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58. Identification of the matrix elastoplastic properties in reinforced active brazing alloys

Author

Galli, M., Cugnoni, J., Botsis, J., and Janczak-Rusch, J.

Subjects
Carbon-Fibers, Size, particle reinforcement, Alumina, finite element analysis (FEA), metal matrix composites (MMCs), Joints, Strength, mechanical properties, Composite Filler Materials, Model
Abstract

The mechanical response of the reinforced active alloy Incusil (TM) ABA (R)-SiC is studied. Specimens with up to 27 vol.% SiC particles are produced and tested in tension. The presence of the reinforcement leads to modifications in the alloy mechanical response and microstructure, with a decrease in the volume fraction of Ti-containing phases. To study the in situ response of the matrix material in the composites an inverse homogenization approach is proposed. The identified responses of the matrix materials are softer than that of unreinforced Incusil (TM) ABA (R). These results are experimentally confirmed by studying the effect of Ti-addition to Incusil (TM) ABA (R), a braze alloy whose composition is close to that of Incusil (TM) ABA (R) without Ti. (c) 2008 Elsevier Ltd. All rights reserved.

59. L'hydroptere: How multidisciplinary scientific research may help break the sailing speed record

Author

Calmon, M., Farhat, M., Fua, P., Startchev, K., Bonnier, G., Månson, J. -A, Michaud, V., Sigg, A., Marc Oggier, Deville, M. O., Braun, O., Sawley, M. L., Blecha, L., Cugnoni, J., Bourgeon, J. M., Dyen, S., Moyon, D., Schmäh, D., Amacher, R., and Colegrave, D.

Abstract

In 2009, l’Hydroptère broke the symbolic barrier of 50 knots and became the world fastest sailing boat over both 500 meters and 1 nautical mile. This major achievement relied on the high skills of the sailing team but also on technical advances of the boat, resulting from the scientific collaboration between the Hydroptère Design Team and the Ecole Polytechnique Fédérale de Lausanne (EPFL). In the present article, we highlight the multidisciplinary research activity performed within EPFL in the course of this collaboration involving aero- and hydrodynamics, materials and structure as well as computer vision. Various foils were tested at reduced scale in a high speed water tunnel, and the results used to validate the numerical simulations. Composite materials, their processing parameters and assembly components were tested. The structural behaviour was also investigated to determine strains and stresses in normal and extreme sailing conditions, taking waves into account, and a combined model was derived for dynamic simulation. Finally, advanced computer vision methods were developed and implemented on the boat to monitor foil immersion and cross beams deformations.

62. An experimental-numerical study of moisture absorption in an epoxy

Author

Lai, M., Botsis, J., Cugnoni, J., and Coric, D.

Subjects
System, Hygric Characterization, History, Glass-Transition Temperature, Strains, Environmental degradation, Single-Fiber Composite, Fbg Sensor, Water Sorption, Micro-mechanics, Desorption, Fiber Bragg Gratings, Resin, Numerical analysis
Abstract

It is well known that moisture absorption impairs the mechanical and physical properties of polymers. Conventionally, the material's hygric strains are described as the product of a constant coefficient of moisture expansion (CME) and moisture concentration. This hypothesis, however, has not been thoroughly examined experimentally. In this paper, the hygro-mechanical response of a DGBA based epoxy is reported as a function of moisture uptake. Cylindrical specimens are made of epoxy with an axially located optical fiber that contains a 23 mm Bragg grating sensor (FBG). Strain data from the sensor and from a micrometer are combined with experimental absorption curves to determine the resin's CME. The data indicate that diffusion and CME depend on moisture. Analysis of the experiments is carried out by numerical simulations of heat transfer, moisture diffusion and elastic stress analysis of the single fiber composite. The simulated results correlate well with the experimental data. (C) 2012 Elsevier Ltd. All rights reserved.

63. Interfacial Intermetallic Growth and Strength of Composite Lead-Free Solder Alloy Through Isothermal Aging

Author

Sivasubramaniam, V., Bosco, N.S., Janczak-Rusch, J., Cugnoni, J., Botsis, J., Sivasubramaniam, V., Bosco, N.S., Janczak-Rusch, J., Cugnoni, J., and Botsis, J.

