ROBERT S. EISENBERG
Reprints available on this hyperlink
(Last update: September 15, 2006)
[Laboratory of
Robert S. Eisenberg]
Electrical properties of tissues, mostly experimental:
1. Eisenberg, R.S. and Hamilton, D. Action of g-aminobutyric acid on Cancer borealis muscle. Nature 198: 1002-1003 (1963). [PDF]
2. Eisenberg, R.S. Impedance
of single crab muscle fibers. Ph.D. Thesis,
3. Eisenberg, R.S. Equivalent circuit of single crab muscle fibers as determined by impedance measurement with intracellular electrodes. J. Gen. Physiol. 50: 1785-1806 (1967). [PDF]
4. Eisenberg, R.S. and Gage, P.W. Frog skeletal muscle fibers: change in the electrical properties of frog skeletal muscle fibers after disruption of the transverse tubular system. Science 158: 1700-1701 (1967). [PDF]
5. Gage, P.W. and Eisenberg, R.S. Action potentials without contraction in frog skeletal muscle fibers with disrupted transverse tubules. Science 158: 1702-1703 (1967). [PDF]
6. Horowicz, P., Gage, P.W. and Eisenberg, R.S. The role of the electrochemical gradient in determining potassium fluxes in frog striated muscle. J. Gen. Physiol. 51: 193s-203s (1968). [PDF]
7. Eisenberg, B. and Eisenberg, R.S. The transverse tubular system in glycerol treated muscle. Science 160: 1243-1244 (1968). [PDF]
8. Eisenberg, B. and Eisenberg, R.S. Selective disruption of the sarcotubular muscle: A quantitative study with exogenous peroxidase as a marker. J. Cell Biol. 39: 451-467 (1968). [PDF]
9. Gage, P.W. and Eisenberg, R.S. Capacitance of the surface and transverse tubular membrane of frog sartorius muscle fibers. J. Gen. Physiol. 53: 265-278 (1969). [PDF]
10. Eisenberg, R.S. and Gage, P.W. Ionic conductance of the surface and transverse tubular membrane of frog sartorius fibers. J. Gen. Physiol. 53: 279-297 (1969). [PDF]
11. Gage, P.W. and Eisenberg, R.S. Action potentials, after potentials, and excitation-contraction coupling in frog sartorius fibers without transverse tubules. J. Gen. Physiol. 53: 298-310 (1969). [PDF]
12. Eisenberg, R.S., Howell, J. and Vaughan, P. The maintenance of resting potentials in glycerol treated muscle fibers. J. Physiol. 215: 95-102 (1971). [PDF]
13. Vaughan, P., Howell, J. and Eisenberg, R.S. The capacitance of skeletal muscle fibers in solutions of low ionic strength. J. Gen. Physiol. 59: 347-359 (1972). [PDF]
14. Eisenberg, R.S., Vaughan, P. and Howell, J. A theoretical analysis of the capacitance of muscle fibers using a distributed model of the tubular system. J. Gen. Physiol. 59: 360-373 (1972). [PDF]
15. Leung, J. and Eisenberg,
R.S. The effects of the antibiotics gramicidin-A, amphotericin-B, and nystatin
on the electrical properties of frog skeletal muscle. Biochem. Biophys. Acta.
16. Valdiosera, R., Clausen, C. and Eisenberg, R.S. Measurement of the impedance of frog skeletal muscle fibers. Biophys. J. 14: 295-315 (1974). [PDF]
17. Valdiosera, R., Clausen, C. and Eisenberg, R.S. Circuit models of the passive electrical properties of frog skeletal muscle fibers. J. Gen. Physiol. 63: 432-459 (1974). [PDF]
18. Valdiosera, R., Clausen, C. and Eisenberg, R.S. Impedance of frog skeletal muscle fibers in various solutions. J. Gen. Physiol. 63: 460-491 (1974). [PDF]
19. Mobley, B.A., Leung, J. and Eisenberg, R.S. Longitudinal impedance of skinned frog muscle fibers. J. Gen. Physiol. 63: 615-637 (1974). [PDF]
20. Mobley, B.A., Leung, J. and Eisenberg, R.S. Longitudinal impedance of single frog muscle fibers. J. Gen. Physiol. 65: 97-113 (1975). [PDF]
21. Eisenberg, R.S. and Rae, J.L. Current-voltage relationships in the crystalline lens. J. Physiol. 262: 285-300 (1976). [PDF]
22. Mathias, R.T., Eisenberg, R.S. and Valdiosera, R. Electrical properties of frog skeletal muscle fibers interpreted with a mesh model of the tubular system. Biophys. J. 17: 57-93 (1977). [PDF]
23. Eisenberg, R.S., Mathias,
R.T. and Rae, J.L. Measurement, modeling and analysis of the linear electrical
properties of cells.
24. Mathias, R.T., Rae, J.L. and Eisenberg, R.S. Electrical properties of structural components of the crystalline lens. Biophys. J. 25: 181-201 (1979). [PDF]
25. Rae, J.L., Eisenberg, R.S. and Mathias, R.T. The lens as a spherical syncytium. Ed. Satish K. Srivastava. Elsevier North Holland Inc. Red Blood Cell and Lens Metabolism. pp. 277-292 (1980). [PDF]
26. Mathias, R.T., Rae, J.L. and Eisenberg, R.S. The lens as a nonuniform spherical syncytium. Biophys. J. 34: 61-85 (1981). [PDF]
27. Eisenberg, B. and Eisenberg, R.S. The T-SR junction in contracting single skeletal muscle fibers. J. Gen. Physiol. 79: 1-20 (1982). [PDF]
28. Rae, J.L., Thomson, R.D. and Eisenberg, R.S. The effect of 2-4 dinitrophenol on cell to cell communication in the frog lens. Exp. Eye Res. 35: 597-610 (1982). [PDF]
29. Rae, J.L., Mathias, R.T. and Eisenberg, R.S. Physiological role of the membranes and extracellular space within the ocular lens. Exp. Eye Res. 35: 471-490 (1982). [PDF]
30. Eisenberg, R.S., McCarthy,
R.T., and
31.
32. Hui, C.S.,
33. Curtis, B.A. and Eisenberg, R.S. Calcium influx in contracting and paralyzed frog twitch muscle fibers. J. Gen. Physiol. 85: 383-408 (1985). [PDF]
34.
35. Eisenberg, R.S. Membranes,
calcium, and coupling.
