Your search keyword '"biomechanical characterization"' showing total 30 results

1. Influence of vascular embolism level and drug injection rate on thrombolytic therapy of bifurcated femoral vein: Numerical simulation and validation study

Author

Zhang, Xianglei, Cheng, Hongyu, Lin, Boyuan, Li, Sisi, Zhou, Hongming, Huang, Mingrui, and Wu, Jiahao

Published

2025

2. A novel in-situ dynamic mechanical analysis for human plantar soft tissue: The device design, definition of characteristics, test protocol, and preliminary results

Author

Wu, Longyan, Huang, Ran, Tang, Lisheng, Ning, Xinyi, Zhu, Jun, and Ma, Xin

Published

2024

3. An exploratory in-situ dynamic mechanical analysis on the shearing stress–strain mechanism of human plantar soft tissue

Author

Ran Huang, Xinyi Ning, Longyan Wu, Jun Zhu, Lisheng Tang, and Xin Ma

Subjects

Plantar soft tissue, In-vivo/in-situ, Shear modulus, Dynamic mechanical analysis, Biomechanical characterization, Medicine, Science

Abstract

Abstract A DMA (dynamic mechanical analysis)-like device based on the principle of classical viscoelasticity testing is invented to investigate the in-situ/in-vivo shear-bearing mechanism of plantar soft tissue. Forty-three volunteers were recruited for the shear-strain test in the longitudinal and transverse directions at five anatomical spots on the plantar surface. Several encouraging observations indicated significant variances among different spots and individuals, implying that the outer forefoot surrounding the second, fifth metatarsal head is a more intensive shear-bearing region on the plantar surface compared to the inner forefoot under the first metatarsal head, and drawing the hypothesis of a significant effect of BMI on the shear-bearing property. The speculations agree with our expectations and other previous research. The feasibility and practical value of this novel approach are substantiated, and these intriguing discoveries provide foundational underpinnings for further in-depth investigations.

Published

2024

4. Comprehensive Biomechanical Characterization of the Flexible Cat Spine via Finite Element Analysis, Experimental Observations, and Morphological Insights

Author

Lu, Da, Wu, Xueqing, Xu, Yangyang, Zhang, Shijia, Zhang, Le, Huang, Xin, and Pei, Baoqing

Published

2024

5. An exploratory in-situ dynamic mechanical analysis on the shearing stress–strain mechanism of human plantar soft tissue.

Author

Huang, Ran, Ning, Xinyi, Wu, Longyan, Zhu, Jun, Tang, Lisheng, and Ma, Xin

Subjects

DYNAMIC mechanical analysis, METATARSUS, VOLUNTEER recruitment, TISSUES

Abstract

A DMA (dynamic mechanical analysis)-like device based on the principle of classical viscoelasticity testing is invented to investigate the in-situ/in-vivo shear-bearing mechanism of plantar soft tissue. Forty-three volunteers were recruited for the shear-strain test in the longitudinal and transverse directions at five anatomical spots on the plantar surface. Several encouraging observations indicated significant variances among different spots and individuals, implying that the outer forefoot surrounding the second, fifth metatarsal head is a more intensive shear-bearing region on the plantar surface compared to the inner forefoot under the first metatarsal head, and drawing the hypothesis of a significant effect of BMI on the shear-bearing property. The speculations agree with our expectations and other previous research. The feasibility and practical value of this novel approach are substantiated, and these intriguing discoveries provide foundational underpinnings for further in-depth investigations. [ABSTRACT FROM AUTHOR]

Published

2024

6. Optical coherence elastography and its applications for the biomechanical characterization of tissues.

Author

Wang, Chongyang, Zhu, Jiang, Ma, Jiawei, Meng, Xiaochen, Ma, Zongqing, and Fan, Fan

Abstract

The biomechanical characterization of the tissues provides significant evidence for determining the pathological status and assessing the disease treatment. Incorporating elastography with optical coherence tomography (OCT), optical coherence elastography (OCE) can map the spatial elasticity distribution of biological tissue with high resolution. After the excitation with the external or inherent force, the tissue response of the deformation or vibration is detected by OCT imaging. The elastogram is assessed by stress–strain analysis, vibration amplitude measurements, and quantification of elastic wave velocities. OCE has been used for elasticity measurements in ophthalmology, endoscopy, and oncology, improving the precision of diagnosis and treatment of disease. In this article, we review the OCE methods for biomechanical characterization and summarize current OCE applications in biomedicine. The limitations and future development of OCE are also discussed during its translation to the clinic. [ABSTRACT FROM AUTHOR]

Published

2023

7. Analysis of the geometrical influence of ring-opening samples on arterial circumferential residual stress reconstruction

Author

Matías Inostroza, Andrés Utrera, Claudio M. García-Herrera, Eugenio Rivera, Diego J. Celentano, and Emilio A. Herrera

Subjects

residual stress, biomechanical characterization, soft tissues biomechanics, numerical simulation, ring opening, Biotechnology, TP248.13-248.65

Abstract

This work consists of analyzing the impact of geometrical features (thickness and curvature) on the estimation of circumferential residual stresses in arteries. For this purpose, a specific sample of lamb abdominal artery is chosen for analysis and, through computational tools based on Python libraries, the stress-free geometry is captured after the ring opening test. Numerical simulations are then used to reconstruct the sample in order to estimate the circumferential residual stresses. Then, four stress-free geometry models are analyzed: an ideal geometry, i.e., constant curvature and thickness; a constant curvature and variable thickness geometry; a variable curvature and constant thickness geometry; and a variable curvature and thickness geometry. The numerical results show that models perform well from a geometric point of view, where the most different feature was the closed outer perimeter that differs about 14% from the closed real sample. As far as residual stress is concerned, differences up to 198% were found in more realistic models taking a constant curvature and thickness model as reference. Thus, the analysis of a realistic geometry with highly variable curvature and thickness can introduce, compared to an idealized geometry, significant differences in the estimation of residual stresses. This could indicate that the characterization of arterial residual stresses is not sufficient when considering only the opening angle and, therefore, it is also necessary to incorporate more geometrical variables.

Published

2023

8. Mechanical Characterization of Human Fascia Lata: Uniaxial Tensile Tests from Fresh-Frozen Cadaver Samples and Constitutive Modelling.