Abstract

The effects of particle reinforcement of Sn-4.0wt.%Ag-0.5wt.%Cu (SAC405) lead-free solder on interfacial intermetallic layer growth and strength of the ensuing joints through short-term isothermal aging (150°C) were studied. Composite solders were prepared by either incorporating 2wt.% Cu (3μm to 20μm) or Cu2O (∼150nm) particles into SAC405 paste. Aggressive flux had the effect of reducing the Cu2O nanoparticles into metallic Cu which subsequently reacted with the solder alloy to form the Cu6Sn5 intermetallic. While all solders had similar interfacial intermetallic growth upon reflow, both of the composite solders' growth rates slowed through aging to reach a common growth rate exponent of approximately 0.38, considerably lower than that of the nonreinforced solder (n=0.58). The nanoscale reinforced solder additionally exhibited the highest tensile strength in both the initial and aged conditions, behavior also attributed to its quick conversion to a stable microstructure

64. A Study of the Shear Response of a Lead-Free Composite Solder by Experimental and Homogenization Techniques

Author

Sivasubramaniam, V., Galli, M., Cugnoni, J., Janczak-Rusch, J., Botsis, J., Sivasubramaniam, V., Galli, M., Cugnoni, J., Janczak-Rusch, J., and Botsis, J.

Abstract

The current study proposes a combined experimental and modeling approach to characterize the mechanical response of composite lead-free solders. The influence of the reinforcement volume fraction on the shear response of the solder material in the joint is assessed. A novel optimized geometry for single lap shear specimens is proposed. This design minimizes the effect of plastic strain localization, leading to a significant improvement of the quality of experimental data. The constitutive model of the solder material is numerically identified from the load-displacement response of the joint by using inverse finite element identification. Experimental results for a composite solder with 0.13 reinforcement volume fraction indicate that the presence of the reinforcement leads to a 23% increase of the ultimate stress and a 50% decrease of the ultimate strain. To interpret experimental data and predict the elastoplastic response of the composite solder for varying particle volume fraction, a three-dimensional (3D) homogenization model is employed. The agreement between experiments and homogenization results leads to the conclusion that the increase in the ultimate strength and the decrease in ductility are to be attributed to load sharing between matrix material and particles with the development of a significant triaxial stress state which restricts plastic flow in the matrix

69. A functional approach towards the design, development, and test of an affordable dynamic prosthetic foot.

Author

Falbriard M, Huot G, Janier M, Chandran R, Rechsteiner M, Michaud V, Cugnoni J, Botsis J, Schönenberger K, and Aminian K

Subjects
Biomechanical Phenomena, Foot, Gait, Humans, Prosthesis Design, Amputees rehabilitation, Artificial Limbs
Abstract

Humanitarian actors involved in physical rehabilitation, such as the International Committee of the Red Cross (ICRC), usually provide their beneficiaries with lower-limb prostheses comprising Solid Ankle Cushion Heel (SACH) feet as these are considered appropriate (price, durability, low profile to fit a majority of patients, appearance) and reliable for all ambulation levels. However, individuals in low-resource settings having higher ambulation abilities would greatly benefit from dynamic prosthetic feet with improved biomechanics and energy storage and release. Some attempts tried to address this increasing need (e.g. Niagara Foot) but most products proposed by large manufacturers often remain unaffordable and unsuitable to the context of low-resource settings. The design requirements and a price target were defined in partnership with the ICRC according to their initial assessment and used as a starting point for the development process and related technological choices. Numerical simulation and modeling were used to work on the design and to determine the required materials properties (mechanical, chemical, wear), and a cost modeling tool was used to select suitable materials and relevant processing routes (price vs. performance). A prosthetic foot comprising an internal keel made of composite materials, a filling foam, and a cosmetic shell with a foot shape was developed. Manufacturing processes meeting the cost criteria were identified and prototype feet were produced accordingly. These were successfully tested using a compression testing system before gait analyses were performed in the laboratory with non-amputees wearing testing boots. After validation in laboratory conditions, the prototype foot was tested in the field (Vietnam) with 11 trans-tibial unilateral amputees, who showed an increased mobility compared with the SACH foot. The collaboration of different research fields led to the development of a prosthetic foot which met the technical requirements determined by the ICRC's specific needs in its field of operation. The materials and selected production processes led to a manufacturing cost of less than 100 USD per part., Competing Interests: The authors have declared that no competing interests exist.

