Crystallographic recognition controls peptide binding for bio-based nanomaterials

Ryan Coppage; Joseph M. Slocik; Beverly D. Briggs; Anatoly I. Frenkel; Hendrik Heinz; Rajesh R. Naik; Marc R. Knecht

doi:10.1021/ja203726n

Crystallographic recognition controls peptide binding for bio-based nanomaterials

Ryan Coppage
, Joseph M. Slocik
, Beverly D. Briggs
, Anatoly I. Frenkel
, Hendrik Heinz
, Rajesh R. Naik
, Marc R. Knecht

Materials Science and Engineering

University of Miami
Air Force Research Laboratory
University of Akron

Research output: Contribution to journal › Article › peer-review

94 Scopus citations

Abstract

The ability to control the size, shape, composition, and activity of nanomaterials presents a formidable challenge. Peptide approaches represent new avenues to achieve such control at the synthetic level; however, the critical interactions at the bio/nano interface that direct such precision remain poorly understood. Here we present evidence to suggest that materials-directing peptides bind at specific time points during Pd nanoparticle (NP) growth, dictated by material crystallinity. As such surfaces are presented, rapid peptide binding occurs, resulting in the stabilization and size control of single-crystal NPs. Such specificity suggests that peptides could be engineered to direct the structure of nanomaterials at the atomic level, thus enhancing their activity.

Original language	English
Pages (from-to)	12346-12349
Number of pages	4
Journal	Journal of the American Chemical Society
Volume	133
Issue number	32
DOIs	https://doi.org/10.1021/ja203726n
State	Published - Aug 17 2011

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10.1021/ja203726n

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title = "Crystallographic recognition controls peptide binding for bio-based nanomaterials",

abstract = "The ability to control the size, shape, composition, and activity of nanomaterials presents a formidable challenge. Peptide approaches represent new avenues to achieve such control at the synthetic level; however, the critical interactions at the bio/nano interface that direct such precision remain poorly understood. Here we present evidence to suggest that materials-directing peptides bind at specific time points during Pd nanoparticle (NP) growth, dictated by material crystallinity. As such surfaces are presented, rapid peptide binding occurs, resulting in the stabilization and size control of single-crystal NPs. Such specificity suggests that peptides could be engineered to direct the structure of nanomaterials at the atomic level, thus enhancing their activity.",

author = "Ryan Coppage and Slocik, \{Joseph M.\} and Briggs, \{Beverly D.\} and Frenkel, \{Anatoly I.\} and Hendrik Heinz and Naik, \{Rajesh R.\} and Knecht, \{Marc R.\}",

year = "2011",

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day = "17",

doi = "10.1021/ja203726n",

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AU - Coppage, Ryan

AU - Slocik, Joseph M.

AU - Briggs, Beverly D.

AU - Frenkel, Anatoly I.

AU - Heinz, Hendrik

AU - Naik, Rajesh R.

AU - Knecht, Marc R.

PY - 2011/8/17

Y1 - 2011/8/17

N2 - The ability to control the size, shape, composition, and activity of nanomaterials presents a formidable challenge. Peptide approaches represent new avenues to achieve such control at the synthetic level; however, the critical interactions at the bio/nano interface that direct such precision remain poorly understood. Here we present evidence to suggest that materials-directing peptides bind at specific time points during Pd nanoparticle (NP) growth, dictated by material crystallinity. As such surfaces are presented, rapid peptide binding occurs, resulting in the stabilization and size control of single-crystal NPs. Such specificity suggests that peptides could be engineered to direct the structure of nanomaterials at the atomic level, thus enhancing their activity.

AB - The ability to control the size, shape, composition, and activity of nanomaterials presents a formidable challenge. Peptide approaches represent new avenues to achieve such control at the synthetic level; however, the critical interactions at the bio/nano interface that direct such precision remain poorly understood. Here we present evidence to suggest that materials-directing peptides bind at specific time points during Pd nanoparticle (NP) growth, dictated by material crystallinity. As such surfaces are presented, rapid peptide binding occurs, resulting in the stabilization and size control of single-crystal NPs. Such specificity suggests that peptides could be engineered to direct the structure of nanomaterials at the atomic level, thus enhancing their activity.

UR - https://www.scopus.com/pages/publications/80051589789

U2 - 10.1021/ja203726n

DO - 10.1021/ja203726n

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AN - SCOPUS:80051589789

SN - 0002-7863

VL - 133

SP - 12346

EP - 12349

JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

IS - 32

ER -

Crystallographic recognition controls peptide binding for bio-based nanomaterials

Abstract

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