Orientation-Dependent Protein Binding at Nanoparticle Interfaces

Ian Rouse; Nicolae-Viorel Buchete; Vigneshwari Karunakaran Annapoorani; Vladimir Lobaskin

arxiv: 2604.26086 · v2 · pith:S36F2K7Xnew · submitted 2026-04-28 · ⚛️ physics.bio-ph · physics.comp-ph

Orientation-Dependent Protein Binding at Nanoparticle Interfaces

Vigneshwari Karunakaran Annapoorani , Ian Rouse , Vladimir Lobaskin , Nicolae-Viorel Buchete This is my paper

Pith reviewed 2026-05-19 17:47 UTC · model grok-4.3

classification ⚛️ physics.bio-ph physics.comp-ph

keywords protein-nanoparticle interactionsmolecular dockingunited-atom modelsorientation heatmapsJensen-Shannon divergencesilica nanoparticlesprotein adsorptionallergen proteins

0 comments

The pith

Docking and united-atom models match protein orientations at nanoparticle surfaces

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

This paper combines coarse-grained united-atom models with molecular docking to characterize how proteins adsorb onto SiO2 nanoparticles in different orientations. They build heatmaps of binding propensity using polar and azimuthal angles for eight birch pollen allergen proteins and compare the distributions from the two methods using Jensen-Shannon divergence. Encouraging agreement is found in several cases, with suggestions for improving the approach such as better angular resolution. This creates a link between different ways of modeling protein-nanoparticle interfaces, which is useful for nanobiotechnology and drug delivery applications.

Core claim

The central claim is that orientation-resolved heatmaps from minimum UA adsorption energies and docking scores show encouraging agreement for several proteins as measured by Jensen-Shannon divergence, providing a quantitative bridge between coarse-grained energetics and docking outputs at protein-nanoparticle interfaces.

What carries the argument

Orientation-resolved heatmaps specifying relative protein-nanoparticle pose by polar and azimuthal angles with amplitude as binding propensity from minimum adsorption energy or docking score, compared using Jensen-Shannon divergence.

If this is right

This enables systematic comparison of binding geometries across models.
It supports improved predictive modeling of protein adsorption.
It offers mechanistic insight into binding landscapes.
It identifies limitations like the need for optimized angular resolution and iterative refinement of parameters.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

This framework could be tested on other nanoparticle types to see if the agreement holds.
Integrating with experimental orientation data would provide a direct test of the model's accuracy.
The approach may help in designing nanoparticles that bind proteins in specific orientations for therapeutic purposes.

Load-bearing premise

The minimum UA adsorption energy or docking score in each angular bin accurately reports binding propensity and Jensen-Shannon divergence reliably indicates the relation to Boltzmann-averaged energetics.

What would settle it

An experimental determination of the preferred orientations of one of the studied proteins when bound to SiO2 nanoparticles that can be directly compared to the computed distributions.

Figures

Figures reproduced from arXiv: 2604.26086 by Ian Rouse, Nicolae-Viorel Buchete, Vigneshwari Karunakaran Annapoorani, Vladimir Lobaskin.

**Figure 1.** Figure 1: Protein structures analyzed in this study. Eight birch pollen–related proteins are view at source ↗

**Figure 2.** Figure 2: Definition of protein–nanomaterial orientation. (A) A protein-fixed spherical coor view at source ↗

**Figure 3.** Figure 3: Docking-derived protein–nanoparticle interaction (PNI) map for view at source ↗

**Figure 4.** Figure 4: Comparison of docking-based and UAM PNI maps. For the eight birch pollen view at source ↗

**Figure 5.** Figure 5: Comparison of docking and UAM adsorption landscapes. For the eight proteins (see view at source ↗

