Published in J Gen Physiol on April 01, 1974
A non-linear voltage dependent charge movement in frog skeletal muscle. J Physiol (1976) 6.10
Effects of glycerol treatment and maintained depolarization on charge movement in skeletal muscle. J Physiol (1976) 5.83
An improved vaseline gap voltage clamp for skeletal muscle fibers. J Gen Physiol (1976) 5.57
Effects of tetracaine on displacement currents and contraction of frog skeletal muscle. J Physiol (1976) 2.99
Voltage-clamp experiments in normal and denervated mammalian skeletal muscle fibres. J Physiol (1980) 2.91
Effects of membrane potential on the capacitance of skeletal muscle fibers. J Gen Physiol (1976) 2.55
Differential effects of tetracaine on delayed potassium channels and displacement currents in frog skeletal muscle. J Physiol (1976) 2.35
Permeation through an open channel: Poisson-Nernst-Planck theory of a synthetic ionic channel. Biophys J (1997) 2.29
Elemental distribution in striated muscle and the effects of hypertonicity. Electron probe analysis of cryo sections. J Cell Biol (1977) 2.26
The relative contributions of the folds and caveolae to the surface membrane of frog skeletal muscle fibres at different sarcomere lengths. J Physiol (1975) 1.98
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The giant cardiac membrane patch method: stimulation of outward Na(+)-Ca2+ exchange current by MgATP. J Physiol (1992) 1.89
Electrical properties of frog skeletal muscle fibers interpreted with a mesh model of the tubular system. Biophys J (1977) 1.88
Ionic currents in mammalian fast skeletal muscle. J Physiol (1978) 1.72
Measurement of the impedance of frog skeletal muscle fibers. Biophys J (1974) 1.62
Electrical properties of structural components of the crystalline lens. Biophys J (1979) 1.56
Circuit models of the passive electrical properties of frog skeletal muscle fibers. J Gen Physiol (1974) 1.42
Fluorescence intensity changes associated with contractile activation in frog muscle stained with Nile Blue A. J Physiol (1975) 1.38
Impedance analysis of a tight epithelium using a distributed resistance model. Biophys J (1979) 1.28
Delayed rectification in the transverse tubules: origin of the late after-potential in frog skeletal muscle. J Gen Physiol (1977) 1.25
Longitudinal impedance of skinned frog muscle fibers. J Gen Physiol (1974) 1.21
The influence of transverse tubular delays on the kinetics of charge movement in mammalian skeletal muscle. J Gen Physiol (1985) 1.14
Inward rectification in the transverse tubular system of frog skeletal muscle studied with potentiometric dyes. J Physiol (1985) 1.14
Time-course of potential spread along a skeletal muscle fiber under voltage clamp. J Gen Physiol (1976) 1.10
Numerical analysis of Ca2+ depletion in the transverse tubular system of mammalian muscle. Biophys J (2001) 1.04
Effects of sudden changes in external sodium concentration on twitch tension in isolated muscle fibers. J Gen Physiol (1975) 1.03
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Neurally evoked calcium transients in terminal Schwann cells at the neuromuscular junction. Proc Natl Acad Sci U S A (1992) 1.00
The passive electrical properties of frog skeletal muscle fibres at different sarcomere lengths. J Physiol (1977) 0.96
Linear electrical properties of passive and active currents in spherical heart cell clusters. Biophys J (1981) 0.94
Electromechanical coupling in tubular muscle fibers. II. Resistance and capacitance of one transverse tubule. J Gen Physiol (1976) 0.89
Magnetic field of a single muscle fiber. First measurements and a core conductor model. Biophys J (1990) 0.86
AC impedance of the perineurium of the frog sciatic nerve. Biophys J (1984) 0.84
Effects of membrane potential on mechanical activation in skeletal muscle. J Gen Physiol (1982) 0.82
Contribution of electrogenic ion transport to impedance of the algae Valonia utricularis and artificial membranes. Biophys J (1994) 0.81
Action potentials in fast- and slow-twitch mammalian muscles during reinnervation and development. J Gen Physiol (1980) 0.80
Electrical properties of the myotendon region of frog twitch muscle fibers measured in the frequency domain. Biophys J (1985) 0.80