Author

Bonaldi, Lorenza, Berardo, Alice, Pirri, Carmelo, Stecco, Carla, Carniel, Emanuele Luigi, and Fontanella, Chiara Giulia

Subjects

*TENSILE tests, *CONNECTIVE tissues, *COMPOSITE structures, *MEDICAL cadavers, *TISSUE engineering, *COLLAGEN

Abstract

Human Fascia Lata (FL) is a connective tissue with a multilayered organization also known as aponeurotic fascia. FL biomechanics is influenced by its composite structure formed by fibrous layers (usually two) separated by loose connective tissue. In each layer, most of the collagen fibers run parallel in a distinct direction (with an interlayer angle that usually ranges from 75–80°), mirroring the fascia's ability to adapt and withstand specific tensile loads. Although FL is a key structure in several musculoskeletal dysfunctions and in tissue engineering, literature still lacks the evidence that proves tissue anisotropy according to predominant collagen fiber directions. For this purpose, this work aims to analyze the biomechanical properties of ex-vivo FL (collected from fresh-frozen human donors) by performing uniaxial tensile tests in order to highlight any differences with respect to loading directions. The experimental outcomes showed a strong anisotropic behavior in accordance with principal collagen fibers directions, which characterize the composite structure. These findings have been implemented to propose a first constitutive model able to mimic the intra- and interlayer interactions. Both approaches could potentially support surgeons in daily practices (such as graft preparation and placement), engineers during in silico simulation, and physiotherapists during musculoskeletal rehabilitation, to customize a medical intervention based on each specific patient and clinical condition. [ABSTRACT FROM AUTHOR]

Published

2023

9. Towards the biomechanical modelling of the behaviour of ex-vivo porcine perineal tissues.

Author

Kadiaké, Tiguida, Lallemant, Marine, Chambert, Jérôme, Mottet, Nicolas, Lejeune, Arnaud, and Jacquet, Emmanuelle

Subjects

*PERINEUM, *TISSUE mechanics, *ANUS, *TISSUES, *PELVIC floor, *STRUCTURAL models

Abstract

The perineum is a layered soft tissue structure with mechanical properties that maintain the integrity of the pelvic floor. During childbirth, the perineum undergoes significant deformation that often results in tears of various degrees of severity. To better understand the mechanisms underlying perineal tears, it is crucial to consider the mechanical properties of the different tissues that make up the perineum. Unfortunately, there is a lack of data on the mechanical properties of the perineum in the literature. The objective of this study is to partly fill these gaps. Hence sow perineums were dissected and the five perineal tissues involved in tears were characterized by uniaxial tension tests: Skin, Vagina, External Anal Sphincter, Internal Anal Sphincter and Anal Mucosa. From our knowledge, this study is the first to investigate all these tissues and to design a testing protocol to characterize their material properties. Six material models were used to fit the experimental data and the correlation between experimental and predicted data was evaluated for comparison. As a result, even if the tissues are of different nature, the best correlation was obtained with the Yeoh and Martins material models for all tissues. Moreover, these preliminary results show the difference in stiffness between the tissues which indicates that they might have different roles in the structure. These obtained results will serve as a basis to design an improved experimental protocol for a more robust structural model of the porcine perineum that can be used for the human perineum to predict perineal tears. [ABSTRACT FROM AUTHOR]

Published

2024

10. Viscoelastic properties of the central region of porcine temporomandibular joint disc in shear stress-relaxation.

Author

Barrientos, Eva, Pelayo, Fernandez, Tanaka, Eiji, Lamela-Rey, María Jesús, and Fernández-Canteli, Alfonso

Subjects

*TEMPOROMANDIBULAR joint, *MODULUS of rigidity, *EVALUATION methodology, *PTERYGOID muscles

Abstract

In this study, shear relaxation properties of the porcine temporomandibular joint (TMJ) disc are investigated. Previous studies have shown that, in fatigue failure and damage of cartilage and fibrocartilage, shear loads could be one of the biggest contributors to the failure. The aim of the present study is to develop an evaluation method to study shear properties of the disc and to do a mathematical characterization of it. For the experiments, twelve porcine discs were used. Each disc was dissected from the TMJ and, then, static strain control tests were carried out to obtain the shear relaxation modulus for the central region of the discs. From the results, it was found that the disc presents a viscoelastic behavior under shear loads. Relaxation modulus decreased with time. Shear relaxation was 10% of the instantaneous stress, which implies that the viscous properties of the disc cannot be neglected. The present results lead to a better understanding of the discs mechanical behavior under realistic TMJ working conditions. [ABSTRACT FROM AUTHOR]

Published

2019

11. Biomechanical properties of the fascial system.

Author

Bonaldi, Lorenza, Berardo, Alice, Pirri, Carmelo, Stecco, Carla, and Fontanella, Chiara Giulia

Subjects

*FASCIAE (Anatomy), *CONNECTIVE tissues, *FAT cells, *ISLANDS of Langerhans, *MEDICAL rehabilitation

Abstract

The "fascial system" has been defined as a fascial network involved in functional aspects such as force transmission. The fascial system comprises the superficial and deep fasciae which are connected through skin ligaments, also known as retinacula, providing a continuity from the skin to the muscular plane (See Figure). Indeed, superficial and deep fascia roles in clinical disorders have been shown to reflect their structures. Specifically, the superficial fascia has been described anatomically as an irregular multilamellar structure of interconnected substrates with islets of fat cells. Meanwhile, for example, the deep aponeurotic fascia consists of multilayered structures of dense and loose connective tissues, where collagen fibers follow specific directions. Since the properties of superficial and deep fasciae mimic their structural organization, the biomechanical characterization of these tissues is key to understanding how they influence each other. Despite the clinical impact of these arguments, to date, the literature is still poor in data comparing different substrates of the fascial system through mechanical tests. Therefore, the aim of this work is to investigate this open topic by presenting the biomechanical properties of both superficial and deep fasciae. The study highlights how these tissues have different biomechanical properties in relation to their specific structures and functions. These results have a direct impact in the medical field such as in the surgical treatment of soft tissue repair or reconstruction, as well as in rehabilitation intervention (e.g., manual treatment). [ABSTRACT FROM AUTHOR]

Published

2023

12. On the impact of single cell biomechanics on the spatio-temporal organization of regenerative tissue

Author

Galle, J., Krinner, A., Buske, P., Drasdo, D., Loeffler, M., Magjarevic, Ratko, Dössel, Olaf, editor, and Schlegel, Wolfgang C., editor

Published

2010

13. Mechanical characterization of arteries affected by fetal growth restriction in guinea pigs (Cavia porcellus).

Author

Cañas, Daniel, García-Herrera, Claudio M., Herrera, Emilio A., Celentano, Diego J., and Krause, Bernardo J.

Subjects

BIOMECHANICS, FETAL growth disorders, GUINEA pigs, LOW birth weight, CARDIOVASCULAR diseases risk factors, DIAGNOSIS, DISEASES

Abstract

Abstract Fetal growth restriction (FGR) is a perinatal condition associated with a low birth weight that results mainly from maternal and placental constrains. Newborns affected by this condition are more likely to develop in the long term cardiovascular diseases whose origins would be in an altered vascular structure and function defined during fetal development. Thus, this study presents the modeling and numerical simulation of systemic vessels from guinea pig fetuses affected by FGR. We aimed to characterize the biomechanical properties of the arterial wall of FGR-derived the aorta, carotid, and femoral arteries by performing ring tensile and ring opening tests and, based on these data, to simulate the biomechanical behavior of FGR vessels under physiological conditions. The material parameters were first obtained from the experimental data of the ring tensile test. Then, the residual stresses were determined from the ring opening test and taken as initial stresses in the simulation of the ring tensile test. These two coupled steps are iteratively considered in a nonlinear least-squares algorithm to obtain the final material parameters. Then, the stress distribution changes along the arterial wall under physiological pressure were quantified using the adjusted material parameters. Overall, the obtained results provide a realistic approximation of the residual stresses and the changes in the mechanical behavior under physiological conditions. [ABSTRACT FROM AUTHOR]

Published

2018

14. Biomechanical characterization of the native porcine aortic root.

Author

Bechsgaard, T., Lindskow, T., Lading, T., Hasenkam, J.M., Røpcke, D.M., Nygaard, H., Johansen, P., and L. Nielsen, S.

