Carboxyl-Terminated Dendrimer-Coated Bioactive Interface for Protein Microarray:  High-Sensitivity Detection of Antigen in Complex Biological Samples

Ajikumar, Parayil Kumaran; Ng, Jin Kiat; Tang, Yew Chung; Lee, Jim Yang; Stephanopoulos, Gregory; Too, Heng‐Phon

doi:10.1021/la063717u

Cited by 92 publications

(82 citation statements)

References 76 publications

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“…We realized that the availability and the lifetime of the NHS esters on the dendritic linker would determine the reaction efficiency and yields in the conjugation with the biomolecule that needs to be labeled. The activation reaction with EDC and NHS is most efficient at slightly acidic pH and usually performed in MES buffer at pH 4.7-6.0 [41,42,27]. With that in mind, we decided to explore on the effect of some other variables present in the EDC/NHS activation step such as the molar excess of NHS per COOH group, the ratio of the EDC/NHS co-reactants and the reaction time needed for the COOH activation.…”

Section: Optimisation Of Bioconjugationmentioning

confidence: 99%

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A comparison of mono and multivalent linkers and their effect on the colloidal stability of nanoparticle and immunoassays performance

Gubala

Guével

Nooney

et al. 2010

Talanta

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When designing devices for biomedical diagnostics, increasing the signal to noise ratio is often critical for achieving clinically relevant sensitivity and limits of detection (LOD). In antibodybased assays, the measured signal can be amplified through the replacement of molecular fluorophores with doped nanoparticles (NP). However, the benefits of using NPs can only be realized if the NPs are coated efficiently with detection antibody, have good colloidal stability and the ratio of specific to non-specific binding (NSB) is high enough. The main focus of this paper is on the optimization of the bioconjugation protocol for antibody labeling of NPs leading to improved assay performance. Two types of linkers were used: monovalent linkers (glutaraldehyde; sulfo-SMCC; and sulfo-SIAB), and three generations of dendrimers endowed with multivalent carboxylic functionality. Overall, the NP-IgG conjugates prepared using multivalent linkers showed a significantly lower LOD and higher sensitivity than their homo-or hetero-functional counterparts. The multivalent dendrimers also improved NP stability and reduced aggregation. Moreover, the dendrimers showed a higher reactivity with biological material, a feature that could significantly reduce the cost of high-throughput biodiagnostics tests. Introduction:

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Section: Optimisation Of Bioconjugationmentioning

confidence: 99%

“…Multivalent dendrimers are attracting a great deal of interest for applications in biomedical diagnostics [27][28][29][30], pharmacology / drug delivery [31,32] [33], cancer research [34], and nanomedicine [35]. Their use in research is still unabated now, 30 years after their first reported synthesis by Vogtle [36].…”

mentioning

confidence: 99%

A comparison of mono and multivalent linkers and their effect on the colloidal stability of nanoparticle and immunoassays performance

Gubala

Guével

Nooney

et al. 2010

Talanta

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“…Polyethylene(glycol) derivatives are also known in surface chemistry as effective suppressors of non-specific binding of biomolecules [15][16][17][18]. Their function is associated less with electrostatic forces but rather with vast hydration and effects of change of configurational entropy when large molecules adsorb upon them.…”

Section: Introductionmentioning

confidence: 99%

“…In this process, TEOS was grafted onto a Zeonor substrate and allowed to cross-link with molecules of acrylic acid. The polymerization reaction was initiated by plasma and resulted in the formation of exceptionally stable, hydrophilic film with high density of Ð COOH groups.Polyethylene(glycol) derivatives are also known in surface chemistry as effective suppressors of non-specific binding of biomolecules [15][16][17][18]. Their function is associated less with electrostatic forces but rather with vast hydration and effects of change of configurational entropy when large molecules adsorb upon them.…”