An analysis of the relationships between subthreshold electrical properties and excitability in skeletal muscle. J Gen Physiol (2011) 0.79
Charge movements measured during transverse-tubular uncoupling in frog skeletal muscle. Biophys J (1986) 0.77
Transverse impedance of single frog skeletal muscle fibers. Biophys J (1982) 0.76
The sarcoplasmic reticulum and transverse tubules of the frog's sartorius. J Cell Biol (1965) 15.09
Voltage dependent charge movement of skeletal muscle: a possible step in excitation-contraction coupling. Nature (1973) 13.75
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Voltage clamp experiments in striated muscle fibres. J Physiol (1970) 12.92
The kinetics of mechanical activation in frog muscle. J Physiol (1969) 8.00
The effect of diameter on the electrical constants of frog skeletal muscle fibres. J Physiol (1972) 6.36
Capacitance of the surface and transverse tubular membrane of frog sartorius muscle fibers. J Gen Physiol (1969) 5.50
Ionic conductances of the surface and transverse tubular membranes of frog sartorius fibers. J Gen Physiol (1969) 5.45
Some relations between changes in the linear electrical properties of striated muscle fibers and changes in ultrastructure. J Gen Physiol (1967) 4.53
Analysis of the membrane capacity in frog muscle. J Physiol (1972) 4.36
A note on conduction velocity. J Physiol (1954) 4.17
Linear electrical properties of the transverse tubules and surface membrane of skeletal muscle fibers. J Gen Physiol (1970) 3.80
Selective disruption of the sarcotubular system in frog sartorius muscle. A quantitative study with exogenous peroxidase as a marker. J Cell Biol (1968) 3.61
The role of sodium current in the radial spread of contraction in frog muscle fibers. J Gen Physiol (1970) 2.68
Some effects of hypertonic solutions on contraction and excitation-contraction coupling in frog skeletal muscles. J Gen Physiol (1970) 2.62
A lesion of the transverse tubules of skeletal muscle. J Physiol (1969) 2.53
The effect of change in length on conduction velocity in muscle. J Physiol (1954) 1.97
Electrical properties of toad sartorius muscle fibres in summer and winter. J Physiol (1973) 1.90
Sodium dependence of the inward spread of activation in isolated twitch muscle fibres of the frog. J Physiol (1972) 1.86
Measurement of the impedance of frog skeletal muscle fibers. Biophys J (1974) 1.62
Circuit models of the passive electrical properties of frog skeletal muscle fibers. J Gen Physiol (1974) 1.42
Changes in the T-system of muscle fibres under the influence of influx and efflux of glycerol. Nature (1969) 1.33
Speed of repolarization and morphology of glygerol-treated frog muscle fibres. J Physiol (1973) 1.32
The capacitance of skeletal muscle fibers in solutions of low ionic strength. J Gen Physiol (1972) 1.16
Measurement of membrane capacity in skeletal muscle. Nat New Biol (1973) 1.08
The volume of the T-system and its association with the sarcoplasmic reticulum in slow muscle fibres of the frog. J Physiol (1971) 0.97
The effect of fixative tonicity on the myosin filament lattice volume of frog muscle fixed following exposure to normal or hypertonic Ringer. Histochem J (1973) 0.96
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Capacitance of the surface and transverse tubular membrane of frog sartorius muscle fibers. J Gen Physiol (1969) 5.50
Ionic conductances of the surface and transverse tubular membranes of frog sartorius fibers. J Gen Physiol (1969) 5.45
Action potentials without contraction in frog skeletal muscle fibers with disrupted transverse tubules. Science (1967) 4.16
Action potentials, afterpotentials, and excitation-contraction coupling in frog sartorius fibers without transverse tubules. J Gen Physiol (1969) 3.86
Frog skeletal muscle fibers: changes in electrical properties after disruption of transverse tubular system. Science (1967) 3.76
Selective disruption of the sarcotubular system in frog sartorius muscle. A quantitative study with exogenous peroxidase as a marker. J Cell Biol (1968) 3.61
The maintenance of resting potentials in glycerol-treated muscle fibres. J Physiol (1971) 2.78
The role of the electrochemical gradient in determining potassium fluxes in frog striated muscle. J Gen Physiol (1968) 2.72
