Covalent Biofunctionalization of Silicon Nitride Surfaces

Arafat, Ahmed; Giesbers, Marcel; Rosso, Michel; Sudhölter, Ernst J. R.; Schroën, Karin; White, R. G.; Li, Yang; Linford, Matthew R.; Zuilhof, Han

doi:10.1021/la7007045

Cited by 79 publications

(100 citation statements)

References 63 publications

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“…Arafat et al [25] concluded that fragments corresponding to Si-C bonds in their SIMS spectra were indicative of covalent binding between the monolayer of alkyl chains and the silicon nitride substrate, as the low ion flux used in TOF-SIMS makes recombination above the surface an unfavorable process. Additionally, neutral ions may be ejected from the surface and, due to the internal kinetic energy, subsequently dissociate to form the detected ion.…”

Section: Resultsmentioning

confidence: 99%

Use of TOF-SIMS to study adsorption and loading behavior of methylene blue and papain in a nano-porous silicon layer

Kempson

Barnes

Prestidge

2010

J. Am. Soc. Mass Spectrom.

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TOF-SIMS was applied to study the cross-sectional distribution of methylene blue and papain in porous silicon layers. Elemental and molecular information were used to study their distributions in the porous region and the chemistry of their adsorption. Methylene blue (MW ϭ 284 Da) [4], and the delivery of active pharmaceutical ingredients [5,6]. The ongoing interest in pSi for use as a therapeutic delivery system is due to the large internal surface area available, the readily modified surface chemistry [7] and, in particular, the excellent in vivo biodegradation and biocompatibility (low toxicity) of the silicon substrate, hydrolysing to form orthosilicic acid, which is readily excreted [8]. The loading dynamics of molecules into a pSi matrix is dependent on wetting and the size of the pores. Likewise, the interaction between a loaded molecule and the pSi substrate is of interest, particularly in the case of protein based therapeutics, whose bioactivity is dependent on remaining in a specific 3D conformation.TOF-SIMS analysis provides information regarding elemental and molecular species present in a sample surface (i.e., within 1-1.5 nm) with high mass resolution (up to ϳ10,000 m/⌬m) and spatial resolution for imaging (ϳ1 micron). Molecular and elemental information is obtained for organic and inorganic materials providing a powerful technique to image organic compounds associated with inorganic substrates or vice versa [9,10]. This has been demonstrated by imaging solid-state pharmaceutical formulations [11][12][13][14], however, to date this has not been extended to porous silicon substrates.In this study, TOF-SIMS was used to map the distribution of methylene blue and papain across porous silicon layers after loading from aqueous solution. Methylene blue (C 16 H 18 N 3 S ϩ , MW ϭ 284.12 g/mol) is a relatively small organic dye molecule commonly used in adsorption studies and can be considered analogous to therapeutic molecules. A molecular mass of 284 g/mol is within a reasonable mass range for a TOF-SIMS' Ga ϩ primary ion beam and can be easily and uniquely identified without interference or confusion from spectral peaks originating from the silicon substrate or in the instance of organic contamination. This molecule was chosen for its convenience, and to assess the ability to use smaller organic fragments to reflect the distribution of the molecule of interest. This is important to be able to extend this work to studying larger molecules, such as proteins and enzymes of pharmaceutical interest, which will not provide a molecular ion in TOF-SIMS. In contrast to methylene blue, papain is a much larger molecule, detailed elsewhere [15], comprising 212 residue units in two domains, giving a molecular weight of 23,406 g/mol. Papain is a cysteine protease hydrolase enzyme present in papaya. This molecular weight is far greater than can be detected with TOF-SIMS, however, fragmentation products can be detected. Smaller organic fragments can be compared with the distribution of methylene blue to investigate si...