Theoretical Analysis and Modeling of Spread of Current:
36. Eisenberg, R.S. and Johnson, E.A. Three dimensional electrical field problem in physiology. Prog. Biophys. Mol. Biol. 20: 1-65 (1970). [PDF]
37. Eisenberg, R.S. and Engel, E. The spatial variation of membrane potential near a small source of current in a spherical cell. J. Gen. Physiol. 55: 736-757 (1970). [PDF]
38. Barcilon, V., Cole, J. and
Eisenberg, R.S. A singular perturbation analysis of induced electric fields in
nerve cells.
39. Eisenberg, R.S. and Costantin, L.L. The radial variation of potential in the transverse tubular system of skeletal muscle. J. Gen. Physiol. 58:700-701 (1971). [PDF]
40. Engel, E., Barcilon, V. and Eisenberg, R.S. The interpretation of current-voltage relationships from a spherical cell recorded with a single microelectrode. Biophys. J. 12: 384-403 (1972). [PDF]
41. Peskoff, A., Eisenberg, R.S. and Cole, J.D. Potential induced by a point source of current in the interior of a spherical cell. UCLA Engineering Report #7259, 62pp. (1972). [PDF]
42. Peskoff, A., Eisenberg, R.S. and Cole, J.D. Potential induced by a point source of current inside an infinite cylindrical cell. UCLA Engineering Report #7303, 70pp. (1973). [PDF]
43. Peskoff, A. and Eisenberg, R.S. Interpretation of some microelectrode measurements of electrical properties of cells. Ann. Rev. Biophysics. and Bioeng. 2: 65-79 (1973). [PDF]
44. Peskoff, A. and Eisenberg, R.S. A point source in a cylindrical cell: potential for a step-function of current inside an infinite cylindrical cell in a medium of finite conductivity. UCLA Engineering Report #7421, 73pp. (1974). [PDF]
45. Peskoff, A. and Eisenberg, R.S. The time-dependent potential in a spherical cell using matched asymptotic expansions. Journal of Math. Biol. 2: 277-300 (1975). [PDF]
46. Peskoff, A., Eisenberg,
R.S. and Cole, J.D. Matched asymptotic expansions of the Green’s function for
the electric potential in an infinite cylindrical cell.
47. Eisenberg, R.S., Barcilon, V., and Mathias, R.T. Electrical properties of spherical syncytia. Biophys. J. 25: 151-180 (1979). [PDF]
48. Mathias, R.T.,
Electrical Properties of Ionic Channels:
49. K.E. Cooper, Tang, J.M., Rae, J.L., and Eisenberg, R.S. A Cation Channel in Frog Lens Epithelia Responsive to pressure and Calcium. J. Membrane Biology. 93: 259-269 (1986). [PDF]
50. K.E. Cooper, P.Y. Gates, and Eisenberg, R.S. Surmounting barriers in ionic channels. Quart. Rev. Biophysics. 21: 331-364 (1988). [PDF]
51. K.E. Cooper, P.Y. Gates, and Eisenberg, R.S. Diffusion theory and discrete rate constants in ion permeation. J. Membrane Biol. 106: 95-105 (1988). [PDF]
52. J.M. Tang, J. Wang, and Eisenberg, R.S. K+ selective channel from sarcoplasmic reticulum of split lobster muscle fibers. J. Gen. Physiol. 94:261-278 (1989). [PDF]
53. P.Y. Gates, K.E. Cooper, J. Rae, and Eisenberg, R.S. Predictions of diffusion models for one ion membrane channels. in Progress in Biophysics and Molecular Biology. 53: 153-196 (1989). [PDF]
54. P.Y. Gates, K.E. Cooper, and Eisenberg, R.S. Analytical diffusion models for membrane channels. in Ion Channels, Volume 2 (editor. T. Narahashi), Plenum Press (1990). [PDF]
55. D. Junge and R.S. Eisenberg. Uniqueness and interconvertibility among membrane potassium channels. Comments on Theoret. Biology. 11: 45-55 (1990). [PDF]
56. Tang, J.M., Wang, J., F.N. Quandt, and R.S. Eisenberg. Perfusing pipettes. Pflügers Arch. 416:347-350 (1990). [PDF]
57. Chen, D.P., Barcilon, V.,
and R.S. Eisenberg. Constant fields and constant gradients in open ionic
channels. Biophysical J. 61:1372-1393 (1992).
[PDF]
58. Barcilon, V., D.P. Chen,
and R.S. Eisenberg. Ion flow through narrow membrane channels. Part II.
59. Wang, J., Tang, J.M., and R.S. Eisenberg. A calcium conducting channel akin to a calcium pump. J. Membrane Biology 130:163-181 (1992). [PDF]
60. Barcilon, V., D.P. Chen, R. Eisenberg, and M. Ratner. Barrier crossing with concentration boundary conditions in biological channels and chemical reactions. J. Chem. Phys. 98(2) 1193-1211 (1993). [PDF]
61. Chen, D.P. and R.S. Eisenberg. Charges, currents, and potentials in ionic channels of one conformation. Biophysical Journal. 64:1405-1421 (1993a). [PDF]
62. Chen, D.P. and R.S.
Eisenberg. Flux, coupling, and selectivity in ionic channels of one
conformation. Biophysical Journal 65:727-746 (1993b). [PDF]
63. Hainsworth, A.H.,
64. Eisenberg, R.S., Klosek, M.M., and Schuss, Z. Diffusion as a chemical reaction: stochastic trajectories between fixed concentrations. J. Chem. Phys., 102(4): 1767-1780 (1995). [PDF]
65. Elber, R., Chen, D., Rojewska, D., and Eisenberg, R.S. Sodium in gramicidin: an example of a permion. Biophysical Journal, 68: 906-924, (1995). [PDF]
66. Chen, D., Eisenberg, R., Jerome, J., and Shu, C. Hydrodynamic model of temperature change in open ionic channels. Biophysical J. 69: 2304-2322. (1995). [PDF]
67. Barkai, E., Eisenberg, R.S., and Schuss, Z. (1996). A bidirectional shot noise in a singly occupied channel. (Physical Review E(2), 54 1161-1175). [PDF]
68. Chen, D., Lear, J., and Eisenberg, Bob. (1997) Permeation through an Open channel. Poisson-Nernst-Planck Theory of a Synthetic Ionic Channel. (Biophysical Journal, 72 97-116). [PDF]
69. Barcilon, V., Chen, D.-P.,
Eisenberg, R.S., and J.W. Jerome. (1997) Qualitative properties of steady-state
Poisson-Nernst-Planck systems: perturbation and simulation study.