Subjects

*BIOMECHANICS, *BIOMEDICAL engineering, *PORCINE somatotropin, *STIFFNESS (Mechanics), *ENERGY storage

Abstract

A thorough understanding of the well-functioning, native aortic root is pivotal in an era, where valve sparing surgical techniques are developed and used with increasing frequency. The objective of this study was to characterize the local structural stiffness of the native aortic root, to create a baseline for understanding how different surgical interventions affect the dynamics of the aortic root. In this acute porcine study (N = 10), two dedicated force transducers were implanted to quantify the forces acting on both the annular plane and on the sinotubular junction (STJ). To assess the changes in geometry, eleven sonomicrometry crystals were implanted within the aortic root. The combination of force and length measurements yields the radial structural stiffness for each segment of the aortic root. The least compliant segment at the annular plane was the right-left interleaflet triangle with a stiffness modulus of 1.1 N mm −1 (SD0.4). At the sinotubular junction the same segment (right-left) was most compliant, compared with the two other segments, however not statistically significant different. The elastic energy storage was derived from the aortic root pressure volume relationship; the mean elastic energy storage was 826 µJ (SD529). In conclusion, the aortic root has been characterized in terms of both segmental forces, segmental change in length and elastic energy storage. This study is the first to assess the radial structural stiffness of different segments of the aortic root. The presented data is reference for further studies regarding the impact of surgical interventions on the aortic root. [ABSTRACT FROM AUTHOR]

Published

2018

15. Comparison of Compressive Stress-Relaxation Behavior in Osteoarthritic (ICRS Graded) Human Articular Cartilage.

Author

Kumar, Rajesh, Pierce, David M., Isaksen, Vidar, Davies, Catharina de Lange, Drogset, Jon O., and Lilledahl, Magnus B.

Subjects

*OSTEOARTHRITIS, *ARTICULAR cartilage diseases, *PROTEOGLYCANS, *DIAGNOSTIC imaging, *TOTAL knee replacement

Abstract

Osteoarthritis (OA) is a common joint disorder found mostly in elderly people. The role of mechanical behavior in the progression of OA is complex and remains unclear. The stress-relaxation behavior of human articular cartilage in clinically defined osteoarthritic stages may have importance in diagnosis and prognosis of OA. In this study we investigated differences in the biomechanical responses among human cartilage of ICRS grades I, II and III using polymer dynamics theory. We collected 24 explants of human articular cartilage (eight each of ICRS grade I, II and III) and acquired stress-relaxation data applying a continuous load on the articular surface of each cartilage explant for 1180 s. We observed a significant decrease in Young’s modulus, stress-relaxation time, and stretching exponent in advanced stages of OA (ICRS grade III). The stretch exponential model speculated that significant loss in hyaluronic acid polymer might be the reason for the loss of proteoglycan in advanced OA. This work encourages further biomechanical modelling of osteoarthritic cartilage utilizing these data as input parameters to enhance the fidelity of computational models aimed at revealing how mechanical behaviors play a role in pathogenesis of OA. [ABSTRACT FROM AUTHOR]

Published

2018

16. Mechanical parameter assessment of fresh human cancellous bone of the femoral head in atraumatic femoral head necrosis and primary coxarthrosis.

Author

Fischer, Benjamin, Reise, Rebekka, Schleifenbaum, Stefan, and Roth, Andreas

Subjects

*ANALYSIS of bones, *OSTEONECROSIS, *HIP osteoarthritis, *TOTAL hip replacement, *DESCRIPTIVE statistics, *BIOMECHANICS, *FEMUR, *COLLECTION & preservation of biological specimens, *CANCELLOUS bone

Abstract

Atraumatic femoral head necrosis is a rare pathological change of the femoral head. It is characterized by local necrosis of the cancellous bone as a result of reduced blood supply to the bone. Even today it remains unclear how to assess the hardness of the necrosis, whether it is soft tissue that is easily removed, or hard tissue that is difficult to resect. Femoral heads with primary coxarthrosis were selected as a comparison group. For this purpose, 49 femoral heads obtained during total hip arthroplasty surgery with either condition (23 femoral head necrosis, 26 coxarthrosis) were transferred to the testing laboratory in fresh condition. Cylindrical specimens were obtained using a tenon cutter along the main trabecular load direction in the subchondral region of the femoral head. Additionally, thin bone slices were extracted proximal and distal to the specimens for density measurements. Brass plates were glued to the circular surfaces of the specimens. After curing of the adhesive, the specimens were mounted in the testing machine and destructive uniaxial compression tests were conducted. The recorded mean compressive strengths and elastic moduli were almost identical for both groups, but the necrosis group showed significantly higher data scattering and range regarding the elastic modulus. The mean density of the coxarthrosis specimens was significantly higher than that of the necrotic specimens. The mechanical properties of cancellous bone vary considerably in the presence of femoral head necrosis. The existence of hard necrosis implies a potential challenge regarding the clinical resection of these tissues. • Femoral head necrosis is very heterogeneous in appearance and mechanical properties. • Presence of sclerotic tissue has an increasing influence on the elastic modulus. • Mean density differs significantly between coxarthrosis and femoral head necrosis. [ABSTRACT FROM AUTHOR]

Published

2023

17. Dynamic and stress relaxation properties of the whole porcine temporomandibular joint disc under compression.

Author

Barrientos, Eva, Pelayo, Fernández, Tanaka, Eiji, Lamela-Rey, María Jesús, and Fernández-Canteli, Alfonso

Subjects

STRESS relaxation (Mechanics), TEMPOROMANDIBULAR joint, MATERIALS compression testing, VISCOELASTICITY, LABORATORY swine

Abstract

In this study, the dynamic and static compressive properties of the whole porcine temporomandibular joint (TMJ) disc were investigated. The aim of the study was to develop a new simple method for the evaluation of joint viscoelasticity, enabling examination of the load-bearing capacity and joint flexibility of the entire disc. For the experiments, a novel testing fixture that reproduces the condylar and fossa surfaces of the TMJ was developed to replicate TMJ disc geometry. Ten porcine discs were used in the experiments. Each disc was dissected from the TMJ and sinusoidal compressive strain was applied to obtain the storage and loss moduli. Static strain control tests were carried out to obtain the relaxation modulus. The result of static and dynamic tests indicated that the whole disc presented viscoelastic behavior under compression. Storage and loss moduli increased with frequency and the relaxation modulus decreased over time. The loss tangent showed less frequency dependence, with values ranging from 0.2 to 0.3, suggesting that the viscous properties of the disc cannot be neglected. These results provide a better understanding of whole disc mechanical compression behavior under realistic TMJ working conditions. [ABSTRACT FROM AUTHOR]

Published

2016

18. A new methodology for the in vivo estimation of the elastic constants that characterize the patient-specific biomechanical behavior of the human cornea.

