Modelling the Bioelectronic Interface in Engineered Tethered Membranes: From Biosensing to Electroporation

This paper studies the construction and predictive models of three novel measurement platforms: (i) a Pore Formation Measurement Platform (PFMP) for detecting the presence of pore forming proteins and peptides, (ii) the Ion Channel Switch (ICS) biosensor for detecting the presence of analyte molecules in a fluid chamber, and (iii) an Electroporation Measurement Platform (EMP) that provides reliable measurements of the electroporation phenomenon. Common to all three measurement platforms is that they are comprised of an engineered tethered membrane that is formed via a rapid solvent exchange technique allowing the platform to have a lifetime of several months. The membrane is tethered to a gold electrode bioelectronic interface that includes an ionic reservoir separating the membrane and gold surface, allowing the membrane to mimic the physiological response of natural cell membranes. The electrical response of the PFMP, ICS, and EMP are predicted using continuum theories for electrodiffusive flow coupled with boundary conditions for modelling chemical reactions and electrical double layers present at the bioelectronic interface. Experimental measurements are used to validate the predictive accuracy of the dynamic models. These include using the PFMP for measuring the pore formation dynamics of the antimicrobial peptide PGLa and the protein toxin Staphylococcal α-Hemolysin; the ICS biosensor for measuring nano-molar concentrations of streptavidin, ferritin, thyroid stimulating hormone (TSH), and human chorionic gonadotropin (pregnancy hormone hCG); and the EMP for measuring electroporation of membranes with different tethering densities, and membrane compositions.

[1]  D. Miklavčič,et al.  Electroporation of archaeal lipid membranes using MD simulations. , 2014, Bioelectrochemistry.

[2]  V. Krishnamurthy,et al.  An engineered membrane to measure electroporation: effect of tethers and bioelectronic interface. , 2014, Biophysical journal.

[3]  Laurent Pilon,et al.  Simulations of Cyclic Voltammetry for Electric Double Layers in Asymmetric Electrolytes: A Generalized Modified Poisson–Nernst–Planck Model , 2013, The Journal of Physical Chemistry C.

[4]  B. Potapkin,et al.  Molecular Dynamic Simulation of Transmembrane Pore Growth , 2013, The Journal of Membrane Biology.

[5]  Dongqing Li,et al.  A Theoretical Study of Single-Cell Electroporation in a Microchannel , 2013, The Journal of Membrane Biology.

[6]  I. Sargent,et al.  Exosome-mediated delivery of siRNA in vitro and in vivo , 2012, Nature Protocols.

[7]  J. J. López-García,et al.  Equilibrium properties of charged spherical colloidal particles suspended in aqueous electrolytes: finite ion size and effective ion permittivity effects. , 2012, Journal of colloid and interface science.

[8]  Vikram Krishnamurthy,et al.  A molecular machine biosensor: construction, predictive models and experimental studies. , 2012, Biosensors & bioelectronics.

[9]  F. Ivanauskas,et al.  Electrochemical impedance spectroscopy of tethered bilayer membranes. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[10]  Qiong Zheng,et al.  Second-order Poisson-Nernst-Planck solver for ion transport , 2011, J. Comput. Phys..

[11]  M. Kotulska,et al.  Metastable Pores at the Onset of Constant-Current Electroporation , 2010, The Journal of Membrane Biology.

[12]  Qin Hu,et al.  Analysis of cell membrane permeabilization mechanics and pore shape due to ultrashort electrical pulsing , 2010, Medical & Biological Engineering & Computing.

[13]  Paul Gaynor,et al.  Modelling single cell electroporation with bipolar pulse parameters and dynamic pore radii , 2010 .

[14]  Vikram Krishnamurthy,et al.  Ion Channel Biosensors—Part II: Dynamic Modeling, Analysis, and Statistical Signal Processing , 2010, IEEE Transactions on Nanotechnology.

[15]  Vikram Krishnamurthy,et al.  Ion-Channel Biosensors—Part I: Construction, Operation, and Clinical Studies , 2010, IEEE Transactions on Nanotechnology.

[16]  Hao Lin,et al.  The current-voltage relation for electropores with conductivity gradients. , 2010, Biomicrofluidics.

[17]  M. Bazant,et al.  Effective zero-thickness model for a conductive membrane driven by an electric field. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[18]  M. Bazant,et al.  Strongly nonlinear dynamics of electrolytes in large ac voltages. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[19]  M. Lösche,et al.  A new lipid anchor for sparsely tethered bilayer lipid membranes. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[20]  M. Lösche,et al.  Structure of functional Staphylococcus aureus alpha-hemolysin channels in tethered bilayer lipid membranes. , 2009, Biophysical journal.

