| scholarly article | Q13442814 |
| P50 | author | Hsieh-Fu Tsai | Q58787347 |
| P2093 | author name string | Chun-Ying Wu | |
| Ji-Yen Cheng | |||
| Hui-Fang Chang | |||
| Shih-Wei Peng | |||
| P2860 | cites work | Gene expression of human lung cancer cell line CL1-5 in response to a direct current electric field | Q27317026 |
| A role for PP1/NIPP1 in steering migration of human cancer cells | Q27334105 | ||
| Local calcium elevation and cell elongation initiate guided motility in electrically stimulated osteoblast-like cells | Q27346911 | ||
| Golgi polarization in a strong electric field | Q30477291 | ||
| Lymphocyte electrotaxis in vitro and in vivo | Q30484220 | ||
| Persistent directional cell migration requires ion transport proteins as direction sensors and membrane potential differences in order to maintain directedness. | Q30498220 | ||
| Application of direct current electric fields to cells and tissues in vitro and modulation of wound electric field in vivo | Q33286528 | ||
| Electrotaxis of lung cancer cells in a multiple-electric-field chip. | Q33460843 | ||
| A transparent cell-culture microchamber with a variably controlled concentration gradient generator and flow field rectifier | Q33495201 | ||
| Distinct roles for the small GTPases Cdc42 and Rho in endothelial responses to shear stress | Q33849349 | ||
| A theoretical model study of the influence of fluid stresses on a cell adhering to a microchannel wall | Q34168610 | ||
| Effects of physiological electric fields on migration of human dermal fibroblasts. | Q34186241 | ||
| The role of electro-osmosis in the electric-field-induced movement of charged macromolecules on the surfaces of cells | Q34252082 | ||
| Electrical signals control wound healing through phosphatidylinositol-3-OH kinase-gamma and PTEN. | Q34652580 | ||
| A real time in vitro assay for studying leukocyte transendothelial migration under physiological flow conditions. | Q35048817 | ||
| Electrically guiding migration of human induced pluripotent stem cells. | Q35580471 | ||
| DC electric stimulation upregulates angiogenic factors in endothelial cells through activation of VEGF receptors | Q35624685 | ||
| Electrotaxis of lung cancer cells in ordered three-dimensional scaffolds. | Q35702847 | ||
| Mechanotransduction in endothelial cell migration | Q36259213 | ||
| Cell population tracking and lineage construction with spatiotemporal context | Q37161717 | ||
| Electric field-guided neuron migration: a novel approach in neurogenesis | Q37833101 | ||
| Microfluidic devices for studying chemotaxis and electrotaxis | Q37888280 | ||
| Asymmetric cancer-cell filopodium growth induced by electric-fields in a microfluidic culture chip | Q39620742 | ||
| Label-free quantification of asymmetric cancer-cell filopodium activities in a multi-gradient chip. | Q39871624 | ||
| Lung cancer A549 cells migrate directionally in DC electric fields with polarized and activated EGFRs. | Q39962592 | ||
| EGF receptor signalling is essential for electric-field-directed migration of breast cancer cells | Q40078231 | ||
| Characterization of 3 oral squamous cell carcinoma cell lines with different invasion and/or metastatic potentials | Q40089601 | ||
| Effect of pulse direct current signals on electrotactic movement of nematodes Caenorhabditis elegans and Caenorhabditis briggsae | Q40239186 | ||
| Global analysis of gene expression in invasion by a lung cancer model. | Q40795720 | ||
| Electrophoresis along cell membranes | Q41052841 | ||
| Selection of invasive and metastatic subpopulations from a human lung adenocarcinoma cell line | Q41089777 | ||
| Xenopus neural crest cell migration in an applied electrical field | Q41429076 | ||
| Influence of Transepithelial Potential Difference on the Sodium Uptake at the Outer Surface of the Isolated Frog Skin | Q41819092 | ||
| Electrical stimulation directly induces pre-angiogenic responses in vascular endothelial cells by signaling through VEGF receptors | Q41836434 | ||
| Variant sublines with different metastatic potentials selected in nude mice from human oral squamous cell carcinomas | Q42815585 | ||