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confidence: 99%

TIRF microscopy as a screening method for non-specific binding on surfaces

Charlton

Gubala

Gandhiraman

et al. 2011

Journal of Colloid and Interface Science

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We report a method for studying nanoparticle-biosensor surface interactions based on Total Internal Reflection Fluorescence (TIRF) Microscopy. We demonstrate that this simple technique allows for high throughput screening of non-specific adsorption (NSA) of nanoparticles on surfaces of different chemical composition. Binding events between fluorescent nanoparticles and functionalized Zeonor¨ surfaces are observed in real-time, giving a measure of the attractive or repulsive properties of the surface and the kinetics of the interaction. Three types of coatings have been studied: one containing a polymerized aminosilane network with terminal ÐNH 2 groups, a second film with a high density of Ð COOH surface groups and the third with sterically restraining branched poly(ethylene)glycol (PEG) functionality. TIRF microscopy revealed that the NSA of nanoparticles with negative surface charge on such modified coatings decreased in the following order ÐNH 2 > -branched PEG > -COOH. The surface specificity of the technique also allows discrimination of the degree of NSA of the same surface at different pH. KeywordsTotal Internal Reflection, Fluorescence, Microscopy, Non-Specific Binding, SurfaceParticle Interaction IntroductionCurrent research in biomedical diagnostics is directed at inexpensive, highly sensitive, miniaturized devices, in which usually disposable substrates or chips are used. Such devices are required to measure analytes in microliter volume samples, typically at picomolar level. In fluorescence-based assays, the signal can be greatly enhanced with the use of dye doped nanoparticles as fluorescent labels [1][2][3][4]. However, in a successful diagnostics device, signal-to-noise ratio is paramount to its performance and effectively controls the sensitivity. Controlling the noise and background contribution, dictated by non-specific binding of the non-analyte constituents of the sample remains very challenging. The chemical composition of the substrate surface and its interactions with the active surface area of the dye-doped nanoparticles, therefore, play a key role in the performance of diagnostic platform. In this work, we focus on surface functionalization of the substrate ZeonorÒ, a cyclo-olefin polymer (COP), which is characterized by ease of injection molding for biochip fabrication and relatively low autofluorescence, which is an important factor for fluorescence-based applications including TIRF microscopy.Total Internal Reflection Fluorescence (TIRF) microscopy [5] is presented here as a very useful and fast method to compare non-specific adsorption of detection molecules on different surfaces. This method allowed for rapid screening of surfaces to find their ability to prevent non-specific binding. Total internal reflection occurs an any interface between materials of different refractive index inside the material of higher refractive index provided the angle of incidence of the light is above the critical angle defined as:where n 1 is the refractive index of the high refractive index mat...

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“…DP-coated surfaces can load more proteins and more protein activity than planar surfaces. [64][65][66][67] Furthermore, we determined the relative amounts of dendrimer immobilized on the surface and monitored the enzymecatalyzed reactions using fluorescence microscopy by means of the fluorescent properties of the DP. 66 To prepare a DP-coated surface, the surface of a silicon wafer was covered with positively charged amine groups using 3-aminopropyltriethoxysilane deposited DP via electrostatic interaction in a silanization reaction (Figure 12).…”

Section: Dp-immobilized Surfaces For Diagnostic Toolsmentioning

confidence: 99%

Dendrimer porphyrin-based self-assembled nano-devices for biomedical applications

Jeong

Yoon

Jang

2012

Polym J

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Dendrimers have attracted great interest for the design of functional materials. Because the core porphyrin unit in dendrimer porphyrin (DP) is surrounded by large poly(benzyl ether) dendritic wedges with ionic peripheries, the resulting electrostatic interaction with oppositely charged polymeric materials has been used to create various functional nano-devices. In this paper, we briefly review DP-based self-assembled biomedical nano-devices, including DP-loaded polyion complex micelles, the ternary complex systems used for gene delivery, polymer-metal complex micelles, the hollow nanocapsules used for combination cancer therapy, and the DP-immobilized surfaces used for diagnostic tools.

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Carboxyl-Terminated Dendrimer-Coated Bioactive Interface for Protein Microarray: High-Sensitivity Detection of Antigen in Complex Biological Samples

Cited by 92 publications

References 76 publications

A comparison of mono and multivalent linkers and their effect on the colloidal stability of nanoparticle and immunoassays performance

A comparison of mono and multivalent linkers and their effect on the colloidal stability of nanoparticle and immunoassays performance

TIRF microscopy as a screening method for non-specific binding on surfaces

Dendrimer porphyrin-based self-assembled nano-devices for biomedical applications

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