Varying Ti‐6Al‐4V surface roughness induces different early morphologic and molecular responses in MG63 osteoblast‐like cells

Kim, H. J.; Kim, S. H.; Kim, M. S.; Lee, E. J.; Oh, Hyung-Hoon; Oh, Wooseok; Park, S. W.; Kim, W. J.; Lee, G. J.; Choi, Nam-Ki; Koh, Jeong‐Tae; Dinh, D. B.; Hardin, Robert R.; Johnson, Kay; Sylvia, V. L.; Schmitz, John P.; Dean, David D.

doi:10.1002/jbm.a.30327

Cited by 85 publications

(62 citation statements)

References 32 publications

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“…This has been demonstrated to occur on nanofabricated substrates, whereby ordered nanotopography can induce a state of ''superhydrophobicity'' on a material surface. 3 This, in turn, results in decreased protein adsorption, 6,33 as well as conformational changes in integrin specific ECM protein binding domains. 34 A third, and interesting possibility, is that of increased cellular motility at the substrate surface, whereby HOBs perceive the local topography as unfavorable for adhesion, leading to protein production and assembly via intercellular signaling cascades, resulting in contact guidance induced mobility.…”

Section: Discussionmentioning

confidence: 99%

“…[1][2][3] In vitro studies have shown that osteoblast response is influenced by substrate morphology, 4 and that extracellular matrix (ECM) synthesis and osteoblast differentiation are influenced by substrate microtopography, 5 factors that have consistently been shown to affect osteoblast infiltration and adhesion in vivo when applied to an orthopedic device. 6 Accordingly, nanogrooves, nanopits, and nanoislands have been shown to affect contact guidance in vitro and directly influence cell adhesion to a degree related to feature dimension, cell type, and cell density. [7][8][9][10] Present studies indicate that fibroblasts react significantly to nanotopographical cues in vitro, perceiving the topography of an implanted surface via dynamic filopodial formation and extension to find sites topographicaly suitable for adhesion, growth, and maturation.…”

Section: Introductionmentioning

confidence: 99%

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Regulation of implant surface cell adhesion: characterization and quantification of S‐phase primary osteoblast adhesions on biomimetic nanoscale substrates

Biggs

Richards

Gadegaard

et al. 2006

Journal Orthopaedic Research

109

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Integration of an orthopedic prosthesis for bone repair must be associated with osseointegration and implant fixation, an ideal that can be approached via topographical modification of the implant/bone interface. It is thought that osteoblasts use cellular extensions to gather spatial information of the topographical surroundings prior to adhesion formation and cellular flattening. Focal adhesions (FAs) are dynamic structures associated with the actin cytoskeleton that form adhesion plaques of clustered integrin receptors that function in coupling the cell cytoskeleton to the extracellular matrix (ECM). FAs contain structural and signalling molecules crucial to cell adhesion and survival. To investigate the effects of ordered nanotopographies on osteoblast adhesion formation, primary human osteoblasts (HOBs) were cultured on experimental substrates possessing a defined array of nanoscale pits. Nickel shims of controlled nanopit dimension and configuration were fabricated by electron beam lithography and transferred to polycarbonate (PC) discs via injection molding. Nanopits measuring 120 nm diameter and 100 nm in depth with 300 nm center-center spacing were fabricated in three unique geometric conformations: square, hexagonal, and near-square (300 nm spaced pits in square pattern, but with AE50 nm disorder). Immunofluorescent labeling of vinculin allowed HOB adhesion complexes to be visualized and quantified by image software. Perhipheral adhesions as well as those within the perinuclear region were observed, and adhesion length and number were seen to vary on nanopit substrates relative to smooth PC. S-phase cells on experimental substrates were identified with bromodeoxyuridine (BrdU) immunofluorescent detection, allowing adhesion quantification to be conducted on a uniform flattened population of cells within the S-phase of the cell cycle. Findings of this study demonstrate the disruptive effects of ordered nanopits on adhesion formation and the role the conformation of nanofeatures plays in modulating these effects. Highly ordered arrays of nanopits resulted in decreased adhesion formation and a reduction in adhesion length, while introducing a degree of controlled disorder present in near-square arrays, was shown to increase focal adhesion formation and size. HOBs were also shown to be affected morphologicaly by the presence and conformation of nanopits. Ordered arrays affected cellular spreading, and induced an elongated cellular phenotype, indicative of increased motility, while near-square nanopit symmetries induced HOB spreading. It is postulated that nanopits affect osteoblast-substrate adhesion by directly or indirectly affecting adhesion complex formation, a phenomenon dependent on nanopit dimension and conformation. ß

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Regulation of implant surface cell adhesion: characterization and quantification of S‐phase primary osteoblast adhesions on biomimetic nanoscale substrates

Biggs

Richards

Gadegaard

et al. 2006

Journal Orthopaedic Research

109

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“…In general, "rough" surfaces are known to have beneficial effects on bone integration [16][17][18][19][20][21] 15) . However, no in vitro study has evaluated the highly roughened surfaces of SLM materials combined with a bioactive treatment.…”

Section: Introductionmentioning

confidence: 99%

Bioactive treatment promotes osteoblast differentiation on titanium materials fabricated by selective laser melting technology

et al. 2016

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Selective laser melting (SLM) technology is useful for the fabrication of porous titanium implants with complex shapes and structures. The materials fabricated by SLM characteristically have a very rough surface (average surface roughness, Ra=24.58 µm). In this study, we evaluated morphologically and biochemically the specific effects of this very rough surface and the additional effects of a bioactive treatment on osteoblast proliferation and differentiation. Flat-rolled titanium materials (Ra=1.02 µm) were used as the controls. On the treated materials fabricated by SLM, we observed enhanced osteoblast differentiation compared with the flat-rolled materials and the untreated materials fabricated by SLM. No significant differences were observed between the flat-rolled materials and the untreated materials fabricated by SLM in their effects on osteoblast differentiation. We concluded that the very rough surface fabricated by SLM had to undergo a bioactive treatment to obtain a positive effect on osteoblast differentiation.

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“…The influence of physical properties such as surface topography and roughness on osseointegration have translated to shorter healing times from implant placement to restoration (Cochran et al, 2002). The biologic basis underlying these clinical improvements continues to be explored (Kim et al, 2005, Lossdorfer et al, 2004. Albrektsson et al (1981) suggested six factors that are particluarly important for the establishment of reliable osseointegration: implant material, implant design, surface conditions, status of the bone, surgical technique, and implant loading conditions.…”

Section: Introductionmentioning

confidence: 99%

Dental Implant Surface Enhancement and Osseointegration

Anil¹,

Anand²,

Alghamdi³

et al. 2011

Implant Dentistry - A Rapidly Evolving Practice

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Varying Ti‐6Al‐4V surface roughness induces different early morphologic and molecular responses in MG63 osteoblast‐like cells

Cited by 85 publications

References 32 publications

Regulation of implant surface cell adhesion: characterization and quantification of S‐phase primary osteoblast adhesions on biomimetic nanoscale substrates

Regulation of implant surface cell adhesion: characterization and quantification of S‐phase primary osteoblast adhesions on biomimetic nanoscale substrates

Bioactive treatment promotes osteoblast differentiation on titanium materials fabricated by selective laser melting technology

Dental Implant Surface Enhancement and Osseointegration

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