Designing Nanostructured Ti<sub>6</sub>Al<sub>4</sub>V Bioactive Interfaces with Directed Irradiation Synthesis toward Cell Stimulation to Promote Host–Tissue-Implant Integration

Civantos, Ana; Barnwell, Alethia; Shetty, Akshath R.; Pavón, Juan José; El-Atwani, Osman; Arias, Sandra L.; Lang, Eric; Reece, Lisa M.; Chen, Michael; Allain, Jean Paul

doi:10.1021/acsbiomaterials.9b00469

Cited by 14 publications

(31 citation statements)

References 68 publications

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“…Furthermore, the orientation and symmetry of these patterns often shows a pronounced dependence on temperature [92]. For polycrystalline surfaces, these effects may result in different orientations of the nanopatterns obtained on different grains [93]. Similar crystallinityrelated effects may also be observed for certain amorphizable materials such as Si or Ge at high temperatures, where the ion-induced damage to the crystal lattice is dynamically annealed during sputtering [56].…”

Section: Amorphous Amorphizable and Crystalline Surfacesmentioning

confidence: 85%

“…Nanopatterned Ti6Al4V surfaces were also produced by Civantos et al using 1 keV Ar + irradiation at various incident angles [93]. At normal and oblique, non-grazing incidence, surface topographies similar to those described by Riedel et al [126] were obtained, i.e., sub-100 nm ripple patterns with different orientations on different grains.…”

Section: Mammalian Tissue Cellsmentioning

confidence: 92%

“…Nevertheless, small patterns with periodicities below 100 nm and peak-to-peak amplitudes down to the sub-nanometer level have also been shown to induce significant changes in cell morphology. This in particular concerns the density, length, and alignment of cell extensions such as filopodia [89,93]. This in combination with the fact that ion beam surface modification is a well-established and scalable technology suitable for the processing of large surface areas makes ion beam nanopatterning a promising method for tissue engineering applications.…”

Section: Bacteriamentioning

confidence: 99%

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Ion Beam Nanopatterning of Biomaterial Surfaces

Yang

Keller

2021

Applied Sciences

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Ion beam irradiation of solid surfaces may result in the self-organized formation of well-defined topographic nanopatterns. Depending on the irradiation conditions and the material properties, isotropic or anisotropic patterns of differently shaped features may be obtained. Most intriguingly, the periodicities of these patterns can be adjusted in the range between less than twenty and several hundred nanometers, which covers the dimensions of many cellular and extracellular features. However, even though ion beam nanopatterning has been studied for several decades and is nowadays widely employed in the fabrication of functional surfaces, it has found its way into the biomaterials field only recently. This review provides a brief overview of the basics of ion beam nanopatterning, emphasizes aspects of particular relevance for biomaterials applications, and summarizes a number of recent studies that investigated the effects of such nanopatterned surfaces on the adsorption of biomolecules and the response of adhering cells. Finally, promising future directions and potential translational challenges are identified.

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Section: Amorphous Amorphizable and Crystalline Surfacesmentioning

confidence: 85%

Section: Mammalian Tissue Cellsmentioning

confidence: 92%

Section: Bacteriamentioning

confidence: 99%

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Ion Beam Nanopatterning of Biomaterial Surfaces

Yang

Keller

2021

Applied Sciences

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“…DIS experiments were performed at the Radiation Surface Science and Engineering Laboratory (RSSEL) in the School of Nuclear Engineering, Purdue University, in the Particle and Radiation Interaction with Soft and Hard Matter (PRIHSM) facility, originally developed and operated by Prof. Jean Paul Allain at Purdue University [27]. DIS conditions are summarized in Table 1; Energy, fluence, and incidence angle were chosen after an exhaustive revision of our previous DIS nano-structuring results on metallic materials [33,34], as well as from some other revised works on Ti, TiO 2 , Cu, Au, and Ag [35][36][37][38][39][40][41][42][43][44][45]. Argon (Ar + ) source at 1 and 0.5 keV was used to irradiate PPS samples and NPS; the selection of DIS parameters were designed to evaluate their effect on nanopatterning.…”

Section: Directed Irradiation Synthesis (Dis) Of Porous and Non-poroumentioning

confidence: 99%

“…Afterwards, the fluorescence signal was read in a microplate reader (Biotek, Synergy) and the results were expressed as relative fluorescence units using c.p. Ti as a control surface for the PPS1 # and PPS1 samples following the method described in a previous work [33]. At 24 h, cytotoxic experiments were performed using The Comet Assay ® (cat.…”

Section: Biological Evaluation Of Cp Ti Samples Modified By Dismentioning

confidence: 99%

Directed Irradiation Synthesis as an Advanced Plasma Technology for Surface Modification to Activate Porous and “as-received” Titanium Surfaces