The spatial variation of membrane potential near a small source of current in a spherical cell. J Gen Physiol (1970) 2.70
Failure to detect ampicillin-resistant, non-beta-lactamase-producing Haemophilus influenzae by standard disk susceptibility testing. Antimicrob Agents Chemother (1986) 2.38
Electrical properties of spherical syncytia. Biophys J (1979) 2.12
Diffusion theory and discrete rate constants in ion permeation. J Membr Biol (1988) 2.05
The equivalent circuit of single crab muscle fibers as determined by impedance measurements with intracellular electrodes. J Gen Physiol (1967) 1.97
Electrical properties of frog skeletal muscle fibers interpreted with a mesh model of the tubular system. Biophys J (1977) 1.88
Problems with current recommendations for susceptibility testing of Haemophilus influenzae. Antimicrob Agents Chemother (1990) 1.84
The T-SR junction in contracting single skeletal muscle fibers. J Gen Physiol (1982) 1.74
Paralysis of frog skeletal muscle fibres by the calcium antagonist D-600. J Physiol (1983) 1.71
Electrical models of excitation-contraction coupling and charge movement in skeletal muscle. J Gen Physiol (1980) 1.68
Measurement of the impedance of frog skeletal muscle fibers. Biophys J (1974) 1.62
Nystatin as a probe for investigating the electrical properties of a tight epithelium. J Gen Physiol (1977) 1.59
Electrical properties of structural components of the crystalline lens. Biophys J (1979) 1.56
Flux, coupling, and selectivity in ionic channels of one conformation. Biophys J (1993) 1.52
The interpretation of current-voltage relations recorded from a spherical cell with a single microelectrode. Biophys J (1972) 1.49
Surmounting barriers in ionic channels. Q Rev Biophys (1988) 1.47
A cation channel in frog lens epithelia responsive to pressure and calcium. J Membr Biol (1986) 1.44
A low-cost method for rapid transfer function measurements with direct application to biological impedance analysis. Pflugers Arch (1981) 1.43
Circuit models of the passive electrical properties of frog skeletal muscle fibers. J Gen Physiol (1974) 1.42
Charge movement in skeletal muscle fibers paralyzed by the calcium-entry blocker D600. Proc Natl Acad Sci U S A (1984) 1.42
Current-voltage relationships in the crystalline lens. J Physiol (1976) 1.41
The lens as a nonuniform spherical syncytium. Biophys J (1981) 1.40
Derivation of Poisson and Nernst-Planck equations in a bath and channel from a molecular model. Phys Rev E Stat Nonlin Soft Matter Phys (2001) 1.39
The role of the electrochemical gradient in determining potassium fluxes in frog striated muscle. J Gen Physiol (1968) 1.30
Impedance analysis of a tight epithelium using a distributed resistance model. Biophys J (1979) 1.28
Bone and joint infections caused by Kingella kingae: six cases and review of the literature. Rev Infect Dis (1988) 1.27
Constant fields and constant gradients in open ionic channels. Biophys J (1992) 1.23
Lymphocytosis and histamine sensitization of mice by fractions from Bordetella pertussis. J Bacteriol (1968) 1.22
Longitudinal impedance of skinned frog muscle fibers. J Gen Physiol (1974) 1.21
The capacitance of skeletal muscle fibers in solutions of low ionic strength. J Gen Physiol (1972) 1.16
Ionic currents and endothelin signaling in smooth muscle cells from rat renal resistance arteries. Am J Physiol (1994) 1.10
Interpretation of some microelectrode measurements of electrical properties of cells. Annu Rev Biophys Bioeng (1973) 1.08
The effect of 2-4 dinitrophenol on cell to cell communication in the frog lens. Exp Eye Res (1982) 1.03
Longitudinal impedance of single frog muscle fibers. J Gen Physiol (1975) 1.03
Ionic channels in ocular epithelia. Ion Channels (1988) 1.02
Perfusing pipettes. Pflugers Arch (1990) 1.01
Structural analysis of electrical properties of cells and tissues. Crit Rev Bioeng (1980) 1.01
Dielectric boundary force and its crucial role in gramicidin. Phys Rev E Stat Nonlin Soft Matter Phys (2003) 1.00
A theoretical analysis of the capacitance of muscle fibers using a distributed model of the tubular system. J Gen Physiol (1972) 0.99
Invasive Haemophilus influenzae infections in older children and adults in Seattle. Clin Infect Dis (1993) 0.98
