Histological Evidence of the Osseointegration of Fractured Direct Metal Laser Sintering Implants Retrieved after 5 Years of Function

Mangano, Francesco; Mangano, Carlo; Piattelli, Adriano; Iezzi, Giovanna

doi:10.1155/2017/9732136

Cited by 27 publications

(25 citation statements)

References 28 publications

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“…Nano-pore structure can increase the bone binding force by 3.1-fold, 17 which can imitate the cellular environment in vivo, favoring the absorption of extracellular matrix protein and promoting receptor recognition and subsequent adhesion and proliferation of cells, as well as advancing the biological behavior of cell attachment and migration through signaling of surface integrins. 16,18 In this study the rotating torsion test and histomorphometric results indicated that the SLA-Bio group had considerably greater torque strength, a larger area of bone-implant contact, and faster initiation of osseointegration in comparison with the other 2 groups. The increased osseointegration in the SLA-Bio group at early stages of healing can be achieved by the biological effects of the nano-and micro-surface structure, as well as the promotion of cellular adhesion and protein (eg, sialoprotein and osteopontin) deposition on the titanium implant surface.…”

Section: E9mentioning

confidence: 54%

Effects of Biomineralization on Osseointegration of Pure Titanium Implants in the Mandible of Beagles

Mei

Fang

Khan

2018

Journal of Oral and Maxillofacial Surgery

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Section: E9mentioning

confidence: 54%

Effects of Biomineralization on Osseointegration of Pure Titanium Implants in the Mandible of Beagles

Mei

Fang

Khan

2018

Journal of Oral and Maxillofacial Surgery

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“…[53][54][55] AM technologies have been selected to manufacture Ti implants, customized subperiosteal Ti implants, [82][83][84][85][86] customized AM Ti meshes for bone grafting techniques, [87][88][89][90][91][92][93][94][95] Co-Co frameworks for implant impression procedures, 96,97 and Co-Cr and Ti implant frameworks for implant-supported prostheses. [98][99][100][101][102] With the introduction of AM technologies, different studies have analyzed the potential to manufacture Ti AM dental implants (Table 1), [55][56][57][58][59][60][61][62][63][64][65][66][67][68][69][70][71][72][73] customized designs that replicate the tooth's root shape (Table 2), [74][75]…”

Section: Application Of Am Technologies In Implant Dentistrymentioning

confidence: 99%

“…Furthermore, the mechanical properties, osteoconduction, and bone augmentation properties of titanium porous lattice structures have been evaluated. 102,103 Different in vitro and animal studies, 17,53,54,56,[60][61][62]64,72 as well as clinical studies 57,60,[65][66][67][68][69][70][71] have analyzed the utility of AM titanium implants. Authors concluded that AM technologies are an alternative for manufacturing custom implants, providing adequate and controlled porosity levels, superficial roughness that promotes new bone formation, and improves the osseointegration process.…”

Section: Application Of Am Technologies In Implant Dentistrymentioning

confidence: 99%

“…Several clinical studies have described a high incidence of prosthodontic complications while using AM titanium implant procedures (Table 1). 67,68,70 Current challenges in additively manufactured dental implants include surface characteristics, dimensional accuracy, and high manufacturing cost. 54 Further studies are needed to define a standardized protocol to fabricate dental implants using AM technologies.…”

Section: Application Of Am Technologies In Implant Dentistrymentioning

confidence: 99%

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A Review of the Applications of Additive Manufacturing Technologies Used to Fabricate Metals in Implant Dentistry

Revilla‐León

Sadeghpour²,

Özcan

2020

Journal of Prosthodontics

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Purpose To review the primary additive manufacturing (AM) technologies used to fabricate metals in implant dentistry and compare them to conventional casting and subtractive methods. Methods The literature on metal AM technologies was reviewed, and the AM procedures and their current applications in implant dentistry were collated and described. Collection of published articles about metal AM in dental field data sources: MEDLINE, EMBASE, EBSCO, and Web of Science searched. All studies related to AM technology description, analysis, and evaluation of applications in implant dentistry, including AM titanium (Ti) dental implants, customized Ti mesh for bone grafting techniques, cobalt‐chromium (Co‐Cr) frameworks for implant impression procedures, and Co‐Cr and Ti frameworks for dental implant‐supported prostheses were reviewed. Results Literature has demonstrated the potential of AM technologies to fabricate dental implants, root‐analog implants, and functionally graded implants; as well as the ability to fabricate customized meshes for bone grafting procedures. Metal AM technologies provide a reliable method to manufacture frameworks for implant impression procedures. Co‐Cr and Ti AM frameworks for implant‐supported prostheses provide a clinically acceptable discrepancy at the implant‐prostheses interface. Conclusions Additional clinical studies are required to assess the long‐term clinical performance, biological and mechanical complications, and prosthetic restoration capabilities of additively manufactured dental implants. Moreover, further studies are needed to evaluate their long‐term success and survival rates and biological and mechanical complications of AM implant‐supported prostheses.

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“…The size of the necks is influenced by the sintering temperature and duration 61 . This large porosity translates to a large surface area, promoting better osseointegration 62 and allowing for drug delivery in joint replacements. Sintering is best performed with metals that are of a similar melting point.…”

Section: Materials Usedmentioning

confidence: 99%

Plasma-Sprayed and Sintered Silver-Based Antimicrobial Coatings for Industrial and Biomedical Application

Salvatore¹

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Bacteria are ever-present in many industries, especially food and water processing, and medicine. Bacteria can colonize the surfaces of equipment and implants, risking potential infection. An antimicrobial coating that could be applied to an alloy would prove invaluable in these industries. This thesis suggests using silver as an active antibacterial agent and details the experimental data and analysis of coatings produced via plasmaspraying and sintering. The coatings were applied to cobalt chromium, an alloy used in both industries. The plasma-sprayed coatings used cobalt chromium as a base metal, containing 0%, 2%, and 5% silver by weight. The sintered coatings had a greater adhesion strength than the plasma-sprayed coatings (25.86 MPa versus 24.66 MPa in the 2% silver coating). The plasma-sprayed coatings saw no leaching of silver in sterile water, and the 2% and 5% silver plasma-sprayed coatings reduced bacteria proliferation relative to the 0% (99.9% and 63.4% reduction).iii Acknowledgements Special thanks to Dr.

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Histological Evidence of the Osseointegration of Fractured Direct Metal Laser Sintering Implants Retrieved after 5 Years of Function

Cited by 27 publications

References 28 publications

Effects of Biomineralization on Osseointegration of Pure Titanium Implants in the Mandible of Beagles

Effects of Biomineralization on Osseointegration of Pure Titanium Implants in the Mandible of Beagles

A Review of the Applications of Additive Manufacturing Technologies Used to Fabricate Metals in Implant Dentistry

Plasma-Sprayed and Sintered Silver-Based Antimicrobial Coatings for Industrial and Biomedical Application

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