70. Chen, D.; Xu, L.; Tripathy, A.; Meissner, G.; Eisenberg, B. (1997) Permeation through the Calcium Release Channel of Cardiac Muscle. with an appendix Rate Constants in Channology. Biophys. J. 73(3) 1337-1354. [PDF]
71. Nonner, W.; Chen, D.; Eisenberg, B. (1998) Anomalous Mole Fraction Effect, Electrostatics, and Binding. Biophys. J. 74 2327-2334. [PDF]
72. Nonner, W. and Eisenberg, B. (1998) Ion Permeation and Glutamate Residues Linked by Poisson-Nernst-Planck Theory in L-type Calcium Channels. Biophys. J. 75:1287-1305. [PDF]
73. Chen, D.; Xu, L.; Tripathy, A.; Meissner, G.; and Eisenberg, B. (1999) Selectivity and Permeation in Calcium Release Channel of Cardiac Muscle: Alkali Metal Ions. Biophysical Journal 76:1346-1366. [PDF]
74. Hollerbach, U., Chen,
D.P., Busath,
75. Gardner, C., Jerome, J.
and R.S. Eisenberg (2000) Electrodiffusion Model of Rectangular Current Pulses
in Ionic Channels of Cellular Membranes.
76. Nonner, W., L. Catacuzzeno, and Eisenberg, B. (2000). Binding and Selectivity in L-type Ca Channels: a Mean Spherical Approximation. Biophysical Journal 79: 1976-1992. [PDF]
77. Hollerbach, U., Chen, D.P., and Eisenberg, B. (2001) Two and Three Dimensional Poisson-Nernst-Planck Simulations of Current Through Gramicidin-A. J. Scientific Computing 16 (4) 373-409. [PDF]
78. Gillespie, D. and Eisenberg, R.S. (2001) Modified Donnan potentials for ion transport through biological ion channels. Phys Rev E, 63 061902 1-8. [PDF]
79. Nonner, W., Gillespie, D., Henderson, D., and Eisenberg, Bob. (2001) Ion accumulation in a biological calcium channel: effects of solvent and confining pressure. J Physical Chemistry B 105: 6427-6436. [PDF]
80. Schuss, Zeev, Nadler,
Boaz, and Eisenberg, R.S. (2001) Derivation of PNP Equations in
81. Gillespie, Dirk, Nonner,
W., Henderson,
82. Gillespie, Dirk, and
Eisenberg, Robert S. (2002). Physical descriptions of experimental selectivity
measurements in ion channels. European Biophysics Journal 31: 454-466). [PDF]
83. Gillespie, Dirk, Nonner, W., and Eisenberg, Robert S. (2002) Coupling Poisson-Nernst-Planck and Density Functional Theory to Calculate Ion Flux. Journal of Physics (Condensed Matter) 14: 12129–12145. [PDF]
84. Gardner, Carl L., Jerome, Joseph W., and Eisenberg. R.S. (2002) Electrodiffusion Model Simulation of Rectangular Current Pulses in a Voltage Biased Biological Channel. Journal of Theoretical Biology 219 291-299. [PDF]
85. Gardner, Carl L., Jerome, Joseph W., and Eisenberg. R.S. (2002) Electrodiffusion Model Simulation of Rectangular Current Pulses in a Biological Channel. J Computational Electronics, 1 347-351. [PDF]
86. van der Straaten, T.A., Tang, J., Eisenberg, R.S., Ravaioli, U., and Aluru, N.R. (2002) Three-dimensional continuum simulations of ion transport through biological ion channels: effects of charge distribution in the constriction region of porin. J. Computational Electronics 1 335-340 [PDF]
87. Boda, D., Busath, D., Eisenberg, B., Henderson, D., and Nonner, W. (2002) Monte Carlo Simulations of ion selectivity in a biological Na channel: charge-space competition. Physical Chemistry Chemical Physics 4 5154-5160. [PDF]
88. Hollerbach, Uwe and Robert Eisenberg. (2002) Concentration-Dependent Shielding of Electrostatic Potentials Inside the Gramicidin A Channel. Langmuir 18 3262-3631. [PDF]
89. Gillespie, D., Nonner, W. and RS Eisenberg. (2003) Crowded Charge in Biological Ion Channels Nanotech 3: 435-438. [PDF]
90. Nadler, B., Schuss, Z., Singer, A., Eisenberg, B. (2003) Diffusion through protein channels: from molecular description to continuum equations. Nanotech 3: 439-442. [PDF]
91. Wigger-Aboud, S., Saraniti, M. and R. Eisenberg. (2003) Self-consistent particle based simulations of three dimensional ionic solutions. Nanotech 3: 443-446. [PDF]
92. Aboud, S., Saraniti, M. and R. Eisenberg. (2003) Computational issues in modeling ion transport in biological channels: Self-consistent particle-based simulations. Journal of Computational Electronics 2: 239-243. [PDF]
93. van der Straaten, T., Kathawala, G., Kuang, Z., Boda, D., Chen, D.P., Ravaioli, U., Eisenberg, R.S., and Henderson, D. (2003) Equilibrium structure of electrolyte calculated using equilibrium Monte Carlo, Molecular Dynamics, and Transport Monte Carlo simulation. Nanotech 3: 447-451. [PDF]
94. Chen, D.; Xu, L.;
Eisenberg, B; and Meissner, G. (2003) Calcium Ion Permeation through the
Calcium Release Channel (Ryanodine Receptor) of Cardiac Muscle. J Phys Chem 107
9139-9145. [PDF]
95. Nadler, Boaz, Hollerbach, Uwe, Eisenberg, Bob. (2003) The Dielectric Boundary Force and its Crucial Role in Gramicidin. Phys. Rev. E 68 021905 p1-9. [PDF]
96. Gillespie, Dirk, Nonner, Wolfgang, and Eisenberg, Robert S. (2003) Density functional theory of charged, hard-sphere fluids. Phys Rev E 68 0313503 1-10. [PDF]
97. Boda, Dezso, Varga, Tibor,
98. van der Straaten, T. A., Tang, J. M., Ravaioli, U., Eisenberg, R. S. and Aluru, N. (2003) Simulating Ion Permeation Through the OmpF Porin Ion channel Using Three-Dimensional Drift-Diffusion Theory. Journal of Computational Electronics 2: 29-47. [PDF]
99. Boda, Dezso, Gillespie,
Dirk, Nonner, Wolfgang,
100. Goryll, M., Wilk, S., Laws, G. M., Thornton, T. J., Goodnick, S. M., Saraniti, M., Tang, J. M. and R. S. Eisenberg (2003) Silicon-based ion channel sensor Superlattices & Microstructures 34(3-6), 451-457. [PDF]
101. Goryll, M., Wilk, S., Laws, G.M., Thornton, T. J., Goodnick, S. M., Saraniti, M., Tang, J. M. and R. S. Eisenberg (2004) Ion Channel Sensor on a Silicon Support Mat. Res. Soc. Symp. Proc. Vol. 820, O7.2.1-5. Proceedings Title: Nanoengineered Assemblies and Advanced Micro/Nanosystems Editors (Symposium O): Jun Liu, Jeffrey T. Borenstein, Piotr Grodzinski, Luke P. Lee, Zhong Lin Wang. [PDF]