Measurement, modeling, and analysis of the linear electrical properties of cells. Ann N Y Acad Sci (1977) 0.98
Hydrodynamic model of temperature change in open ionic channels. Biophys J (1995) 0.97
Electrical properties of sheep Purkinje strands. Electrical and chemical potentials in the clefts. Biophys J (1983) 0.95
The radial variation of potential in the transverse tubular system of skeletal muscle. J Gen Physiol (1971) 0.92
Clinical and microbiologic characteristics of cutaneous infection with Yersinia enterocolitica. J Infect Dis (1992) 0.92
Calcium influx in contracting and paralyzed frog twitch muscle fibers. J Gen Physiol (1985) 0.91
Urinary proteases degrade epithelial sodium channels. J Membr Biol (1991) 0.91
Computing numerically the access resistance of a pore. Eur Biophys J (2005) 0.89
Piperacillin pharmacokinetics in pediatric patients. Antimicrob Agents Chemother (1982) 0.89
Transverse tubular system in glycerol-treated skeletal muscle. Science (1968) 0.89
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K+-selective channel from sarcoplasmic reticulum of split lobster muscle fibers. J Gen Physiol (1989) 0.86
Electrical events during stimulation of HCl secretion by frog gastric mucosa in vitro. Gastroenterology (1977) 0.86
General method for the derivation and numerical solution of epithelial transport models. J Membr Biol (1984) 0.85
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Physiological role of the membranes and extracellular space with the ocular lens. Exp Eye Res (1982) 0.84
Do referrals work? Responses of childbearing newcomers to referrals for care. J Immigr Minor Health (2009) 0.84
A calcium conducting channel akin to a calcium pump. J Membr Biol (1992) 0.83
Na+ transport and impedance properties of cultured renal (A6 and 2F3) epithelia. J Membr Biol (1992) 0.83
Impedance analysis in tight epithelia. Methods Enzymol (1989) 0.83
Dopamine inhibits GABA transmission from the globus pallidus to the thalamic reticular nucleus via presynaptic D4 receptors. Neuroscience (2010) 0.83
Transport-dependent alterations of membrane properties of mammalian colon measured using impedance analysis. J Membr Biol (1987) 0.83
The effects of the antibiotics gramicidin A, amphotericin B, and nystatin on the electrical properties of frog skeletal muscle. Biochim Biophys Acta (1973) 0.83
Use of AC impedance analysis to study membrane changes related to acid secretion in amphibian gastric mucosa. Biophys J (1983) 0.81
Origins of open-channel noise in the large potassium channel of sarcoplasmic reticulum. J Gen Physiol (1994) 0.81
Perfusing patch pipettes. Methods Enzymol (1992) 0.81
Electrical properties of the myotendon region of frog twitch muscle fibers measured in the frequency domain. Biophys J (1985) 0.80
Middle lobe syndrome secondary to allergic bronchopulmonary aspergillosis. Ann Allergy (1980) 0.80
Self-consistent analytic solution for the current and the access resistance in open ion channels. Phys Rev E Stat Nonlin Soft Matter Phys (2009) 0.80
Effects of aldosterone on the impedance properties of cultured renal amphibian epithelia. J Membr Biol (1993) 0.80
Changes in the cell membranes of the bullfrog gastric mucosa with Acid secretion. Science (1982) 0.78
Impedance analysis in epithelia. Soc Gen Physiol Ser (1981) 0.78
Transport-related modulation of the membrane properties of toad urinary bladder epithelium. Biochim Biophys Acta (1991) 0.78
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Impedance measurements as estimators of the properties of the extracellular space. Ann N Y Acad Sci (1986) 0.77
Membrane electrical parameters in turtle bladder measured using impedance-analysis techniques. J Membr Biol (1986) 0.77
Effects of an educational segment concerning organ donation and transplantation. Transplant Proc (2000) 0.77
Nebulization of amphotericin B. Am Rev Respir Dis (1971) 0.76
Memoryless control of boundary concentrations of diffusing particles. Phys Rev E Stat Nonlin Soft Matter Phys (2004) 0.76
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Proton transport and membrane shuttling in turtle bladder epithelium. J Membr Biol (1986) 0.76
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