**Figure 6.** Figure 6: Docking and UAM PNI maps for lysozyme – SiO view at source ↗

read the original abstract

Accurate quantification of protein-nanoparticle interactions is essential for applications in nanobiotechnology, nanomedicine, and drug delivery. Motivated by recent computational and experimental work, we combine coarse-grained united-atom (UA) models with molecular docking to characterize protein adsorption on SiO_2 nanoparticles. We construct orientation-resolved heatmaps in which polar and azimuthal angles uniquely specify the relative protein-nanoparticle pose, and the map amplitude reports binding propensity via the minimum UA adsorption energy or the docking score. Each angular bin corresponds to a distinct docked complex, enabling systematic comparison of binding geometries across models. To relate docking score landscapes to Boltzmann-averaged UA adsorption energetics, we analyze eight birch pollen allergen proteins previously studied experimentally. Similarity between the two orientational distributions is quantified using the Jensen-Shannon divergence (JSD). We find encouraging agreement between the two approaches in several cases, while also identifying limitations and routes for improvement, including optimized angular resolution and iterative refinement of interaction parameters. Overall, this framework provides a quantitative bridge between coarse-grained energetics and docking outputs at protein-nanoparticle interfaces, supporting improved predictive modeling and mechanistic insight into protein-nanoparticle binding landscapes.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper gives a workable angular heatmap method to compare UA adsorption minima with docking scores on SiO2 for eight allergens, but the comparison rests on per-bin minima rather than proper thermal averages.

read the letter

The main thing to know is that this work builds orientation heatmaps for protein-nanoparticle poses, using the lowest UA energy or docking score in each angular bin, then measures similarity with Jensen-Shannon divergence across eight birch pollen allergens on silica. They report encouraging agreement in several cases and note routes for refinement like better angular bins and parameter tuning. That combination of UA models, docking, and JSD on these specific proteins is the concrete new piece; it extends existing techniques into a side-by-side geometry comparison that was not already in the cited literature for this system. The execution is straightforward and the choice of JSD is reasonable for checking distribution overlap. They also tie the results back to proteins with some experimental context, which helps ground the claims. The central soft spot is exactly the one flagged in the stress test. Taking the single minimum energy per bin does not equal the Boltzmann-weighted integral over poses and translations inside that bin. Without that averaging or at least a check on bin-width sensitivity, the reported agreement could be inflated because both sides are using the same non-thermal proxy. The abstract gives no numbers or error bars, so the full figures and methods need to show whether they tested this or simply compared minima to minima. If the paper does not include those checks, the validation is weaker than it first appears. This is for people working on computational predictions of protein adsorption in nanomedicine or nanobiotech. A reader who already runs UA simulations or docking on nanoparticles would pick up a practical way to cross-check orientational preferences and could adapt the heatmap approach. It is coherent enough on its own terms to deserve a serious referee, even though the averaging issue will probably require revision. I would send it to review with a request that the authors either add the thermal averaging or demonstrate why the minimum is a sufficient proxy here.

Referee Report

2 major / 2 minor

Summary. The manuscript develops a framework combining coarse-grained united-atom (UA) models with molecular docking to generate orientation-resolved heatmaps of protein adsorption on SiO2 nanoparticles. For eight birch pollen allergen proteins, polar and azimuthal angles define poses, with bin amplitudes given by the minimum UA adsorption energy or docking score; Jensen-Shannon divergence (JSD) then quantifies similarity between the resulting orientational distributions, with the abstract reporting encouraging agreement in several cases and noting routes for improvement such as optimized angular resolution and iterative parameter refinement.

Significance. If the reported agreement survives proper thermal averaging, the work would supply a practical bridge between detailed UA energetics and rapid docking outputs, supporting mechanistic insight and predictive modeling for protein-nanoparticle interfaces in nanobiotechnology and drug delivery. The choice of experimentally studied proteins offers a potential external anchor, and the explicit use of an external statistical measure (JSD) between independently computed distributions avoids immediate circularity.

major comments (2)

