Preparing and immobilizing antimicrobial osteogenic growth peptide on titanium substrate surface

Liu, Ju; Yang, Weihu; Tao, Bailong; Shen, Tingting; Shen, Xinkun; Cai, Kaiyong

doi:10.1002/jbm.a.36491

Cited by 11 publications

(9 citation statements)

References 48 publications

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“…In order to successfully install the implants, researchers make efforts to create bioactive coating materials on titanium surface using different techniques. 1 , 2 In these studies, favorable osteogenic, angiogenic and antibacterial capacities of coating materials have been widely explored. 3 , 4 However, many coating materials with excellent properties mentioned above could not achieve satisfactory results in the subsequent in vivo studies in terms of the regeneration of bones.…”

Section: Introductionmentioning

confidence: 99%

<p>Magnesium-doped Nanostructured Titanium Surface Modulates Macrophage-mediated Inflammatory Response for Ameliorative Osseointegration</p>

Qiao¹,

Yang²,

Shang³

et al. 2020

IJN

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Background: Next generation of coating materials on the surface of implants is designed with a paradigm shift from an inert material to an osteoimmunomodulatory material. Regulating immune response to biomedical implants through influencing the polarization of macrophage has been proven to be an effective strategy. Methods: Through anodization and hydrothermal treatment, magnesium ion incorporated TiO 2 nanotube array (MgN) coating was fabricated on the surface of titanium and it is hypothesized that it has osteoimmunomodulatory properties. To verify this assumption, systematic studies were carried out by in vitro and in vivo experiments. Results: Mg ion release behavior results showed that MgN coating was successfully fabricated on the surface of titanium using anodization and hydrothermal technology. Scanning electron microscopy (SEM) images showed the morphology of the MgN coating on the titanium. The expression of inflammation-related genes (IL-6, IL-1β, TNF-α) was downregulated in MgN group compared with TiO 2 nanotube (NT) and blank Ti groups, but anti-inflammatory genes (IL-10 and IL-1ra) were remarkably upregulated in the MgN group. The in vitro and in vivo results demonstrated that MgN coating influenced macrophage polarization toward the M2 phenotype compared with NT and blank-Ti groups, which enhanced osteogenic differentiation of rat bone mesenchymal stem cells rBMSCs in conditioned media (CM) generated by macrophages. Conclusion: MgN coating on the titanium endowed the surface with immune-regulatory features and exerted an advantageous effect on osteogenesis, thereby providing excellent strategies for the surface modification of biomedical implants.

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Section: Introductionmentioning

confidence: 99%

<p>Magnesium-doped Nanostructured Titanium Surface Modulates Macrophage-mediated Inflammatory Response for Ameliorative Osseointegration</p>

Qiao¹,

Yang²,

Shang³

et al. 2020

IJN

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“…They demonstrated that the release of chlorhexidine could facilitate osseointegration by completely preventing the formation of bacterial biofilm on the implant surface [ 96 ]. In addition, the failure of osseointegration caused by bacterial infection could be prevented by direct grafting of antibiotic ciprofloxacin on Ti implants or by loading ciprofloxacin on CS/nanoHA/Ti [ 97 , 98 ]. In order to obtain more superior antibacterial implants, Park et al loaded silver nanoparticles, cephalothin, minocycline (Mino), and amoxicillin on mesoporous TiO 2 .…”

Section: Local Drug Delivery Systems With Ti-based Implantsmentioning

confidence: 99%

Construction of Local Drug Delivery System on Titanium-Based Implants to Improve Osseointegration

et al. 2022

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Titanium and its alloys are the most widely applied orthopedic and dental implant materials due to their high biocompatibility, superior corrosion resistance, and outstanding mechanical properties. However, the lack of superior osseointegration remains the main obstacle to successful implantation. Previous traditional surface modification methods of titanium-based implants cannot fully meet the clinical needs of osseointegration. The construction of local drug delivery systems (e.g., antimicrobial drug delivery systems, anti-bone resorption drug delivery systems, etc.) on titanium-based implants has been proved to be an effective strategy to improve osseointegration. Meanwhile, these drug delivery systems can also be combined with traditional surface modification methods, such as anodic oxidation, acid etching, surface coating technology, etc., to achieve desirable and enhanced osseointegration. In this paper, we review the research progress of different local drug delivery systems using titanium-based implants and provide a theoretical basis for further research on drug delivery systems to promote bone–implant integration in the future.