Author

Lago, M. A., Rupérez, M. J., Martínez-Martínez, F., Monserrat, C., Larra, E., Güell, J. L., and Peris-Martínez, C.

Subjects

*BIOMECHANICS, *CORNEA diseases, *ELASTIC constants, *TONOMETRY, *FINITE element method

Abstract

This work presents a methodology for the in vivo characterization of the complete biomechanical behavior of the human cornea of each patient. Specifically, the elastic constants of a hyperelastic, secondorder Ogden model were estimated for 24 corneas corresponding to 12 patients. The inite element method was applied to simulate the deformation of human corneas due to non-contact tonometry, and an iterative search controlled by a genetic heuristic was used to estimate the elastic parameters that most closely approximates the simulated deformation to the real one. The results from a synthetic experiment showed that these parameters can be estimated with an error of about 5%. The results of 24 in vivo corneas showed an overlap of about 90% between simulation and real deformed cornea and a modified Hausdorff distance of 25 μm, which indicates the great accuracy of the proposed methodology. [ABSTRACT FROM AUTHOR]

Published

2015

19. Dynamic and stress relaxation properties of the whole porcine temporomandibular joint disc under compression

Author

Barrientos, Eva, Pelayo, Fernández, Tanaka, Eiji, Lamela-Rey, María Jesús, and Fernández-Canteli, Alfonso

Subjects

stomatognathic system, Experimental techniques, Soft tissues, Viscoelasticity, TMJ, Biomechanical characterization, Temporomandibular joint

Abstract

In this study, the dynamic and static compressive properties of the whole porcine temporomandibular joint (TMJ) disc were investigated. The aim of the study was to develop a new simple method for the evaluation of joint viscoelasticity, enabling examination of the load-bearing capacity and joint flexibility of the entire disc. For the experiments, a novel testing fixture that reproduces the condylar and fossa surfaces of the TMJ was developed to replicate TMJ disc geometry. Ten porcine discs were used in the experiments. Each disc was dissected from the TMJ and sinusoidal compressive strain was applied to obtain the storage and loss moduli. Static strain control tests were carried out to obtain the relaxation modulus. The result of static and dynamic tests indicated that the whole disc presented viscoelastic behavior under compression. Storage and loss moduli increased with frequency and the relaxation modulus decreased over time. The loss tangent showed less frequency dependence, with values ranging from 0.2 to 0.3, suggesting that the viscous properties of the disc cannot be neglected. These results provide a better understanding of whole disc mechanical compression behavior under realistic TMJ working conditions.

Published

2015

20. Évaluation de la biomécanique cardiovasculaire par élastographie ultrasonore non-invasive

Author

Porée, Jonathan, Cloutier, Guy, and Garcia, Damien

Subjects

maladies cardiovasculaires, ultrafast ultrasound imaging, cardiovascular disease, Élastographie quasi-statique, athérosclérose, biomechanical characterization, caractérisation biomécanique, atherosclerosis, Quasi-static elastography, imagerie ultrasonore ultrarapide

Abstract

L’élastographie est une technique d’imagerie qui vise à cartographier in vivo les propriétés mécaniques des tissus biologiques dans le but de fournir des informations diagnostiques additionnelles. Depuis son introduction en imagerie ultrasonore dans les années 1990, l’élastographie a trouvé de nombreuses applications. Cette modalité a notamment été utilisée pour l’étude du sein, du foie, de la prostate et des artères par imagerie ultrasonore, par résonance magnétique ou en tomographie par cohérence optique. Dans le contexte des maladies cardiovasculaires, cette modalité a un fort potentiel diagnostique puisque l’athérosclérose modifie la structure des tissus biologiques et leurs propriétés mécaniques bien avant l’apparition de tout symptôme. Quelle que soit la modalité d’imagerie utilisée, l’élastographie repose sur : l’excitation mécanique du tissu (statique ou dynamique), la mesure de déplacements et de déformations induites, et l’inversion qui permet de recouvrir les propriétés mécaniques des tissus sous-jacents. Cette thèse présente un ensemble de travaux d’élastographie dédiés à l’évaluation des tissus de l’appareil cardiovasculaire. Elle est scindée en deux parties. La première partie intitulée « Élastographie vasculaire » s’intéresse aux pathologies affectant les artères périphériques. La seconde, intitulée « Élastographie cardiaque », s’adresse aux pathologies du muscle cardiaque. Dans le contexte vasculaire, l’athérosclérose modifie la physiologie de la paroi artérielle et, de ce fait, ses propriétés biomécaniques. La première partie de cette thèse a pour objectif principal le développement d’un outil de segmentation et de caractérisation mécanique des composantes tissulaires (coeur lipidique, tissus fibreux et inclusions calciques) de la paroi artérielle, en imagerie ultrasonore non invasive, afin de prédire la vulnérabilité des plaques. Dans une première étude (Chapitre 5), nous présentons un nouvel estimateur de déformations, associé à de l’imagerie ultrarapide par ondes planes. Cette nouvelle méthode d’imagerie permet d’augmenter les performances de l’élastographie non invasive. Dans la continuité de cette étude, on propose une nouvelle méthode d’inversion mécanique dédiée à l’identification et à la quantification des propriétés mécaniques des tissus de la paroi (Chapitre 6). Ces deux méthodes sont validées in silico et in vitro sur des fantômes d’artères en polymère. Dans le contexte cardiaque, les ischémies et les infarctus causés par l’athérosclérose altèrent la contractilité du myocarde et, de ce fait, sa capacité à pomper le sang dans le corps (fonction myocardique). En échocardiographie conventionnelle, on évalue généralement la fonction myocardique en analysant la dynamique des mouvements ventriculaires (vitesses et déformations du myocarde). L’abscence de contraintes physiologiques agissant sur le myocarde (contrairement à la pression sanguine qui contraint la paroi vasculaire) ne permet pas de résoudre le problème inverse et de retrouver les propriétés mécaniques du tissu. Le terme d’élastographie fait donc ici référence à l’évaluation de la dynamique des mouvements et des déformations et non à l’évaluation des propriétés mécanique du tissu. La seconde partie de cette thèse a pour principal objectif le développement de nouveaux outils d’imagerie ultrarapide permettant une meilleure évaluation de la dynamique du myocarde. Dans une première étude (Chapitre 7), nous proposons une nouvelle approche d’échocardiographie ultrarapide et de haute résolution, par ondes divergentes, couplée à de l'imagerie Doppler tissulaire. Cette combinaison, validée in vitro et in vivo, permet d’optimiser le contraste des images mode B ainsi que l’estimation des vitesses Doppler tissulaires. Dans la continuité de cette première étude, nous proposons une nouvelle méthode d’imagerie des vecteurs de vitesses tissulaires (Chapitre 8). Cette approche, validée in vitro et in vivo, associe les informations de vitesses Doppler tissulaires et le mode B ultrarapide de l’étude précédente pour estimer l’ensemble du champ des vitesses 2D à l’intérieur du myocarde., Elastography is an imaging technique that aims to map the in vivo mechanical properties of biological tissues in order to provide additional diagnostic information. Since its introduction in ultrasound imaging in the 1990s, elastography has found many applications. This method has been used for the study of the breast, liver, prostate and arteries by ultrasound imaging, magnetic resonance imaging (MRI) or optical coherence tomography (OCT). In the context of cardiovascular diseases (CVD), this modality has a high diagnostic potential as atherosclerosis, a common pathology causing cardiovascular diseases, changes the structure of biological tissues and their mechanical properties well before any symptoms appear. Whatever the imaging modality, elastography is based on: the mechanical excitation of the tissue (static or dynamic), the measurement of induced displacements and strains, and the inverse problem allowing the quantification of the mechanical properties of underlying tissues. This thesis presents a series of works in elastography for the evaluation of cardiovascular tissues. It is divided into two parts. The first part, entitled « Vascular elastography » focuses on diseases affecting peripheral arteries. The second, entitled « Cardiac elastography » targets heart muscle pathologies. In the vascular context, atherosclerosis changes the physiology of the arterial wall and thereby its biomechanical properties. The main objective of the first part of this thesis is to develop a tool that enables the segmentation and the mechanical characterization of tissues (necrotic core, fibrous tissues and calcium inclusions) in the vascular wall of the peripheral arteries, to predict the vulnerability of plaques. In a first study (Chapter 5), we propose a new strain estimator, associated with ultrafast plane wave imaging. This new imaging technique can increase the performance of the noninvasive elastography. Building on this first study, we propose a new inverse problem method dedicated to the identification and quantification of the mechanical properties of the vascular wall tissues (Chapter 6). These two methods are validated in silico and in vitro on polymer phantom mimicking arteries. In the cardiac context, myocardial infarctions and ischemia caused by atherosclerosis alter myocardial contractility. In conventional echocardiography, the myocardial function is generally evaluated by analyzing the dynamics of ventricular motions (myocardial velocities and deformations). The abscence of physiological stress acting on the myocardium (as opposed to the blood pressure which acts the vascular wall) do not allow the solving the inverse problem and to find the mechanical properties of the fabric. Elastography thus here refers to the assessment of motion dynamics and deformations and not to the evaluation of mechanical properties of the tissue. The main objective of the second part of this thesis is to develop new ultrafast imaging tools for a better evaluation of the myocardial dynamics. In a first study (Chapter 7), we propose a new approach for ultrafast and high-resolution echocardiography using diverging waves and tissue Doppler. This combination, validated in vitro and in vivo, optimize the contrast in B-mode images and the estimation of myocardial velocities with tissue Doppler. Building on this study, we propose a new velocity vector imaging method (Chapter 8). This approach combines tissue Doppler and ultrafast B-mode of the previous study to estimate 2D velocity fields within the myocardium. This original method was validated in vitro and in vivo on six healthy volunteers.