[Abstract / Methods] Abstract and methods: The central claim to relate docking score landscapes to Boltzmann-averaged UA adsorption energetics is not supported by the reported procedure. The heatmaps use the single lowest (minimum) UA energy or docking score per angular bin rather than the bin partition function ∫ exp(−E/kT) dV dΩ over translations, fluctuations, and the solid angle of the bin. This minimum reports only the deepest point and does not equal the thermal propensity; no evidence is given that the authors performed the required averaging, corrected for bin volume, or tested sensitivity to bin width. Consequently the JSD values may reflect use of the same non-thermal proxy on both sides rather than a true validation.
[Results] Results: The abstract states “encouraging agreement” for several of the eight proteins yet supplies no quantitative JSD values, error estimates, data-exclusion criteria, or parameter choices. Without these numbers it is impossible to judge whether the similarity is statistically meaningful or merely qualitative.

minor comments (2)

[Methods] Clarify the precise definition of the angular bins (solid-angle normalization, overlap between neighboring bins) and state whether the same binning is applied to both UA and docking calculations.
[Results] Add a short table or figure caption listing the eight proteins, their experimental references, and the specific JSD values obtained for each.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for their careful reading and constructive comments, which help clarify the scope and limitations of our framework. We respond to each major comment below.

read point-by-point responses

Referee: [Abstract / Methods] Abstract and methods: The central claim to relate docking score landscapes to Boltzmann-averaged UA adsorption energetics is not supported by the reported procedure. The heatmaps use the single lowest (minimum) UA energy or docking score per angular bin rather than the bin partition function ∫ exp(−E/kT) dV dΩ over translations, fluctuations, and the solid angle of the bin. This minimum reports only the deepest point and does not equal the thermal propensity; no evidence is given that the authors performed the required averaging, corrected for bin volume, or tested sensitivity to bin width. Consequently the JSD values may reflect use of the same non-thermal proxy on both sides rather than a true validation.

Authors: We agree that the manuscript employs the minimum UA energy or docking score per angular bin as a proxy for orientational binding propensity rather than a full thermal average over the partition function within each bin. This choice prioritizes computational efficiency and focuses on the dominant low-energy poses for heatmap construction. We will revise the abstract and methods to explicitly state that the comparison uses these minimum-based proxies on both sides, remove or qualify the phrasing about direct relation to Boltzmann-averaged energetics, and add a brief discussion of the approximation along with a note on bin-width sensitivity. These changes will be incorporated in the revised manuscript. revision: yes
Referee: [Results] Results: The abstract states “encouraging agreement” for several of the eight proteins yet supplies no quantitative JSD values, error estimates, data-exclusion criteria, or parameter choices. Without these numbers it is impossible to judge whether the similarity is statistically meaningful or merely qualitative.

Authors: The results section of the manuscript reports the JSD values computed for each of the eight proteins together with the angular resolution and binning parameters employed. To improve accessibility, we will update the abstract to include representative quantitative JSD values for the cases of encouraging agreement, along with a concise statement of the key parameter choices. This revision will allow readers to assess the quantitative basis for the reported similarities. revision: yes

Circularity Check

0 steps flagged

No significant circularity; independent distributions compared via external metric

full rationale

The paper constructs orientation-resolved heatmaps separately from minimum UA adsorption energies and from docking scores, then quantifies similarity between the resulting distributions using Jensen-Shannon divergence. No load-bearing step reduces by construction to a fitted parameter, self-definition, or self-citation chain. The central comparison relies on two independently generated maps and an external statistical measure, making the derivation self-contained against external benchmarks.

Axiom & Free-Parameter Ledger

1 free parameters · 2 axioms · 0 invented entities

The approach rests on standard domain assumptions in molecular modeling without introducing new entities or heavily fitted parameters beyond typical interaction refinement.

free parameters (1)

interaction parameters
Abstract mentions iterative refinement of interaction parameters to improve agreement.

axioms (2)

domain assumption Coarse-grained united-atom models provide a reasonable approximation to protein adsorption energetics on nanoparticles
Used to compute minimum adsorption energy for each orientation.
domain assumption Docking scores can be interpreted as proxies for binding propensity in orientational space
Used to generate the second set of heatmaps for comparison.

pith-pipeline@v0.9.0 · 5746 in / 1431 out tokens · 58954 ms · 2026-05-19T17:47:25.912696+00:00 · methodology

Review history (2 revisions) →

discussion (0)

Lean theorems connected to this paper

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IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

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unclear
Relation between the paper passage and the cited Recognition theorem.

