R. L. Cabrini scite author profile

Osseointegration was originally defined as a direct structural and functional connection between ordered living bone and the surface of a load‐carrying implant. It is now said that an implant is regarded as osseointegrated when there is no progressive relative movement between the implant and the bone with which it is in direct contact. Although the term osseointegration was initially used with reference to titanium metallic implants, the concept is currently applied to all biomaterials that have the ability to osseointegrate. Biomaterials are closely related to the mechanism of osseointegration; these materials are designed to be implanted or incorporated into the living system with the aims to substitute for, or regenerate, tissues and tissue functions. Objective evaluation of the properties of the different biomaterials and of the factors that influence bone repair in general, and at the bone tissue–implant interface, is essential to the clinical success of an implant. The Biomaterials Laboratory of the Oral Pathology Department of the School of Dentistry at the University of Buenos Aires is devoted to the study and research of the properties and biological effects of biomaterials for dental implants and bone substitutes. This paper summarizes the research work resulting from over 25 years’ experience in this field. It includes studies conducted at our laboratory on the local and systemic factors affecting the peri‐implant bone healing process, using experimental models developed by our research team. The results of our research on corrosion, focusing on dental implants, as well as our experience in the evaluation of failed dental implants and bone biopsies obtained following maxillary sinus floor augmentation with bone substitutes, are also reported. Research on biomaterials and their interaction with the biological system is a continuing challenge in biomedicine, which aims to achieve optimal biocompatibility and thus contribute to patient health.

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Macrophages Related to Dental Implant Failure

Olmedo¹,

Fernández²,

Guglielmotti³

et al. 2003

Implant Dentistry

115

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Alveolar wound healing and ridge remodeling after tooth extraction in the rat: A histologic, radiographic, and histometric study

Guglielmotti

Cabrini

1985

Journal of Oral and Maxillofacial Surgery

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Oral Mucosa Tissue Response to Titanium Cover Screws

Olmedo

Paparella

Spielberg³

et al. 2012

Journal of Periodontology

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Biological response of tissues with macrophagic activity to titanium dioxide

Olmedo

Tasat

Evelson

et al. 2007

J Biomedical Materials Res

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The titanium dioxide layer is composed mainly of anatase and rutile. This layer is prone to break, releasing particles to the milieu. Therefore, corrosion may cause implant failure and body contamination. We have previously shown that commercial anatase-titanium dioxide (TiO(2)-anatase) is deposited in organs with macrophagic activity, transported in the blood by phagocytic-mononuclear cells, and induces an increase in the production of reactive oxygen species (ROS). In this study, we evaluated the effects of rutile-titanium dioxide (TiO(2)-rutile). Male Wistar rats were injected i.p. with a suspension of TiO(2)-rutile powder at a dose of 1.60 g/100 g b.w. Six months postinjection, the presence of Ti was assessed in serum, blood cells, liver, spleen, and lung. Titanium was found in phagocytic mononuclear cells, serum, and in the parenchyma of all the organs tested. TiO(2)-rutile generated a rise in the percentage of reactive cells, which was smaller than that observed when TiO(2)-anatase was employed in a previous study. Although TiO(2)-rutile provoked an augmentation of ROS, it failed to induce damage to membrane lipids, possibly due to an adaptive response. The present study reveals that TiO(2)-rutile is less bioreactive than TiO(2)-anatase.

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Biological performance of boron-modified bioactive glass particles implanted in rat tibia bone marrow

Gorustovich¹,

López²,

Guglielmotti³

et al. 2006

Biomed. Mater.

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The aim of the present study was to characterize the neoformed bone tissue around boron-modified bioactive glass particles implanted in rat tibia bone marrow by histologic, histomorphometric and microchemical evaluation. Melt-derived glasses were prepared from a base 45S5 bioactive glass of nominal composition (45% SiO(2), 24.5% CaO, 24.5% Na(2)O and 6% P(2)O(5) in wt%). The glass composition was modified by adding 2% wt of boron oxide (45S5.2B). Histological and histomorphometric analyses using undecalcified sections showed that at 15 days post-implantation the area of neoformed bone tissue around the 45S5.2B particles was significantly higher than control 45S5 glass. No statistically significant differences were observed at 30 days post-implantation. The thickness of osseointegrated tissue on 45S5.2B BG particles was significantly greater than on the control at all experimental time-points evaluated. A statistically significant increase in the Ca:P ratio was observed in the neoformed bone around 45S5.2B particles 15 days post-implantation. The results of the present study provide evidence that particles of boron-modified 45S5 BG (45S5.2B) enhance bone formation more than 45S5 glass when implanted into the intramedullary canal of rat tibiae.

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R. L. Cabrini

Reactive lesions of peri-implant mucosa associated with titanium dental implants: a report of 2 cases

Exfoliative Cytology and Titanium Dental Implants: A Pilot Study

Research on implants and osseointegration

Macrophages Related to Dental Implant Failure

Alveolar wound healing and ridge remodeling after tooth extraction in the rat: A histologic, radiographic, and histometric study

Oral Mucosa Tissue Response to Titanium Cover Screws

Biological response of tissues with macrophagic activity to titanium dioxide

Biological performance of boron-modified bioactive glass particles implanted in rat tibia bone marrow

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