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

Civantos, Ana; Allain, Jean Paul; Pavón, Juan José; Shetty, Akshath R.; El-Atwani, Osman; Walker, Emily; Arias, Sandra L.; Gordon, Emily K.; Rodríguez-Ortiz, José Antonio; Chen, Mike Y.; Torres, Yadir

doi:10.3390/met9121349

Cited by 8 publications

(7 citation statements)

References 55 publications

(73 reference statements)

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“…Other authors have used femtosecond laser [103,104] or directed irradiation synthesis (DIS) [105,106] techniques to obtain micro-and nano-textured surfaces of titanium implants to improve osseointegration by the replication of bone structures, increasing protein attachment and therefore cell adhesion.…”

Section: Laser Ablationmentioning

confidence: 99%

Latest Trends in Surface Modification for Dental Implantology: Innovative Developments and Analytical Applications

et al. 2022

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An increase in the world population and its life expectancy, as well as the ongoing concern about our physical appearance, have elevated the relevance of dental implantology in recent decades. Engineering strategies to improve the survival rate of dental implants have been widely investigated, focusing on implant material composition, geometry (usually guided to reduce stiffness), and interface surrounding tissues. Although efforts to develop different implant surface modifications are being applied in commercial dental prostheses today, the inclusion of surface coatings has gained special interest, as they can be tailored to efficiently enhance osseointegration, as well as to reduce bacterial-related infection, minimizing peri-implantitis appearance and its associated risks. The use of biomaterials to replace teeth has highlighted the need for the development of reliable analytical methods to assess the therapeutic benefits of implants. This literature review considers the state-of-the-art strategies for surface modification or coating and analytical methodologies for increasing the survival rate for teeth restoration.

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Section: Laser Ablationmentioning

confidence: 99%

Latest Trends in Surface Modification for Dental Implantology: Innovative Developments and Analytical Applications

et al. 2022

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“…On the other hand, the inherent roughness to pore wall (increase of surface contact) and surface free energy, are both considered key factors for cell adhesion, migration and differentiation [32] while inhibiting the bacterial attachment and biofilm formation [33,34]. In this context, many reports have shown the interaction between roughness and cellular response and how the microstructure and nanostructure [35] can interfere and modulate cellular adhesion, spreading and differentiation of mesenchymal stem cells [36], osteoblasts [37,38], macrophages [39,40] and osteoclast [41]. The vast majority of surface modification treatments are based on the micro and submicron scale roughness development but recently the nanotopography architecture has shown an important role for guiding bone regeneration [35].…”

Section: Introductionmentioning

confidence: 99%

“…Different techniques have been used in the literature: Archimedes, helium pycnometry, micro-tomography, image analysis [42][43][44][45] and electrical impedance spectroscopy [35,[46][47][48]. Some preliminary studies were developed using the latter technique to correlate porosity of titanium, pore size and electrical conductivity, although the influence of the electric frequency in the measured impedance was not described [35]. Furthermore, in this work, the electrochemical impedance spectroscopy is used to conclude that the pores in the porous titanium play a negative part in corrosion resistance and the flowing electrolyte can increase the corrosive rate of all titanium samples.…”

Section: Introductionmentioning

confidence: 99%

Use of Impedance Spectroscopy for the Characterization of In-Vitro Osteoblast Cell Response in Porous Titanium Bone Implants

Giner

Olmo

Hernández

et al. 2020

Metals

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The use of titanium implants with adequate porosity (content, size and morphology) could solve the stress shielding limitations that occur in conventional titanium implants. Experiments to assess the cellular response (adhesion, proliferation and differentiation of osteoblasts) on implants are expensive, time-consuming and delicate. In this work, we propose the use of impedance spectroscopy to evaluate the growth of osteoblasts on porous titanium implants. Osteoblasts cells were cultured on fully-dense and 40 vol.% porous discs with two ranges of pore size (100–200 μm and 355–500 μm) to study cell viability, proliferation, differentiation (Alkaline phosphatase activity) and cell morphology. The porous substrates 40 vol.% (100–200 µm) showed improved osseointegration response as achieved more than 80% of cell viability and higher levels of Cell Differentiation by Alkaline Phosphatase (ALP) at 21 days. This cell behavior was further evaluated observing an increase in the impedance modulus for all study conditions when cells were attached. However, impedance levels were higher on fully-dense due to its surface properties (flat surface) than porous substrates (flat and pore walls). Surface parameters play an important role on the global measured impedance. Impedance is useful for characterizing cell cultures in different sample types.

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“…As seen in Table 3, the mechanical stiffness of FD samples ($101.2 ± 0.3 GPa) is higher compared to cortical bone's ($25 GPa) and trabecular bone tissue (0.5-1 GPa). 11,46,47 This great difference is one of the main causes of stress shielding, which derives from a stiffness mismatch that induces bone resorption and can cause implant failure. 1,5 In contrast, the Young modulus of 50 vol % and 60% porous samples (2.32 and 3.97 GPa, respectively), were closer to trabecular bone young modulus.…”

Section: Resultsmentioning

confidence: 99%

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

Cited by 8 publications

References 55 publications

Latest Trends in Surface Modification for Dental Implantology: Innovative Developments and Analytical Applications

Latest Trends in Surface Modification for Dental Implantology: Innovative Developments and Analytical Applications

Use of Impedance Spectroscopy for the Characterization of In-Vitro Osteoblast Cell Response in Porous Titanium Bone Implants

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

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