Efficient long‐term cell tracing in a noninvasive and real‐time manner is of great importance to understand genesis, development, invasion, and metastasis of cancerous cells. Cell penetrating organic dots with aggregation‐ induced emission (AIE) characteristics are successfully developed as long‐term cell trackers. The AIE dots enjoy the advantages of high emission efficiency, large Stokes shift, good biocompatibility, and high photostability, which ensure their good performance in long‐term non‐invasive in vitro cell tracing. Moreover, it is the first report that AIE dots exhibit certain permeability to cellular nucleus, making them attractive potential candidates for nucleus imaging. The AIE dots display superior performance compared to their counterparts of inorganic quantum dots, opening a new avenue in the development of fluorescent probes for monitoring biological processes.
We demonstrate continuous high-throughput selective capture of circulating tumor cells by dielectrophoresis at arrays of wireless electrodes (bipolar electrodes, BPEs). The use of BPEs removes the requirement of ohmic contact to individual array elements, thus enabling otherwise unattainable device formats. Capacitive charging of the electrical double layer at opposing ends of each BPE allows an AC electric field to be transmitted across the entire device. Here, two such designs are described and evaluated. In the first design, BPEs interconnect parallel microchannels. Pockets extruding from either side of the microchannels volumetrically control the number of cells captured at each BPE tip and enhance trapping. High-fidelity single-cell capture was achieved when the pocket dimensions were matched to those of the cells. A second, open design allows many non-targeted cells to pass through. These devices enable high-throughput capture of rare cells and single-cell analysis.
Synthetic
organic electrosynthesis has grown in the past few decades
by achieving many valuable transformations for synthetic chemists.
Although electrocatalysis has been popular for improving selectivity
and efficiency in a wide variety of energy-related applications, in
the last two decades, there has been much interest in electrocatalysis
to develop conceptually novel transformations, selective functionalization,
and sustainable reactions. This review discusses recent advances in
the combination of electrochemistry and homogeneous transition-metal
catalysis for organic synthesis. The enabling transformations, synthetic
applications, and mechanistic studies are presented alongside advantages
as well as future directions to address the challenges of metal-catalyzed
electrosynthesis.
In this minireview, we discuss advancements in ion concentration polarization (ICP)-based preconcentration, separation, desalination, and dielectrophoresis that have been made over the past three years. ICP as a means of controlling the distribution of the ions and electric field in a microfluidic device has rapidly expanded its areas of application. Recent advancements have focused on the development of ion-permselective materials with tunable dimensions and surface chemistry, adaptation to paper microfluidics, higher-throughput device geometries, and coupling ICP with other separation (isotachophoresis and dielectrophoresis) and fluidic (valve and droplet microfluidic) strategies. These studies have made great strides toward solving real-world problems such as low-cost and rapid analysis, accessible desalination technology, and single-cell research tools.
Simulation and experimental demonstration of the in vitro gene delivery enhancement using electrostatic forces and electroporation (EP) microchips were conducted. Electroporation is a technique with which DNA molecules can be delivered into cells using electric field pulses. This study demonstrates that plasmid DNA can be attracted to the cell surfaces at the specific regions using an electrostatic force. Therefore, the DNA concentration on the cell surface is dramatically increased, which highly enhances the gene transfection efficiency compared to that without an attracting-electric field. The electrostatic force can be designed into specific regions, where the DNA plasmids are attracted to, to provide the region-targeting function. In this micro-device, the top electrode and the interdigitated electrodes provided the DNA attracting-electric field, and the interdigitated electrodes provided adequate electric fields for the electroporation process on the chip surface. Using the EP microchip, cells could be manipulated in situ without detachment if adherent cells were used for electroporation. Five different cells of two different types, primary cell and cell line, were successfully transfected under multi-pulse or single pulse electric field stimulation without applying an attracting-electric field. This study simulated and analyzed the electric field distributions at the DNA attracting and electroporation processes, and successfully demonstrated that the electrostatic force attracted DNA plasmids to specific regions and highly enhanced the gene delivery. In summary, this EP microchip should provide many potential applications for gene therapy.
In this review, recent advances that leverage dielectrophoretic approaches to accomplish single-cell analysis (both "on-chip" and "off-chip") are discussed with special emphasis on eukaryotic cells. Dielectrophoresis as an electric-field-induced force utilized for cell manipulation can confer selectivity without labeling. Recent technical improvements have increased the volumetric throughput of the separation of cells from complex mixtures, introduced new strategies for massively parallel single-cell confinement for subsequent on-chip analysis, made possible selective transport of individual cells off-chip, and integrated preconcentration and prefocusing steps to enhance dielectrophoretic performance. Collectively, these studies potentiate all-in-one platforms capable of taking as their input complex mixtures of cells and accomplishing single-cell analysis. Assays requiring small reaction volumes (e.g., enzymatic assays, fluorescent in situ hybridization, and immunostaining) have been demonstrated. Still greater opportunities to unravel cell-to-cell variations and for point-of-care applications can be realized by making possible on-chip gene amplification, live-cell assays, and either dielectrophoretic manipulation in native media or on-chip exchange of media. We therefore conclude with a discussion of emerging capabilities in these areas.
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