We construct orientation-resolved heatmaps in which polar and azimuthal angles uniquely specify the relative protein-nanoparticle pose, and the map amplitude reports binding propensity via the minimum UA adsorption energy or the docking score... Similarity between the two orientational distributions is quantified using the Jensen–Shannon divergence (JSD).

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

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work page 2004
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Orientation-dependent coarse- grained potentials derived by statis- tical analysis of molecular structural databases,

N. Buchete, J. Straub, and D. Thiru- malai, “Orientation-dependent coarse- grained potentials derived by statis- tical analysis of molecular structural databases,”Polymer, vol. 45, pp. 597– 608, 2004

work page 2004
[48]

Continuous anisotropic repre- sentation of coarse-grained potentials for proteins by spherical harmonics synthe- sis,

N. Buchete, J. Straub, and D. Thiru- malai, “Continuous anisotropic repre- sentation of coarse-grained potentials for proteins by spherical harmonics synthe- sis,”Journal of Molecular Graphics and Modelling, vol. 22, pp. 441–450, 2004

work page 2004
[49]

Anisotropic coarse-grained statistical potentials improve the ability to identify nativelike protein structures,

N. Buchete, J. Straub, and D. Thiru- malai, “Anisotropic coarse-grained statistical potentials improve the ability to identify nativelike protein structures,”The Journal of Chemical Physics, vol. 118, pp. 7658–7671, 2003

work page 2003
[50]

Development of novel statistical potentials for protein fold recognition,

N. Buchete, J. Straub, and D. Thiru- malai, “Development of novel statistical potentials for protein fold recognition,” Current Opinion in Structural Biology, vol. 14, pp. 225–232, 2004. 13 1 Supplemental Material: Orientation-Dependent Protein Binding at Nanoparticle Interfaces Vigneshwari Karunakaran Annapoorani1,2, Ian Rouse1,2, Vladimir Lobaskin1,2, N...

work page 2004

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Protein- nanoparticle interactions,

I. Lynch and K. Dawson, “Protein- nanoparticle interactions,”Nano Today, vol. 3, pp. 40–47, 2008

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Kinet- ics of the formation of a protein corona around nanoparticles,

V. Zhdanov and N.-J. Cho, “Kinet- ics of the formation of a protein corona around nanoparticles,”Mathe- matical Biosciences, vol. 282, pp. 82–90, 2016

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Un- derstanding protein-nanoparticle inter- actions leading to protein corona for- mation: In vitro - in vivo correlation study,

C. Marques, P. Maroni, L. Maurizi, O. Jordan, and G. Borchard, “Un- derstanding protein-nanoparticle inter- actions leading to protein corona for- mation: In vitro - in vivo correlation study,”International Journal of Biolog- ical Macromolecules, vol. 256, p. 128339, 2024

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A computational view on nanomaterial intrinsic and ex- trinsic features for nanosafety and sus- tainability,

G. Mancardi, A. Mikolajczyk, V. An- napoorani, A. Bahl, K. Blekos, J. Burkf, Y. C ¸ etin, K. Chairetakis, S. Dutta, L. Escorihuela,et al., “A computational view on nanomaterial intrinsic and ex- trinsic features for nanosafety and sus- tainability,”Materials Today, vol. 67, pp. 344–370, 2023

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Un- derstanding the nanoparticle–protein corona using methods to quantify ex- change rates and affinities of proteins for nanoparticles,

T. Cedervall, I. Lynch, S. Lindman, T. Bergg˚ ard, E. Thulin, H. Nilsson, K. A. Dawson, and S. Linse, “Un- derstanding the nanoparticle–protein corona using methods to quantify ex- change rates and affinities of proteins for nanoparticles,”Proceedings of the Na- tional Academy of Sciences, vol. 104, pp. 2050–2055, 2007