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“…Induced in vitro mineralization [29] SiO 2 /MgO doped HA -plasma spraying -↑ In vivo osteogenesis and osteointegration [35] Chitosan/gelatin/HA -LBL assembly -↑ Adhesion, proliferation and osteogenic differentiation of MSCs ↑ Adhesion and mitigation of HUVECs ↑ In vivo osteogenesis and angiogenesis [151] TNT -electrochemical anodization CaP -biomimetic coating -↑ Early stage in vivo osteointegration and mineralization [23] Ti6Al4V HA -plasma spraying ↑ Surface roughness ↑ Adhesion and attachment of osteoblast ↓ Osteosarcoma ↑ In vivo osteointegration [16] HA -magnetron sputtering Homogeneous crystalline coating - [24] Si doped HA -dip coating VEGF -physical adsorption ↑ Proliferation of pre-osteoblasts and endothelial cells ↑ In vivo osteointegration and angiogenesis in osteoporotic model [30] Biphasic CaP nHA -hydrothermal deposition -↑ Viability and osteogenic differentiation of MSC PEG -electrodeposition RGD/LF1-11 -covalent immobilization ↑ Hydrophilicity ↑ Osteoblast adhesion and spreading ↓ Adhesion and viability of S. sanguinis and protein adsorption [132] GL13K (AMP) -covalent immobilization ↑ Hydrophilicity Slightly ↑ surface roughness ↓ Viability of P. gingivalis ↑ Fibroblast viability and attachment [110] Osteogenic growth peptide/ciprofloxacin -covalent immobilization ↑ Hydrophilicity → Surface roughness ↑ Osteoblast spreading and osteodifferentiation [111] NO releasing coating -silanization, diazeniumdiolate functionalization ↓ Hydrophilicity ↑ Surface roughness ↓ Adhesion and colonization of S. aureus and P. aeruginosa No cytotoxicity to osteoblasts [161] Ag/PDA -physical adsorption -↓ Growth and colonization of S. mutans and P. gingivalis [162] Ag NPs/GO -electroplating Microstructured ↓ Adhesion and viability of S. mutans and P. gingivalis ↑ Cytotoxicity with higher GO and Ag NPs [163] GL13K/TNT -physical adsorption/electrochemical anodization -↓ Growth of F. nucleatum and P. gingivalis ↑ Proliferation and no cytotoxicity to MC3T3-E1 cells [124] Ag NPs/ vancomycin/TNTs -plasma immersion ion implantation (PIII)/lyophilization/electrochemical anodization -↓ Adhesion of S. aureus No cytotoxicity to fibroblasts [123] Ag ↑: enhancement; ↓: hindered effect; →: comparable result.…”

Section: Controllable and Homogeneous Coatingmentioning

confidence: 99%

“…A dual functional AMP was synthesized by conjugating osteogenic growth peptide with ciprofloxacin, and covalently immobilized on titanium surface. [ 111 ] Such AMP modified titanium promoted proliferation, spreading and osteogenic differentiation of osteoblasts. The sustained release of this AMP for 7 days led to less adhered and viable bacteria.…”

Section: Strategies To Realize Bacteriostatic and Bactericidal Perfor...mentioning

confidence: 99%

Surface engineering of biomaterials in orthopedic and dental implants: Strategies to improve osteointegration, bacteriostatic and bactericidal activities

Liu

Ramakrishna

2021

Biotechnology Journal

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Background The success of biomedical implants in orthopedic and dental applications is usually limited due to insufficient bone‐implant integration, and implant‐related infections. Biointerfaces are critical in regulating their interactions and the desirable performance of biomaterials in biological environment. Surface engineering has been widely studied to realize better control of the interface interaction to further enhance the desired behavior of biomaterials. Purpose and Scope This review aims to investigate surface coating strategies in hard tissue applications to address insufficient osteointegration and implant‐related infection problems. Summary We first focused on surface coatings to enhance the osteointegration and biocompatibility of implants by emphasizing calcium phosphate‐related, nanoscale TiO2‐related, bioactive tantalum‐based and biomolecules incorporated coatings. Different coating strategies such as plasma spraying, biomimetic deposition, electrochemical anodization and LENS are discussed. We then discussed techniques to construct anti‐adhesive and bactericidal surface while emphasizing multifunctional surface coating techniques that combine potential osteointegration and antibacterial activities. The effects of nanotopography via TiO2 coatings on antibacterial performance are interesting and included. A smart bacteria‐responsive titanium dioxide nanotubes coating is also attractive and elaborated. Conclusion Developing multifunctional surface coatings combining osteogenesis and antimicrobial activity is the current trend. Surface engineering methods are usually combined to obtain hierarchical multiscale surface structures with better biofunctionalization outcomes.

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Preparing and immobilizing antimicrobial osteogenic growth peptide on titanium substrate surface

Cited by 11 publications

References 48 publications

<p>Magnesium-doped Nanostructured Titanium Surface Modulates Macrophage-mediated Inflammatory Response for Ameliorative Osseointegration</p>

<p>Magnesium-doped Nanostructured Titanium Surface Modulates Macrophage-mediated Inflammatory Response for Ameliorative Osseointegration</p>

Construction of Local Drug Delivery System on Titanium-Based Implants to Improve Osseointegration

Surface engineering of biomaterials in orthopedic and dental implants: Strategies to improve osteointegration, bacteriostatic and bactericidal activities

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