanced Materials

536

518

View full text Add to dashboard Cite

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“…By exposing 5-nm-sized Au nanoparticles to the hexagonally packed intermediate (HPI) layer of Deinococcus radiodurans, long-range ordered twodimensional particle arrays exhibiting a honey-comb structure with hexagonal symmetry were obtained. 38 The citrate-capped Au nanoparticles were shown to adsorb at every second vertex point between adjacent hexameric units, and not to the 2.2-nmsized central pores. If particle -particle repulsion was reduced by increasing the ionic strength with NaCl, nearly every vertex point was occupied by Au nanoparticles.…”

Section: Cellular Componentsmentioning

confidence: 98%

Biologically Templated Nanostructure Assemblies

Behrens¹

2011

Encyclopedia of Inorganic and Bioinorganic Chemistry

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Living organisms are able to manufacture a variety of sophisticated inorganic materials with precise control over chemical composition, crystal structure, and shape. Biomolecules offer unique functionalities such as specific recognition capabilities or catalytic activity. On the basis of these recognition capabilities, biological subunits are able to self‐assemble into defined superstructures with unique shapes. Furthermore, they may respond to multiple physical, chemical, or biological stimuli, and therefore provide a potential means for manufacturing nanomachines. However, naturally occurring inorganic materials are typically based on protein scaffolds with inorganic minerals, e.g., iron oxide or calcium carbonate, which limits their technical application. Hence, the knowledge of biological concepts, functions, and design features has recently been exploited for manufacturing new, technologically important, and functional inorganic nanomaterials that have no isomorphous complement in nature. One major challenge in manufacturing nanostructures by biotemplating has been the need to either modify traditional methodologies derived from chemistry or microelectronics, or to develop new synthetic pathways, in order to make the material synthesis compatible with the relatively labile biotemplates. Various chemical procedures illustrated by selected examples have been elaborated to direct the nucleation and deposition of inorganic materials (e.g., metals, alloys, or semiconductors) on bioassemblies or to link preformed inorganic building blocks to functional biomolecules. Bioassemblies template complex, multidimensional, and inorganic nanoarchitectures that are typically not available by conventional material synthesis. Recently, the templating ability of natural bioassemblies has been improved by means of genetic engineering. Moreover, it has been demonstrated that the biological functionality of the system may be retained under appropriate conditions, which allows the manufacturing of inorganic nanostructures with motility functions. The use of diverse nanostructured bioassemblies based on both proteins (e.g., cell components such as microtubules, microfilaments, S‐layers) or microorganisms (i.e., viruses, diatoms) and deoxyribonucleic acid (DNA) is discussed for their potential of templating of inorganic nanoarchitectures.

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“…Bergkvist et al [9] used the hexagonally packed intermediate layer of Deinococcus radiodurans to assemble and study 5 nm arrays of gold nanoparticles with approximately 0.18 nm interparticle spacing that correlated with the pore-to-pore distance of the S-layer [9]. Bacterial channel porins from Gram-positive bacteria are also being investigated as potential protein-based layers on semi-conducting and conducting surfaces for application in new device architectures for information recording [10].…”

Section: Structure Utilizationmentioning

confidence: 99%