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Coarse master equations for binding kinetics of amyloid peptide dimers,

C. Leahy, R. Murphy, G. Hummer, E. Rosta, and N.-V. Buchete, “Coarse master equations for binding kinetics of amyloid peptide dimers,”The Journal of Physical Chemistry Letters, vol. 7, pp. 2676–2682, 2016

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Modelling bionano inter- actions and potential health risks for environmental nanoplastics: the case of functionalized polystyrene,

J. Subbotina, O. McElligott, and V. Lobaskin, “Modelling bionano inter- actions and potential health risks for environmental nanoplastics: the case of functionalized polystyrene,”Environ- mental Science: Nano, vol. 13, pp. 1568– 1587, 2026

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Multiscale physics-based in silico modelling of nanocarrier- assisted intravascular drug delivery,

N. Buchete, I. Cicha, S. Dutta, and P. Neofytou, “Multiscale physics-based in silico modelling of nanocarrier- assisted intravascular drug delivery,” Frontiers in Drug Delivery, vol. 4, p. 1362660, 2024

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Edito- rial: Modelling of intravascular drug de- livery using nanocarriers,

P. Neofytou and N.-V. Buchete, “Edito- rial: Modelling of intravascular drug de- livery using nanocarriers,”Frontiers in Drug Delivery, vol. 5, 2025

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Computer simulations of the dis- sociation mechanism of gleevec from abl kinase with milestoning,

B. Narayan, N.-V. Buchete, and R. El- ber, “Computer simulations of the dis- sociation mechanism of gleevec from abl kinase with milestoning,”The Jour- nal of Physical Chemistry B, vol. 125, pp. 5706–5715, 2021

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A hard- sphere model of protein corona for- mation on spherical and cylindrical nanoparticles,

I. Rouse and V. Lobaskin, “A hard- sphere model of protein corona for- mation on spherical and cylindrical nanoparticles,”Biophysical Journal, vol. 120, pp. 4457–4471, 2021

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Multiscale modelling of biomolecular corona formation on metal- lic surfaces,

P. Amini, I. Rouse, J. Subbotina, and V. Lobaskin, “Multiscale modelling of biomolecular corona formation on metal- lic surfaces,”Beilstein Journal of Nan- otechnology, vol. 15, pp. 215–229, 2024

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Modelling bionano inter- actions and potential health risks for environmental nanoplastics: the case of functionalized polystyrene,

J. Subbotina, O. McElligott, and V. Lobaskin, “Modelling bionano inter- actions and potential health risks for environmental nanoplastics: the case of functionalized polystyrene,”Environ- mental Science: Nano, 2026. 10

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Milk protein adsorption on metallic iron surfaces,

P. Mosaddeghi Amini, J. Subbotina, and V. Lobaskin, “Milk protein adsorption on metallic iron surfaces,”Nanomateri- als, vol. 13, p. 1857, 2023

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Computational modelling of bionano interface,

V. Lobaskin, J. Subbotina, and I. Rouse, “Computational modelling of bionano interface,”Europhysics Letters, vol. 143, p. 57001, 2023

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UA- NanoDock: A web-based UnitedAtom multiscale nanodocking tool for predict- ing protein adsorption onto nanoparti- cles,

J. Subbotina, P. Kolokathis, A. Tsouma- nis, N. Sidiropoulos, I. Rouse, I. Lynch, V. Lobaskin, and A. Afantitis, “UA- NanoDock: A web-based UnitedAtom multiscale nanodocking tool for predict- ing protein adsorption onto nanoparti- cles,”Journal of Chemical Information and Modeling, vol. 65, pp. 3142–3153, 2025

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Comp- SafeNano project: NanoInformatics approaches for safe-by-design nanoma- terials,

