Microfluidic Assays for DNA Manipulation Based on a Block Copolymer Immobilization Strategy

Vasdekis, Andreas E.; O’Neil, Conlin P.; Hubbell, Jeffrey A.

doi:10.1021/bm901453u

Cited by 15 publications

(12 citation statements)

References 45 publications

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“…Physisorption methods are simple and rapid. However, these methods are relatively limited since the coated modifiers are not durable during the protein separation [5][6][7]. On the contrary, modification of PDMS microchannels by chemical grafting using polymer brushes exhibits high stability and repeatability [8].…”

Section: Introductionmentioning

confidence: 99%

“Click” chemistry‐based surface modification of poly(dimethylsiloxane) for protein separation in a microfluidic chip

Zhang

Feng

et al. 2010

Electrophoresis

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"Click" chemistry-based surface modification strategy was developed for PDMS microchips to enhance separation performance for both amino acids and proteins. Alkyne-PEG was synthesized by a conventional procedure and then "click" grafted to azido-PDMS. FTIR absorption by attenuated total reflection and contact angle measurements proved efficient grafting of alkyne-PEG onto PDMS surface. Manifest EOF regulation and stability of PEG-functionalized PDMS microchips were illustrated via EOF measurements and protein adsorption investigations. The stability of nonspecific protein adsorption resistance property was investigated up to 30 days. Separation of fluorescence-labeled amino acids and proteins was further demonstrated with high repeatability and reproducibility. Comparison of protein separation using PDMS microchips before and after surface modification suggested greatly improved electrophoretic performance of the PEG-functionalized PDMS microchips. We expect the "click" chemistry-based surface modification method to have wide applications in microseparation of proteins with long-term surface stability.

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Section: Introductionmentioning

confidence: 99%

“Click” chemistry‐based surface modification of poly(dimethylsiloxane) for protein separation in a microfluidic chip

Zhang

Feng

et al. 2010

Electrophoresis

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“…Physisorption with PEG copolymers is one of the simplest ones, and involves only the incubation of aqueous buffers of the copolymer. Poly( l -lysine)- g -poly(ethylene glycol) (PLL- g -PEG) is one such copolymer, which has found numerous applications in both oxide and PDMS based microfluidics for cell cultures, protein studies and single molecule manipulation and imaging [40,153,158,159] (Figure 7). An alternative PEG surface functionalization is based on the covalent bonding of PEG to albumin microgels, which are recognized by the surface [160].…”

Section: Noise Reduction Using Microfluidic Compatible Surface Passivmentioning

confidence: 99%

“…Right: An optically magnified image of an individual nucleic acid; the scale bar is 1 μm. In these experiments, the copolymer aided both the prevention of non-specific interactions, but also the stretching of the DNA below its contour length due to the hydrophilic nature of the PEG [40]. …”

Section: Figurementioning

confidence: 99%

Enhancing Single Molecule Imaging in Optofluidics and Microfluidics

Vasdekis

Laporte

2011

IJMS

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Microfluidics and optofluidics have revolutionized high-throughput analysis and chemical synthesis over the past decade. Single molecule imaging has witnessed similar growth, due to its capacity to reveal heterogeneities at high spatial and temporal resolutions. However, both resolution types are dependent on the signal to noise ratio (SNR) of the image. In this paper, we review how the SNR can be enhanced in optofluidics and microfluidics. Starting with optofluidics, we outline integrated photonic structures that increase the signal emitted by single chromophores and minimize the excitation volume. Turning then to microfluidics, we review the compatible functionalization strategies that reduce noise stemming from non-specific interactions and architectures that minimize bleaching and blinking.

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“…In order to work at the physiological pH 7.4 and to avoid the overstretching of DNA molecules, Dukkipati et al introduced a protein-assisted DNA immobilization and stretching approach, in which the proteins on the DNA-protein complex adsorbed on the channel surface to stretch the DNA under a hydrodynamic flow [103]. In another study, the surface of microchannel was rendered passive to adsorption by functionalizing with a block copolymer, poly(L-lysine-graft-polyethylene glycol), thus minimizing the fluorescence background from the nontargeted adsorbed molecules, and more importantly, the channel surface properties were stable under either wet or dry conditions [104]. Manipulation of DNA molecules has also been demonstrated in free solution without immobilization.…”

Section: Dna Manipulationmentioning

confidence: 99%

Recent advances in single‐molecule detection on micro‐ and nano‐fluidic devices

Liu¹,

Qu²,

Luo³

et al. 2011

Electrophoresis

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Single-molecule detection (SMD) allows static and dynamic heterogeneities from seemingly equal molecules to be revealed in the studies of molecular structures and intra- and inter-molecular interactions. Micro- and nanometer-sized structures, including channels, chambers, droplets, etc., in microfluidic and nanofluidic devices allow diffusion-controlled reactions to be accelerated and provide high signal-to-noise ratio for optical signals. These two active research frontiers have been combined to provide unprecedented capabilities for chemical and biological studies. This review summarizes the advances of SMD performed on microfluidic and nanofluidic devices published in the past five years. The latest developments on optical SMD methods, microfluidic SMD platforms, and on-chip SMD applications are discussed herein and future development directions are also envisioned.

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Microfluidic Assays for DNA Manipulation Based on a Block Copolymer Immobilization Strategy

Cited by 15 publications

References 45 publications

“Click” chemistry‐based surface modification of poly(dimethylsiloxane) for protein separation in a microfluidic chip

“Click” chemistry‐based surface modification of poly(dimethylsiloxane) for protein separation in a microfluidic chip

Enhancing Single Molecule Imaging in Optofluidics and Microfluidics

Recent advances in single‐molecule detection on micro‐ and nano‐fluidic devices

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