Ryu et al., 2008 - Google Patents
Open micro-fluidic system for atomic force microscopy-guided in situ electrochemical probing of a single cellRyu et al., 2008
View PDF- Document ID
- 11723066289711065553
- Author
- Ryu W
- Huang Z
- Park J
- Moseley J
- Grossman A
- Fasching R
- Prinz F
- Publication year
- Publication venue
- Lab on a Chip
External Links
Snippet
Ultra-sharp nano-probes and customized atomic force microscopy (AFM) have previously been developed in our laboratory for in situ sub-cellular probing of electrochemical phenomena in living plant cells during their photosynthesis. However, this AFM-based …
- 238000011065 in-situ storage 0 title abstract description 7
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| JP6854376B2 (en) | Control of DEP force and control of electrowetting in different compartments of the same microfluidic device | |
| DK3023151T3 (en) | PROCEDURE FOR INFLUENCING A LOCALIZED CIRCULATORY AREA FOR FLUIDUM FLOW AND SIMILAR PIPETTE | |
| Ryu et al. | Open micro-fluidic system for atomic force microscopy-guided in situ electrochemical probing of a single cell | |
| Rusu et al. | Direct integration of micromachined pipettes in a flow channel for single DNA molecule study by optical tweezers | |
| Sima et al. | 3D biomimetic chips for cancer cell migration in nanometer-sized spaces using “Ship-in-a-Bottle” femtosecond laser processing | |
| Nagai et al. | Development and characterization of hollow microprobe array as a potential tool for versatile and massively parallel manipulation of single cells | |
| US20220195486A1 (en) | Multiplexable microfluidic culture chamber for imaging monolayer growth of single cells | |
| Amselem et al. | Universal anchored-droplet device for cellular bioassays | |
| Vecchione et al. | Confined gelatin dehydration as a viable route to go beyond micromilling resolution and miniaturize biological assays | |
| Kalisch et al. | Force generation by dynamic microtubules in vitro | |
| US20220032290A1 (en) | Open fluidic array systems and methods of making and using same | |
| Huang et al. | Surface-directed boundary flow in microfluidic channels | |
| Rao et al. | Demonstration of cancer cell migration using a novel microfluidic device | |
| Takeuchi et al. | Semi-closed microchip for probe manipulation and the target cell harvesting | |
| Gracias et al. | Novel microfabrication approach of embedded SU 8™ fluidic networks for cell transport on chips | |
| Kaprou et al. | Novel design for a microfluidic-based platform for yeast replicative lifespan (RLS) analysis | |
| Nakano et al. | Increase of Expansion Rate and Direction Control of Microgel Actuators for Single Cell Manipulations | |
| Ghanbari Mardasi | Lab-On-Chip for Ex-Vivo study of morphogenesis of tip growing cells of pollen tube | |
| Karimi | Acoustically-Driven Directed Assembly in Three Dimensional and Microfluidic Environments | |
| Akhtar | A microsystem for on-chip droplet storage and processing | |
| Sonmez | Controlling the physical microenvironment of cells with microfluidics for studying mechanically regulated cellular behaviors | |
| Ikuta et al. | Light-drive biomedical micro-tools and biochemical IC chips fabricated by 3D micro/nano stereolithography | |
| Busche | Optofluidic microsystem for antibiotic susceptibility testing | |
| Malboubi et al. | Microfluidic devices for examining the physical limits of migration in confined environments | |
| Tayagui et al. | Fabrication of Lab-on-a-Chip Devices to Study the Forces Imparted by Growing Phytophthora Hyphae |