D. Zouraris, A. Mavrogiorgis, A. Tsoumanis, L. Saarim¨ aki, G. del Giu- dice, A. Federico, A. Serra, D. Greco, I. Rouse, J. Subbotina,et al., “Comp- SafeNano project: NanoInformatics approaches for safe-by-design nanoma- terials,”Computational and Structural Biotechnology Journal, vol. 29, pp. 13– 28, 2025

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In silico prediction of protein binding affinities onto core–shell PEGylated no- ble metal nanoparticles for rational de- sign of drug nanocarriers,

J. Subbotina, I. Rouse, and V. Lobaskin, “In silico prediction of protein binding affinities onto core–shell PEGylated no- ble metal nanoparticles for rational de- sign of drug nanocarriers,”Nanoscale, vol. 15, pp. 13371–13383, 2023

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Protein corona finger- printing predicts the cellular interaction of gold and silver nanoparticles,

C. Walkey, J. Olsen, F. Song, R. Liu, H. Guo, D. Olsen, Y. Cohen, A. Emili, and W. Chan, “Protein corona finger- printing predicts the cellular interaction of gold and silver nanoparticles,”ACS Nano, vol. 8, pp. 2439–2455, 2014

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Computational predic- tion and experimental analysis of the nanoparticle-protein corona: Showcas- ing an in vitro-in silico workflow provid- ing FAIR data,

I. Hasenkopf, R. Mills-Goodlet, L. John- son, I. Rouse, M. Geppert, A. Duschl, D. Maier, V. Lobaskin, I. Lynch, and M. Himly, “Computational predic- tion and experimental analysis of the nanoparticle-protein corona: Showcas- ing an in vitro-in silico workflow provid- ing FAIR data,”Nano Today, vol. 46, p. 101561, 2022

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Interactions of nanoparticles and biosystems: Microenvironment of nanoparticles and biomolecules in nanomedicine,

C. Aur´ ıa-Soro, T. Nesma, P. Juanes- Velasco, A. Landeira-Vi˜ nuela, H. Fidalgo-Gomez, V. Acebes- Fernandez, R. Gongora, M. Parra, R. Manzano-Roman, and M. Fuentes, “Interactions of nanoparticles and biosystems: Microenvironment of nanoparticles and biomolecules in nanomedicine,”Nanomaterials, vol. 9, p. 1365, 2019

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Structure and interac- tion of nanoparticle–protein complexes,

S. Kumar, I. Yadav, V. Aswal, and J. Kohlbrecher, “Structure and interac- tion of nanoparticle–protein complexes,” Langmuir, vol. 34, pp. 5679–5695, 2018

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Modelling and predicting the biological effects of nanomaterials,

D. Winkler, F. Burden, B. Yan, R. Weissleder, C. Tassa, S. Shaw, and V. Epa, “Modelling and predicting the biological effects of nanomaterials,”SAR and QSAR in Environmental Research, vol. 25, pp. 161–172, 2014

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A nanoinformatics decision support tool for the virtual screening of gold nanoparticle cellular association using protein corona fingerprints,

A. Afantitis, G. Melagraki, A. Tsouma- nis, E. Valsami-Jones, and I. Lynch, “A nanoinformatics decision support tool for the virtual screening of gold nanoparticle cellular association using protein corona fingerprints,”Nanotoxi- cology, vol. 12, pp. 1148–1165, 2018

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A semi-automated workflow for fair ma- turity indicators in the life sciences,

A. Ammar, S. Bonaretti, L. Winckers, J. Quik, M. Bakker, D. Maier, I. Lynch, J. van Rijn, and E. Willighagen, “A semi-automated workflow for fair ma- turity indicators in the life sciences,” Nanomaterials, vol. 10, p. 2068, 2020. 11

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Poly(ε-caprolactone)-based nanocom- posites: Influence of compatibilization on properties of poly(ε-caprolactone)- silica nanocomposites,

M. Avella, F. Bondioli, V. Can- nillo, E. Di Pace, M. Errico, A. Fer- rari, B. Focher, and M. Malinconico, “Poly(ε-caprolactone)-based nanocom- posites: Influence of compatibilization on properties of poly(ε-caprolactone)- silica nanocomposites,”Composites Sci- ence and Technology, vol. 66, pp. 886– 894, 2006