Published
2022
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70. Numerical prediction of peri-implant bone adaptation: Comparison of mechanical stimuli and sensitivity to modeling parameters.

Author

Piccinini M, Cugnoni J, Botsis J, Ammann P, and Wiskott A

Subjects
Animals, Female, Osseointegration, Rats, Rats, Sprague-Dawley, Stress, Mechanical, Weight-Bearing, Adaptation, Physiological, Finite Element Analysis, Prostheses and Implants, Tibia physiology
Abstract

Long term durability of osseointegrated implants depends on bone adaptation to stress and strain occurring in proximity of the prosthesis. Mechanical overloading, as well as disuse, may reduce the stability of implants by provoking bone resorption. However, an appropriate mechanical environment can improve integration. Several studies have focused on the definition of numerical methods to predict bone peri-implant adaptation to the mechanical environment. Existing adaptation models differ notably in the type of mechanical variable adopted as stimulus but also in the bounds and shape of the adaptation rate equation. However, a general comparison of the different approaches on a common benchmark case is still missing and general guidelines to determine physically sound parameters still need to be developed. This current work addresses these themes in two steps. Firstly, the histograms of effective stress, strain and strain energy density are compared for rat tibiae in physiological (homeostatic) conditions. According to the Mechanostat, the ideal stimulus should present a clearly defined, position and tissue invariant lazy zone in homeostatic conditions. Our results highlight that only the octahedral shear strain presents this characteristic and can thus be considered the optimal choice for implementation of a continuum level bone adaptation model. Secondly, critical modeling parameters such as lazy zone bounds, type of rate equation and bone overloading response are classified depending on their influence on the numerical predictions of bone adaptation. Guidelines are proposed to establish the dominant model parameters based on experimental and simulated data., (Copyright © 2016 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published
2016
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71. Peri-implant bone adaptations to overloading in rat tibiae: experimental investigations and numerical predictions.

Author

Piccinini M, Cugnoni J, Botsis J, Ammann P, and Wiskott A

Subjects
Animals, Biomechanical Phenomena, Bone Density, Female, Finite Element Analysis, Implants, Experimental, Rats, Rats, Sprague-Dawley, Stress, Mechanical, Tibia diagnostic imaging, Titanium, Tomography, X-Ray Computed, Dental Implantation, Endosseous methods, Dental Implants, Osseointegration physiology, Tibia surgery
Abstract

Objectives: (i) To assess the effects of mechanical overloading on implant integration in rat tibiae, and (ii) to numerically predict peri-implant bone adaptation., Materials and Methods: Transcutaneous titanium implants were simultaneously placed into both tibiae of rats (n = 40). After 2 weeks of integration, the implants of the right tibiae were stimulated daily for 4 weeks with loads up to 5N (corresponding to peak equivalent strains of 3300 ± 500 με). The effects of stimulation were assessed by ex vivo mechanical tests and quantification of bone mineral density (BMD) in selected regions of interests (ROIs). Specimen-specific finite element models were generated and processed through an iterative algorithm to mimic bone adaptation., Results: Bilateral implantation provoked an unstable integration that worsened when mild (2-4N) external loads were applied. In contrast, a stimulation at 5N tended to "counterbalance" the harmful effects of daily activity and, if applied to well-integrated specimens, significantly augmented the implants' resistance to failure (force: +73% P < 0.01, displacement: +50% P < 0.01 and energy: +153% P < 0.01). Specimen-specific numerical predictions were in close agreement with the experimental findings. Both local and overall BMD variations, as well as the implants' lateral stability, were predicted with small errors (0.14 gHA/cm 3 and 0.64%, respectively)., Conclusions: The rats' daily activity detrimentally affects implant integration. Conversely, external stimulations of large magnitudes counterbalance this effect and definitively improve integration. These changes can be predicted using the proposed numerical approach., (© 2016 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published
2016
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72. Influence of gait loads on implant integration in rat tibiae: experimental and numerical analysis.

