Relevant bibliographies by topics / Customizable implant

Academic literature on the topic 'Customizable implant'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Customizable implant"

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Bezerra, Fabio Jose Barbosa, Felipe Moura Araujo, Guilherme Jose Pimentel Lopes de Oliveira, and Bruna Ghiraldini. "Clinical application of the customizable PEEK healing abutment. A case report." Journal of Multidisciplinary Dentistry 10, no. 1 (June 3, 2020): 93–6. http://dx.doi.org/10.46875/jmd.v10i1.42.

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The aim of this case report was to present an indication of the PEEK as a material of customizable healing abutment. A 35-year-old male complained about the absence of the right upper first molar that had been previously extracted (2 years) due to unsuccessful endodontic treatment. After the anamnesis, the clinical and radiographic evaluation, a good bone availability that enables a dental implants placement was observed in the edentulous region. A dental implant with hybrid microgeometry and morse taper prosthetic connection was placed. A good primary stability was obtained (32 Ncm), however, the early loading technique was opted for this case instead of the immediate loading, since the implants placed in the posterior region requires to support a high masticatory loading force which could interfere with the healing process of the dental implant. Then, a customizable PEEK healing abutment was installed in order to define the prosthetic emergence profile. There were no signs of complications during the postoperative period, and after the twenty-eight-day healing period, a prosthetic interface for digital transfer was installed and intraoral scanning was performed. The prosthetic rehabilitation was performed by the CAD/CAM system, and a screwed prosthetic rehabilitation was installed at the same day. The patient was followed up for 12 months, and no signs or symptoms of peri-implant pathology or prosthetic complications were detected. The customizable PEEK healing abutment is a good option to induce a properly soft-tissue healing that enables an adequate prosthetic emergency profile.
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Thomé, Geninho, Marcos Boaventura de Moura, Jean Uhlendorf, Carolina Accorsi Cartelli, Larissa Carvalho Trojan, and Sérgio Rocha Bernardes. "Reabilitação implantossuportada de molar superior com implante cônico interno de diâmetro extra-largo – relato de caso." Full Dentistry in Science 12, no. 46 (2021): 53–58. http://dx.doi.org/10.24077/2021;1246-5358.

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Tooth loss can occur due to several factors including dental caries. Immediate replacement of posterior teeth with dental implants facilitates to plan and to obtain consistent results with good prognosis. Factors such as minimally traumatic extraction, primary implant stability, maintenance of proximal bone ridges, buccal and lingual bone plates, in addition to a temporary or customizable component for tissue stabilization are important parameters to make the case predictable. The immediate technique for implants placement in the posterior regions has been described in the literature since the 1990s, presenting a high success rate and predictability of patients rehabilitation with shorter waiting times and maintenance of soft and bone tissue architecture. This study reports a clinical case of extraction of an upper molar tooth (26) with dental caries and placement of an extra-wide diameter implant, followed by filling of the surgical alveolar socket with bioactive calcium phosphate ceramic and placement of a customizable healing abutment. Clinical and radiographic control was performed after 8 months with success, with maintenance of soft tissue and marginal bone.
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Junior, Joao Moretti, Cristiane de Oliveira Iamada Moretti, Diego henrique Rossafa Crocco, Gislaine Cristina dos Santos Silva Souza, and Marina Magri Porto. "Manutenção do perfil gengival com cicatrizador personalizado em implante imediato – relato de caso." Prosthesis and Esthetics in Science 10, no. 39 (2021): 17–20. http://dx.doi.org/10.24077/2021;10391720.

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This article aimed to present a clinical case whose cicatrizador was made through the multifunctional component of PEEK. This is a biocompatible polymer that is customizable and has good adhesion to resins. The case described is an immediate implant in the region of 15, installed with a palatal approach and filling the vestibular gap with an alloplastic graft (Nanosynt). The case was followed until the final prosthesis was made, in which the maintenance of the architecture of the peri-implant tissues was checked for health and aesthetics.
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Luis, Eric, Houwen Matthew Pan, Swee Leong Sing, Ram Bajpai, Juha Song, and Wai Yee Yeong. "3D Direct Printing of Silicone Meniscus Implant Using a Novel Heat-Cured Extrusion-Based Printer." Polymers 12, no. 5 (May 1, 2020): 1031. http://dx.doi.org/10.3390/polym12051031.