Civantos

Allain

Pavón

et al. 2019

Metals

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For the design of smart titanium implants, it is essential to balance the surface properties without any detrimental effect on the bulk properties of the material. Therefore, in this study, an irradiation-driven surface modification called directed irradiation synthesis (DIS) has been developed to nanopattern porous and “as-received” c.p. Ti surfaces with the aim of improving cellular viability. Nanofeatures were developed using singly-charged argon ions at 0.5 and 1.0 keV energies, incident angles from 0° to 75° degrees, and fluences up to 5.0 × 1017 cm−2. Irradiated surfaces were evaluated by scanning electron microscopy, atomic force microscopy and contact angle, observing an increased hydrophilicity (a contact angle reduction of 73.4% and 49.3%) and a higher roughness on both surfaces except for higher incident angles, which showed the smoothest surface. In-vitro studies demonstrated the biocompatibility of directed irradiation synthesis (DIS) reaching 84% and 87% cell viability levels at 1 and 7 days respectively, and a lower percentage of damaged DNA in tail compared to the control c.p. Ti. All these results confirm the potential of the DIS technique to modify complex surfaces at the nanoscale level promoting their biological performance.

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Nanotextured porous titanium scaffolds by argon ion irradiation: Toward conformal nanopatterning and improved implant osseointegration

Civantos

Restrepo

Torres

et al. 2023

J Biomedical Materials Res

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Stress shielding and osseointegration are two main challenges in bone regeneration, which have been targeted successfully by chemical and physical surface modification methods. Direct irradiation synthesis (DIS) is an energetic ion irradiation method that generates self‐organized nanopatterns conformal to the surface of materials with complex geometries (e.g., pores on a material surface). This work exposes porous titanium samples to energetic argon ions generating nanopatterning between and inside pores. The unique porous architected titanium (Ti) structure is achieved by mixing Ti powder with given amounts of spacer NaCl particles (vol % equal to 30%, 40%, 50%, 60%, and 70%), compacted and sintered, and combined with DIS to generate a porous Ti with bone‐like mechanical properties and hierarchical topography to enhance Ti osseointegration. The porosity percentages range between 25% and 30% using 30 vol % NaCl space‐holder (SH) volume percentages to porosity rates of 63%–68% with SH volume of 70 vol % NaCl. Stable and reproducible nanopatterning on the flat surface between pores, inside pits, and along the internal pore walls are achieved, for the first time on any porous biomaterial. Nanoscale features were observed in the form of nanowalls and nanopeaks of lengths between 100 and 500 nm, thicknesses of 35‐nm and heights between 100 and 200 nm on average. Bulk mechanical properties that mimic bone‐like structures were observed along with increased wettability (by reducing contact values). Nano features were cell biocompatible and enhanced in vitro pre‐osteoblast differentiation and mineralization. Higher alkaline phosphatase levels and increased calcium deposits were observed on irradiated 50 vol % NaCl samples at 7 and 14 days. After 24 h, nanopatterned porous samples decreased the number of attached macrophages and the formation of foreign body giant cells, confirming nanoscale tunability of M1–M2 immuno‐activation with enhanced osseointegration.

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Designing Nanostructured Ti₆Al₄V Bioactive Interfaces with Directed Irradiation Synthesis toward Cell Stimulation to Promote Host–Tissue-Implant Integration

Cited by 14 publications

References 68 publications

Ion Beam Nanopatterning of Biomaterial Surfaces

Ion Beam Nanopatterning of Biomaterial Surfaces

Directed Irradiation Synthesis as an Advanced Plasma Technology for Surface Modification to Activate Porous and “as-received” Titanium Surfaces

Nanotextured porous titanium scaffolds by argon ion irradiation: Toward conformal nanopatterning and improved implant osseointegration

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Designing Nanostructured Ti6Al4V Bioactive Interfaces with Directed Irradiation Synthesis toward Cell Stimulation to Promote Host–Tissue-Implant Integration

Cited by 14 publications

References 68 publications

Ion Beam Nanopatterning of Biomaterial Surfaces

Ion Beam Nanopatterning of Biomaterial Surfaces

Directed Irradiation Synthesis as an Advanced Plasma Technology for Surface Modification to Activate Porous and “as-received” Titanium Surfaces

Nanotextured porous titanium scaffolds by argon ion irradiation: Toward conformal nanopatterning and improved implant osseointegration

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Designing Nanostructured Ti₆Al₄V Bioactive Interfaces with Directed Irradiation Synthesis toward Cell Stimulation to Promote Host–Tissue-Implant Integration