Droplet Microfluidic Device for Chemoenzymatic Sensing

Yakimov, Anton S.; Denisov, Ivan A.; Bukatin, Anton; Lukyanenko, Kirill A.; Belousov, K. I.; Kukhtevich, I. V.; Esimbekova, Elena N.; Evstrapov, A. A.; Belobrov, P. I.

doi:10.3390/mi13071146

Cited by 5 publications

(3 citation statements)

References 57 publications

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“…Microfluidic droplets have unique chemical properties that are analogous to test tubes or microplates, where the signals from many droplets are averaged to provide higher sensitivity and detection limits [58–62] . Microfluidic technology also has the following advantages [63] : (1) significantly reduced sample/reagent volume and ultrahigh analytical throughput [64] ; (2) precise control of heat and mass transport [65] ; (3) different functional modules can be easily integrated into microfluidic instruments [66] ; (4) rapid temperature equilibration and mixing of reactants with efficient heat and mass transfer [67] ; and (5) extraction of the thermodynamic and kinetic information of enzymes through the high‐throughput extraction of reactants, allowing unbiased analysis and analysis of the reactants, which allows the thermodynamic study of fragile enzymes [68] . In this section, we review the organic synthesis processes enabled by biological enzymes in microfluidics, including homogeneous w/w interfaces and heterogeneous w/o interfaces.…”

Section: Enzyme Catalysismentioning

confidence: 99%

Homogeneous, heterogeneous, and enzyme catalysis in microfluidics droplets

Mei

Lin

et al. 2023

Smart Molecules

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Microfluidics has received extensive attention due to its ability to rapidly prepare a large number of microdroplets with controlled sizes and defined morphologies. In addition to having large surface areas and controllable confinement environments, these prepared microdroplets can be used as analytical detection devices to screen and optimize various kinetic parameters. This review summarizes recent advances in the microfluidic control of droplet‐based catalytic reactions and discusses the role of these droplets in both homogeneous and heterogeneous catalyzes and in the catalysis of macromolecular biological enzymes in water‐in‐oil and oil‐in‐oil environments. Additionally, the existing problems and future development directions of droplets in catalysis are highlighted to promote the development of catalytic reactions in droplet media and provide guidance for the high‐throughput screening of catalysts and the directed evolution of biological enzymes.

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Section: Enzyme Catalysismentioning

confidence: 99%

Homogeneous, heterogeneous, and enzyme catalysis in microfluidics droplets

Mei

Lin

et al. 2023

Smart Molecules

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“…as their interaction products are extremely sensitive to a variety of factors, such as concentration and ratio of components [ 22 , 28 , 29 ], solvent [ 30 ], pH [ 31 ], among others. Nonequilibrium microfluidic confinement allows the simultaneous application of these factors to synthesize and modify soft matter structures [ 32 , 33 , 34 , 35 , 36 ]. By varying microchip operation parameters, we can use various mixing strategies for polymers, colloids and related low-molecular compounds, such as electrolytes [ 35 , 37 , 38 , 39 , 40 ].…”

Section: Introductionmentioning

confidence: 99%

Activation and Switching of Supramolecular Chemical Signals in Multi-Output Microfluidic Devices

Bezrukov

Galyametdinov

2022

Micromachines

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In this study, we report on the developing of a continuous microfluidic reaction device that allows selective activation of polyelectrolyte–surfactant chemical signals in microflows and switches them between multiple outputs. A numerical model was developed for convection–diffusion reaction processes in reactive polymer–colloid microfluidic flows. Matlab scripts and scaling laws were developed for this model to predict reaction initiation and completion conditions in microfluidic devices and the location of the reaction front. The model allows the optimization of microfluidic device geometry and the setting of operation modes that provide release of the reaction product through specific outputs. Representing a chemical signal, polyelectrolyte–surfactant reaction products create various logic gate states at microfluidic chip outputs. Such systems may have potential as biochemical signal transmitters in organ-on-chip applications or chemical logic gates in cascaded microfluidic devices.

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“…[1,2]. Надмолекулярноорганизованные системы на основе жидких кристаллов (ЖК) в микрожидкостных «чипах» находят применение в фотонике [3,4], в качестве биосенсоров [5][6][7] и систем защитной маркировки [8,9], а также в качестве компонентов люминесцентных термометров [10,11] и темплатов для получения полимерных микрочастиц [12].…”

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