scholarly article | Q13442814 |
P819 | ADS bibcode | 2013PLoSO...861509T |
P356 | DOI | 10.1371/JOURNAL.PONE.0061509 |
P932 | PMC publication ID | 3621860 |
P698 | PubMed publication ID | 23585907 |
P5875 | ResearchGate publication ID | 236182562 |
P2093 | author name string | Wei Chen | |
Xiaodong Zhang | |||
Min Zhao | |||
Vu Tran | |||
Benjamin Lee | |||
Lin Cao | |||
Hanqing Li | |||
Michelle So | |||
Yaohui Sun | |||
P2860 | cites work | Voltage dependence of the Na/K pump | Q41362534 |
Characterization of two MDCK-cell subtypes as a model system to study principal cell and intercalated cell properties | Q41444691 | ||
The influence of ions, ouabain, propranolol and amiloride on the transepithelial potential and resistance of rabbit cornea | Q41621991 | ||
Influence of Transepithelial Potential Difference on the Sodium Uptake at the Outer Surface of the Isolated Frog Skin | Q41819092 | ||
A molecular network for de novo generation of the apical surface and lumen | Q42116509 | ||
Electrical profiles in the corneal epithelium | Q42439418 | ||
Frequency spectrum of transepithelial potential difference reveals transport-related oscillations. | Q42551780 | ||
The role of electrical signals in murine corneal wound re‐epithelialization | Q42700284 | ||
The two-membrane model of epithelial transport: Koefoed-Johnsen and Ussing (1958). | Q43240827 | ||
Use of in vivo nasal transepithelial potential difference to evaluate efficacy in CF gene therapy phase I trials. | Q45870169 | ||
Extracellular matrix and Na+,K+-ATPase in human corneas following cataract surgery: comparison with bullous keratopathy and Fuchs' dystrophy corneas | Q46062173 | ||
The glabrous epidermis of cavies contains a powerful battery | Q46176315 | ||
Electrical dimensions in cell science | Q48404226 | ||
Fluid transport and ion fluxes in mammalian kidney proximal tubule: a model analysis of isotonic transport. | Q51940683 | ||
Aldosterone metabolism and transepithelial potential difference in normal and cystic fibrosis subjects. | Q54418425 | ||
Electrical fields in the vicinity of epithelial wounds in the isolated bovine eye | Q56568074 | ||
Nerve regeneration and wound healing are stimulated and directed by an endogenous electrical field in vivo | Q56568075 | ||
Transepithelial potential difference in cystic fibrosis | Q24563342 | ||
Resonance transduction of low level periodic signals by an enzyme: an oscillatory activation barrier model | Q30538579 | ||
Butyrate metabolism upstream and downstream acetyl-CoA synthesis and growth control of human colon carcinoma cells | Q30940423 | ||
Ionic components of electric current at rat corneal wounds | Q33833822 | ||
The polarized expression of Na+,K+-ATPase in epithelia depends on the association between beta-subunits located in neighboring cells | Q33913636 | ||
Fluctuation-driven directional flow in biochemical cycle: further study of electric activation of Na,K pumps | Q33915547 | ||
Electrical cues regulate the orientation and frequency of cell division and the rate of wound healing in vivo | Q34160066 | ||
Effects of sodium butyrate, a new pharmacological agent, on cells in culture | Q34249353 | ||
Wound healing in rat cornea: the role of electric currents | Q34599774 | ||
Controlling cell behavior electrically: current views and future potential | Q34650760 | ||
Electrical signals control wound healing through phosphatidylinositol-3-OH kinase-gamma and PTEN. | Q34652580 | ||
Na,K-ATPase beta-subunit is required for epithelial polarization, suppression of invasion, and cell motility | Q34980580 | ||
Endogenous electric fields in embryos during development, regeneration and wound healing | Q35613555 | ||
A role for endogenous electric fields in wound healing | Q35622952 | ||
Electrical signaling in control of ocular cell behaviors | Q35623982 | ||
Apical plasma membrane mispolarization of NaK-ATPase in polycystic kidney disease epithelia is associated with aberrant expression of the beta2 isoform | Q35793334 | ||
Regional differences in rat conjunctival ion transport activities | Q36312382 | ||
Stoichiometry and voltage dependence of the sodium pump in voltage-clamped, internally dialyzed squid giant axon | Q36410289 | ||
[Na] and [K] dependence of the Na/K pump current-voltage relationship in guinea pig ventricular myocytes | Q36434429 | ||
Transport efficiency and workload distribution in a mathematical model of the thick ascending limb | Q36699810 | ||
Electrical fields in wound healing-An overriding signal that directs cell migration | Q37369299 | ||
Physiological measurements confirming the diagnosis of cystic fibrosis: the sweat test and measurements of transepithelial potential difference | Q37625266 | ||
Structural-functional relationship along the distal nephron | Q39735391 | ||
Restoration of the transepithelial potential within tissue-engineered human skin in vitro and during the wound healing process in vivo | Q39871569 | ||
Selective basolateral localization of overexpressed Na-K-ATPase beta1- and beta2- subunits is disrupted by butryate treatment of MDCK cells | Q40162061 | ||
Mechanisms of ouabain toxicity | Q40637348 | ||
High-resistance MDCK-C7 monolayers used for measuring invasive potency of tumour cells | Q40872231 | ||
Low permeabilities of MDCK cell monolayers: a model barrier epithelium | Q41101523 | ||
Stimulation of a ouabain-sensitive Rb+ uptake in human erthrocytes with an external electric field | Q71833678 | ||
Electrical potential profile of the isolated frog cornea | Q72074880 | ||
Reversibility of ouabain induced inhibition of cell division and cation transport in Ehrlich ascites cells | Q72138873 | ||
Epithelial potential of the cornea | Q72218045 | ||
Evidence of voltage-induced channel opening in Na/K ATPase of human erythrocyte membrane | Q72863019 | ||
The asymmetric, rectifier-like I-V curve of the Na/K pump transient currents in frog skeletal muscle fibers | Q74093477 | ||
Transepithelial potential differences and Na(+) flux in isolated perfused gills of the crab Chasmagnathus granulatus (Grapsidae) acclimated to hyper- and hypo-salinity | Q77569673 | ||
Synchronization of Na/K pump molecules by a train of squared pulses | Q79412404 | ||
Wound healing with electric potential | Q79579058 | ||
Synchronization modulation of Na/K pump molecules can hyperpolarize the membrane resting potential in intact fibers | Q79821637 | ||
Charging the batteries to heal wounds through PI3K | Q80143380 | ||
Membrane potential hyperpolarization in Mammalian cardiac cells by synchronization modulation of Na/K pumps | Q80741317 | ||
Entrainment of Na/K pumps by a synchronization modulation electric field | Q81360367 | ||
Synchronization of ion exchangers by an oscillating electric field: theory | Q81683886 | ||
Hyperpolarization of the membrane potential in cardiomyocyte tissue slices by the synchronization modulation electric field | Q83497959 | ||
Quick and effective hyperpolarization of the membrane potential in intact smooth muscle cells of blood vessels by synchronization modulation electric field | Q83756314 | ||
P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
P6216 | copyright status | copyrighted | Q50423863 |
P433 | issue | 4 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | e61509 | |
P577 | publication date | 2013-04-09 | |
P1433 | published in | PLOS One | Q564954 |
P1476 | title | Synchronization modulation increases transepithelial potentials in MDCK monolayers through Na/K pumps | |
P478 | volume | 8 |
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