Published

2017

21. Spine

Author

Wafa Skalli, Pierre-Yves Rohan, Clayton J. Adam, Maxim Van den Abbeele, Philippe Rouch, Sébastien Laporte, Arts et Métiers ParisTech, HESAM Université (HESAM), Institut de Biomecanique Humaine Georges Charpak, Université Paris 13 (UP13)-Arts et Métiers ParisTech, Queensland University of Technology [Brisbane] (QUT), Payan, Yohan, and Ohayon, Jacques

Subjects

090302 Biomechanical Engineering, Computer science, medicine.medical_treatment, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Human spine, medicine, vertebral mobility, Patient-Specific Modeling, Rehabilitation, biomechanical characterization, [SPI.MECA.BIOM]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Biomechanics [physics.med-ph], finite element modeling, Surgery planning, spine disorders, Spine biomechanics, multiscale modeling, Spine (zoology), Risk analysis (engineering), spine modeling, intervertebral disc, Fe model, Construct (philosophy), viscoelastic properties of intervertebral disc, 030217 neurology & neurosurgery, 110314 Orthopaedics

Abstract

International audience; Clinical problems of the human spine have a high prevalence, affecting more than 25.5 million people in 2012. Older adults, in particular, are susceptible to degenerative spine disorders such as deformities or osteoporosis. A basic requirement for proper management of various spinal disorders, effective injury prevention, and rehabilitation is a detailed knowledge of the fundamental biomechanics of the spine. Despite growing interest in biomechanical research on the spine during the last decades, however, many clinical problems remain largely unsolved, because of poor understanding of the underlying degeneration phenomena and the complexity of the spinal construct. In particular, diagnosis is challenging, because of the lack of tools to quantitatively assess soft tissue alteration, and because the most relevant clinical indices for diagnosis are not clearly established. Driven by ever-growing computer power and imaging devices, the development of FE models has become widespread, allowing scientists to overcome some of the existing shortcomings (invasiveness, complexity of the organization of the biological tissues, and complexity of establishing the loads present in the human spine, for example). These have emerged as powerful and reliable tools with considerable applications in surgery planning, in studying the etiology, progression, and effects of spinal deformities and intervertebral discs. These models have enhanced our understanding of the spine and will continue to do so. In our group, numerical work performed using FE modeling has highlighted the paramount influence of both geometric patient-specific modeling and in vivo personalization of tissue mechanical properties. Among the many exciting avenues for future research is the question of the validation of computational modeling and simulation with the perspective of supporting the development of medical devices.

Published

2017

22. Spine

Author

Payan, Y, Ohayon, J, Laporte, Sebastien, Van den Abbeele, Maxim, Rohan, Pierre-Yves, Adam, Clayton, Rouch, Philippe, Skalli, Wafa, Payan, Y, Ohayon, J, Laporte, Sebastien, Van den Abbeele, Maxim, Rohan, Pierre-Yves, Adam, Clayton, Rouch, Philippe, and Skalli, Wafa

Abstract

Spine disorders affect a large portion of the population, from children and adolescents (who suffer from deformities or trauma), to working age adults. More than 25.5 million people were affected by back or neck pain in 2012, resulting in 290.8 million workdays lost. Older adults form a continuously growing age group with degenerative spine disorders such as deformities or osteoporosis, affecting 10 million Americans, mostly women. Prevention is a key factor. However, it is still difficult because of the poor understanding of the underlying degeneration phenomena and the complexity of the spinal construct. Moreover, diagnosis is challenging, because of the lack of tools to quantitatively assess soft tissue alteration, and because the most relevant clinical indices for diagnosis are not clearly established. A subject-specific basis for treatment strategy is limited, because the cause of spinal disorders is often multifactorial. Although surgery is widely used, the rate of mechanical complications is still high, particularly for spine deformities. Such complications are often unpredictable, because the mechanisms yielding mechanical complications are difficult to understand. In this context, a biomechanical analysis of the spine is essential to better understand physiological behavior, the injury mechanisms, and the key factors to take into account in treatment. There are many exciting avenues for future research. Among these, the question of the validation of computational modeling and simulation with the perspective of supporting the development of medical devices is central. As highlighted by the US Food and Drug Administration (FDA), there is currently a lack of consistency and predictability of the review of computational models, which hinders their use for the evaluation of the safety and effectiveness of medical devices.