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Section: Resultsmentioning

confidence: 99%

Use of TOF-SIMS to study adsorption and loading behavior of methylene blue and papain in a nano-porous silicon layer

Kempson

Barnes

Prestidge

2010

J. Am. Soc. Mass Spectrom.

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“…Alkene-based monolayers were also formed on flat Si x N 4 [Arafat, et al, 2007& Arafat, et al, 2004, (Fig. 6) and 6H-SiC and polycrystalline 3C-SiC [Rosso, et al, 2008b] using thermal conditions close to those used for the surface modification of silicon.…”

Section: Organic Monolayers On the Surfaces Of Silicon-rich Materialsmentioning

confidence: 98%

“…Semi-carbazides and esters can be easily converted to amine [Coffinier, et al, 2007] and acid groups [Rosso, et al, 2009], respectively, which can serve for further attachment of biomolecules or biorepelling molecules and polymers [Asanuma, et al, 2006& Coffinier, et al, 2005& Love, et al, 2005a. The advantage of alkene-based monolayers is their stability, mainly due to the absence of a silicon oxide layer, and the presence of stable and non-polar Si-C bonds, in the case of Si [Linford & Chidsey, 1993] and Si x N 4 , [Arafat, et al, 2007] [Rosso, et al, 2008b] and stable C-O-C bonds in the case of SiC surfaces [Rosso, et al, 2008a]. Stability measurements revealed the outstanding stability of thermally produced 1-hexadecene monolayers on Si x N 4 substrates, in acidic or basic conditions at 60 ºC, with changes in contact angles of less than 5º after 4 h of such a treatment [Arafat, et al, 2007].…”

Section: Organic Monolayers On the Surfaces Of Silicon-rich Materialsmentioning

confidence: 99%

“…The advantage of alkene-based monolayers is their stability, mainly due to the absence of a silicon oxide layer, and the presence of stable and non-polar Si-C bonds, in the case of Si [Linford & Chidsey, 1993] and Si x N 4 , [Arafat, et al, 2007] [Rosso, et al, 2008b] and stable C-O-C bonds in the case of SiC surfaces [Rosso, et al, 2008a]. Stability measurements revealed the outstanding stability of thermally produced 1-hexadecene monolayers on Si x N 4 substrates, in acidic or basic conditions at 60 ºC, with changes in contact angles of less than 5º after 4 h of such a treatment [Arafat, et al, 2007]. On SiC substrates, a good stability is also obtained after 4 h treatments in 2M HCl at 90 ºC and at pH 11 at 60 ºC, with resulting water contact angle values of 106º and 96º, respectively (coming from 108/109º for the original alkyl monolayer) [Rosso, et al, 2009].…”

Section: Organic Monolayers On the Surfaces Of Silicon-rich Materialsmentioning

confidence: 99%

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Silicon and Silicon-Related Surfaces for Biosensor Applications

Arafat¹,

Daous²

2011

Environmental Biosensors

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“…[1][2][3] Devices and applications exploiting these beneficial native features can be augmented and improved using designer metal overlayers that fulfill structural roles, serve as electrodes, and provide alternative surface chemistry options, including as a platform for subsequent thiol monolayer self-assembly. The field of nanopore single-molecule sensing offers compelling examples of the prospects of merging SiNx thin films and designer metal layers into devices, and does this within a nanofluidic context where the need for versatile metallizing approaches is clear.…”

mentioning

confidence: 99%

Solution-Based Photo-Patterned Gold Film Formation on Silicon Nitride

Bandara

Karawdeniya

Whelan

et al. 2016

ACS Appl. Mater. Interfaces

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Silicon nitride fabricated by low-pressure chemical vapor deposition (LPCVD) to be silicon-rich (SiN x ), is a ubiquitous insulating thin film in the microelectronics industry, and an exceptional structural material for nanofabrication. Free-standing <100 nm thick SiN x membranes are especially compelling, particularly when used to deliver forefront molecular sensing capabilities in nanofluidic devices. We developed an accessible, gentle, and solution-based photodirected surface metallization approach well-suited to forming patterned metal films as integral structural and functional features in thin-membrane-based SiN x devicesfor use as electrodes or surface chemical functionalization platforms, for exampleaugmenting existing device capabilities and properties for a wide range of applications.

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Covalent Biofunctionalization of Silicon Nitride Surfaces

Cited by 79 publications

References 63 publications

Use of TOF-SIMS to study adsorption and loading behavior of methylene blue and papain in a nano-porous silicon layer

Use of TOF-SIMS to study adsorption and loading behavior of methylene blue and papain in a nano-porous silicon layer

Silicon and Silicon-Related Surfaces for Biosensor Applications

Solution-Based Photo-Patterned Gold Film Formation on Silicon Nitride

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