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Abstract

The success of orthopedic implants depends on the sufficient integration between tissue and implant, which is influenced by the cellular responses to their microenvironment. The conformation of adsorbed extracellular matrix is crucial for cellular behavior instruction via manipulating the physiochemical features of materials. To investigate the electrostatic adsorption mechanism of fibronectin on nanotopographies, a theoretical model was established to determine surface charge density and Coulomb’s force of nanotopography – fibronectin interactions using a Laplace equation satisfying the boundary conditions. Surface charge density distribution of nanotopographies with multiple random fibronectin was simulated based on random number and Monte Carlo hypothesis. The surface charge density on the nanotopographies was compared to the experimental measurements, to verify the effectiveness of the theoretical model. The model was implemented to calculate the Coulomb force generated by nanotopographies to compare the fibronectin adsorption. This model has revealed the multiple random quantitative fibronectin electrostatic adsorption to the nanotopographies, which is beneficial for orthopedic implant surface design.

Significance: The conformation and distribution of adsorbed extracellular matrix on biomedical implants are crucial for directing cellular behaviors. However, the Ti nanotopography-ECM interaction mechanism remains largely unknown. This is mostly because of the interactions that are driven by electrostatic force, and any experimental probe could interfere with the electric field between the charged protein and Ti surface. A theoretical model is hereby proposed to simulate the adsorption between nanotopographies and fibronectin. Random number and Monte Carlo hypothesis were applied for multiple random fibronectin simulation, and the Coulomb’s force between nanoconvex and nanoconcave structures was comparatively analyzed.

Graphical abstract

In the macroscale, the combination between bone tissue and implant is dominated by the cellular responses to their microenvironment, which are initially influenced by the cell – extracellular matrix (ECM) interactions. The ECM adsorption on nanoscale Ti-topography is dominated by the Coulomb’s force, we proposed a theoretical model to simulate multiple random fibronectin adsorption.

Keywords

Nanotopography Coulomb’s force charge density protein adsorption bone implant interface

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References

Lin

Yang

Lai

, et al. Orthopedic implant biomaterials with both osteogenic and anti-infection capacities and associated in vivo evaluation methods. Nanomedicine 2017; 13(1): 123–142.

Wang

Ouyang

Poh

. Orthopaedic implant technology: biomaterials from past to future. Ann Acad Med Singap 2011; 40(5): 237–244.

Arciola

Campoccia

Montanaro

. Implant infections: adhesion, biofilm formation and immune evasion. Nat Rev Microbiol 2018; 16(7): 397–409.

Tomizawa

Ishikawa

Bello-Irizarry

, et al. Biofilm producing Staphylococcus epidermidis (RP62A strain) inhibits osseous integration without osteolysis and histopathology in a murine septic implant model. J Orthop Res 2020; 38(4): 852–860.

Fernandez-Yague

Abbah

McNamara

, et al. Biomimetic approaches in bone tissue engineering: integrating biological and physicomechanical strategies. Adv Drug Deliv Rev 2015; 84: 1–29.

Wang

Wen

Hodgson

, et al. Biocompatibility of TiO₂ nanotubes with different topographies. J Biomed Mater Res 2014; 102(3): 743–751.

Florea

Albuleà

Grumezescu

, et al. Surface modification – a step forward to overcome the current challenges in orthopedic industry and to obtain an improved osseointegration and antimicrobial properties. Mater Chem Phys 2020; 243: 122579.

Devgan

Sidhu

. Evolution of surface modification trends in bone related biomaterials: a review. Mater Chem Phys 2019; 233: 68–78.

Luo

Tamaddon

Yan

, et al. Improving the fretting biocorrosion of Ti₆Al₄V alloy bone screw by decorating structure optimised TiO₂ nanotubes layer. J Mater Sci Technol 2020; 49: 47–55.

10.

Luo

Ajami

, et al. Growth of TiO₂ nanotube on titanium substrate to enhance its biotribological performance and biocorrosion resistance. J Bionic Eng 2019; 16: 1039–1051.

11.

Rockwell

Lohstreter

Dahn

. Fibrinogen and albumin adsorption on titanium nanoroughness gradients. Colloids Surf B Biointerfaces 2012; 91: 90–96.

12.

Hoyos-Nogués

Velasco

Ginebra

, et al. Regenerating bone via multifunctional coatings: the blending of cell integration and bacterial inhibition properties on the surface of biomaterials. ACS Appl Mater Interfaces 2017; 9(26): 21618–21630.

13.

Luo

Walker

Xiao

, et al. The influence of nanotopography on cell behaviour through interactions with the extracellular matrix - a review. Bioact Mater 2022; 15: 145–159.

14.

Anselme

. Osteoblast adhesion on biomaterials. Biomaterials 2000; 21(7): 667–681.

15.

Jung

Bohner

Hanisch

, et al. Influence of implant material and surface on mode and strength of cell/matrix attachment of human adipose derived stromal cell. Int J Mol Sci 2020; 21(11): 4110.

16.

Raines

Berger

Schwartz

, et al. Osteoblasts grown on microroughened titanium surfaces regulate angiogenic growth factor production through specific integrin receptors. Acta Biomater 2019; 97: 578–586.

17.

García

Vega

Boettiger

. Modulation of cell proliferation and differentiation through substrate-dependent changes in fibronectin conformation. Mol Biol Cell 1999; 10(3): 785–798.