Published

2017

23. A new methodology for the in vivo estimation of the elastic constants that characterize the patient-specific biomechanical behavior of the human cornea

Author

Miguel A. Lago, J.L. Güell, M. J. Rupérez, Carlos Monserrat, E. Larra, Cristina Peris-Martínez, and F. Martínez-Martínez

Subjects

Adult, Male, Patient-Specific Modeling, Finite Element Analysis, Biomedical Engineering, Biophysics, Models, Biological, Cornea, Tonometry, Ocular, Optics, In vivo, medicine, Humans, Orthopedics and Sports Medicine, Mathematics, Ogden, business.industry, Rehabilitation, Patient specific, Elasticity, eye diseases, Finite element method, Biomechanical Phenomena, Hausdorff distance, medicine.anatomical_structure, Parameter optimization, Hyperelastic material, sense organs, Deformation (engineering), Biological system, business, Biomechanical characterization, LENGUAJES Y SISTEMAS INFORMATICOS, Algorithms

Abstract

This work presents a methodology for the in vivo characterization of the complete biomechanical behavior of the human cornea of each patient. Specifically, the elastic constants of a hyperelastic, second-order Ogden model were estimated for 24 corneas corresponding to 12 patients. The finite element method was applied to simulate the deformation of human corneas due to non-contact tonometry, and an iterative search controlled by a genetic heuristic was used to estimate the elastic parameters that most closely approximates the simulated deformation to the real one. The results from a synthetic experiment showed that these parameters can be estimated with an error of about 5%. The results of 24 in vivo corneas showed an overlap of about 90% between simulation and real deformed cornea and a modified Hausdorff distance of 25 mu m, which indicates the great accuracy of the proposed methodology. (C) 2014 Elsevier Ltd. All rights reserved., This project has been partially funded by MECD (reference AP2009-2414) and MINECO (INNPACTO, IPT-2012-0495-300000).

Published

2015

24. A new approach for the in-vivo characterization of the biomechanical behavior of the breast and the cornea

Author

Lago Ángel, Miguel Ángel, Monserrat Aranda, Carlos, Rupérez Moreno, María José, and Universitat Politècnica de València. Departamento de Sistemas Informáticos y Computación - Departament de Sistemes Informàtics i Computació

Subjects

Fem, Materials science, Similarity (geometry), Ogden, Constitutive equation, Function (mathematics), Finite element method, Genetic heuristics, Cornea, Search algorithm, Approximation error, Hyperelastic material, Breast, Biological system, Biomechanical characterization, LENGUAJES Y SISTEMAS INFORMATICOS, Biomedical engineering

Abstract

The characterization of the mechanical behavior of soft living tissues is a big challenge in Biomechanics. The difficulty arises from both the access to the tissues and the manipulation in order to know their physical properties. Currently, the biomechanical characterization of the organs is mainly performed by testing ex-vivo samples or by means of indentation tests. In the first case, the obtained behavior does not represent the real behavior of the organ. In the second case, it is only a representation of the mechanical response of the indented areas. The purpose of the research reported in this thesis is the development of a methodology to in-vivo characterize the biomechanical behavior of two different organs: the breast and the cornea. The proposed methodology avoids invasive measurements to obtain the mechanical response of the organs and is able to completely characterize of the biomechanical behavior of them.The research reported in this thesis describes a methodology to in-vivo characterize the biomechanical behavior of the breast and the cornea. The estimation of the elastic constants of the constitutive equations that define the mechanical behavior of these organs is performed using an iterative search algorithm which optimizes these parameters. The search is based on the iterative variation of the elastic constants of the model in order to increase the similarity between a simulated deformation of the organ and the real one. The similarity is measured by means of a volumetric similarity function which combines overlap-based coefficients and distance-based coefficients. Due to the number of parameters to be characterized as well as the non-convergences that the solution may present in some regions, genetic heuristics were chosen to drive the search algorithm.In the case of the breast, the elastic constants of an anisotropic hyperelastic neo-Hookean model proposed to simulate the compression of the breast during an MRI-guided biopsy were estimated. Results from this analysis showed that the proposed algorithm accurately found the elastic constants of the proposed model, providing an average relative error below 10%. The methodology was validated using breast software phantoms. Nevertheless, this methodology can be easily transferred into its use with real breasts. In the case of the cornea, the elastic constants of a hyperelastic second-order Ogden model were estimated for 24 corneas corresponding to 12 patients. The finite element method was applied in order to simulate the deformation of the human corneas due to non-contact tonometry. The iterative search was applied in order to estimate the elastic constants of the model which approximates the most the simulated deformation to the real one. Results showed that these constants can be estimated with an error of about 5%.After the results obtained for both organs, it can be concluded that the iterative search methodology presented in this thesis allows the \textit{in-vivo} estimation the patient-specific elastic constants of the constitutive biomechanical models that govern the biomechanical behavior of these two organs., Lago Ángel, MÁ. (2014). A new approach for the in-vivo characterization of the biomechanical behavior of the breast and the cornea [Tesis doctoral no publicada]. Universitat Politècnica de València. doi:10.4995/Thesis/10251/44116., Alfresco

Published

2014

25. A new methodology for the in vivo estimation of the elastic constants that characterize the patient-specific biomechanical behavior of the human cornea

Author

Universitat Politècnica de València. Instituto Interuniversitario de Investigación en Bioingeniería y Tecnología Orientada al Ser Humano - Institut Interuniversitari d'Investigació en Bioenginyeria i Tecnologia Orientada a l'Ésser Humà, Universitat Politècnica de València. Departamento de Sistemas Informáticos y Computación - Departament de Sistemes Informàtics i Computació, Ministerio de Educación, Ministerio de Economía y Competitividad, Lago, M. A., Rupérez Moreno, María José, Martínez Martínez, Francisco, Monserrat Aranda, Carlos, Larra, E., Gueell, J. L., Peris-Martinez, C., Universitat Politècnica de València. Instituto Interuniversitario de Investigación en Bioingeniería y Tecnología Orientada al Ser Humano - Institut Interuniversitari d'Investigació en Bioenginyeria i Tecnologia Orientada a l'Ésser Humà, Universitat Politècnica de València. Departamento de Sistemas Informáticos y Computación - Departament de Sistemes Informàtics i Computació, Ministerio de Educación, Ministerio de Economía y Competitividad, Lago, M. A., Rupérez Moreno, María José, Martínez Martínez, Francisco, Monserrat Aranda, Carlos, Larra, E., Gueell, J. L., and Peris-Martinez, C.