102. Nadler, Boaz, Schuss, Zeev, Singer, Amit, and RS Eisenberg. (2004) Ionic diffusion through confined geometries: from Langevin equations to partial differential equations. J. Physics: Condensed Matter 16: S2153-S2165. [PDF]
103. Schuss, Zeev, B. Nadler, A. Singer, and R.S. Eisenberg, Models of boundary behavior of particles diffusing between two concentrations in Fluctuations and Noise in Biological, Biophysical, and Biomedical Systems II editors: D. Abbot, S. M. Bezrukov, A. Der, A. Sanchez, 26-28 May 2004 Maspalomas, Gran Canaria, Spain, Spie proceedings series Volume 5467, pp. 345-358. [PDF]
104. Miedema, Henk, Anita Meter-Arkema, Jenny Wierenga, John Tang, Bob Eisenberg, Wolfgang Nonner, Hans Hektor, Dirk Gillespie and Wim Meijberg (2004) Permeation properties of an engineered bacterial OmpF porin containing the EEEE-locus of Ca2+ channels. Biophysical Journal Volume 87 3137–3147. [PDF]
105. Aboud, S., Marreiro, D., Saraniti, M., and R. Eisenberg. (2004) A Poisson P3M Force Field Scheme for Particle-Based Simulations of Ionic Liquids. J. Computational Electronics, 3: 117–133. [PDF]
106. Wilk, Seth, Goryll, Michael, Laws, Gerard M., Goodnick, Stephen M., Thornton, Trevor J., Saraniti, Marco, Tang, John M. and Eisenberg, Robert S. (2004) Teflon coated silicon aperture for lipid bilayer attachment Applied Physics Letters, 85, 3307-3309 [PDF]
107. Nadler, Boaz, Schuss,
Zeev, Hollerbach, Uwe, R.S. Eisenberg. (2004) Saturation of conductance in
single ion channels: the blocking effect of the near reaction field
Phys Rev E 70, 051912. [PDF]
108. Nonner, Wolfgang, Peyser, Alexander, Gillespie, Dirk, and Bob Eisenberg. (2004) Relating microscopic charge movement to macroscopic currents: the Ramo-Shockley theorem applied to ion channels. Biophysical Journal, 87: 3716-22. [PDF]
109. Singer, A., Schuss, Z., Nadler, B., and RS Eisenberg (2004) Memoryless control of boundary concentrations of diffusing particles Phys Rev E 70, 061106. [PDF]
110. van der Straaten, Trudy A., Kathawala, G. Trellakis, A., Eisenberg, R.S., Ravaioli, U. (2005) BioMOCA — a Boltzmann transport Monte Carlo model for ion channel simulation. Molecular Simulation, 31: 151-171. [PDF]
111. Aguilella-Arzo, Marcel, Aguilella, Vicente and R. S. Eisenberg (2005) Computing numerically the access resistance of a pore European Biophysics Journal, 34: 314-322. [PDF]
112. Singer, Amit, Schuss, Zeev, and R. S. Eisenberg. (2005) Attenuation of the electric potential and field in disordered systems J. Stat. Phys. 119 (5/6) 1397-1418. [PDF]
113. Singer, Amit, Schuss, Zeev, Holcman, David and R. S. Eisenberg. (2006) Narrow Escape. Part I, J. Stat. Phys. 122, 437-463. [PDF]
114. Siwy, Zuzanna, S., Powell, Matthew R., Kalman, Eric, Asumian, R. Dean, Eisenberg, Robert S. (2006) Negative Incremental Resistance Induced by Calcium in Asymmetric Nanopores. Nano Letters 6, 473-477. [PDF]
115.
Eisenberg, Bob, Nonner, Wolfgang (2006) Shockley-Ramo Theorem Measures Conformation
Changes of Ion Channels and Proteins. J
Computational Electronics (in the press)
116. Miedema, Henk, Vrouenraets, Maarten,
Wierenga, Jenny, Eisenberg, Bob,
Schirmer,
Tilman, Baslé, Arnaud and Wim Meijberg. (2006)
Conductance and selectivity fluctuations in D127
mutants of the bacterial porin OmpF. European Journal of Biophysics, Online:
August 29, 2006 [PDF]
117.
Siwy, Zuzanna, S., Powell, Matthew R., Kalman, Eric, Petrov, Alexander,
Trautmann, Christina, and Robert S Eisenberg, Robert S. (2006) Calcium Induced Voltage Gating in Single Conical Nanopores.
Nano Letters 6, 1729 -1734.
118. Miedema, Henk, Vrouenraets, Maarten, Wierenga, Jenny, Gillespie, Dirk, Eisenberg, Bob, Meijberg, Wim and Wolfgang Nonner. (2006) Ca2+ selectivity of a chemically modified OmpF with reduced pore volume. Biophysical Journal (in the press)
119. Boda, Dezso, Valisk, Monika Eisenberg, Bob, Nonner, Wolfgang, Henderson, Douglas, and Dirk Gillespie (2006) The Effect of Protein Dielectric Coefficient on the Ionic Selectivity of a Calcium Channel. Journal of Chemical Physics 125, 034901 1-11 [PDF]
120. Eisenberg, Bob, Liu, Weishi (2006) Poisson-Nernst-Planck systems for ion channels with permanent charges. (submitted)
121.
Burger, Martin, Eisenberg, Robert S. and Heninz Engl (2006) Inverse Problems
Related to Ion Channel Selectivity. (submitted)
Reviews,
mostly invited:
1. †Eisenberg, R.S. The equivalent circuit of frog skeletal muscle. (1971) In: Contractility of Muscle Cells (Ed. R. Podolsky) Prentice Hall, p. 73-88. [PDF]
2. †Eisenberg, R.S. and Mathias, R.T. (1980) Structural analysis of electrical properties. Critical Reviews in Bioengineering 4: 203-232. [PDF]
3. Eisenberg, R.S. Structural Complexity, Circuit Models, and Ion Accumulation. (1980) Fed. Proc. 39: 1540-1543. [PDF]
4. Mathias, R.T., R.A. Levis,
and R.S. Eisenberg. (1981) An alternative interpretation of charge movement in
muscle. In: The Regulation of Muscle
Contraction: Excitation-Contraction
Coupling. Ed. A. D. Grinnell & M.A.B. Brazier, Academic Press,
5. †Eisenberg, R.S. (1984) Membranes and Channels. Physiology and Molecular Biology, pp. 235-283. In: Membranes, Channels, and Noise, Eds. R.S. Eisenberg, M. Frank, and C.F. Stevens, Plenum Press, NY. [PDF]
6. Eisenberg, R.S. (1986) Electrical field problems in muscle and their meaning to mathematicians, physiologists, and muscle. in: Some Mathematical Questions in Biology - Muscle Physiology. Lectures on Mathematics in the Life Sciences, Vol. 16. Ed., Robert M. Miura, American Mathematical Society, Providence, Rhode Island, 16: 223-234. [PDF]
7. †Eisenberg, R.S.
