Camila Ferreira Escobar scite author profile

Coating on prostheses and implantable devices is one of the ways to increase the osseointegration of these products. However, plasma spray techniques, that are normally used, present high complexity and high cost. In this work, a new methodology for coating with nanometric hydroxyapatite is presented, with a low cost and ease of production. The technique proposed involves the formation of a suspension of hydroxyapatite (HAp) and oil of turpentine (OT) and its application, with a paintbrush, on the titanium substrate. In order to qualify the process for medical devices, the properties of the titanium substrate, before and after the coating process, the calcium phosphate phases present and the adhesive bond of the coating were evaluated. The results indicated that thermal treatment does not affect the properties of ASTM F67 titanium in order to compromise the properties and the analyses, by X-ray diffraction and Raman spectroscopy, proved that no formation of second phases of calcium phosphate occurred. The adhesive bond assay showed that the coating behaved according to ISO 13779-2, i.e., it had adhesive bond values higher than 15 MPa. The proposed new coating method proved promising for the titanium coating and is an alternative to the complex and high cost processes normally used in metal implants.

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Thermal behaviour of drugs from binary and ternary systems

Veiga

Bernad

Escobar

1993

International Journal of Pharmaceutics

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Dissolution behaviour of drugs from binary and ternary systems

Veiga

Escobar

Bernad

1993

International Journal of Pharmaceutics

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Chemical and physical properties of nanocrystalline chitosan by the method: Modified nanochitosan complex and process of obtaining modified nanochitosan

Guimarães

Pighinelli

Paz

et al. 2020

Carbohydrate Research

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Mechanical properties, in vitro and in vivo biocompatibility analysis of pure iron porous implant produced by metal injection molding: A new eco-friendly feedstock from natural rubber (Hevea brasiliensis)

Wermuth

Paim

Bertaco

et al. 2021

Materials Science and Engineering: C

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Projeto, fabricação e avaliação de implantes craniofaciais personalizados: proposta de utilização de materiais combinados

Bertol¹,

Escobar²,

Kindlein³

et al. 2010

RBEB

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Resumo Um material adequado para a reconstrução óssea cranio facial deve ser simples de implantar, possuir forma adequada, resistência à fratura e à deformação similares ao osso original, ser eventualmente substituído por osso natural, ser largamente disponível e não possuir um custo muito elevado. Baseado no fato de que um material com todas estas características ainda não está disponível atualmente, tornase importante buscar novos materiais, novas composições e novas conformações. Diferentes biomateriais são utilizados atualmente para cirurgias de reconstrução craniofacial, cada um apresentando suas vantagens e limitações. Entre eles destacam-se o titânio, o polimetilmetacrilato e os cimentos de fosfato de cálcio. O titânio apresenta difícil conformação; o polimetilmetacrilato polimeriza-se por meio de uma reação exotérmica, podendo causar necrose de tecidos adjacentes ao implante; o cimento de fosfato de cálcio, por sua vez apresenta certa fragilidade, característica de alguns materiais cerâmicos. Neste sentido, este estudo examinou diferentes materiais utilizados para reconstrução craniofacial e suas propriedades mecânicas quando submetidos a ensaios de flexão, como o polimetilmetacrilato, o cimento de fosfato de cálcio e o cimento de fosfato de cálcio reforçado com titânio. Foi verificada a melhoria de propriedades mecânicas do cimento de fosfato de cálcio quando reforçado com malha de titânio. Além disso, este estudo apresenta uma técnica para o projeto e fabricação de implantes craniofaciais personalizados utilizando cimento de fosfato de cálcio reforçado com titânio, validada através de quatro casos de indicação cirúrgica de reconstrução craniofacial. Palavras-chave: Materiais para implantes craniofaciais personalizadosBertol, L. S.; Escobar, C. F.; Kindlein Júnior, W.; Santos, L. A.; Medeiros, E. B.; Torriani, M. A.; Bergmann, C. P.

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Electrochemical Impedance Spectroscopy: Evaluation of Drug Delivery System of Alpha-Tricalcium Phosphate Cement

Colpo

Pigatto

Escobar

et al. 2015

MSF

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Tricalcium phosphate cement (α-TCP) can be used in various fields of health, including as drug delivery systems. The application of a biomaterial based on α-TCP could enable both the constant drug delivery as support and shape damaged muscleskeletics tissues until which can be regenerated by the organism itself, replacing the biomaterial, while maintaining stable levels of the drug in the organism. The aim of this study was to evaluate the release of gentamicin sulfate using the technique of electrochemical impedance spectroscopy in drug delivery systems of α-TCP. The results obtained in vitro study validated the proposed methodology for assessment of controlled drug delivery systems on the basis of α-TCP.

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New eco-friendly binder based on natural rubber for ceramic injection molding process

Escobar

Santos

2015

Journal of the European Ceramic Society

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