Abstract

This work presents a methodology for the in vivo characterization of the complete biomechanical behavior of the human cornea of each patient. Specifically, the elastic constants of a hyperelastic, second-order Ogden model were estimated for 24 corneas corresponding to 12 patients. The finite element method was applied to simulate the deformation of human corneas due to non-contact tonometry, and an iterative search controlled by a genetic heuristic was used to estimate the elastic parameters that most closely approximates the simulated deformation to the real one. The results from a synthetic experiment showed that these parameters can be estimated with an error of about 5%. The results of 24 in vivo corneas showed an overlap of about 90% between simulation and real deformed cornea and a modified Hausdorff distance of 25 mu m, which indicates the great accuracy of the proposed methodology. (C) 2014 Elsevier Ltd. All rights reserved.

Published

2015

26. Caractérisation biomécanique des anévrismes de l'aorte thoracique ascendante

Author

Romo Marquez, Aaron, Surfaces et Tissus Biologiques (STBio-ENSMSE), École des Mines de Saint-Étienne (Mines Saint-Étienne MSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT)-CIS, Ecole Nationale Supérieure des Mines de Saint-Etienne, and Stéphane Avril

Subjects

[SDV.SA]Life Sciences [q-bio]/Agricultural sciences, Ascending thoracic aorta, Mechanical properties identification, Caractérisation biomécanique, Identification des lois de comportement, Aneurysm, Biomechanical characterization, Aorte thoracique ascendante

Abstract

Epidemiology of aortic aneurysms is a major public health issue that affects a significant proportion of the population in industrialized countries and can cause the death of the patient in case of rupture of the aneurysm.Currently the only criteria for surgery are based on the morphology of the aneurysm, and there are problems to accurately assess the risk of rupture for each patient.The aim of this thesis was to develop a method to identify the mechanical properties of the arterial wall in a personalized way to refine the criteria for surgery.Inflation tests, full-field measurements and a methodology developed were used in order to quantify experimentally the stress distribution of aneurysms. It was possible to highlight the appearance of localized weakening in the wall which will let us predict the location of the rupture on the aneurysm. Then a method was developed to identify the mechanical properties of the aortic tissue. It was possible to highlight the heterogeneity of arterial tissue and locate the places where the rupture of the tissue may occur.The identification of the aneurysm’s mechanical properties from experimental data will improved arterial numerical models used today. In addition, the methodology developed for the analysis of the rupture of aneurysms during this thesis opens the door to a step that aims to develop the in vivo mechanical characterization by the use of medical imaging. The ultimate goal will be to assess the risk of rupture of the aneurysm of each patient in a noninvasive manner.; L’épidémiologie des anévrismes de l’aorte est un problème de santé publique majeur dans les pays industrialisés. Cette pathologie peut engendrer la mort du patient en cas de rupture de l’anévrisme. Actuellement les critères d’intervention chirurgicale sont basés sur la morphologie de l’anévrisme et il existe des difficultés à évaluer correctement le risque de rupture pour chaque patient. L’objectif de cette thèse était de développer une méthode d’identification des propriétés mécaniques de la paroi artérielle de manière personnalisée permettant d’affiner les critères d’intervention chirurgicale. Des essais de gonflement utilisant des mesures de champs et le développement d’une méthodologie d’analyse ont permis de quantifier la distribution des contraintes des anévrismes de manière expérimentale et de mettre en évidence l’apparition des affaiblissements ponctuels dans la paroi afin de prédire la localisation de la rupture de l’anévrisme. Ensuite, une méthode d’identification de propriétés mécaniques a été mise en place pour mettre en évidence l’hétérogénéité du tissu artériel et pour localiser les endroits à l’origine de la rupture du tissu. L’identification des lois de comportement à partir de données expérimentales issues de patients permettra d’améliorer les modèles numériques artériels utilisées aujourd’hui. De plus, la méthodologie créée pour l’analyse de la rupture d’anévrismes pendant cette thèse ouvre la porte à une étape qui vise à développer la caractérisation mécanique in-vivo par l’utilisation de l’imagerie médicale. L’objectif final sera d’évaluer le risque de rupture de l’anévrisme de chaque patient de manière non-invasive.

Published

2014

27. Biomechanical characterization of the ascending thoracic aortic aneurysms

Author

Romo Marquez, Aaron, STAR, ABES, Surfaces et Tissus Biologiques (STBio-ENSMSE), École des Mines de Saint-Étienne (Mines Saint-Étienne MSE), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT)-CIS, Ecole Nationale Supérieure des Mines de Saint-Etienne, and Stéphane Avril

Subjects

[SDV.SA]Life Sciences [q-bio]/Agricultural sciences, [SDV.SA] Life Sciences [q-bio]/Agricultural sciences, Ascending thoracic aorta, Mechanical properties identification, Caractérisation biomécanique, Identification des lois de comportement, Biomechanical characterization, Aneurysm, Aorte thoracique ascendante

Abstract

Epidemiology of aortic aneurysms is a major public health issue that affects a significant proportion of the population in industrialized countries and can cause the death of the patient in case of rupture of the aneurysm.Currently the only criteria for surgery are based on the morphology of the aneurysm, and there are problems to accurately assess the risk of rupture for each patient.The aim of this thesis was to develop a method to identify the mechanical properties of the arterial wall in a personalized way to refine the criteria for surgery.Inflation tests, full-field measurements and a methodology developed were used in order to quantify experimentally the stress distribution of aneurysms. It was possible to highlight the appearance of localized weakening in the wall which will let us predict the location of the rupture on the aneurysm. Then a method was developed to identify the mechanical properties of the aortic tissue. It was possible to highlight the heterogeneity of arterial tissue and locate the places where the rupture of the tissue may occur.The identification of the aneurysm’s mechanical properties from experimental data will improved arterial numerical models used today. In addition, the methodology developed for the analysis of the rupture of aneurysms during this thesis opens the door to a step that aims to develop the in vivo mechanical characterization by the use of medical imaging. The ultimate goal will be to assess the risk of rupture of the aneurysm of each patient in a noninvasive manner., L’épidémiologie des anévrismes de l’aorte est un problème de santé publique majeur dans les pays industrialisés. Cette pathologie peut engendrer la mort du patient en cas de rupture de l’anévrisme. Actuellement les critères d’intervention chirurgicale sont basés sur la morphologie de l’anévrisme et il existe des difficultés à évaluer correctement le risque de rupture pour chaque patient. L’objectif de cette thèse était de développer une méthode d’identification des propriétés mécaniques de la paroi artérielle de manière personnalisée permettant d’affiner les critères d’intervention chirurgicale. Des essais de gonflement utilisant des mesures de champs et le développement d’une méthodologie d’analyse ont permis de quantifier la distribution des contraintes des anévrismes de manière expérimentale et de mettre en évidence l’apparition des affaiblissements ponctuels dans la paroi afin de prédire la localisation de la rupture de l’anévrisme. Ensuite, une méthode d’identification de propriétés mécaniques a été mise en place pour mettre en évidence l’hétérogénéité du tissu artériel et pour localiser les endroits à l’origine de la rupture du tissu. L’identification des lois de comportement à partir de données expérimentales issues de patients permettra d’améliorer les modèles numériques artériels utilisées aujourd’hui. De plus, la méthodologie créée pour l’analyse de la rupture d’anévrismes pendant cette thèse ouvre la porte à une étape qui vise à développer la caractérisation mécanique in-vivo par l’utilisation de l’imagerie médicale. L’objectif final sera d’évaluer le risque de rupture de l’anévrisme de chaque patient de manière non-invasive.