(1987) Impedance measurements as estimators of the properties of the
extracellular space.
8. †Rae, J.L.,
9. †Eisenberg, R.S. Channels as Enzymes. J. Memb. Biol., 115, 1-12 (1990). [PDF]
10. †Tang, J.M., Wang, J., and Eisenberg, R.S. (1992) Studies on intact sarcoplasmic reticulum: patch clamp recording and tension measurement in lobster split muscle fibers. in Ion Channels (ed.’s B. Rudy and L.E. Iverson), a volume of Methods in Enzymology. [PDF]
11. †Tang, J.M., Wang, J., and Eisenberg, R.S. (1992) Perfusing patch pipettes, easily and quietly. in Ion Channels (ed.’s B. Rudy and L.E. Iverson), 207: 176-180 Methods in Enzymology. [PDF]
12. †Tang, J.M., F.N. Quandt, and R.S. Eisenberg. Perfusion of Patch Pipettes. (1995) in Patch Clamp Techniques and Protocols. (p.123-140) ed.’s: A.A. Boulton, hG.B. Baker, and W. Walz. Humana Press. [PDF]
13. †Eisenberg, R.S. (1996a)
Atomic Biology, Electrostatics and Ionic Channels.
14. Eisenberg, R.S. (1996b). Computing the field in proteins and channels. J. Membrane Biol. 150:1-25. [PDF]
15. Eisenberg, Bob (1998). Ionic channels in biological membranes. Natural nanotubes. Accounts of Chemical Research 31:117-125. [PDF]
16. Eisenberg, Bob (1998). Ionic Channels in Biological Membranes: Natural Nanotubes described by the Drift-Diffusion Equations. (Invited by and accepted by VLSI Design) Proceedings of the Fifth International Workshop on Computational Electronics. 8:75‑78. [PDF]
17. Eisenberg, Bob (1998). Ionic channels in biological membranes. Electrostatic analysis of a natural nanotube. Contemporary Physics, 39 (6) 447-466. [PDF]
18. Nonner, Wolfgang, Chen, Duan, and Bob Eisenberg. (1999). Progress and prospects in permeation. Journal of General Physiology 113: 773-782. [PDF]
19. Eisenberg, R.S. (1999). From Structure to Function in Open Ionic Channels. Journal of Membrane Biology 171 1-24. [PDF]
20. Nonner, Wolfgang, and Bob Eisenberg. (2000) Electrodiffusion in Ionic Channels of Biological Membranes. Journal of Molecular Fluids 87:149-162. [PDF]
21. Eisenberg, Bob. (2000). Permeation as a Diffusion Process. Chapter 4 in Biophysics Textbook On Line “Channels, Receptors, and Transporters” Louis J. DeFelice, Volume Editor. Updated on November 18, 2005 [PDF]
22. Eisenberg, R. (2000) Ionic channels: natural nanotubes described by the drift diffusion equations. Superlattices and Microstructuers. 27 (5/6) 545-549. [PDF]
23. Eisenberg, Bob (2003)
Proteins, Channels, and Crowded Ions Biophysical Chemistry 100: 507 - 517. [Edsall Memorial
Volume] [PDF]
23a. Eisenberg,
Bob (2003) Erratum to ``Proteins, channels and crowded ions'', Biophysical
Chemistry 106 p.93. [N.B., note misprint in title of Erratum in
initial, i.e., left quotation marks!] [PDF]
24. Schuss, Zeev, Nadler, Boaz, Singer, Amit, and Eisenberg, Robert S. Eisenberg. (2002) A PDE formulation of non-equilibrium statistical mechanics for ionic permeation, AIP Conference Proceedings 665, Washington, DC, 3-6 September 2002: Unsolved Problems Of Noise And Fluctuations, UPoN 2002, 3rd International Conference on Unsolved Problems of Noise and Fluctuations in Physics, Biology, and High Technology (S.M. Bezrukov, ed.), p.312, Washington, DC. [PDF]
25. Eisenberg, Bob. (2002) Ionic channels as natural nanodevices. J. Computational Electronics 1 331-334. [PDF]
26. Eisenberg, Bob (2003) Ion channels as devices. J. Computational Electronics 2 245-249. [PDF]
27. Eisenberg, Bob (2003) Why can’t protons move through ion channels? Biophysical Journal 85 3427-3428. [PDF]
28. Eisenberg, Bob (2005)
Living Transistors: a Physicist’s View of Ion Channels. Posted on http://arxiv.org/ with PaperID q-bio.BM/0506016,
June 14, 2005. [PDF]
29. Saraniti, Marco, Aboud,
Shela, and Robert Eisenberg (2006). The Simulation of Ionic Charge Transport in
Biological Ion Channels: an Introduction to Numerical Methods. Reviews in
Computational Chemistry Vol 22, pp 229-294.
[PDF]
Everything Else:
1. Eisenberg, R.S. (1975)
Electrophysiology. A review of Electric
Current Flow in Excitable Cells. J.B. Jack, D. Noble and R.W. Tsien.
Clarendon (Oxford University Press),
2. Eisenberg, R.S. (1973)
Studies of Biomembranes. Book review of Perspective
in Membranes. A Tribute to Kenneth S. Cole, D.P. Agin (Ed.)
3. Eisenberg, R.S. (1982) Book
review of The Biophysical Approach to
Excitable Systems. Eds. W.J. Adelman, Jr. and D.E. Goldman, Plenum,
4. Eisenberg, R.S. (1987)
Gating Current. Encyclopedia of
Neuroscience, Birkhauser,
5. Eisenberg, R.S. (1987)
Ionic Channels in Membranes. Encyclopedia
of Neurosciences. Birkhauser,
6. Eisenberg, R.S. (1987)
Structural Complexity in Nerve Cells. Encyclopedia
of Neuroscience, Birkhauser,
7. †Eisenberg, R.S. (1983) Impedance Measurement of the Electrical Structure of Skeletal Muscle. In: Handbook of Physiology, Section 10: Skeletal Muscle, Ed. L.D. Peachey American Physiological Society, pp 301-323. [PDF]
8. Eisenberg, R.S. (1987) Volumes apart. Nature. Scientific Correspondence on a paper of Zimmerberg and Parsegian. 325: 114. [PDF]
9. Eisenberg, R.S. (1990) Complexities in solution. Trends in Biochemical Sciences, 15:51, A Letter concerning a paper of Payne and Rudnick. [PDF]
10. Eisenberg, RS. (1992) A
unified theory of membrane transport. in Harvard Class of 1962. Thirtieth Anniversary Report.
