about
Voltage-gated proton channels: what's next?Experimental generation and computational modeling of intracellular pH gradients in cardiac myocytes.Evidence from mathematical modeling that carbonic anhydrase II and IV enhance CO2 fluxes across Xenopus oocyte plasma membranesLocal pH domains regulate NHE3-mediated Na⁺ reabsorption in the renal proximal tubule.Regulation of ion gradients across myocardial ischemic border zones: a biophysical modelling analysis.Na⁺ ions as spatial intracellular messengers for co-ordinating Ca²⁺ signals during pH heterogeneity in cardiomyocytesBiophysical significance of the inner mitochondrial membrane structure on the electrochemical potential of mitochondria.Bicarbonate, NBCe1, NHE, and carbonic anhydrase activity enhance lactate-H+ transport in bovine corneal endothelium.pH-Dependence of extrinsic and intrinsic H(+)-ion mobility in the rat ventricular myocyte, investigated using flash photolysis of a caged-H(+) compound.A reaction-diffusion model of CO2 influx into an oocyte.Mathematical modeling of acid-base physiology.Molecular pharmacodynamics, clinical therapeutics, and pharmacokinetics of topiramate.Temperature dependence of proton permeation through a voltage-gated proton channel.High-Resolution pH Imaging of Living Bacterial Cells To Detect Local pH Differences.Proton production, regulation and pathophysiological roles in the mammalian brainRed blood cell thickness is evolutionarily constrained by slow, hemoglobin-restricted diffusion in cytoplasm.Computer model of unstirred layer and intracellular pH changes. Determinants of unstirred layer pHIntracellular carbonic anhydrase activity sensitizes cancer cell pH signaling to dynamic changes in CO2 partial pressure.Common phenotype of resting mouse extensor digitorum longus and soleus muscles: equal ATPase and glycolytic flux during transient anoxia.Sarcolemmal localisation of Na+/H+ exchange and Na+-HCO3- co-transport influences the spatial regulation of intracellular pH in rat ventricular myocytes.Novel method for measuring junctional proton permeation in isolated ventricular myocyte cell pairs.Relationship between intracellular pH and proton mobility in rat and guinea-pig ventricular myocytes.Mathematical modeling of buffers used in myocardial preservation.Myoendothelial coupling through Cx40 contributes to EDH-induced vasodilation in murine renal arteries: evidence from experiments and modelling.Sustained self-organizing pH patterns in hydrogen peroxide driven aqueous redox systems.Effect of human carbonic anhydrase II on the activity of the human electrogenic Na/HCO3 cotransporter NBCe1-A in Xenopus oocytes.Mobile trap algorithm for zinc detection using protein sensors.Simulation of Ca2+-activated Cl- current of cardiomyocytes in rabbit pulmonary vein: implications of subsarcolemmal Ca2+ dynamics.Fluorescent, Bioluminescent, and Optogenetic Approaches to Study Excitable Physiology in the Single Cardiomyocyte.
P2860
Q24657828-35C931ED-DCE6-4325-9689-EB800BAD4A2BQ34189895-FAA05656-59A9-4723-A383-6BAA0CE0500DQ34439472-C1F32656-9D7E-4858-9DC9-C4AD742FE52BQ34627566-53ACD8C2-2B0B-4EBB-B77E-9201868D15CBQ34663717-0114D8F1-7A3B-4545-A015-F85D8788687EQ34979122-E4303C1B-05B3-45F8-B86F-49C0E40E9BFCQ35043652-2A130131-57DA-4629-98BA-F03463550802Q35522245-723F5F9C-ADBD-4D0A-84F0-6A2366556B2BQ35545531-B61502ED-7904-4035-A843-C2ECE2A641FFQ36317674-E1E96C1D-8C41-441B-A82F-E64F230BA9C0Q36337462-A4F0B474-0B54-4468-B7A9-01C6D9DBADDFQ37164665-9DC57F20-C749-4A22-A762-72CA29AE94B3Q37340110-594D9E2D-9B89-43D0-BD7F-48FCE2766091Q37481747-B2EDF90C-6DFF-4494-BEE0-3D57711F2626Q37974749-6690295C-6CCB-4F79-96FF-79627501C9B7Q41567865-6A047718-F559-45DC-8D4E-CF67FF0242AEQ41849626-2AB6796D-5F74-48A9-8F2A-307A10524DFEQ42169333-E6B10703-B1BD-4C8C-9F52-E826773968A5Q43121785-B679AD7D-FF69-4730-93B3-1FEA94A5946FQ44289986-2021A637-142A-46FA-8325-D6D4376969E8Q44970313-972B55F4-3289-40F3-B882-79FB8B447EECQ46513145-80CB72D0-524A-41E3-BE49-52AC292EA72BQ46641821-CBAC6124-383B-4176-A49C-07A51975DDCAQ47802158-7C3A8918-46B9-49D1-8A3D-628B27AAFCA0Q47836064-4416CC70-6476-4990-A9CF-74550395A415Q50649527-96E090B0-5788-443C-913B-8EBFF5607DBCQ50860783-15616FFD-E1F7-4427-8CF5-CA47A01BC3D7Q51943916-5851D6D1-7485-4CBF-B85A-3CAD6CCCAB8FQ55517726-5DDA07AB-056E-4DCE-B96F-C32DF97B967F
P2860
description
2003 nî lūn-bûn
@nan
2003 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2003 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2003年の論文
@ja
2003年論文
@yue
2003年論文
@zh-hant
2003年論文
@zh-hk
2003年論文
@zh-mo
2003年論文
@zh-tw
2003年论文
@wuu
name
Modelling intracellular H(+) ion diffusion.
@ast
Modelling intracellular H(+) ion diffusion.
@en
type
label
Modelling intracellular H(+) ion diffusion.
@ast
Modelling intracellular H(+) ion diffusion.
@en
prefLabel
Modelling intracellular H(+) ion diffusion.
@ast
Modelling intracellular H(+) ion diffusion.
@en
P2093
P1476
Modelling intracellular H(+) ion diffusion.
@en
P2093
Alessandra Rossini
Andrew K Stewart
Kenneth W Spitzer
Massimiliano Zaniboni
Pawel Swietach
Richard D Vaughan-Jones
P304
P356
10.1016/S0079-6107(03)00027-0
P577
2003-10-01T00:00:00Z