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Conformational dynamics of human IAPP monomers,

R. Murphy, J. Conlon, T. Mansoor, S. Luca, S. Vaiana, and N.-V. Buchete, “Conformational dynamics of human IAPP monomers,”Biophysical Chem- istry, vol. 167, pp. 1–7, 2012

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Nano- SolveIT project: Driving nanoinformat- ics research to develop innovative and integrated tools for in silico nanosafety assessment,

A. Afantitis, G. Melagraki, P. Isigonis, A. Tsoumanis, D. Varsou, E. Valsami- Jones, A. Papadiamantis, L. Ellis, H. Sarimveis, P. Doganis,et al., “Nano- SolveIT project: Driving nanoinformat- ics research to develop innovative and integrated tools for in silico nanosafety assessment,”Computational and Struc- tural Biotechnology Journal, vol. 18, pp. 583–602, 2020

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Patch- Dock and SymmDock: servers for rigid and symmetric docking,

D. Schneidman-Duhovny, Y. Inbar, R. Nussinov, and H. Wolfson, “Patch- Dock and SymmDock: servers for rigid and symmetric docking,”Nucleic Acids Research, vol. 33, pp. W363–W367, 2005

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Molecular docking, a tool to determine interaction of CuO and TiO2 nanoparticles with hu- man serum albumin,

S. Chibber and I. Ahmad, “Molecular docking, a tool to determine interaction of CuO and TiO2 nanoparticles with hu- man serum albumin,”Biochemistry and Biophysics Reports, vol. 6, pp. 63–67, 2016

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The need for improved methodology in protein corona analy- sis,

M. Mahmoudi, “The need for improved methodology in protein corona analy- sis,”Nature Communications, vol. 13, p. 49, 2022

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The interpre- tation of protein structures: Estimation of static accessibility,

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Multiscale modelling of bionano interface,

H. Lopez, E. Brandt, A. Mirzoev, D. Zhurkin, A. Lyubartsev, and V. Lobaskin, “Multiscale modelling of bionano interface,” inModelling the Toxicity of Nanoparticles(L. Tran, M. Ba˜ nares, and R. Rallo, eds.), pp. 173–206, Springer International Publishing, 2017

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Biophysical descriptors of nanoparticle protein coronas,

V. Karunakaran Annapoorani, S. Dutta, O. Ajia, O. Petrisor, V. Lobaskin, and N.-V. Buchete, “Biophysical descriptors of nanoparticle protein coronas,”The Journal of Physical Chemistry Letters, pp. 11356–11364, 2025

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A multiscale model of protein adsorption on a nanoparticle surface,

D. Power, I. Rouse, S. Poggio, E. Brandt, H. Lopez, A. Lyubart- sev, and V. Lobaskin, “A multiscale model of protein adsorption on a nanoparticle surface,”Modelling and Simulation in Materials Science and Engineering, vol. 27, p. 084003, 2019

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Coarse- grained model of adsorption of blood plasma proteins onto nanoparticles,

H. Lopez and V. Lobaskin, “Coarse- grained model of adsorption of blood plasma proteins onto nanoparticles,” The Journal of Chemical Physics, vol. 143, p. 243138, 2015

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Optimization of the additive CHARMM all-atom protein force field targeting improved sampling of the back- boneϕ,ψand side-chainχ 1 andχ 2 dihe- dral angles,

R. Best, X. Zhu, J. Shim, P. Lopes, J. Mittal, M. Feig, and A. MacK- erell, “Optimization of the additive CHARMM all-atom protein force field targeting improved sampling of the back- boneϕ,ψand side-chainχ 1 andχ 2 dihe- dral angles,”Journal of Chemical The- ory and Computation, vol. 8, pp. 3257– 3273, 2012

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Efficient unbound docking of rigid molecules,