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The first successful direct 3D printing, or additive manufacturing (AM), of heat-cured silicone meniscal implants, using biocompatible and bio-implantable silicone resins is reported. Silicone implants have conventionally been manufactured by indirect silicone casting and molding methods which are expensive and time-consuming. A novel custom-made heat-curing extrusion-based silicone 3D printer which is capable of directly 3D printing medical silicone implants is introduced. The rheological study of silicone resins and the optimization of critical process parameters are described in detail. The surface and cross-sectional morphologies of the printed silicone meniscus implant were also included. A time-lapsed simulation study of the heated silicone resin within the nozzle using computational fluid dynamics (CFD) was done and the results obtained closely resembled real time 3D printing. Solidworks one-convection model simulation, when compared to the on-off model, more closely correlated with the actual probed temperature. Finally, comparative mechanical study between 3D printed and heat-molded meniscus is conducted. The novel 3D printing process opens up the opportunities for rapid 3D printing of various customizable medical silicone implants and devices for patients and fills the current gap in the additive manufacturing industry.
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Fischer, C. M. Maximilian, W. John Schlasche, Stefan Schröder, J. Philippe Kretzer, M. Moritz Innmann, and Tobias Renkawitz. "Additive Fertigung hybrider Hüftimplantate/HybridHipProcess – Manufacturing of customizable stiffness-optimized hip stems – Additive Manufacturing of Hybrid Hip Implants." wt Werkstattstechnik online 112, no. 05 (2022): 292–96. http://dx.doi.org/10.37544/1436-4980-2022-05-22.

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Unter Verwendung der additiven Fertigungstechnologie lassen sich Implantate in biomechanisch angepasster, hybrider Leichtbauweise mit einer dem natürlichen Knochen angenäherten Steifigkeit herstellen. Der Einsatz eines Homogenisierungsansatzes für die optimierten Implantatbereiche mit Gitterstrukturen erlaubt durch eine deutliche Verkürzung der Simulationszeiten eine Integration einer verzugskompensierenden und temperaturstabilisierenden Prozesssimulation der additiven Fertigung in eine individualisierte Serienproduktion. Implants with a biomechanically customized hybrid lightweight design that is adapted to the stiffness of the native bone can be produced using additive manufacturing technology. The use of a homogenization approach for the optimized implant areas with lattice structures enables the integration of a process simulation of the additive manufacturing process including a distortion compensation and temperature stabilization into a customized serial production by a considerable reduction of the simulation time.
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Blonde, Jackson D., Megan Roussy, Rogelio Luna, Borna Mahmoudian, Roberto A. Gulli, Kevin C. Barker, Jonathan C. Lau, and Julio C. Martinez-Trujillo. "Customizable cap implants for neurophysiological experimentation." Journal of Neuroscience Methods 304 (July 2018): 103–17. http://dx.doi.org/10.1016/j.jneumeth.2018.04.016.

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Rathore, Lakshya P., and Naina Verma. "Additive manufacturing in medical sciences: past, present and the future." International Journal of Research in Orthopaedics 5, no. 1 (December 25, 2018): 201. http://dx.doi.org/10.18203/issn.2455-4510.intjresorthop20185345.

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Additive manufacturing (AM) is a novel technique that despite having been around for more than 35 years, has been underutilized. Its great advantage lies in the basic fact that it is incredibly customizable. Since its use was recognized in various fields of medicine like orthopaedics, otorhinolaryngology, ophthalmology etc, it has proved to be one of the most promising developments in most of them. Customizable orthotics, prosthetics and patient specific implants and tracheal splints are few of its advantages. And in the future too, the combination of tissue engineering with AM is believed to produce an immense change in biological tissue replacement.
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Li, Cuidi, Xiaoyu Han, Zhenjiang Ma, Tianyang Jie, Jinwu Wang, Lianfu Deng, and Wenguo Cui. "Engineered Customizable Microvessels for Progressive Vascularization in Large Regenerative Implants." Advanced Healthcare Materials 11, no. 4 (November 28, 2021): 2101836. http://dx.doi.org/10.1002/adhm.202101836.

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Weksler, Benny. "Commentary: Three-dimensional printing and customizable implants: The future is now." JTCVS Techniques 8 (August 2021): 216–17. http://dx.doi.org/10.1016/j.xjtc.2021.05.006.

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El-Habashy, Salma E., Amal H. El-Kamel, Marwa M. Essawy, Elsayeda-Zeinab A. Abdelfattah, and Hoda M. Eltaher. "3D printed bioinspired scaffolds integrating doxycycline nanoparticles: Customizable implants for in vivo osteoregeneration." International Journal of Pharmaceutics 607 (September 2021): 121002. http://dx.doi.org/10.1016/j.ijpharm.2021.121002.

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Book chapters on the topic "Customizable implant"

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Gatenholm, Paul, Joel Berry, Andrea Rojas, Michael B. Sano, Rafael V. Davalos, Kara Johnson, and Laurie O’Rourke. "Bacterial Nanocellulose Biomaterials with Controlled Architecture for Tissue Engineering Scaffolds and Customizable Implants." In Bacterial NanoCellulose, 197–216. CRC Press, 2016. http://dx.doi.org/10.1201/b12936-11.

