A critical comparison of protein microarray fabrication technologies

Romanov, Valentin; Davidoff, S. Nikki; Miles, Adam; Grainger, David W.; Gale, Bruce K.; Brooks, Benjamin D.

doi:10.1039/c3an01577g

Cited by 154 publications

(111 citation statements)

References 175 publications

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“…The pin is then moved to the appropriate location on the chip and then a light contact between the pins and the surface results in the deposition of typically nano liters of the protein liquid onto the chip surface. The morphology and size of the resulting spot depends on the drop volume, the concentration of the protein and other non-volatile compound, on the surface tension of the droplet, the drying conditions and the surface properties of the chip (Romanov et al, 2014). These printers are easy to use and very flexible concerning the properties of the print solution (different viscosities or the presence of charges).…”

Section: Microarraysmentioning

confidence: 99%

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The Impact of Diffusion on Biochemical Assay Kinetics in 3d-Hydrogel Microarrays

Mahmoud¹

2015

JOSHA

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JOSHA is a service that helps scholars, researchers, and students descover, use, and build upon a wide range of content DeclarationI hereby confirm that this master thesis at hand is solely my own written work and that no other sources, than those indicated in the references, were used.All text passages and diagrams, quoted or paraphrased, from these sources have been properly acknowledged as such and fully cited.This thesis has not been submitted in the same, similar or even partial version to another examination board and was not published elsewhere. In the past few years, this technology has developed a lot with the implementation of novel surface chemistries, detection techniques, and different assay formats. 3D-hydrogel microarrays were developed using unique immobilization techniques based on hydrophilic polymer networks. The 3D polymer network attaches and immobilizes the capture molecules onto the surface in form of a spot with molecules immobilized both on the surface and inside the gel matrix. This retains the molecule's natural confirmation and structure and enables higher immobilization efficiency, which allows for higher sensitivity. However, the achieved sensitivities are still far from the theoretical limit and in many cases, long incubation times are required. These limitations are caused by both the resolution of the used detection techniques and the assay kinetics. This hinders the transfer of the technology from the laboratory to routine diagnostics.The kinetics of a biochemical assay in a microarray can be controlled either by the transport of molecules to the spot or by the binding interaction itself. This work focuses on studying the assay kinetics in 3D-hydrogel microarrays in order to understand and characterize the limiting step for signal development. To simulate conditions of high affinity binding partners and therefore reduce the influence of the reaction kinetics, the biotin-streptavidin system was selected as the biological model for this work.A microarray to study the kinetic processes involved in the signal development was designed and the optimum working concentrations for kinetic characterization were defined. To confirm the mass transport limited kinetics, the measured kinetics was compared to the ideal reaction kinetics depending on the affinity parameters for biotin-streptavidin interaction. The ideal reaction kinetics was three orders of magnitude faster than measured kinetics. The two-compartment model, which is widely used to describe the assay kinetics in 2D microarrays, was used to fit the observed kinetics. However, a deviation from the model after the initial phase of signal development was observed. A hypothesis was made that this deviation is due to an additional diffusion step in the hydrogel. Therefore, a microarray model to study this diffusion step was designed. In this model, the microarrays were dip coated with hydrogel layers of various thickness and mesh sizes. This model simulated conditions where the signal development should depend only on the diffusion t...

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Section: Microarraysmentioning

confidence: 99%

“…These printers are easy to use and very flexible concerning the properties of the print solution (different viscosities or the presence of charges). However, they suffer from the following drawbacks (Romanov et al, 2014):…”

Section: Microarraysmentioning

confidence: 99%

The Impact of Diffusion on Biochemical Assay Kinetics in 3d-Hydrogel Microarrays

Mahmoud¹

2015

JOSHA

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“…Quite a few patterning methods have been developed and commonly used, such as microwriting, 14 microstamping, 15 and micromachining. 16 We describe here another strategy which utilizes addressable electrochemical control of the sensing elements to fabricate sensor arrays with a variety of supramolecular interfacial architecture.…”

Section: The Concept Of Electrochemical Patterningmentioning

confidence: 99%

Integrating plasmonic diagnostics and microfluidics

et al. 2015

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Plasmonics is generally divided into two categories: surface plasmon resonance (SPR) of electromagnetic modes propagating along a (noble) metal/dielectric interface and localized SPRs (LSPRs) on nanoscopic metallic structures (particles, rods, shells, holes, etc.). Both optical transducer concepts can be combined with and integrated in microfluidic devices for biomolecular analyte detections, with the benefits of small foot-print for point-of-care detection, lowcost for one-time disposal, and ease of being integrated into an array format. The key technologies in such integration include the plasmonic chip, microfluidic channel fabrication, surface bio-functionalization, and selection of the detection scheme, which are selected according to the specifics of the targeting analytes. This paper demonstrates a few examples of the many versions of how to combine plasmonics and integrated microfluidics, using different plasmonic generation mechanisms for different analyte detections. One example is a DNA sensor array using a gold film as substrate and surface plasmon fluorescence spectroscopy and microscopy as the transduction method. This is then compared to gratingcoupled SPR for poly(ethylene glycol) thiol interaction detected by angle interrogation, gold nanohole based LSPR chip for biotin-strepavidin detection by wavelength shift, and gold nanoholes/nanopillars for the detection of prostate specific antigen by quantum dot labels excited by the LSPR. Our experimental results exemplified that the plasmonic integrated microfluidics is a promising tool for understanding the biomolecular interactions and molecular recognition process as well as biosensing, especially for on-site or point-of-care diagnostics. V C 2015 AIP Publishing LLC. [http://dx

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“…Microarrays supplies useful tools for clinical studies (vaccine development, disease diagnosis, drug screening for example) as well as an important approach to give advancements in analytical studies [16].…”

Section: Introductionmentioning

confidence: 99%

Analysis of protein microarrays by FTIR imaging

Meutter

Derfoufi

Goormaghtigh

2016

BSI

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Abstract. BACKGROUND:Proteins are sensitive to environmental conditions. Whether they are produced for therapeutic purposes or for fundamental research, the integrity of their structure and post-traductional modifications are key issues. Measuring glycosylation or phosphorylation level as well as their secondary structure most often rely on complex and indirect experiments. Infrared spectroscopy presents a series of advantages related to its multivariate character. There is a lack of high-throughput methods able to analyse these parameters. OBJECTIVE: In this paper we attempted to combine protein microarrays and infrared imaging for high throughput analysis of proteins. METHODS: A protein microarrayer was used to produce protein microarrays on BaF 2 slides transparent in the mid-infrared. Spot density was about 25 spots/mm 2 . A 128 × 128 focal plane array infrared detector was used to record images of the protein microarrays. RESULTS: We show that 100 µm diameter spot are easily analyzed. Spots obtained with low protein concentrations, resulting in an average of a single protein monolayer (ca 3 fg/µm 2 for a 66 kDa protein) provided good quality spectra. CONCLUSIONS: Infrared imaging is a label free, high throughput method, able to analyse protein microarrays and to take advantage from the wide information available in the infrared spectra.

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A critical comparison of protein microarray fabrication technologies

Cited by 154 publications

References 175 publications

The Impact of Diffusion on Biochemical Assay Kinetics in 3d-Hydrogel Microarrays

The Impact of Diffusion on Biochemical Assay Kinetics in 3d-Hydrogel Microarrays

Integrating plasmonic diagnostics and microfluidics

Analysis of protein microarrays by FTIR imaging

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