Hydrogel microparticles for biosensing

Goff, Gaelle C. Le; Srinivas, Rathi L.; Hill, W. A.; Doyle, Patrick S.

doi:10.1016/j.eurpolymj.2015.02.022

Cited by 175 publications

(147 citation statements)

References 142 publications

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“…Monodispersed hydrogel microbeads were fabricated using a cross‐junction droplet generation device (Figure S1, Supporting Information) prior to their functionalization with capture primary antibodies (IgGs). Covalent coupling enables the stable immobilization of the capture antibodies without the leaching problems typically associated with physical absorption approaches . For PNIPAM‐based gels, additional functional groups are required to perform covalent modifications.…”

Section: Resultsmentioning

confidence: 99%

“…The hydrated and nonrigid gel matrix also improved the target binding kinetics by reducing steric issues, potentially augmenting assay performances. However, more often than not, hydrogel‐based systems suffer from diffusion limitations, giving rise to large assay variabilities and reduced detection capabilities. Therefore, an interconnected pore structure with significantly large pores is crucial for allowing target proteins to diffuse freely through P (NIPAM‐ co ‐AAc) gels.…”

Section: Resultsmentioning

confidence: 99%

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Smart Hydrogel Microfluidics for Single‐Cell Multiplexed Secretomic Analysis with High Sensitivity

Hsu

Wei

Guo

et al. 2018

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Secreted proteins determine a range of cellular functionalities correlated with human health and disease progression. Because of cell heterogeneity, it is essential to measure low abundant protein secretions from individual cells to determine single‐cell activities. In this study, an integrated platform consisting of smart hydrogel immunosensors for the sensitive detection of single‐cell secretions is developed. A single cell and smart hydrogel microparticles are encapsulated within a droplet. After incubation, target secreted proteins from the cell are captured in the smart hydrogel particle for immunoassay. The temperature‐induced volume phase transition of the hydrogel biosensor allows the concentration of analytes within the gel matrix to increase, enabling high‐sensitivity measurements. Distinct heterogeneity for live cell secretions is determined from 6000 cells within 1 h. This method is tested for low abundant essential secretions, such as interleukin‐6, interleukin‐8, and monocyte chemoattractant protein‐1 secretions of both suspended cells (HL60) and adherent cells (MCF7 and MDA‐MB‐231). This platform is highly flexible and can be used to simultaneously measure a wide range of clinically relevant cellular secretions; it thus represents a novel tool for precise biological assays.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Smart Hydrogel Microfluidics for Single‐Cell Multiplexed Secretomic Analysis with High Sensitivity

Hsu

Wei

Guo

et al. 2018

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“…Recently developed spectrally encoded hydrogel beads provide an appealing alternative that have been used for a variety of biomedical and sensing applications 20,21 . Hydrogel beads are comprised of a cross-linked, hydrated polymeric network made up of one or more hydrophilic monomers, providing near fluid-phase kinetics at functionalized surfaces as well as high-efficiency molecular loading 22,23 , and microfluidic droplet generators have been used to produce and polymerize hydrogel beads at high-throughput 24 .…”

Section: Introductionmentioning

confidence: 99%

MRBLES 2.0: High-throughput generation of chemically functionalized spectrally and magnetically-encoded hydrogel beads using a simple single-layer microfluidic device

Feng

White

Hein

et al. 2020

Preprint

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Widespread adoption of bead-based multiplexed bioassays requires the ability to easily synthesize encoded microspheres and conjugate analytes of interest to their surface. Here, we present a simple method (MRBLEs 2.0) for efficient high-throughput generation of microspheres with ratiometric barcode lanthanide encoding (MRBLEs) bearing functional groups for downstream bioconjugation. Bead production in MRBLEs 2.0 relies on manual mixing of lanthanide/polymer mixtures (each of which comprises a unique spectral code) followed by droplet generation using single-layer, parallel flow-focusing devices and off-chip batch polymerization of droplets into beads. To streamline downstream analyte coupling, MRBLEs 2.0 crosslinks copolymers bearing functional groups on the bead surface simultaneously during bead generation. Using the MRBLEs 2.0 pipeline, we generate monodisperse MRBLEs containing 48 distinct well-resolved spectral codes in high-throughput (>150,000/min and can be boosted to 450,000/min). We further demonstrate the efficient conjugation of oligonucleotides and entire proteins to carboxyl MRBLEs and biotin to amino MRBLEs. Finally, we show that MRBLEs can also be magnetized via simultaneous incorporation of magnetic nanoparticles with only a minor decrease in the potential code space. We anticipate that MRBLEs 2.0 can be directly applied towards a wide variety of downstream assays from basic biology to diagnostics and other translational research.

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“…The assembly of cell‐encapsulating blocks with a defined 3D structure represents a promising approach to create a functional hetero‐architecture to mimic complex natural tissues. These approaches have a significant potential for microscale tissue engineering, personalized medicine screening, and drug delivery . In brief, these reported methods for fabricating 3D tissue structures can be classified into two categories: top‐down and bottom‐up.…”

Section: Introductionmentioning

confidence: 99%

High‐Throughput Fabrication and Modular Assembly of 3D Heterogeneous Microscale Tissues

Yang

et al. 2016

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3D hydrogel microstructures that encapsulate cells have been used in broad applications in microscale tissue engineering, personalized drug screening, and regenerative medicine. Recent technological advances in microstructure assembly, such as bioprinting, magnetic assembly, microfluidics, and acoustics, have enabled the construction of designed 3D tissue structures with spatially organized cells in vitro. However, a bottleneck exists that still hampers the application of microtissue structures, due to a lack of techniques that combined high-throughput fabrication and flexible assembly. Here, a versatile method for fabricating customized microstructures and reorganizing building blocks composed of functional components into a combined single geometric shape is demonstrated. The arbitrary microstructures are dynamically synthesized in a microfluidic device and then transferred to an optically induced electrokinetics chip for manipulation and assembly. Moreover, building blocks containing different cells can be arranged into a desired geometry with specific shape and size, which can be used for microscale tissue engineering.

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Hydrogel microparticles for biosensing

Cited by 175 publications

References 142 publications

Smart Hydrogel Microfluidics for Single‐Cell Multiplexed Secretomic Analysis with High Sensitivity

Smart Hydrogel Microfluidics for Single‐Cell Multiplexed Secretomic Analysis with High Sensitivity

MRBLES 2.0: High-throughput generation of chemically functionalized spectrally and magnetically-encoded hydrogel beads using a simple single-layer microfluidic device

High‐Throughput Fabrication and Modular Assembly of 3D Heterogeneous Microscale Tissues

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