Author

Piccinini M, Cugnoni J, Botsis J, Ammann P, and Wiskott A

Subjects
Animals, Rats, Titanium, Finite Element Analysis, Gait, Materials Testing, Prostheses and Implants, Tibia physiology, Weight-Bearing
Abstract

Implanted rat bones play a key role in studies involving fracture healing, bone diseases or drugs delivery among other themes. In most of these studies the implants integration also depends on the animal daily activity and musculoskeletal loads, which affect the implants mechanical environment. However, the tissue adaption to the physiological loads is often filtered through control groups or not inspected. This work aims to investigate experimentally and numerically the effects of the daily activity on the integration of implants inserted in the rat tibia, and to establish a physiological loading condition to analyse the peri-implant bone stresses during gait. Two titanium implants, single and double cortex crossing, are inserted in the rat tibia. The animals are caged under standard conditions and divided in three groups undergoing progressive integration periods. The results highlight a time-dependent increase of bone samples with significant cortical bone loss. The phenomenon is analysed through specimen-specific Finite Element models involving purpose-built musculoskeletal loads. Different boundary conditions replicating the post-surgery bone-implant interaction are adopted. The effects of the gait loads on the implants integration are quantified and agree with the results of the experiments. The observed cortical bone loss can be considered as a transient state of integration due to bone disuse atrophy, initially triggered by a loss of bone-implant adhesion and subsequently by a cyclic opening of the interface., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published
2014
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73. A toolbox of oligopeptide-modified polymers for tailored elastomers.

Author

Croisier E, Liang S, Schweizer T, Balog S, Mionić M, Snellings R, Cugnoni J, Michaud V, and Frauenrath H

Subjects
Biocompatible Materials chemistry, Protein Structure, Secondary, Protein Structure, Tertiary, Elastomers chemistry, Nanostructures chemistry, Oligopeptides chemistry, Polyenes chemistry, Polymers chemistry
Abstract

Biomaterials are constructed from limited sets of building blocks but exhibit extraordinary and versatile properties, because hierarchical structure formation lets them employ identical supramolecular motifs for different purposes. Here we exert a similar degree of structural control in synthetic supramolecular elastomers and thus tailor them for a broad range of thermomechanical properties. We show that oligopeptide-terminated polymers selectively self-assemble into small aggregates or nanofibrils, depending on the length of the oligopeptides. This process is self-sorting if differently long oligopeptides are combined so that different nanostructures coexist in bulk mixtures. Blends of polymers with oligopeptides matching in length furnish reinforced elastomers that exhibit shear moduli one order of magnitude higher than the parent polymers. By contrast, novel interpenetrating supramolecular networks that display excellent vibration damping properties are obtained from blends comprising non-matching oligopeptides or unmodified polymers. Hence, blends of oligopeptide-modified polymers constitute a toolbox for tailored elastomers with versatile properties.

Published
2014
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74. Factors affecting subject-specific finite element models of implant-fitted rat bone specimens: critical analysis of a technical protocol.

Author

Piccinini M, Cugnoni J, Botsis J, Zacchetti G, Ammann P, and Wiskott A

Subjects
Animals, Bone Density, Bone and Bones diagnostic imaging, Computer Simulation, Elasticity, Models, Biological, Prostheses and Implants, Rats, Rats, Sprague-Dawley, Tomography, X-Ray Computed, Bone and Bones physiology, Finite Element Analysis
Abstract

The authors propose a protocol to derive finite element (FE) models from micro computer tomography scans of implanted rat bone. A semi-automatic procedure allows segmenting the images using specimen-specific bone mineral density (BMD) thresholds. An open-source FE model generator processes the segmented images to a quality tetrahedral mesh. The material properties assigned to each element are integrated from the BMD field. Piecewise, threshold-dependent density-elasticity relationships are implemented to limit the effects of metal artefacts. A detailed sensitivity study highlights the coherence of the generated models and quantifies the influence of the modelling parameters on the results. Two applications of the protocol are proposed. The stiffness of bare and implanted rat tibiae specimens is predicted by simulating three-point bending and inter-implant displacement, respectively. Results are compared with experimental tests. The mean value and the variability between the specimens are well captured in both tests.

Published
2014
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75. External mechanical microstimuli modulate the osseointegration of titanium implants in rat tibiae.