11. Eisenberg, R.S. (1993) Popper, Wolpert, and Critics. Nature 361 292. [PDF]
12. Bertl, A., Blumwald, E., Coronado, R., Eisenberg, R., Findlay, G., Gradmann, D., Hille, B., Köhler, K., Kolb, H., MacRobbie, E., Meissner, G., Miller, C. Neher, E., Palade, P. Pantoja, O., Sanders, D., Schroeder, J., Slayman, C., Spanswick, R., Walker, A., and Williams, A. (1992) Electrical measurements on endomembranes. Science 258: 873-874. [PDF]
13. Chen, D.; Xu, L.; Tripathy, A.; Meissner, G.; Eisenberg, B. (1997) with an Appendix Rate Constants in Channology. in Permeation through the Calcium Release Channel of Cardiac Muscle. Biophys. J. 73 1337-1354. [original paper is also cited in this CV]
14. Eisenberg, Bob (2000)
Vignette Applications of Physical Chemistry, a Biological Example. in
15. Eisenberg, Bob (2005). Validating the need to validate code. Physics Today (Letter to the Editor) 58 (8) p. 13. [PDF]
16. Eisenberg, Bob (2006). The value of Einstein’s mistakes. “Einstein should be allowed his mistakes …” Physics Today (Letter to the Editor) 59 (4) p.12. [PDF]
Books:
1. Eisenberg, R.S., M. Frank, and C.F. Stevens (eds.) (1984) Membranes, Channels, and Noise. Plenum Press, NY, pp. 1-54.
Abstracts:
1. Eisenberg, R.S. and Gage, P.W. Electrical properties of frog skeletal muscle fibers with disrupted transverse tubules. Biophys. J. 8: A-188 (1968).
2. Eisenberg, R.S. and Eisenberg, B. The extent of disruption of the transverse tubular system in glycerol treated skeletal muscle. Federation Proceedings 27: 247 (1968).
3. Eisenberg, R.S. and Gage, P.W. The surface and tubular membranes of frog sartorius muscle fibers. J. Cell Biol. 39: 39a, (1968).
4. Eisenberg, R.S. and Gage, P.W. The conductance of the surface and tubular membranes of frog sartorius muscle. Biophys. J. 9: A99 (1969).
5. Eisenberg, R.S. and Johnson, E.A. The interpretation of potentials recorded with double-barrel microelectrodes or with a single electrode bridge. Federation Proceedings 28: 397 (1969).
6. Howell, J., Vaughan, P. and Eisenberg, R.S. Maintenance of resting potentials in glycerol treated muscle fibers. Biophys. J. 10: 75a, (1970).
7. Howell, J., Vaughan, P. and Eisenberg, R.S. Changes in the capacitance of frog skeletal muscle. Federation Proceedings 29: 656 (1970).
8. Eisenberg, R.S. The electrical properties of the internal membrane structures of skeletal muscle. J. Physiol. Soc. Japan. 34:90 (1972).
9. Valdiosera, R., Clausen, C. and Eisenberg, R.S. Impedance of frog skeletal muscle fibers. Biophys. Soc. Abst. 195a, (1973).
10. Mobley, B.A., Leung, J. and Eisenberg, R.S. Longitudinal Impedance of skinned frog muscle fibers. Federation Proceedings 33: 401 (1974).
11. Peskoff, A. and Eisenberg, R.S. Influence of extracellular resistance on membrane potential of cells. Federation Proceeding 33: 1266 (May 1974).
12. Mathias, R.T., Clausen, C. and Eisenberg, R.S. Mesh model of the electrical properties of the tubular system of skeletal muscle. The Physiologist, 18:(August 1975).
13. Clausen, C.,
14. Eisenberg, R.S., Barcilon, V. and Mathias, R.T. Electrical properties of a spherical syncytium. Biophys. J. 21: 48a, (1978).
15. Mathias, R.T., Rae, J. and Eisenberg, R.S. Linear electrical properties of the lens of the eye. Biophys. J. 21: 48a, (1978).
16. Eisenberg, B.R. and Eisenberg, R.S. T-SR Junction in activated muscle. J. Cell. Biol. 87: 264a, (1980).
17. Eisenberg, R.S. Structural analysis of electrical properties. Biophys. J. 33: 267a, 1981.
18. Eisenberg, R.S., Mathias, R.T., and J.L. Rae. Series resistance measured by integrals of transients. Biophys. J. 37: 63a, (1982).
19.
20. Hui, C.S.,
21. McCarthy, R.T.,
22.
23. Curtis, B.A. and Eisenberg, R.S. A delayed calcium influx related to contraction in frog twitch fibers. J. Gen. Physiol. 84: 36a, (1984).
24. Cooper, K.E., McCarthy,
R.T.,
25. Eisenberg, R.S., Curtis, B.A. and McCarthy, R.T. Calcium uptake and K+ contractures in paralyzed and contracting muscle fibers. Biophys. J. 45: 234a (1984).
26. Eisenberg, R.S. Structural analysis of neuronal integration. Biophys. J. 45: 153a, (1984).
27. Curtis, B.A. and Eisenberg, R.S. A delayed influx related to contraction in frog twitch fibers. J. Gen. Physiol. 84: 36a, (1984).
28. Curtis, B.A. and Eisenberg, R.S. Calcium entry and the repriming period of frog twitch fibers. Biophys. J. 47: 132a, (1985).
29. Eisenberg, R.S. Calcium Signals in Muscle. Biophys. J. 47: 194a, (1985).
30. Curtis, B.A. and Eisenberg, R.S. Calcium ions: The link between t depolarization and SR Ca release. Biophys. J. 47: 195a, (1985).
31. Cooper, K.E., J.M. Tang, J.L. Rae and R.S. Eisenberg. Cation selective channel in the epithelium of frog lens. Biophys. J. 86: 9a, (1985).
32. Cooper, K.E., J.M. Tang, J.L. Rae and R.S. Eisenberg. Cation-selective channel in the epithelium of frog lens. J. Gen. Physiol. 86: 9a-10a, (1985).
