[Anti-tumor effect and its related mechanisms of cinobufotalin combined with cisplatin on H22 liver cancer mice].

In order to observe the anti-tumor effect of cinobufotalin on H22 liver cancer mice and to explore its regulatory mechanism, 50 Kunming mice were subcutaneously inoculated with H22 intraperitoneal passage cells under the armpit to establish H22 hepatocellular carcinoma model. They were then randomly divided into model group, cinobufotalin low dose group, cinobufotalin high dose group, cisplatin group and cisplatin+cinobufotalin group, which received 0.01% ethanol solution, 1 mg·kg~(-1) cinobufotalin, 5 mg·kg~(-1) cinobufotalin, 5 mg·kg~(-1) cisplatin, 5 mg·kg~(-1)cisplatin + 5 mg·kg~(-1) cinobufotalin respectively for 10 days.

The Mechanism of Computed Tomography-Guided 125I Particle in Treating Lung Cancer.

BACKGROUND The incidence of malignant tumor has gradually increased. How to improve the survival and quality of life of patients who lose the opportunity for surgery or who are unwilling to receive surgery remains an obstacle. At present, 125I particle interstitial implant therapy has been applied in a variety of treatments of tumors.

Modular integration of electronics and microfluidic systems using flexible printed circuit boards.

Microfluidic systems offer an attractive alternative to conventional wet chemical methods with benefits including reduced sample and reagent volumes, shorter reaction times, high-throughput, automation, and low cost. However, most present microfluidic systems rely on external means to analyze reaction products. This substantially adds to the size, complexity, and cost of the overall system.

Dual frequency dielectrophoresis with interdigitated sidewall electrodes for microfluidic flow-through separation of beads and cells.

This paper presents a novel design and separation strategy for lateral flow-through separation of cells/particles in microfluidics by dual frequency coupled dielectrophoresis (DEP) forces enabled by vertical interdigitated electrodes embedded in the channel sidewalls. Unlike field-flow-fractionation-DEP separations in microfluidics, which utilize planar electrodes on the microchannel floor to generate a DEP force to balance the gravitational force and separate objects at different height locations, lateral separation is enabled by sidewall interdigitated electrodes that are used to generate non-uniform electric fields and balanced DEP forces along the width of the microchannel. In the current design, two separate AC electric fields are applied to two sets of independent interdigitated electrode arrays fabricated in the sidewalls of the microchannel to generate differential DEP forces that act on the cells/particles flowing through.

Unique dielectric properties distinguish stem cells and their differentiated progeny.

The relatively new field of stem cell biology is hampered by a lack of sufficient means to accurately determine the phenotype of cells. Cell-type-specific markers, such as cell surface proteins used for flow cytometry or fluorescence-activated cell sorting, are limited and often recognize multiple members of a stem cell lineage. We sought to develop a complementary approach that would be less dependent on the identification of particular markers for the subpopulations of cells and would instead measure their overall character.

Dielectrophoresis switching with vertical sidewall electrodes for microfluidic flow cytometry.

A novel dielectrophoresis switching with vertical electrodes in the sidewall of microchannels for multiplexed switching of objects has been designed, fabricated and tested. With appropriate electrode design, lateral DEP force can be generated so that one can dynamically position particulates along the width of the channel. A set of interdigitated electrodes in the sidewall of the microchannels is used for the generation of non-uniform electrical fields to generate negative DEP forces that repel beads/cells from the sidewalls.

Fungi use efficient algorithms for the exploration of microfluidic networks.

Fungi, in particular, basidiomycetous fungi, are very successful in colonizing microconfined mazelike networks (for example, soil, wood, leaf litter, plant and animal tissues), a fact suggesting that they may be efficient solving agents of geometrical problems. We therefore evaluated the growth behavior and optimality of fungal space-searching algorithms in microfluidic mazes and networks. First, we found that fungal growth behavior was indeed strongly modulated by the geometry of microconfinement.