Author

Zacchetti G, Wiskott A, Cugnoni J, Botsis J, and Ammann P

Subjects
Animals, Rats, Stress, Mechanical, Tibia pathology, Titanium chemistry, Bone Development, Osseointegration, Prostheses and Implants, Tibia growth & development
Abstract

Purpose: To assess the effect of external mechanical microstimuli of controlled magnitude on the microarchitecture of the peri-implant bone beds in rat tibiae., Materials and Methods: Tibiae of forty rats were fitted with two transcutaneous titanium cylinders. After healing, the implants were loaded to 1 to 3 N, five days/week for four weeks. These force levels translated into intraosseous strains of 700 ± 200 με, 1400 ± 400 με, and 2100 ± 600 με. After sacrifice, the implants' pullout strength was assessed. Second, the bone's microarchitecture was analyzed by microcomputed tomography (μCT) in three discrete regions of interest (ROIs). Third, the effect of loading on bone material properties was determined by nanoindentation., Results: The trabecular BV/TV significantly increased in an ROI of 0.98 mm away from the test implant in the 1 N versus the 3 N group with an opposite trend for cortical thickness. Pull-out strength significantly increased in the 2 N relatively to the nonstimulated group. Higher values of E-modulus and hardness were observed in the trabecular bone of the 2 N group., Conclusion: The in vivo mechanical loading of implants induces load-dependent modifications in bone microarchitecture and bone material properties in rat tibiae. In pull-out strength measurements, implant osseointegration was maximized at 2 N (1400 ± 400 με).

Published
2013
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76. Implementation of the "loaded implant" model in the rat using a miniaturized setup--description of the method and first results.

Author

Wiskott HW, Bonhote P, Cugnoni J, Durual S, Zacchetti G, Botsis J, Scherrer SS, and Ammann P

Subjects
Animals, Dental Prosthesis Design, Dental Stress Analysis, Implants, Experimental, Miniaturization, Models, Animal, Osseointegration, Rats, Rats, Sprague-Dawley, Tibia surgery, Titanium, Dental Implantation, Endosseous methods, Dental Implants, Immediate Dental Implant Loading
Abstract

Objective: To miniaturize the "loaded implant" model to permit its application to small rodents. In this model, two titanium implants are placed 8 mm apart with their heads protruding from the skin and are forced together by a dedicated actuator. To assess the effect of (i) the post-implantation healing period and the duration of stimulation and (ii) the intratissular strain level on the microtomographical bone parameters BV/TV, Tb.N., Tb.Th. and BIC., Materials and Methods: Implants, 1 × 8 mm, were machined, inserted into the tibiae of rats and activated. A total of 123 animals were used. In series 1, the implants were left to heal for 2/4 weeks and then loaded to generate intratissular strains of 1125 ± 5% με for 4/8 weeks. Series 2 had their implants loaded to 750, 1500 and 2250 ± 5% με, respectively., Results: Bone to implant contact increased upon loading. In series 1, no difference was observed regarding the duration of healing or the stimulation period. In series 2, at 750 με, the bone parameters did not differ from baseline. At 1500 με, all four parameters increased. At 2250 με, three of four parameters decreased relative to 1500 με., Conclusions: (i) The loaded implant model can be miniaturized to the millimeter range; (ii) in the present model, implant activation beyond 4 weeks did not affect the bone parameters; (iii) mechanical stimulation increased bone to implant contact by up to 20%; (iv) the results obtained are consistent with the concept of an anabolic effect from 750 to 1500 με and deleterious effects at strains in the 2250 με range; and (v) strains at 2250 με did not lead to implant dis-integration., (© 2011 John Wiley & Sons A/S.)

Published
2012
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77. Poroviscoelastic characterization of particle-reinforced gelatin gels using indentation and homogenization.

