Three-layer dielectric models for generalized Coulomb potential calculation in ellipsoidal geometry

Xue, Changfeng; Deng, Shuiquan

doi:10.1103/physreve.83.056709

Cited by 5 publications

(8 citation statements)

References 33 publications

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“…or a similar form if ||r|| < ||r ′ || (see, e.g., 8 ). The normal derivative at the ellipsoid surface defined by λ = a is computed as 21…”

Section: Ellipsoidal Harmonicsmentioning

confidence: 99%

“…Our implementations, written in Python and MATLAB 6 , employ a variety of insights developed over more than a century of research 1,7,8 ; many important results were published during the mid-19th century and early 20th by greats like Heine 9 , and Charles Darwin's son Sir George Howard Darwin 10 . From the authors' perspective, these surprisingly direct ties to mathematical history offer an unusual and inspiring aspect to their study.…”

Section: Introductionmentioning

confidence: 99%

“…Unsurprisingly, the more general shape allows ellipsoidal-harmonic expansions to be more accurate than ones based on spherical harmonics 7,12,13 . Successful applications cover most of potential theory: gravity 7,10 , electrostatics 8,[14][15][16][17][18] , electromagnetics 19-22 , hydrodynamics 23-26 , and elasticity 27 . Specific uses in molecular and biological sciences include solving the Schrödinger equation 28 , modeling van der Waals (close packing) interactions between molecules 12 , design of magnetic resonance imaging (MRI) devices 29 and analysis of clinical electroencephalography (EEG) and magnetoencephalography (MEG) data 21,22 .…”

Section: Introductionmentioning

confidence: 99%

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Computational science and re-discovery: open-source implementation of ellipsoidal harmonics for problems in potential theory

Bardhan

Knepley

2012

Comput. Sci. Disc.

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We present two open-source (BSD) implementations of ellipsoidal harmonic expansions for solving problems of potential theory using separation of variables. Ellipsoidal harmonics are used surprisingly infrequently, considering their substantial value for problems ranging in scale from molecules to the entire solar system. In this article, we suggest two possible reasons for the paucity relative to spherical harmonics. The first is essentially historical-ellipsoidal harmonics developed during the late 19th century and early 20th, when it was found that only the lowest-order harmonics are expressible in closed form. Each higher-order term requires the solution of an eigenvalue problem, and tedious manual computation seems to have discouraged applications and theoretical studies. The second explanation is practical: even with modern computers and accurate eigenvalue algorithms, expansions in ellipsoidal harmonics are significantly more challenging to compute than those in Cartesian or spherical coordinates. The present implementations reduce the "barrier to entry" by providing an easy and free way for the community to begin using ellipsoidal harmonics in actual research. We demonstrate our implementation using the specific and physiologically crucial problem of how charged proteins interact with their environment, and ask: what other analytical tools await re-discovery in an era of inexpensive computation?

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“…or a similar form if ||r|| < ||r ′ || (see, e.g., 8 ). The normal derivative at the ellipsoid surface defined by λ = a is computed as 21…”

Section: Ellipsoidal Harmonicsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Computational science and re-discovery: open-source implementation of ellipsoidal harmonics for problems in potential theory

Bardhan

Knepley

2012

Comput. Sci. Disc.

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“…Semi-analytical series solutions in terms of ellipsoidal harmonics can be easily found [57], but unfortunately, they are too complicated to be used in actual biomolecular dynamics simulations. Therefore, in the same spirit as what we have done for the prolate spheroidal case, we propose the following single image approximation for the reaction field Φ RF inside the ellipsoid

{boldR}_{ind} = \frac{F_{0}^{1} (ξ_{normalb})}{F_{0}^{1} (ξ_{normals})} true(\frac{F_{1}^{1} (ξ_{normals}) E_{1}^{1} (ξ_{normalb})}{F_{1}^{1} (ξ_{normalb}) E_{1}^{1} (ξ_{normals})} x_{normals}, \frac{F_{1}^{2} (ξ_{normals}) E_{1}^{2} (ξ_{normalb})}{F_{1}^{2} (ξ_{normalb}) E_{1}^{2} (ξ_{normals})} y_{normals}, \frac{F_{1}^{3} (ξ_{normals}) E_{1}^{3} (ξ_{normalb})}{F_{1}^{3} (ξ_{normalb}) E_{1}^{3} (ξ_{normals})} z_{normals} true) .

