Effects of negatively and positively charged Ti metal surfaces on ceramic coating adhesion and cell response

Nascimento, Rodney Marcelo do; Carvalho, Vanessa Lôbo de; Govone, Josï¿1⁄2 Silvio; Hernandes, Antï¿½nio Carlos; Cruz, Nilson Cristino da

doi:10.1007/s10856-017-5848-0

Cited by 20 publications

(13 citation statements)

References 33 publications

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“…To build effective tissues, cells need to first develop a suitable morphology and physical features, such as filopodia, in the in vitro conditions [3]. Cells reorganize by interactions with material properties, such as topography [4], mechanical strength [5], and surface potential [6,7,8]. Moreover, they adjust the shape and morphology to a surface geometry, thus, the design of the scaffold is crucial in controlling cells behavior, development, and proliferation [9,10].…”

Section: Introductionmentioning

confidence: 99%

Cell Integration with Electrospun PMMA Nanofibers, Microfibers, Ribbons, and Films: A Microscopy Study

et al. 2019

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Tissue engineering requires properly selected geometry and surface properties of the scaffold, to promote in vitro tissue growth. In this study, we obtained three types of electrospun poly(methyl methacrylate) (PMMA) scaffolds—nanofibers, microfibers, and ribbons, as well as spin-coated films. Their morphology was imaged by scanning electron microscopy (SEM) and characterized by average surface roughness and water contact angle. PMMA films had a smooth surface with roughness, Ra below 0.3 µm and hydrophilic properties, whereas for the fibers and the ribbons, we observed increased hydrophobicity, with higher surface roughness and fiber diameter. For microfibers, we obtained the highest roughness of 7 µm, therefore, the contact angle was 140°. All PMMA samples were used for the in vitro cell culture study, to verify the cells integration with various designs of scaffolds. The detailed microscopy study revealed that higher surface roughness enhanced cells’ attachment and their filopodia length. The 3D structure of PMMA microfibers with an average fiber diameter above 3.5 µm, exhibited the most favorable geometry for cells’ ingrowth, whereas, for other structures we observed cells growth only on the surface. The study showed that electrospinning of various scaffolds geometry is able to control cells development that can be adjusted according to the tissue needs in the regeneration processes.

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Section: Introductionmentioning

confidence: 99%

Cell Integration with Electrospun PMMA Nanofibers, Microfibers, Ribbons, and Films: A Microscopy Study

et al. 2019

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“…These surface-bound host factors may also serve as specific receptors for both tissue cells and colonizing bacteria. Titanium, for instance, has a positively charged surface and will initially form non-covalent bonds with negatively charged proteins such as albumin and fibronectin ( Jager et al., 2017 , Do Nascimento et al., 2017 ). Fibronectin has been observed to promote bacterial adhesion, whereas albumin and whole serum appear to inhibit bacterial adhesion to biomaterial surfaces ( Ribeiro et al., 2012 ).…”

Section: Titanium As An Orthopedic Biomaterialsmentioning

confidence: 99%

Titanium for Orthopedic Applications: An Overview of Surface Modification to Improve Biocompatibility and Prevent Bacterial Biofilm Formation

et al. 2020

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Summary Titanium and its alloys have emerged as excellent candidates for use as orthopedic biomaterials. Nevertheless, there are often complications arising after implantation of orthopedic devices, most notably prosthetic joint infection and aseptic loosening. To ensure that implanted devices remain functional in situ , innovation in surface modification has attracted much attention in the effort to develop orthopedic materials with optimal characteristics at the biomaterial-tissue interface. This review will draw together metallurgy, surface engineering, biofilm microbiology, and biomaterial science. It will serve to appreciate why titanium and its alloys are frequently used orthopedic biomaterials and address some of the challenges facing these biomaterials currently, including the significant problem of device-associated infection. Finally, the authors shall consolidate and evaluate surface modification techniques employed to overcome some of these issues by offering a unique perspective as to the direction in which research is headed from a broad, interdisciplinary point of view.

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“…Primary cultures can provide information more relevant to clinical outcomes when compared to immortalized cell lines such as Saos-2 or MG63, and are also increasingly used in the biomaterials field with tissue engineering applications, and for these reasons were chosen for this study. 30 Although several reports exist on stem cell/osteoblast biocompatibility of either titanium [31][32][33][34][35] or PU, [36][37][38][39] no studies were found on PU/Ti composites. Therefore, the potential cytotoxicity of those used in this study was assessed with both HDPSC and osteoblasts.…”

Section: Biocompatibility Of Compositesmentioning

confidence: 99%

“…This is in contrast with previous reports where either HDPSC or osteoblast were cultured, in the absence of a polymer, on laser sintered or acid etched titanium alloys and where it was observed no difference in cell adhesion. 31 Surface roughness, 32 surface chemistry, 33,34 zeta potential, and surface energy 22,30 have been proposed as the main factors contributing to osteoblast attachment to titanium implants, but to our knowledge, there is no similar study on HDPSC. 35 Although it has been reported that committed cells (human osteoblasts) display better proliferation, distribution, and adhesion in 2D cultures on roughened titanium surface compared to HDPSC, 40 it is possible that HDPSC exhibited higher proliferation at shorter times either due to the higher proliferative index as many multipotent cells or due to the stimulating effect of titanium.…”

Section: Biocompatibility Of Compositesmentioning

confidence: 99%

Preparation and characterization of titanium—segmented polyurethane composites for bone tissue engineering

et al. 2018

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Segmented polyurethanes were prepared with polycaprolactone diol as soft segment and 4,4-methylene-bis cyclohexyl diisocyanate and l-glutamine as the rigid segment. These polyurethanes were filled with 1 wt.% to 5 wt.% titanium particles (Ti), physicochemically characterized and their biocompatibility assessed using human dental pulp stem cells and mice osteoblasts. Physicochemical characterization showed that composites retained the properties of the semicrystalline polyurethane as they exhibited a glass transition temperature (T) between -35°C and -45°C, melting temperature (T) at 52°C and crystallinity close to 40% as determined by differential scanning calorimetry. In agreement with this, X-ray diffraction showed reflections at 21.3° and 23.6° for polycaprolactone diol and reflections at 35.1°, 38.4°, and 40.2° for Ti particles suggesting that these particles are not acting as nucleating sites. The addition of up to 5 wt.% of Ti reduced both, tensile strength and maximum strain from 1.9 MPa to 1.2 MPa, and from 670% to 172% for pristine and filled polyurethane, respectively. Although there were differences between composites at low strain rates, no significant differences in mechanical behavior were observed at higher strain rate where a tensile stress of 8.5 MPa and strain of 223% were observed for 5 wt.% composites. The addition to titanium particles had a beneficial effect on both human dental pulp stem cells and osteoblasts viability, as it increased with the amount of titanium in composites up to 10 days of incubation.

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Effects of negatively and positively charged Ti metal surfaces on ceramic coating adhesion and cell response

Cited by 20 publications

References 33 publications

Cell Integration with Electrospun PMMA Nanofibers, Microfibers, Ribbons, and Films: A Microscopy Study

Cell Integration with Electrospun PMMA Nanofibers, Microfibers, Ribbons, and Films: A Microscopy Study

Titanium for Orthopedic Applications: An Overview of Surface Modification to Improve Biocompatibility and Prevent Bacterial Biofilm Formation

Preparation and characterization of titanium—segmented polyurethane composites for bone tissue engineering

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