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Simulation of the mechanical interlocking capacity of a rough bone implant surface during healing.
Malmö högskola, Faculty of Odontology (OD).
Malmö högskola, Faculty of Odontology (OD).
2015 (English)In: Biomedical engineering online, E-ISSN 1475-925X, Vol. 14, article id 45Article in journal (Refereed) Published
Abstract [en]

BACKGROUND: When an implant is inserted in the bone the healing process starts to osseointegrate the implant by creating new bone that interlocks with the implant. Biomechanical interlocking capacity is commonly evaluated in in vivo experiments. It would be beneficial to find a numerical method to evaluate the interlocking capacity of different surface structures with bone. In the present study, the theoretical interlocking capacity of three different surfaces after different healing times was evaluated by the means of explicit finite element analysis.

METHODS: The surface topographies of the three surfaces were measured with interferometry and were used to construct a 3D bone-implant model. The implant was subjected to a displacement until failure of the bone-to-implant interface and the maximum force represents the interlocking capacity.

RESULTS: The simulated ratios (test/control) seem to agree with the in vivo ratios of Halldin et al. for longer healing times. However the absolute removal torque values are underestimated and do not reach the biomechanical performance found in the study by Halldin et al. which might be a result of unknown mechanical properties of the interface.

CONCLUSION: Finite element analysis is a promising method that might be used prior to an in vivo study to compare the load bearing capacity of the bone-to-implant interface of two surface topographies at longer healing times.

Place, publisher, year, edition, pages
BioMed Central (BMC), 2015. Vol. 14, article id 45
National Category
Dentistry
Identifiers
URN: urn:nbn:se:mau:diva-18582DOI: 10.1186/s12938-015-0038-0ISI: 000354848000001PubMedID: 25994839Scopus ID: 2-s2.0-84929393587OAI: oai:DiVA.org:mau-18582DiVA, id: diva2:1474670
Available from: 2020-10-09 Created: 2020-10-09 Last updated: 2024-02-05Bibliographically approved
In thesis
1. On a biomechanical approach to analysis of stability and load bearing capacity of oral implants
Open this publication in new window or tab >>On a biomechanical approach to analysis of stability and load bearing capacity of oral implants
2015 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

