Covalently Modified Silicon and Diamond Surfaces:  Resistance to Nonspecific Protein Adsorption and Optimization for Biosensing

Lasseter, Tami L.; Clare, Tami Lasseter; Abbott, Nicholas L.; Hamers, Robert J.

doi:10.1021/ja047642x

Cited by 194 publications

(167 citation statements)

References 19 publications

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“…Diamond may be more biocompatible for direct protein immobilization than, for example, metal surfaces [22]. However, from our experience of single-molecule dynamics [23,24], as well as that of others' [10,[25][26][27][28][29][30], we still recommend the use of an intervening layer for preserving enzymatic activities. Polymer layers have a distinct advantage compared with flat solid surfaces in terms of retaining protein activity.…”

Section: Functionalization Of Diamond Surfacementioning

confidence: 97%

Nanoindentation as a Tool to Clarify the Mechanism Causing Variable Stiffness of a Silane Layer on Diamond

Shcherbakova¹,

Hatakeyama²,

Amemiya³

et al. 2012

Nanoindentation in Materials Science

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Section: Functionalization Of Diamond Surfacementioning

confidence: 97%

Nanoindentation as a Tool to Clarify the Mechanism Causing Variable Stiffness of a Silane Layer on Diamond

Shcherbakova¹,

Hatakeyama²,

Amemiya³

et al. 2012

Nanoindentation in Materials Science

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“…It is known that without a protective coating of aminopropylsilane on silica or aminodecane on diamond surfaces, the antibodies can bind nonspecifically to both surfaces [61,29], losing their conformation and specific affinity to antigens. However, it is not known how the antibody proteins could interact with the substrates in the presence of the functionalization layer and how the functionalization layer degrades in solution.…”

Section: Imentioning

confidence: 99%

Modeling the Interface between Biological and SyntheticComponents in Hybrid Nanosystems

Carr¹

2011

Simulations in Nanobiotechnology

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The fusion of biology and nanotechnology holds amazing promise for revolutionizing medicine and personal technology. In order to take advantage of the great feats of engineering coming out of these fields, there needs to be theories and computational tools capable of describing the interface between the pristine and ordered world of precision electronics and the hot, wet, and stochastic world of biology. The success of these technologies will depend on our abilities to design and optimize interactions of biomolecules and solid-state

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“…9,10 Si(111) surfaces can be terminated with methyl groups in a highly controlled manner, which results in coverage by a full monolayer 6 with essentially every Si atom on the surface bonded to a methyl group. Relative to the hydrogenterminated Si(111) surface, methyl-terminated Si(111) surfaces exhibit enhanced resistance to oxidation in air.…”

Section: Introductionmentioning

confidence: 99%

The interaction of organic adsorbate vibrations with substrate lattice waves in methyl-Si(111)-(1 × 1)

Brown

Hund

Campi

et al. 2014

The Journal of Chemical Physics

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A combined helium atom scattering and density functional perturbation theory study has been performed to elucidate the surface phonon dispersion relations for both the CH3-Si(111)-(1 × 1) and CD3-Si(111)-(1 × 1) surfaces. The combination of experimental and theoretical methods has allowed characterization of the interactions between the low energy vibrations of the adsorbate and the lattice waves of the underlying substrate, as well as characterization of the interactions between neighboring methyl groups, across the entire wavevector resolved vibrational energy spectrum of each system. The Rayleigh wave was found to hybridize with the surface rocking libration near the surface Brillouin zone edge at both the ${\rm \bar M}$M¯-point and ${\rm \bar K}$K¯-point. The calculations indicated that the range of possible energies for the potential barrier to the methyl rotation about the Si-C axis is sufficient to prevent the free rotation of the methyl groups at a room temperature interface. The density functional perturbation theory calculations revealed several other surface phonons that experienced mode-splitting arising from the mutual interaction of adjacent methyl groups. The theory identified a Lucas pair that exists just below the silicon optical bands. For both the CH3- and CD3-terminated Si(111) surfaces, the deformations of the methyl groups were examined and compared to previous experimental and theoretical work on the nature of the surface vibrations. The calculations indicated a splitting of the asymmetric deformation of the methyl group near the zone edges due to steric interactions of adjacent methyl groups. The observed shifts in vibrational energies of the -CD3 groups were consistent with the expected effect of isotopic substitution in this system.

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Covalently Modified Silicon and Diamond Surfaces: Resistance to Nonspecific Protein Adsorption and Optimization for Biosensing

Cited by 194 publications

References 19 publications

Nanoindentation as a Tool to Clarify the Mechanism Causing Variable Stiffness of a Silane Layer on Diamond

Nanoindentation as a Tool to Clarify the Mechanism Causing Variable Stiffness of a Silane Layer on Diamond

Modeling the Interface between Biological and SyntheticComponents in Hybrid Nanosystems

The interaction of organic adsorbate vibrations with substrate lattice waves in methyl-Si(111)-(1 × 1)

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