Author

Galli M, Fornasiere E, Cugnoni J, and Oyen ML

Subjects
Animals, Ceramics chemistry, Gels, Hardness, Linear Models, Porosity, Gelatin chemistry, Hardness Tests methods, Viscoelastic Substances chemistry
Abstract

Hydrogels are promising materials for bioengineering applications, and are good model materials for the study of hydrated biological tissues. As these materials often have a structural function, the measurement of their mechanical properties is of fundamental importance. In the present study gelatin gels reinforced with ceramic microspheres are produced and their poroviscoelastic response in spherical indentation is studied. The constitutive responses of unreinforced gels are determined using inverse finite element modeling in combination with analytical estimates of material parameters. The behavior of composite gels is assessed by both analytical and numerical homogenization. The results of the identification of the constitutive parameters of unreinforced gels show that it is possible to obtain representative poroviscoelastic parameters by spherical indentation without the need for additional mechanical tests. The agreement between experimental results on composite gelatin and the predictions from homogenization modeling show that the adopted modeling tools are capable of providing estimates of the poroviscoelastic response of particle-reinforced hydrogels., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published
2011
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78. Hydro-mechanical coupling in the periodontal ligament: a porohyperelastic finite element model.

Author

Bergomi M, Cugnoni J, Galli M, Botsis J, Belser UC, and Wiskott HW

Subjects
Animals, Biomechanical Phenomena, Cattle, Compressive Strength, Computer Simulation, Elasticity, Extracellular Fluid physiology, Finite Element Analysis, Hydrodynamics, In Vitro Techniques, Permeability, Porosity, Stress, Mechanical, Models, Biological, Periodontal Ligament physiology
Abstract

Harmonic tension-compression tests at 0.1, 0.5 and 1 Hz on hydrated bovine periodontal ligament (PDL) were numerically simulated. The process was modeled by finite elements (FE) within the framework of poromechanics, with the objective of isolating the contributions of the solid- and fluid phases. The solid matrix was modeled as a porous hyperelastic material (hyperfoam) through which the incompressible fluid filling the pores flowed in accordance with the Darcy's law. The hydro-mechanical coupling between the porous solid matrix and the fluid phase circulating through it provided an apparent time-dependent response to the PDL, whose rate of deformation depended on the permeability of the porous solid with respect to the interstitial fluid. Since the PDL was subjected to significant deformations, finite strains were taken into account and an exponential dependence of PDL permeability on void ratio - and therefore on the deformation state - was assumed. PDL constitutive parameters were identified by fitting the simulated response to the experimental data for the tests at 1 Hz. The values thus obtained were then used to simulate the tests at 0.1 and 0.5 Hz. The results of the present simulation demonstrate that a porohyperelastic model with variable permeability is able to describe the two main aspects of the PDL's response: (1) the dependency on strain-rate-the saturated material can develop volumetric strains by only exchanging fluid and (2) the asymmetry between tension and compression, which is due to the effect of both the permeability and the elastic properties on deformation., (Copyright © 2010 Elsevier Ltd. All rights reserved.)

Published
2011
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79. Three-dimensional morphometry of strained bovine periodontal ligament using synchrotron radiation-based tomography.

Author

Bergomi M, Cugnoni J, Wiskott HW, Schneider P, Stampanoni M, Botsis J, and Belser UC

Subjects
Animals, Blood Vessels diagnostic imaging, Blood Vessels physiology, Cattle, Microcirculation physiology, Periodontal Ligament blood supply, Periodontal Ligament diagnostic imaging, Periodontal Ligament physiology, Porosity, Specimen Handling methods, Stress, Mechanical, Synchrotrons, Tomography, X-Ray Computed methods, Ultrasonography, Periodontal Ligament anatomy & histology
Abstract

The periodontal ligament (PDL) is a highly vascularized soft connective tissue. Previous studies suggest that the viscous component of the mechanical response may be explained by the deformation-induced collapse and expansion of internal voids (i.e. chiefly blood vessels) interacting with liquids (i.e. blood and interstitial fluids) flowing through the pores. In the present work we propose a methodology by means of which the morphology of the PDL vascular plexus can be monitored at different levels of compressive and tensile strains. To this end, 4-mm-diameter cylindrical specimens, comprising layers of bone, PDL and dentin covered by cementum, were strained at stretch ratios ranging from lambda = 0.6 to lambda = 1.4 and scanned using synchrotron radiation-based computer tomography. It was concluded that: (1) the PDL vascular network is layered in two distinct planes of blood vessels (BVs): an inner layer (close to the tooth), in which the BVs run in apico-coronal direction, and an outer layer (close to the alveolar bone), in which the BVs distribution is more diffuse; (2) during tension and compression, the porosity tissue is kept fairly constant; (3) mechanical straining induces important changes in BV diameters, possibly modifying the permeability of the PDL and thus contributing to the viscous component of the viscoelastic response observed under compressive forces.