[21]  M. Lösche,et al.  Structure of Functional Staphylococcus aureus ¿-Hemolysin Channels in Tethered Bilayer Lipid Membranes | NIST , 2009 .

[22]  R. Joshi,et al.  Transmembrane voltage analyses in spheroidal cells in response to an intense ultrashort electrical pulse. , 2009, Physical review. E, Statistical, nonlinear, and soft matter physics.

[23]  Ingo Köper,et al.  Incorporation of alpha-hemolysin in different tethered bilayer lipid membrane architectures. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[24]  B. Cornell,et al.  Making lipid membranes even tougher , 2007 .

[25]  J. Kasianowicz,et al.  Molecular-scale structural and functional characterization of sparsely tethered bilayer lipid membranes , 2007, Biointerphases.

[26]  W. Krassowska,et al.  Modeling electroporation in a single cell. , 2007, Biophysical journal.

[27]  M. Bazant,et al.  Steric effects in the dynamics of electrolytes at large applied voltages. II. Modified Poisson-Nernst-Planck equations. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[28]  W. Krassowska,et al.  Singular perturbation analysis of the pore creation transient. , 2006, Physical review. E, Statistical, nonlinear, and soft matter physics.

[29]  W. Briels,et al.  Free energy of a trans-membrane pore calculated from atomistic molecular dynamics simulations. , 2006, The Journal of chemical physics.

[30]  R. Eisenberg,et al.  Computing numerically the access resistance of a pore , 2005, European Biophysics Journal.

[31]  Wanda Krassowska,et al.  Model of creation and evolution of stable electropores for DNA delivery. , 2004, Biophysical journal.

[32]  W. Krassowska,et al.  Electrical energy required to form large conducting pores. , 2003, Bioelectrochemistry.

[33]  B. Cornell,et al.  A tethered bilayer sensor containing alamethicin channels and its detection of amiloride based inhibitors. , 2003, Biosensors & bioelectronics.

[34]  W. Krassowska,et al.  Modeling postshock evolution of large electropores. , 2003, Physical review. E, Statistical, nonlinear, and soft matter physics.

[35]  B. Cornell,et al.  Tethered Bilayer Membranes Containing Ionic Reservoirs: The Interfacial Capacitance , 2001 .

[36]  L. Chernomordik,et al.  Voltage-induced nonconductive pre-pores and metastable single pores in unmodified planar lipid bilayer. , 2001, Biophysical journal.

[37]  R. Salvarezza,et al.  Electrodesorption Kinetics and Molecular Interactions in Well-Ordered Thiol Adlayers On Au(111) , 2000 .

[38]  Wanda Krassowska,et al.  Asymptotic model of electroporation , 1999 .

[39]  S. Kalinowski,et al.  Chronopotentiometric studies of electroporation of bilayer lipid membranes. , 1998, Biochimica et biophysica acta.

[40]  Bruce Cornell,et al.  Tethered Lipid Bilayer Membranes: Formation and Ionic Reservoir Characterization , 1998 .

[41]  B. Cornell,et al.  Kinetics of the competitive response of receptors immobilised to ion-channels which have been incorporated into a tethered bilayer. , 1998, Faraday discussions.

[42]  B. Cornell,et al.  A biosensor that uses ion-channel switches , 1997, Nature.

[43]  J. Weaver,et al.  Theory of electroporation of planar bilayer membranes: predictions of the aqueous area, change in capacitance, and pore-pore separation. , 1994, Biophysical journal.

[44]  James C. Weaver,et al.  Electroporation: a unified, quantitative theory of reversible electrical breakdown and mechanical rupture in artificial planar bilayer membranes☆ , 1991 .

[45]  A. Barnett,et al.  The current-voltage relation of an aqueous pore in a lipid bilayer membrane. , 1990, Biochimica et biophysica acta.

[46]  Alan Van Heuvelen,et al.  Intermediate physics for medicine and biology , 1989 .

[47]  L. Chernomordik,et al.  Reversible electrical breakdown of lipid bilayers: formation and evolution of pores. , 1988, Biochimica et biophysica acta.

[48]  V. F. Pastushenko,et al.  247 - Electric breakdown of bilayer lipid membranes II. Calculation of the membrane lifetime in the steady-state diffusion approximation , 1979 .

[49]  V. F. Pastushenko,et al.  Electric breakdown of bilayer lipid membranes , 1979 .

[50]  M. R. Tarasevich,et al.  246 - Electric breakdown of bilayer lipid membranes I. The main experimental facts and their qualitative discussion , 1979 .

[51]  J. Newman Resistance for Flow of Current to a Disk , 1966 .