Analytical detection techniques for droplet microfluidics--a review.

Organ-on-a-chip platforms for studying drug delivery systems.

Micro Electromechanical Systems (MEMS) based microfluidic devices have gained popularity in biomedicine field over the last few years. In this paper, a comprehensive overview of microfluidic devices such as micropumps and microneedles has been presented for biomedical applications. The aim of this paper is to present the major features and issues related to micropumps and microneedles, e.g., working principles, actuation methods, fabrication techniques, construction, performance parameters, failure analysis, testing, safety issues, applications, commercialization issues and future prospects. Based on the actuation mechanisms, the micropumps are classified into two main types, i.e., mechanical and non-mechanical micropumps. Microneedles can be categorized according to their structure, fabrication process, material, overall shape, tip shape, size, array density and application. The presented literature review on micropumps and microneedles will provide comprehensive information for researchers working on design and development of microfluidic devices for biomedical applications.

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Micro Electromechanical Systems (MEMS) Based Microfluidic Devices for Biomedical Applications

https://pure.tue.nl/ws/files/10316586/Du_2015_Microfluidics_for_cell_based_high_throughput_screening_platforms_A_review.pdf

Microfluidics for cell-based high throughput screening platforms—A review

Using light to control liquid motion is a new paradigm for the actuation of microfluidic systems. We review here the different principles and strategies to induce or control liquid motion using light, which includes the use of radiation pressure, optical tweezers, light-induced wettability gradients, the thermocapillary effect, photosensitive surfactants, the chromocapillary effect, optoelectrowetting, photocontrolled electroosmotic flows and optical dielectrophoresis. We analyze the performance of these approaches to control using light many kinds of microfluidic operations involving discrete pL- to μL-sized droplets (generation, driving, mixing, reaction, sorting) or fluid flows in microchannels (valve operation, injection, pumping, flow rate control). We show that a complete toolbox is now available to control microfluidic systems by light. We finally discuss the perspectives of digital optofluidics as well as microfluidics based on all optical fluidic chips and optically reconfigurable devices.

Photo-actuation of liquids for light-driven microfluidics: state of the art and perspectives

Since the start of micro total analysis systems, manipulation of droplets in a microfluidic channel has been one of the most important branches of microfluidics The scale of the droplet is remarkably small so that its mixing and reaction are rapid With an array of channels and reliable programming, droplet microfluidics provides a high-throughput platform for applications in chemistry and biology The droplet in a microfluidics system can be seen as an isolated reactor, with low consumption of samples and reagents, minimal dispersion and flexible control We review progress in manipulation of droplets in microfluidic systems and their applications We also discuss future perspectives

http://www.ipfdd.de/fileadmin/user_upload/mbz/braun/MBEYang2010a.pdf

Manipulation of droplets in microfluidic systems

Exosomes as nanosized vesicles have been recognized as potential noninvasive biomarkers for early cancer diagnosis. Herein, we presented a sensitive multicolor visual method for exosome detection based on enzyme-induced silver deposition on gold nanorods (Au NRs). To achieve highly sensitive determination of exosomes, hybridization chain reaction (HCR) was employed to introduce more alkaline phosphatase (ALP) for signal amplification. First, exosomes were captured by magnetic bead-labeled CD63 aptamer, and, then, cholesterol-modified DNA probes were spontaneously inserted into the exosomal lipid membrane. The ends of the DNA probes act as the initiator to trigger the HCR for signal amplification. Finally, with the help of HCR, increased sites led to enhanced ALP loading and thus boosted the ascorbic acid generation. Silver ions were reduced by ascorbic acid, and silver shells were formed on Au NRs, giving rise to the blue shift of the longitudinal localized surface plasmon resonance peak. Correspondingly, the concentration of exosomes can be obviously distinguished with naked eyes via the vivid color variation. Due to the dual signal amplification of HCR and metallization of Au NRs, highly sensitive detection for exosomes were realized with detection limits as low as 1.6 × 102 particles/μL by UV-vis spectroscopy and 9 × 103 particles/μL by naked eyes. Compared to the reported colorimetric methods for exosome quantification, visualization based on plentiful color tonalities is the most captivating merit of our approach, and HCR-induced signal amplification highlights the virtue of the strategy. The applicability of the method was validated by the analysis of clinical samples.

Sensitive Multicolor Visual Detection of Exosomes via Dual Signal Amplification Strategy of Enzyme-Catalyzed Metallization of Au Nanorods and Hybridization Chain Reaction

An integrated microfluidic concentration gradient chip was developed for generating stepwise concentrations in high-density channels and applied to high-throughput apoptosis analysis of human uterine cervix cancer (HeLa) cells. The concentration gradient was generated by repeated splitting-and-mixing of the source solutions in a radial channel network which consists of multiple concentric circular channels and an increasing number of branch channels. The gradients were formed over hundreds of branches with predictable concentrations in each branch channel. This configuration brings about some distinctive advantages, e.g., more compact and versatile design, high-density of channels and wide concentration ranges. This concentration gradient generator was used in perfusion culture of HeLa cells and a drug-induced apoptosis assay, demonstrated by investigating the single and combined effects of two model anticancer drugs, 5-fluorouracil and Cyclophosphamide, which were divided into 65 concentrations of the two drugs respectively and 65 of their combinatorial concentrations. The gradient generation, the cell culture/stimulation and staining were performed in a single chip. The present device offers a unique platform to characterize various cellular responses in a high-throughput fashion.

A radial microfluidic concentration gradient generator with high-density channels for cell apoptosis assay.

Exosomes involved in tumor-specific processes display excellent potential in the early diagnosis of cancer. Herein, a highly sensitive plasmonic colorimetric biosensor was proposed for exosome quantification. The sensing strategy mainly includes two steps: exosome-triggered competitive reaction and etching of gold nanobipyramid@MnO2 nanosheet nanostructures (Au NBP@MnO2 NSs). A competitive reaction between exosomes and placeholder chains induced by exosomes can translate the signal of exosomes into the amount of alkaline phosphatase, which simplifies the experimental process and amplifies the signal. The etching of Au NBP@MnO2 NSs by ascorbic acid generated from the hydrolysis of l-ascorbic acid 2-phosphate by alkaline phosphatase changes the refractive index of Au NBPs, accompanied by the blue shift of the longitudinal localized surface plasmon resonance peak. Profiting from the signal amplification of the competitive reaction and superior refractive index sensitivity of colorimetric substrates, this protocol exhibits high sensitivity toward exosomes within 8.5 × 102 to 8.5 × 104 particles μL-1, along with a detection limit of 1.35 × 102 particles μL-1, which is more sensitive than previously reported colorimetric methods. In addition, a sensitive multicolor visual detection of exosomes was realized by adjusting the aspect ratio of Au NBPs. It is worth mentioning that the Au NBP@MnO2 NSs was synthesized through in situ growth of MnO2 nanosheets on Au NBPs, and the attractive optical properties and ease of etching make Au NBP@MnO2 NSs promising candidates for plasmonic detection.

Chun-Guang Yang

Papers

Manipulation of droplets in microfluidic systems

Sensitive Multicolor Visual Detection of Exosomes via Dual Signal Amplification Strategy of Enzyme-Catalyzed Metallization of Au Nanorods and Hybridization Chain Reaction

A radial microfluidic concentration gradient generator with high-density channels for cell apoptosis assay.

Plasmonic Colorimetric Biosensor for Sensitive Exosome Detection via Enzyme-Induced Etching of Gold Nanobipyramid@MnO2 Nanosheet Nanostructures.

An osmotic micro-pump integrated on a microfluidic chip for perfusion cell culture.