Microfluidic approaches for the analysis of protein–protein interactions in solution

Arter, William E.; Levin, Aviad; Krainer, Georg; Knowles, Tuomas P. J.

doi:10.1007/s12551-020-00679-4

Cited by 37 publications

(34 citation statements)

References 101 publications

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“…Future iterations of the platform could also incorporate, for example, multicolor single-molecule spectroscopy and FRET techniques, [39][40][41] as well as other microfluidic separation modalities 42,43 combined with downstream analyses, 44 to enhance assay parallelization, sensitivity, and robustness to experimental noise.…”

Section: Resultsmentioning

confidence: 99%

Direct digital sensing of protein biomarkers in solution

Krainer

Saar

Arter

et al. 2020

Preprint

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Highly sensitive detection of proteins is of central importance to biomolecular analysis and diagnostics. Conventional protein sensing assays, such as ELISAs, remain reliant on surface-immobilization of target molecules and multi-step washing protocols for the removal of unbound affinity reagents. These features constrain parameter space in assay design, resulting in fundamental limitations due to the underlying thermodynamics and kinetics of the immunoprobe–analyte interaction. Here, we present a new experimental paradigm for the quantitation of protein analytes through the implementation of an immunosensor assay that operates fully in solution and realizes rapid removal of excess probe prior to detection without the need of washing steps. Our single-step optofluidic approach, termed digital immunosensor assay (DigitISA), is based on microfluidic electrophoretic separation combined with single-molecule laser-induced fluorescence microscopy and enables calibration-free in-solution protein detection and quantification within seconds. Crucially, the solution-based nature of our assay and the resultant possibility to use arbitrarily high probe concentrations combined with its fast operation timescale enables quantitative binding of analyte molecules regardless of the capture probe affinity, opening up the possibility to use relatively weak-binding affinity reagents such as aptamers. We establish and validate the DigitISA platform by probing a biomolecular biotin–streptavidin binding complex and demonstrate its applicability to biomedical analysis by quantifying IgE–aptamer binding. We further use DigitISA to detect the presence of α-synuclein fibrils, a biomarker for Parkinson’s disease, using a low-affinity aptamer at high probe concentration. Taken together, DigitISA presents a fundamentally new route to surface-free specificity, increased sensitivity, and reduced complexity in state-of-the-art protein detection and biomedical analysis.

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Section: Resultsmentioning

confidence: 99%

Direct digital sensing of protein biomarkers in solution

Krainer

Saar

Arter

et al. 2020

Preprint

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“…The microfluidic design can be customized to allow controlled mixing of multiple input materials and to accommodate biological structures of different length-scales. For miscible liquids, the microchannel allows a continuous flow of analytes via diffusional mixing (Arter et al, 2020), i.e., achieved via passive mixing based on the physical design of the microchannel alone ( Figure 5B). Active mixing is possible by applying suitable external stimuli such as electric or magnetic fields, pressure, and acoustics (Solsona et al, 2019).…”

Section: Design Of Microfluidic Systemsmentioning

confidence: 99%

“…Strategies for creating such functional microchannels, by chemically or physically modifying the inner walls of the microchannels, have been summarized in a recent review (Wang et al, 2019). As the field progresses, additional functionalities of the microfluidic platform such as electrophoretic manipulation (Huh et al, 2008;Yasukawa et al, 2008;Unocic et al, 2014;Arter et al, 2020) can be incorporated for more advanced characterization.…”

Section: In Situ Imaging Using Microfluidic Platformsmentioning

confidence: 99%

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In situ Electron Microscopy of Complex Biological and Nanoscale Systems: Challenges and Opportunities

Han

Porter

2020

Front. Nanotechnol.

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In situ imaging for direct visualization is important for physical and biological sciences. Research endeavors into elucidating dynamic biological and nanoscale phenomena frequently necessitate in situ and time-resolved imaging. In situ liquid cell electron microscopy (LC-EM) can overcome certain limitations of conventional electron microscopies and offer great promise. This review aims to examine the status-quo and practical challenges of in situ LC-EM and its applications, and to offer insights into a novel correlative technique termed microfluidic liquid cell electron microscopy. We conclude by suggesting a few research ideas adopting microfluidic LC-EM for in situ imaging of biological and nanoscale systems.

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“…In a laminar flow regime mixing only occurs by diffusion. Thus, the mixing of the analytes depends only on their intrinsic diffusion coefficient (see Arter et al, 2020 for a recent review). After this, the diffusion parameters of the different elements (i.e., oligomers) can be controlled and analyzed during amyloid aggregation.…”

Section: Introductionmentioning

confidence: 99%