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"- Bacterial Nanocellulose Biomaterials with Controlled Architecture for Tissue Engineering Scaffolds and Customizable Implants." In Bacterial NanoCellulose, 230–49. CRC Press, 2016. http://dx.doi.org/10.1201/b12936-14.

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Conference papers on the topic "Customizable implant"

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Dodgen, Eric R., Larry Howell, and Anton Bowden. "Spinal Implant With Adjustable and Nonlinear Stiffness." In ASME 2011 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. ASMEDC, 2011. http://dx.doi.org/10.1115/detc2011-47913.

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The human spine is a complex mechanism composed of both passive and active components. The nonlinear stiffness of the passive components provides mechanical stability to the system. There is a need for spinal implants that have nonlinear stiffness to provide this stabilization if the spine loses stiffness through injury, degeneration, or surgery. There is also a need for spinal implants to be customizable for individual needs. This paper proposes contact-aided inserts to be used with the FlexSuRe™ spinal implant to create a nonlinear stiffness. Moreover, different inserts can be used to create different behaviors. To show this effect an elliptical contact surface is considered and the inserts are varied by changing the semi-major axis of the elliptical section. An analytical model is introduced for insert design, and the model is verified by comparing the models force-deflection profiles to a finite element model and tests of physical prototypes. The models and experiments demonstrate that it is feasible to create a spinal implant that has a nonlinear stiffness, and that different inserts can be used with the base implant to customize the behavior for individual needs. The analytical model developed is a tool available for implant design.
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Gkogkidis, C. A., C. Bentler, X. Wang, M. Gierthmuehlen, C. Scheiwe, H. Cristina Schmitz, J. Haberstroh, T. Stieglitz, and T. Ball. "Neurophysiological Evaluation of a Customizable μECoG-based Wireless Brain Implant*." In 2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC). IEEE, 2018. http://dx.doi.org/10.1109/embc.2018.8513044.

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Rynes, Matthew, Leila Ghanbari, Jay Jia Hu, Daniel Sousa Schulman, Gregory Johnson, Michael Laroque, and Suhasa B. Kodandaramaiah. "Principles of Computer Numerical Control Applied to Small Research Animal Surgical Procedures." In 2018 Design of Medical Devices Conference. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/dmd2018-6959.

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The tools and techniques available for systems neuroscientists for neural recording and stimulation during behavior have become plentiful in the last decade. The tools for implementing these techniques in vivo, however, have not advanced respectively. The use of these techniques requires the removal of sections of skull tissue without damaging the underlying tissue, which is a very delicate procedure requiring significant training. Automating a part of the tissue removal processes would potentially enable more precise procedures to be performed, and it could democratize these procedres for widespread adoption by neuroscience lab groups. Here, we describe the ‘Craniobot’, a microsurgery platform that combines automated skull surface profiling with a computer numerical controlled (CNC) milling machine to perform a variety of microsurgical procedures in mice. Surface profiling by the Craniobot has micrometer precision, and the surface profiling information can be used to perform milling operations with relatively quick, allowing high throughput. We have used the Craniobot to perform skull thinning, small to large craniotomies, as well as drilling pilot holes for anchoring cranial implants. The Craniobot is implemented using open source and customizable machining practices and can be built with of the shelf parts for under $1000.
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Orendain, Adam, Jose Carrasco, Eniko T. Enikov, and Gholam Peyman. "Evaluation of Electro-Spun Tubular Scaffolds to Create an Anastomosis Using the CAM Assay." In ASME 2013 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2013. http://dx.doi.org/10.1115/imece2013-64687.

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Central retinal vein occlusion (CRVO) is a vascular disease characterized by thrombosis of the retinal veins that can eventually lead to ischemia. Ischemic CRVO can then cause macular degeneration and neovascular glaucoma causing partial to full blindness. In this study, we determined the feasibility of electrospinning tubular scaffolds for treating CRVO and vascular disease. Electrospinning was utilized to produce customizable scaffolds from nano-bers using collagen type I. Scaffolds were treated with glutaraldehyde, glycine, ethanol, UV light, and combinations of the treatments for the purpose cross-linking and to study their angiogenic effects. Structural properties of the scaffolds were analyzed with scanning electron micrsoscopy (SEM). Scaffolds were immobilized with human recombinant vascular endothelial growth factor (rhVEGF165) to investigate the drug-delivering abilities of the electrospun materials and as a method to produce vascularization. The chick chorioallantoic membrane (CAM) assay was used to examine the effects of VEGF immobilizations and to evaluate the feasibility of creating an anastomosis to treat CRVO. Collagen onplants (non-electrospun) and electrospun implants were made on day 10 of embryonic development. Findings show collagen loaded with rhVEGF165 had improved vasculature and pro-angiogenic properties. The present study suggests that collagen can immobilize and release growth factor, be electrospun to mimic the ultrastructure of native blood vessels, and holds promise for vascular tissue engineering.
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