D. Duhovny, R. Nussinov, and H. Wolf- son, “Efficient unbound docking of rigid molecules,” inProceedings of the 2nd 12 Workshop on Algorithms in Bioinfor- matics (WABI), pp. 185–200, Springer, 2002

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On the Jensen–Shannon symmetrization of distances relying on abstract means,

F. Nielsen, “On the Jensen–Shannon symmetrization of distances relying on abstract means,”Entropy, vol. 21, p. 485, 2019

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Similarity-based methods for word sense disambiguation,

I. Dagan, L. Lee, and F. Pereira, “Similarity-based methods for word sense disambiguation,” inProceedings of the 35th Annual Meeting of the As- sociation for Computational Linguistics and Eighth Conference of the European Chapter of the Association for Computa- tional Linguistics, Association for Com- putational Linguistics, 1997

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A new metric for probability distributions,

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A new class of metric divergences on probabil- ity spaces and its applicability in statis- tics,

F. ¨Osterreicher and I. Vajda, “A new class of metric divergences on probabil- ity spaces and its applicability in statis- tics,”Annals of the Institute of Statis- tical Mathematics, vol. 55, pp. 639–653, 2003

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Jensen- Shannon divergence and Hilbert space embedding,

B. Fuglede and F. Topsoe, “Jensen- Shannon divergence and Hilbert space embedding,” inProceedings of the In- ternational Symposium on Information Theory (ISIT), p. 31, 2004

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Y. Rubner, C. Tomasi, and L. Guibas, “A metric for distributions with appli- cations to image databases,” inPro- ceedings of the Sixth International Con- ference on Computer Vision (ICCV), pp. 59–66, 1998

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Biologic effects of nanoparticle-allergen conjugates: time- resolved uptake using an in vitro lung epithelial co-culture model of A549 and THP-1 cells,

B. Grotz, M. Geppert, R. Mills-Goodlet, S. Hofer, N. Hofst¨ atter, C. Asam, A. Feinle, K. Kocsis, T. Berger, O. Diwald,et al., “Biologic effects of nanoparticle-allergen conjugates: time- resolved uptake using an in vitro lung epithelial co-culture model of A549 and THP-1 cells,”Environmental Science: Nano, vol. 5, pp. 2184–2197, 2018

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Orientational potentials ex- tracted from protein structures improve native fold recognition,

N.-V. Buchete, J. Straub, and D. Thiru- malai, “Orientational potentials ex- tracted from protein structures improve native fold recognition,”Protein Sci- ence, vol. 13, pp. 862–874, 2004

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Orientation-dependent coarse- grained potentials derived by statis- tical analysis of molecular structural databases,

N. Buchete, J. Straub, and D. Thiru- malai, “Orientation-dependent coarse- grained potentials derived by statis- tical analysis of molecular structural databases,”Polymer, vol. 45, pp. 597– 608, 2004

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Continuous anisotropic repre- sentation of coarse-grained potentials for proteins by spherical harmonics synthe- sis,

N. Buchete, J. Straub, and D. Thiru- malai, “Continuous anisotropic repre- sentation of coarse-grained potentials for proteins by spherical harmonics synthe- sis,”Journal of Molecular Graphics and Modelling, vol. 22, pp. 441–450, 2004

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Anisotropic coarse-grained statistical potentials improve the ability to identify nativelike protein structures,

N. Buchete, J. Straub, and D. Thiru- malai, “Anisotropic coarse-grained statistical potentials improve the ability to identify nativelike protein structures,”The Journal of Chemical Physics, vol. 118, pp. 7658–7671, 2003

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Development of novel statistical potentials for protein fold recognition,

N. Buchete, J. Straub, and D. Thiru- malai, “Development of novel statistical potentials for protein fold recognition,” Current Opinion in Structural Biology, vol. 14, pp. 225–232, 2004. 13 1 Supplemental Material: Orientation-Dependent Protein Binding at Nanoparticle Interfaces Vigneshwari Karunakaran Annapoorani1,2, Ian Rouse1,2, Vladimir Lobaskin1,2, N...

work page 2004