18.

Keselowsky

García

. Surface chemistry modulates integrin binding to direct cell adhesion and function. In: Transactions of the 7th world biomaterials congress, 2004, p.369.

19.

Hasan

Pandey

. Surface modification of Ti6Al4V by forming hybrid self-assembled monolayers and its effect on collagen-I adsorption, osteoblast adhesion and integrin expression. Appl Surf Sci 2020; 505: 144611.

20.

Chang

Kao

You

, et al. Effect of surface potential on epithelial cell adhesion, proliferation and morphology. Colloids Surf B Biointerfaces 2016; 141: 179–186.

21.

Attwood

Kershaw

Uddin

, et al. Understanding how charge and hydrophobicity influence globular protein adsorption to alkanethiol and material surfaces. J Mater Chem B 2019; 7(14): 2349–2361.

22.

Metwally

Stachewicz

. Surface potential and charges impact on cell responses on biomaterials interfaces for medical applications. Mater Sci Eng C 2019; 104: 109883.

23.

Liu

Yeung

KWK

, et al. Surface nano-architectures and their effects on the mechanical properties and corrosion behavior of Ti-based orthopedic implants. Surf Coat Technol 2013; 233: 13–26.

24.

Stevens

George

. Exploring and engineering the cell surface interface. Science 2005; 310(5751): 1135–1138.

25.

Perrotti

Palmieri

Pellati

, et al. Effect of titanium surface topographies on human bone marrow stem cells differentiation in vitro. Odontology 2013; 101(2): 133–139.

26.

Hartvig

van de Weert

Østergaard

, et al. Protein adsorption at charged surfaces: the role of electrostatic interactions and interfacial charge regulation. Langmuir 2011; 27(6): 2634–2643.

27.

Kabaso

Gongadze

Perutková

, et al. Mechanics and electrostatics of the interactions between osteoblasts and titanium surface. Comput Methods Biomech Biomed Eng 2011; 14(5): 469–482.

28.

Wang

Yan

Qiao

. Protein adsorption on implant metals with various deformed surfaces. Colloids Surf B Biointerfaces 2017; 156: 62–70.

29.

Gessner

Lieske

Paulke

, et al. Influence of surface charge density on protein adsorption on polymeric nanoparticles: analysis by two-dimensional electrophoresis. Eur J Pharm Biopharm 2002; 54(2): 165–170.

30.

Luo

Zhao

Gao

, et al. TiO₂ nanotopography-driven osteoblast adhesion through Coulomb’s force evolution. ACS Appl Mater Interfaces 2022; 14(30): 34400–34414.

31.

Hlady

Buijs

. Protein adsorption on solid surfaces. Curr Opin Biotechnol 1996; 7(1): 72–77.

32.

Asthagiri

Lenhoff

. Influence of structural details in modeling electrostatically driven protein adsorption. Langmuir 1997; 13(25): 6761–6768.

33.

Gongadze

Kabaso

Bauer

, et al. Adhesion of osteoblasts to a nanorough titanium implant surface. Int J Nanomedicine 2011; 6: 1801–1816.

34.

Canpolat

Tatlisoz

. Size-dependent protein adsorption on a nanoparticle. IEEE Trans Nanobioscience 2023; 22: 597–602.

35.

Atif

La Cis

Engqvist

, et al. Experimental characterization and mathematical modeling of the adsorption of proteins and cells on biomimetic hydroxyapatite. ACS Omega 2022; 7(1): 908–920.

36.

Ercan

Khang

Carpenter

, et al. Using mathematical models to understand the effect of nanoscale roughness on protein adsorption for improving medical devices. Int J Nanomedicine 2013; 8Suppl 1: 75–81.

37.

Canpolat

Tatlisoz

. Protein adsorption on a nanoparticle with a nanostructured surface. Electrophoresis 2022; 43: 2324–2333.

38.

Lubarsky

Browne

Mitchell

, et al. The influence of electrostatic forces on protein adsorption. Colloids Surf B Biointerfaces 2005; 44(1): 56–63.

39.

Park

Bauer

von der Mark

, et al. Nanosize and vitality: TiO₂ nanotube diameter directs cell fate. Nano Lett 2007; 7(6): 1686–1691.

40.

Park

Bauer

Schmuki

, et al. Narrow window in nanoscale dependent activation of endothelial cell growth and differentiation on TiO₂ nanotube surfaces. Nano Lett 2009; 9(9): 3157–3164.

41.

Brammer

Cobb

, et al. Improved bone-forming functionality on diameter-controlled TiO₂ nanotube surface. Acta Biomater 2009; 5(8): 3215–3223.

42.

Park

Bauer

Schlegel

, et al. TiO₂ nanotube surfaces: 15 nm—an optimal length scale of surface topography for cell adhesion and differentiation. Small 2009; 5(6): 666–671.

43.

Gongadze

Kabaso

Bauer

, et al. Adhesion of osteoblasts to a vertically aligned TiO2 nanotube surface. Mini-Rev Med Chem 2013; 13(2): 194–200.

44.

Barberi

Spriano

. Titanium and protein adsorption: an overview of mechanisms and effects of surface features. Materials 2021; 14: 1590.

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Theoretical modeling approach for adsorption of fibronectin on the nanotopographical implants

Abstract

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