33. Cooper, K.E., J.M. Tang, J.L. Rae and R.S. Eisenberg. A cation-selective channel from frog lens epithelium. Biophys. J. 49: 6a, (1986).
34. Cooper, K.E., Gates, P.Y., and R.S. Eisenberg. Rate constants for ionic diffusion over barriers. Biophys. J. 51: 48a, (1987).
35. Gates, P.Y., Cooper, K.E., and R.S. Eisenberg. Diffusive flux through ionic channels. Biophys. J. 51: 48a, (1987).
36. Tang, J. M., Wang, J., and R.S. Eisenberg. Patch clamp of sarcoplasmic reticulum within muscle fibers. Biophys. J. 51: 106a (1987).
37. Eisenberg, R.S.,
Hainsworth, A.H., and R.A. Levis. (1987). Open-channel noise in a cation
channel of the frog lens epithelium. J. Physiol. (
38. Hainsworth, A., Tang,
J.M., Wang, J.,
39. Cooper, K.E., Gates, P.Y., and R.S. Eisenberg. Diffusion theory and discrete rate constants in ion permeation. Biophys. J. 152a, (1988).
40. Moghaddamjoo, A.,
41. R.S. Eisenberg. Channels as Enzymes (title only). Medical Physics 15: No. 4, p. 440 (1988).
42. J. Wang, J.M. Tang, and R.S. Eisenberg. Ca++ channels in the sarcoplasmic reticulum (SR) of skinned lobster muscle fibers: patch clamp measurements. J. Cell Biology 107:144a (1989).
43. R.S. Eisenberg, A.H. Hainsworth, and R.A. Levis. Open-channel noise in the potassium channel of lobster sarcoplasmic reticulum. J. Physiol. (Cambridge Meeting, July 1988: 107P).
44. J. Wang, J.M. Tang, and R.S. Eisenberg. Ca++ channels from sarcoplasmic reticulum of split lobster muscle fibers. Biophysical J. 55: 207a, 1989.
45. A. Hainsworth, R.A. Levis, and R.S. Eisenberg. Excess open-channel noise in the SR K+ channel. Biophysical J. 55: 200a, 1989.
46. R.S. Eisenberg, A.H. Hainsworth, R.A. Levis. The effect of temperature on open-channel noise in the potassium channel of the lobster sarcoplasmic reticulum. J. Physiol. 410: 18P, 1989.
47. J.M. Tang, J. Wang, F.N. Quandt, and Eisenberg, R.S. Perfusing patch pipettes quietly and easily. Biophys. J. 57: 171a, 1990.
48. J.M. Tang, J. Wang, T. Lea and Eisenberg, R.S. Contractures and reloading in skinned lobster muscle fibers. Biophys. J. 57: 171a, 1990.
49. R.S. Eisenberg, J.M. Tang, and J. Wang. Ionic channels of the sarcoplasmic reticulum of lobster remotor muscle. Biophys. J. 59: 177a, 1991.
50. D.P. Chen and R.S. Eisenberg. Constant fields and constant gradients in open ionic channels. Biophys. J. 59: 404a, 1991.
51. R.S. Eisenberg, D.P. Chen, and V. Barcilon. Constant fields and constant gradients in open ionic channels. Physiologist. 34: 102, 1991.
52. Wang, J., Tang, J.M., and RS Eisenberg. Calcium conducting channel in SR: calcium pump without occlusion? Biophys. J. 61. A433, 1992.
53. Chen, DP, Barcilon, V. and RS Eisenberg. Induced and permanent charge in open ionic channels. Biophys. J. 61. A11, 1992.
54. Chen, DP, and R Eisenberg. Exchange diffusion, single filing, and gating in macroscopic channels of one conformation. J. Gen. Physiol. 100: 9a, 1992.
55. Eisenberg, Robert From Structure to Permeation in Open Ionic Channels. Biophys. J. 64:A22, 1993.
56. Eisenberg, Robert and Duanpin Chen. Poisson-Nernst-Planck (PNP) theory of an open ionic channel. Biophys. J. 64:A22, 1993.
57. Chen, Duanpin and Robert Eisenberg. Poisson-Nernst-Planck (PNP) theory of open ionic channels. Biophys. J. 64:A22, 1993.
58. Chen, Duan P. and Robert S. Eisenberg. Divalent effects on mono-valent cation channels, an extension of Poisson-Nernst-Planck theory. Biophys. J. 66(2) A292, 1994.
59. Elber, Ron, Duan Chen, Danuta Rojewska, and Bob Eisenberg. Na+ in Gramicidin: the prototype permion. Biophys. J. 66(2) A354, 1994.
60. Eisenberg, Bob, Malgorzata Klosek, and Zeev Schuss. Stochastic theory of the open channel. Biophys. J. 66(2) A354, 1994.
61. Chen, Duan, Paul Kienker, Jim Lear and Bob Eisenberg. PNP Theory fits current-voltage (IV) relations of a synthetic channel in 7 solutions. Biophys. J. 68:A370 (1995).
62. Chen, Duan, Wolfgang
Nonner, and Bob Eisenberg. PNP
Theory fits current-voltage (IV) relations
of a neuronal anion channel in 13 solutions. Biophys. J. 68:A370 (1995).
63. Chen, D., Eisenberg, R.,
Jerome, J., and Shu, C. PH
(Poisson-Hydrodynamic) Theory of an open channel. Biophys. J., 68:A371 (1995).
64. Tang, John, Rick Levis,
Kelvin Lynn, and Bob Eisenberg. Opening and closing transitions of a large
mitochondrial channel with microsecond time resolution. Biophys. J., 68:A145,
1995.
65. Janovic, Slobidan, Kelvin
Lynn, Xaioye Wu, Bob Eisenberg, and Rick Levis. Real-time analysis of single
channel currents. Biophys. J., 68:A42, 1995.
66. Eisenberg, Robert S., Chen, P. Solutions to Fields in Biological Channels. American Chemical Society, Division of Physical Chemistry, 212th Meeting, 1996. Printed but perhaps not published Abstract.
67. Chen, D., Xu, L., Tripathy, A., Meissner, G., and R. Eisenberg (1997) Permeation through the calcium release channel (CRC) of cardiac muscle. Biophys. J., 72:A108, 1997.
68. Tang, J., Chen, D., Saint, N., Rosenbusch, J., and R. Eisenberg (1997). Permeation through porin and its mutant G119D. Biophys. J., 72:A108, 1997.
69. Tang, J., Saint, N., Rosenbusch, J., and R. Eisenberg (1997). Currents through single channels of maltoporin. Biophys. J., 72:A108, 1997.