| Roles of microtubules, cell polarity and adhesion in electric-field-mediated motility of 3T3 fibroblasts | Q42830778 | ||
| Human keratinocytes migrate to the negative pole in direct current electric fields comparable to those measured in mammalian wounds. | Q43738250 | ||
| Electrophoresis of concanavalin A receptors along embryonic muscle cell membrane | Q43805961 | ||
| Migration of human keratinocytes in electric fields requires growth factors and extracellular calcium | Q44581329 | ||
| Direct-current electrical field guides neuronal stem/progenitor cell migration. | Q46537917 | ||
| Regulation of mesenchymal stem cell adhesion and orientation in 3D collagen scaffold by electrical stimulus | Q46940529 | ||
| In vitro effects of direct current electric fields on adipose-derived stromal cells | Q47175634 | ||
| Transcriptional response of dermal fibroblasts in direct current electric fields | Q47886838 | ||
| Electrical dimensions in cell science | Q48404226 | ||
| Automated tracking of migrating cells in phase-contrast video microscopy sequences using image registration | Q48856043 | ||
| Directional movement of rat prostate cancer cells in direct-current electric field: involvement of voltagegated Na+ channel activity | Q49029407 | ||
| High-resolution cell outline segmentation and tracking from phase-contrast microscopy images. | Q50671424 | ||
| Temporally and spatially coordinated roles for Rho, Rac, Cdc42 and their effectors in growth cone guidance by a physiological electric field. | Q51233431 | ||
| Electrotaxis of Caenorhabditis elegans in a microfluidic environment. | Q51560971 | ||
| Embryonic cell motility can be guided by physiological electric fields. | Q52703706 | ||
| Orientation and directed migration of cultured corneal epithelial cells in small electric fields are serum dependent | Q71517226 | ||
| Analysis of actin dynamics at the leading edge of crawling cells: implications for the shape of keratocyte lamellipodia | Q73373431 | ||
| HGF, MAPK, and a small physiological electric field interact during corneal epithelial cell migration | Q78852998 | ||
| Dynamic shear stress in parallel-plate flow chambers | Q80943639 | ||
| P4510 | describes a project that uses | ImageJ | Q1659584 |
| P433 | issue | 3 | |
| P921 | main subject | oral squamous cell carcinoma | Q18553522 |
| P304 | page(s) | 34116 | |
| P577 | publication date | 2012-09-05 | |
| P1433 | published in | Biomicrofluidics | Q3170210 |
| P1476 | title | Electrotaxis of oral squamous cell carcinoma cells in a multiple-electric-field chip with uniform flow field | |
| P478 | volume | 6 |
| Q27344866 | Collective migration exhibits greater sensitivity but slower dynamics of alignment to applied electric fields |
| Q36143470 | Correlation between cell migration and reactive oxygen species under electric field stimulation. |
| Q36120171 | Designing Microfluidic Devices for Studying Cellular Responses Under Single or Coexisting Chemical/Electrical/Shear Stress Stimuli. |
| Q64982800 | Doxycycline inhibits electric field-induced migration of non-small cell lung cancer (NSCLC) cells. |
| Q38802399 | Electrotaxis Studies of Lung Cancer Cells using a Multichannel Dual-electric-field Microfluidic Chip |
| Q28535226 | Evaluation of EGFR and RTK signaling in the electrotaxis of lung adenocarcinoma cells under direct-current electric field stimulation |
| Q43640102 | Galvanotactic control of collective cell migration in epithelial monolayers |
| Q64064093 | Glioblastoma adhesion in a quick-fit hybrid microdevice |
| Q27008210 | Recent Developments in Electrotaxis Assays |
| Q42367214 | Studying Electrotaxis in Microfluidic Devices |
| Q30576106 | The construction of an interfacial valve-based microfluidic chip for thermotaxis evaluation of human sperm |
| Q27313978 | Uniform electric field generation in circular multi-well culture plates using polymeric inserts |
| Q97426136 | Voltage-gated ion channels mediate the electrotaxis of glioblastoma cells in a hybrid PMMA/PDMS microdevice |
| Q51500606 | Water pollutant monitoring by a whole cell array through lens-free detection on CCD. |
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