IntroductionWhen an implant is placed in the bone the body responds to thetrauma by encapsulating the implant and its survival depends onthe ability for hard tissue encapsulation. The stability of the implantduring the healing phase is essential to achieve a good result[1]. Biological, physiological and mechanical phenomena affectimplant stability. To achieve sufficient stability during the initialhealing phase the implant has to provide sufficient static interactionwith the bone. The static interaction might affect the biologicalprocesses that in turn affect implant stability. Although, numerousstudies on the effect of dynamic interaction on implant stabilityand bone remodeling exist, the effect of static strain has yetto be clarified.As the healing progresses it may result in bone formation in closecontact with the implant (i.e osseointegration) that stabilizes theimplant. It has been found that implant surface modifications atthe micro level promote osseointegration and that moderatelyroughened implants provide rapid and strong bone response [2, 3].In addition, the application of nanostructures to an implant surfacehas been shown to elicit an initial complex gene response that mayresult in further enhancement in bone formation around the implant[4]. Furthermore the implant surface structure interlocks mechanicallywith the bone that affects the stability of the implant.The implant surface design has to take into account both biologicaland mechanical behavior of the tissues.Materials and methodsTo investigate how implant stability and the biological responseare affected by an induced static load to the bone an in vivo studywas performed. Two types of controlled static loads, excessive andmoderate, were induced by specially designed implants. Two typesof surface structure, turned and blasted, were applied on the implants.The implants were inserted in rabbits and healed for 3-84days before the stability was measured by removal torque.To simulate how the pressure changes, due to biological and mechanicalphenomena, on an implant surface that was subjected toan initial pressure, a constitutive model was developed that wascomprised of visco-elastic, visco-plastic and remodeling components.The pressure on the surface in turn affects the implant stability.To investigate how the biomechanical and the biological responsesare affected by the surface structure an in vivo study and a finiteelement analysis of the theoretical interfacial shear strength wereperformed. In the pre-clinical study, three groups of implants withdifferent nano- and microstructures were compared to an implantwith a control surface structure.The theoretical interfacial strength at different healing times wasestimated by simulating the surface structure interlocking capacityto bone using an explicit finite element method. Simulations wereperformed for different surface structures and for different pressures,simulating visco-elastic and remodeling phenomena.ResultsImplants that induced a moderate bone condensation in the bonehad a significantly higher removal torque value at the implantationtimes of 3-24 days compared to implants that did not induce condensation.The effect the induced moderate bone condensation hadon implant stability decreases over time until the pressure has vanished,which approximately occurred after 28-30 days. Turned implants,placed in tibia, that induced excessive bone condensationresulted in significant increased implant stability at implantationtimes of 3-24 days compared to implants that induced no condensation.However, when they were placed in femur it provided nosignificant difference in removal torque at an implantation time of24 days compared to implants that induced no condensation.The developed constitutive model is able to capture visco-elasticmaterial behavior and remodeling phenomena of cortical bonewhich can be used to simulate how the pressure changes on an implantsurface that is subjected to an initial pressure caused by condensation.The implant nano- and microsurface structure affects the magnitudeof the removal torque value. It was found that implants, withno significant difference in surface roughness parameters (Sa, Ssk,Sdr) on micro level, can present a significant difference in removaltorque value at 4 weeks of implantation time. In addition, it wasalso found that implants with a significant difference in surfaceroughness parameters (Sa, Ssk, Sdr) can present no significant differencein removal torque value at 4 weeks of implantation times. Thedifference may be due to various biological responses from thenano- and microstructure surfaces.The simulated interfacial strength for the different surfaces did notreach the interfacial strength that corresponds to the removaltorque obtained in the in vivo study. Comparing the two surfaces in respect of removal torque ratio, suggests that during the earlyhealing phase the difference is caused by different bone formationrates from biological processes. As the healing progresses the effectof structural interlocking capacity is more pronounced.ConclusionsThe results suggest that increased static strain in the bone not onlycreates higher implant stability at the time of insertion, but alsogenerates increased implant stability throughout the observationperiod of 3-24 days. The proposed constitutive material model consists of three differentcomponents: a visco-elastic component, a visco-plastic componentand a remodeling component. The model captures with goodagreement the experimental behavior of cortical bone during differentlongitudinal loading situations i.e. in vitro stress-strain relationship,in vivo relaxation, in vitro creep and in vivo remodeling.The results of the present study suggest that nano- and microstructurealteration on a blasted implant might enhance the initial biomechanicalperformance, while for longer healing times, the surfaceinterlocking capacity seems to be more important.Simulation of the interfacial shear strength by means of finite elementanalysis seems to be a promising method to estimate the loadbearing capacity of the bone-to-implant interface for different surfacestructures at stable healing conditions i.e. longer healing times.Furthermore, it is a promising method to estimate the implant stabilityfor different magnitudes of condensation.

Place, publisher, year, edition, pages
Malmö university. Faculty of Odontology, 2015. p. 160
Series
Doctoral Dissertation in Odontology
Keywords
animal model, bone resorption, implant stability, cortical bone, viscoelastic-viscoplastic, creep remodeling, constitutive model
National Category
Dentistry
Identifiers
urn:nbn:se:mau:diva-7690 (URN)18626 (Local ID)9789171044075 (ISBN)9789171044082 (ISBN)18626 (Archive number)18626 (OAI)
Note

Note: The papers are not included in the fulltext online.

Paper V in dissertation as accepted manuscript, paper VI as manuscript.

Available from: 2020-02-28 Created: 2020-02-28 Last updated: 2024-03-15Bibliographically approved

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