70. Gardner, Carl, Eisenberg, B., and Joe Jerome. Numerical simulation of rectangular channel currents. Biophys. J., 74 A342 (1998).
71. Schuss, Zeev and Eisenberg, B. Stochastic and continuum models of unidirectional fluxes in open ionic channels. Biophys. J., 74 A342 (1998).
72. Elber, R. and Eisenberg, B. Molecular dynamics simulations of solvated ions between a membrane and metal electrodes at various electric potentials. Biophys. J., 74 A342 (1998).
73. Chen, D., Tripathy, A., Xu, L., Meissner, G. and Bob Eisenberg. Permeation in the calcium release channel (CRC) of skeletal muscle. Biophys. J., 74 A342 (1998).
74. Chen, D., Tripathy, A., Xu, L., Meissner, G. and Bob Eisenberg. Selectivity of calcium release channel (CRC) of cardiac muscle. Biophys. J., 74 A342 (1998).
75. Nonner, W., Chen, D. and Bob Eisenberg. Anomalous mole fraction effects: an electrostatic interpretation. Biophys. J., 74 A342 (1998).
76. Nonner, W. and Bob Eisenberg. Calcium channel permeability and glutamate residues linked by PNP Theory. Biophys. J., 74 A342 (1998).
77. Catacuzzeno, L., W. Nonner, and B. Eisenberg. 1999. PNP2 Links Crystallographic Structure and Conduction in K Channels. Biophysical Journal. 76:A79 (1999).
78. Gillespie, D, and Bob Eisenberg. An analytic formula for the reversal potential derived from PNP theory. . Biophysical Journal. 76:A192 (1999).
79. Hollerbach, U., Chen, D., Nonner, W., and Bob Eisenberg. Three-dimensional Poisson-Nernst-Planck Theory of Open Channels. Biophysical J. Biophysical J. 76:A205 (1999).
80. Catacuzzeno, L., W. Nonner, L. Blum, and B. Eisenberg. Ca Selectivity in the ‘EEEE’ Locus of L-type Ca Channels. Biophysical Journal. 76:A259 (1999).
81. Nonner, W, L. Catacuzzeno, and B. Eisenberg. Ionic selectivity in K channels. Biophysical Journal. 78:A96 (2000).
82. Nonner, W, L. Catacuzzeno, and B. Eisenberg. Ionic selectivity in calcium channels. Biophysical Journal. 78:A455 (2000).
83. Chen, Duan, Le Xu, Bob Eisenberg, and Gerhard Meissner. Calcium and potassium ion selectivity of skeletal muscle ryanodine receptor. Biophysical Journal. 78:A462 (2000).
84. van der Straaten, T.A., RS
Eisenberg, JM Tang, U Ravaioli, and
85. Chen, Duan, L Xu, B Eisenberg, and G Meissner. Ca ion permeation through the calcium release channel (ryanodine receptor) of cardiac muscle Biophysical Journal. 50: 115a (2001).
84. Nonner, W., B Eisenberg, and D Henderson Ca channel selectivity: the role of solvent Biophysical Journal. 80:453a (2001).
85. Nonner, W., Gillespie, D., and B Eisenberg. Flux and selectivity in the Ca channel: a density functional approach. Biophysical Journal. 82: 340a (2002).
86. Gillespie, D. and RS Eisenberg. Measurements of selectivity: physical interpretation. Biophysical Journal. 82:206a. (2002).
87. Van der Straaten, T.A., Tang, J.M., Eisenberg, RS, Ravaioli, U., Aluru, N., Varma, S., and E. Jakobsson. A study of mutations of ompf porin using Poisson-Nernst-Planck theory. Biophys. J. 82: 207a (2002).
88. Chiu, See-Wing, Varma, S., Jakobsson, E., Tang, J.M., van der Straaten, T., Eisenberg, R.S. Molecular dynamics of permeation in porin and its mutant G119D. Biophysical Journal. 82:208a (2002).
89. Gillespie, D., Nonner, W., and Bob Eisenberg. Physical model of selectivity and flux in Na channels. Biophysical Journal 84 (Number 2) p. 67a (2003).
90. Nonner, Wolfgang, Gillsepsie, Dirk, Eisenberg, Bob, and Douglas Henderson. A physical basis for large-ion selectivity. Biophysical Journal 84 (Number 2) 93a (2003).
91. Chen, Duan, Kuang,
Zhifeng, Boda, Deszo, Eisenberg, Bob, Busath, David and Douglas Henderson. Ion
channel permeation simulated by non-equilibrium molecular dynamics calibrated
by equilibrium
92. Boda, Dezso, Gillespie,
Dirk, Nonner, Wolfgang,
93. Mediema, Henk, Meter-Arkema, Anita, Wierenga, Jenny, Hektor, Hans, Tang, John, Bob Eisenberg, Bob and Wim Meijberg. Permeation properties of an engineered OmpF containing the EEEE locus of Ca-channels. Biophysical Journal 86 260a (2004).
94. Nonner, Wolfgang, Gillespie, Dirk, and Bob Eisenberg. Moving gating charges: comparing electrostatic energetics of the S4 motion of different models. Biophysical Journal 86 436a (2004).
95. Aguilella-Arzo, Marcel, Garcia-Celma, Juan, Aguilella, Vicente, and Robert Eisenberg. Computing numerically access resistance of a channel. Bob Eisenberg. Biophysical Journal 86 629a (2004).
96. Peyser, Alexander, Nonner, Wofgang R., Gillespie, Dirk, Eisenberg Bob. Electrostrictive Forces in S4 Models. Biophysical Journal 88 458a (2005).
97. Henderson, D., Boda, D., Valisko, M., Gillespie, D, Eisenberg, B., Nonner, W. (2005) New constant voltage method of simulating ions in a dielectric near a metallic electrode PacifiChem 2005, Honolulu HI.
98.
Eisenberg, R. S. (2005) Ions in channels: Life's transistors PacifiChem 2005,
99.
Wilk, S.J., Petrossian, L., Goryll, M.,
100.
Siwy, Z, Powell, M., Kalman, E., Heins, E., Martin, C.R., R.S.
Eisenberg. (2006). Pores in plastic can
be calcium sensitive and gate. Biophysical Journal 206 314a Society
Abstract.
101.
Boda, Dezso, Valisko, Monika, Gillespie, Dirk, Nonner, Wolfgang,
102. Nonner, Wolfgang, Gillespie, Dirk, Eisenberg, Bob. (2006) How Do Long Pores Make Better K Channels? Biophysical Journal 206 239a Society Abstract.
[Laboratory of
Robert S. Eisenberg]