Similarly, this image approximation has two sources of errors.…”

Section: The Generalized Image Charge Solvation Modelmentioning

confidence: 99%

Generalized image charge solvation model for electrostatic interactions in molecular dynamics simulations of aqueous solutions

Deng

Xue

Baumketner

et al. 2013

Journal of Computational Physics

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This paper extends the image charge solvation model (ICSM) [J. Chem. Phys. 131, 154103 (2009)], a hybrid explicit/implicit method to treat electrostatic interactions in computer simulations of biomolecules formulated for spherical cavities, to prolate spheroidal and triaxial ellipsoidal cavities, designed to better accommodate non-spherical solutes in molecular dynamics (MD) simulations. In addition to the utilization of a general truncated octahedron as the MD simulation box, central to the proposed extension is an image approximation method to compute the reaction field for a point charge placed inside such a non-spherical cavity by using a single image charge located outside the cavity. The resulting generalized image charge solvation model (GICSM) is tested in simulations of liquid water, and the results are analyzed in comparison with those obtained from the ICSM simulations as a reference. We find that, for improved computational efficiency due to smaller simulation cells and consequently a less number of explicit solvent molecules, the generalized model can still faithfully reproduce known static and dynamic properties of liquid water at least for systems considered in the present paper, indicating its great potential to become an accurate but more efficient alternative to the ICSM when bio-macromolecules of irregular shapes are to be simulated.

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“…We can repeat the procedure above for ellipsoids, so that the Coulomb and reaction potentials are expanded in the internal ellipsoidal harmonics

E_{n}^{m} false(boldr false)

, and the solvent potential is expanded in the external ellipsoidal harmonics

F_{n}^{m} false(boldr false)

. The exact boundary conditions are 88 :

\frac{C_{n}^{m}}{ε_{protein}} + R_{n}^{m} \frac{E_{n}^{m} false(a false)}{F_{n}^{m} false(a false)} = S_{n}^{m}

\frac{C_{n}^{m}}{ε_{water}} + R_{n}^{m} \frac{ε_{protein}}{ε_{water}} \frac{1 \frac{\partial E_{n}^{m} (λ)}{\partial λ} ∣_{a}}{1 \frac{\partial F_{n}^{m} (λ)}{\partial λ} ∣_{a}} = S_{n}^{m}

where the integer pair ( n , m ) identifies a single harmonic just as for spherical harmonics, the functions

E_{n}^{m} false(λ false)

and

F_{n}^{m} false(λ false)

are the first-kind and second-kind Lamè functions for that harmonic, and the argument a is the ellipsoid’s longest semi-axis. To derive a BIBEE model in ellipsoidal harmonics, we perform a similar procedure of considering the modified boundary condition as was done for the sphere.…”

Section: Theorymentioning

confidence: 99%

Analysis of fast boundary-integral approximations for modeling electrostatic contributions of molecular binding

Kreienkamp¹,

Liu²,

Minkara³

et al. 2013

Computational and Mathematical Biophysics

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We analyze and suggest improvements to a recently developed approximate continuum-electrostatic model for proteins. The model, called BIBEE/I (boundary-integral based electrostatics estimation with interpolation), was able to estimate electrostatic solvation free energies to within a mean unsigned error of 4% on a test set of more than 600 proteins—a significant improvement over previous BIBEE models. In this work, we tested the BIBEE/I model for its capability to predict residue-by-residue interactions in protein–protein binding, using the widely studied model system of trypsin and bovine pancreatic trypsin inhibitor (BPTI). Finding that the BIBEE/I model performs surprisingly less well in this task than simpler BIBEE models, we seek to explain this behavior in terms of the models’ differing spectral approximations of the exact boundary-integral operator. Calculations of analytically solvable systems (spheres and tri-axial ellipsoids) suggest two possibilities for improvement. The first is a modified BIBEE/I approach that captures the asymptotic eigenvalue limit correctly, and the second involves the dipole and quadrupole modes for ellipsoidal approximations of protein geometries. Our analysis suggests that fast, rigorous approximate models derived from reduced-basis approximation of boundary-integral equations might reach unprecedented accuracy, if the dipole and quadrupole modes can be captured quickly for general shapes.

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Three-layer dielectric models for generalized Coulomb potential calculation in ellipsoidal geometry

Cited by 5 publications

References 33 publications

Computational science and re-discovery: open-source implementation of ellipsoidal harmonics for problems in potential theory

Computational science and re-discovery: open-source implementation of ellipsoidal harmonics for problems in potential theory

Generalized image charge solvation model for electrostatic interactions in molecular dynamics simulations of aqueous solutions

Analysis of fast boundary-integral approximations for modeling electrostatic contributions of molecular binding

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