Published
2010
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80. The role of the fluid phase in the viscous response of bovine periodontal ligament.

Author

Bergomi M, Cugnoni J, Botsis J, Belser UC, and Anselm Wiskott HW

Subjects
Animals, Biomechanical Phenomena, Body Fluids physiology, Cattle, Compressive Strength, In Vitro Techniques, Models, Biological, Stress, Mechanical, Tensile Strength, Viscosity, Periodontal Ligament physiology
Abstract

The mechanical response of the periodontal ligament (PDL) is complex. This tissue responds as a hyperelastic solid when pulled in tension while demonstrating a viscous behavior under compression. This intricacy is reflected in the tissue's morphology, which comprises fibers, glycosaminoglycans, a jagged interface with the surrounding porous bone and an extensive vascular network. In the present study we offer an analysis of the viscous behavior and the interplay between the fibrous matrix and its fluid phase. Cylindrical specimens comprising layers of dentine, PDL and bone were extracted from bovine first molars and affixed to a tensile-compressive loading machine. The viscous properties of the tissue were analyzed (1) by subjecting the specimens to sinusoidal displacements at various frequencies and (2) by cycling the specimens in 'fully saturated' and in 'partially dry' conditions. Both modes assisted in determining the contribution of the fluid phase to the mechanical response. It was concluded that: (1) PDL showed pseudo-plastic viscous features for cyclic compressive loading, (2) these viscous features essentially resulted from interactions between the porous matrix and unbound fluid content of the tissue. Removing the liquid from the PDL largely eliminates its damping effect in compression., (Copyright 2010. Published by Elsevier Ltd.)

Published
2010
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81. Bone reactions to controlled loading of endosseous implants: a pilot study.

Author

Wiskott HW, Cugnoni J, Scherrer SS, Ammann P, Botsis J, and Belser UC

Subjects
Animals, Bone Density, Bone Remodeling, Bone and Bones diagnostic imaging, Implants, Experimental, Models, Biological, Pilot Projects, Porosity, Rabbits, Tibia surgery, X-Ray Microtomography, Bone and Bones pathology, Dental Implantation, Endosseous methods, Dental Implants, Dental Stress Analysis instrumentation
Abstract

Objectives: To validate an experimental setup designed to apply load onto bone tissue using osseointegrated implants in a rabbit model. Specifically, (1) to design an apparatus capable of generating controlled forces, (2) to assess implant placement, maintenance and loading and (3) to evaluate outcome variables using three radiological methods., Material and Methods: New Zealand White rabbits were used. Two dental implants were inserted 15-18 mm apart in the animals' tibiae. After 3 months of healing, the implants were loaded normal to their long axes using a pneumatically activated device. A 15 min load regimen at 1 Hz was applied 5 days per week. Every week the applied load was increased by 5 N up to week 8 and by 10 N up to 100 N by week 14. Groups of animals (n=3) were sacrificed at load levels 25, 50 and 100 N. One unloaded controlateral implant in each group provided the baseline data. The rabbits were computer tomography (CT) scanned and radiographed using conventional frames every 4-5 weeks. After sacrifice, a volume of interest (VOI) located in the inter-implant zones and a VOI set as a ring surrounding the distal implant were analyzed using micro computer tomography (microCT)., Results: A variety of osseous responses was observed, ranging from minor alterations to significant increases in porosity and lamelling of the cortical layer. microCT data of the inter-implant VOI demonstrated an initial increase in total volume (upto 50 N) followed by stabilization. Concomitantly, bone volumetric density first decreased and then augmented until the end of the experiment. This phenomenon was not observed in the peri-implant VOI, for which volumetric density augmented from the beginning to the end of the experiment., Conclusions: 1. In future trials the loading devices must be constructed so as to sustain heavy cyclic loads over prolonged periods. 2. When properly handled, rabbits are cooperative animals in this application. In a third of the sites, signs of inflammation were observed. 3. In the inter-implant VOI, the cortical bone tended to react in two phases: first, as an increase in porosity and lamelling and second, as an augmentation of bone volumetric density. The peri-implant VOI adapted only by augmenting volumetric density.

Published
2008
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