INTELLECTUAL MERIT: This symposium, to be held in the context of the 2012 Spring Meeting of the Materials Research Society (MRS), will focus on developing novel strategies to design and construct novel materials useful for a broad range of biologically relevant functions. It is one of eleven scheduled symposia with a bioimaterials theme. Abstracts have been solicited in the following topic areas: (1) peptide, oligonucleotide, or virus-mediated assembly or precipitation, (2) peptide or oliogonucleotide-based aptamers for specific targeting, (3) 3D cellular mimics as therapeutic or diagnostic vehicles, (4) 2D ligand-functionalized SAMS or bilayers, and (5) hierarchically structured biomaterials. These approaches are appropriate for development of materials that may be employed for gene and drug delivery, of self-assembled nanoscopic arrays that may be used for biosensing or bioactivation, of cellular mimics that may have therapeutic or diagnostic applications, and of functionalized surfaces and matrices that may be used to support tissue culture or to suppress bacterial colonization or fouling by protein deposition.

BROADER IMPACTS: Recently, bio-enabled strategies in which biological components are incorporated into otherwise abiological systems, have proven powerful approaches to obtaining intricate hierarchical structures with unique properties that are not otherwise accessible. The challenges involved in these strategies include successfully interfacing nonbiological materials with biomacromolecules, cellular components, or cellular mimics to achieve the desired function. Successful realization of these bio-inspired or bio-enabled hybrid materials often stems from specific associations between heterogeneous components that enable unique synergistic behavior such as controlled precipitation events, precise pattern formation, or molecular recognition-based assembly. Recent successful examples include peptide-driven nucleation of inorganic particles, spontaneous organization of organic and inorganic components to form nanocomposites, and self-assembled monolayers or bilayers to promote cellular activity on a material surface. The symposium will provide opportunities for younger and more established scientists to learn of recent developments from the leading practitioners.

Project Report

Biological systems continue to inspire the design and function of many modern advanced materials. Recently, bio-enabled strategies in which biological components are incorporated into otherwise abiological systems, have proven powerful approaches to obtaining intricate hierarchical structures with unique properties that are not otherwise accessible. The challenges involved in these strategies include successfully interfacing nonbiological materials with biomacromolecules, cellular components, or cellular mimics to achieve the desired function. During the three-day symposium at the MRS 2012 Spring Meeting, several techniques emerged as promising methods for fabricating complex and multifunctional bio-enabled structures. These included DNA self-assembly, polymer and polypeptide networks, peptide-based materials and well-defined nanoparticles. In many presentations, it was evident that preparing multifunctional systems requires the ability to design and control a wide range of materials including biopolymers, inorganic materials, and their composites. This symposium also provided a forum for a rich array of speakers at various stages in their education and career. In order to accommodate the large number of abstract submissions (over 100), a one three-hour poster session was included. Furthermore, abstract submissions and attendance of young faculty and students was encouraged through travel awards to the best presenters. All of the organizers served as judges for best oral presentations in the symposium and for the poster session.

Agency
National Science Foundation (NSF)
Institute
Division of Materials Research (DMR)
Type
Standard Grant (Standard)
Application #
1202832
Program Officer
David A. Brant
Project Start
Project End
Budget Start
2012-02-15
Budget End
2013-01-31
Support Year
Fiscal Year
2012
Total Cost
$5,000
Indirect Cost
Name
Materials Research Society
Department
Type
DUNS #
City
Warrendale
State
PA
Country
United States
Zip Code
15086