Published

2014

28. A new approach for the in-vivo characterization of the biomechanical behavior of the breast and the cornea

Author

Monserrat Aranda, Carlos, Rupérez Moreno, María José, Universitat Politècnica de València. Departamento de Sistemas Informáticos y Computación - Departament de Sistemes Informàtics i Computació, Lago Ángel, Miguel Ángel, Monserrat Aranda, Carlos, Rupérez Moreno, María José, Universitat Politècnica de València. Departamento de Sistemas Informáticos y Computación - Departament de Sistemes Informàtics i Computació, and Lago Ángel, Miguel Ángel

Abstract

The characterization of the mechanical behavior of soft living tissues is a big challenge in Biomechanics. The difficulty arises from both the access to the tissues and the manipulation in order to know their physical properties. Currently, the biomechanical characterization of the organs is mainly performed by testing ex-vivo samples or by means of indentation tests. In the first case, the obtained behavior does not represent the real behavior of the organ. In the second case, it is only a representation of the mechanical response of the indented areas. The purpose of the research reported in this thesis is the development of a methodology to in-vivo characterize the biomechanical behavior of two different organs: the breast and the cornea. The proposed methodology avoids invasive measurements to obtain the mechanical response of the organs and is able to completely characterize of the biomechanical behavior of them. The research reported in this thesis describes a methodology to in-vivo characterize the biomechanical behavior of the breast and the cornea. The estimation of the elastic constants of the constitutive equations that define the mechanical behavior of these organs is performed using an iterative search algorithm which optimizes these parameters. The search is based on the iterative variation of the elastic constants of the model in order to increase the similarity between a simulated deformation of the organ and the real one. The similarity is measured by means of a volumetric similarity function which combines overlap-based coefficients and distance-based coefficients. Due to the number of parameters to be characterized as well as the non-convergences that the solution may present in some regions, genetic heuristics were chosen to drive the search algorithm. In the case of the breast, the elastic constants of an anisotropic hyperelastic neo-Hookean model proposed to simulate the compression of the breast during an MRI-guided biopsy were estimated. Resu

Published

2014

29. Biomechanical Characterization of Human Pluripotent Stem Cell-Derived Cardiomyocytes by Use of Atomic Force Microscopy.

Author

Pribyl J, Pešl M, Caluori G, Acimovic I, Jelinkova S, Dvorak P, Skladal P, and Rotrekl V

Subjects

Biosensing Techniques, Drug Evaluation, Preclinical, Humans, Biomechanical Phenomena, Microscopy, Atomic Force instrumentation, Microscopy, Atomic Force methods, Myocytes, Cardiac cytology, Pluripotent Stem Cells cytology

Abstract

Atomic force microscopy (AFM) is not only a high-resolution imaging technique but also a sensitive tool able to study biomechanical properties of bio-samples (biomolecules, cells) in native conditions-i.e., in buffered solutions (culturing media) and stable temperature (mostly 37 °C). Micromechanical transducers (cantilevers) are often used to map surface stiffness distribution, adhesion forces, and viscoelastic parameters of living cells; however, they can also be used to monitor time course of cardiomyocytes contraction dynamics (e.g. beating rate, relaxation time), together with other biomechanical properties. Here we describe the construction of an AFM-based biosensor setup designed to study the biomechanical properties of cardiomyocyte clusters, through the use of standard uncoated silicon nitride cantilevers. Force-time curves (mechanocardiograms, MCG) are recorded continuously in real time and in the presence of cardiomyocyte-contraction affecting drugs (e.g., isoproterenol, metoprolol) in the medium, under physiological conditions. The average value of contraction force and the beat rate, as basic biomechanical parameters, represent pharmacological indicators of different phenotype features. Robustness, low computational requirements, and optimal spatial sensitivity (detection limit 200 pN, respectively 20 nm displacement) are the main advantages of the presented method.

Published

2019

30. Choosing sheep (Ovis aries) as animal model for temporomandibular joint research: Morphological, histological and biomechanical characterization of the joint disc.

Author

Angelo DF, Morouço P, Alves N, Viana T, Santos F, González R, Monje F, Macias D, Carrapiço B, Sousa R, Cavaco-Gonçalves S, Salvado F, Peleteiro C, and Pinho M

Subjects

Animals, Biomechanical Phenomena, Compressive Strength, Dissection, Female, Imaging, Three-Dimensional, Temporomandibular Joint Disc cytology, Temporomandibular Joint Disc diagnostic imaging, Tensile Strength, Mandibular Condyle anatomy & histology, Models, Animal, Sheep, Domestic anatomy & histology, Temporomandibular Joint Disc anatomy & histology

Abstract

Preclinical trials are essential to the development of scientific technologies. Remarkable molecular and cellular research has been done using small animal models. However, significant differences exist regarding the articular behavior between these models and humans. Thus, large animal models may be more appropriate to perform trials involving the temporomandibular joint (TMJ). The aim of this work was to make a morphological (anatomic dissection and white light 3D scanning system), histological (TMJ in bloc was removed for histologic analysis) and biomechanical characterization (tension and compression tests) of sheep TMJ comparing the obtained results with human data. Results showed that sheep processus condylaris and fossa mandibularis are anatomically similar to the same human structures. TMJ disc has an elliptical perimeter, thinner in the center than in periphery. Peripheral area acts as a ring structure supporting the central zone. The disc cells display both fibroblast and chondrocyte-like morphology. Marginal area is formed by loose connective tissue, with some chondrocyte-like cells and collagen fibers in diverse orientations. Discs obtained a tensile modulus of 3.97±0.73MPa and 9.39±1.67MPa, for anteroposterior and mediolateral assessment. The TMJ discs presented a compressive modulus (E) of 446.41±5.16MPa and their maximum stress value (σmax) was 18.87±1.33MPa. Obtained results suggest that these animals should be considered as a prime model for TMJ research and procedural training. Further investigations in the field of oromaxillofacial surgery involving TMJ should consider sheep as a good animal model due to its resemblance of the same joint in humans., (Copyright © 2016 Elsevier Masson SAS. All rights reserved.)

Published

2016