Global ETD Search

51	The Effects of Mechanical Loading on the Local Myofibrogenic Differentiation of Aortic Valve Interstitial Cells Watt, Derek Randall 25 July 2008 (has links) Calcific aortic valve sclerosis is characterized by focal lesions in the valve leaflet. These lesions are rich in myofibroblasts that express α-SMA and cause fibrosis. Lesions tend to occur in regions of the leaflet that are subjected to large bending loads, suggesting a mechanobiological basis for myofibrogenic differentiation and valve pathogenesis. In this thesis, a bioreactor was developed to study the effect of physiological loading on myofibrogenic differentiation of valve interstitial cells. Cyclic loading of native porcine aortic valve leaflets ex vivo resulted in increased α-SMA expression, predominantly in the fibrosa and spongiosa (similar to sclerotic leaflets). Cofilin, an actin-binding protein, was also upregulated by loading, suggesting it plays a role in mechanically-induced myofibrogenesis. Similarly, loading of a tissue engineered aortic valve leaflet model resulted in increased α-SMA transcript and protein expression. These data support an integral role for mechanical stimuli in myofibrogenic differentiation and sclerosis in the aortic valve. Mechanobiology Tissue Engineering Myofibroblasts α-Smooth Muscle Actin Cofilin Aortic Valve Disease 0541
52	The Development of a 3D Piezoelectric Active Microtissue Model for Airway Smooth Muscle Walker, Matthew 08 April 2013 (has links) Although asthma is primarily thought to be an inflammatory disease of the airways, it has recently been hypothesized that the altered mechanical environment of an asthmatic airway may contribute to the development of the disease through changes in cellular phenotype. In regards to this hypothesis, the effects of stretch on airway smooth muscle (ASM) have previously been investigated using 2D cell culture. However, over the last few years there has been an increasing appreciation to the importance of the role of the 3D extracellular matrix in the regulation of cellular response. For this reason, the work presented in this thesis covers the development of a device capable of high-throughput investigations into the effects of acute or chronic, uniaxial, oscillatory mechanical strain on an array of miniature, 3D, multi-cell, tissue-engineered constructs. Microtisse Piezoelectric 3D Cell Culture Airway Smooth Muscle Stretch Asthma Mechanobiology
53	Mechanobiological analyses of healing tendons using computational approaches Bajuri, Mohd Nazri Bin January 2016 (has links) The healing process of ruptured tendons is problematic due to scar tissue formation and deteriorated material properties. In some cases, it may take nearly a year to complete. Mechanical loading has been shown to positively influence tendon healing; however, the mechanisms remain unclear. Computational mechanobiology methods employed extensively to model bone healing have achieved high fidelity, but not yet been explored to understand tendon regeneration. The general objective of this thesis is to develop computational approaches to enhance the knowledge of the role that mechanical factors play in fibre re-organisation in healing tendons, by proposing an appropriate constitutive formulation, followed by analysing the mechano-adaptation of the models created when regulated by different biophysical stimuli. Curve fitting of an established hyperelastic fibre-reinforced continuum model introduced by Gasser, Ogden and Holzapfel (GOH) against experimental tensile testing data of rat Achilles tendons at four timepoints during the tendon repair was used and achieved excellent fits (0.9903 &LT; R<sup>2</sup> &LT; 0.9986). A parametric sensitivity study using a three-level central composite design, which is a fractional factorial design method, showed that the collagen-fibre-related parameters in the GOH model had almost equal influence on the fitting. The mechano-adaptation of the healing tendons when regulated by axial and principal strain predicted fibre re-organisation comparable to experimental findings, in contrast to models regulated by deviatoric strain. Also, mechano-adaptive models regulated by deviatoric strain were more spatially and temporally sensitive to different boundary conditions - length and loading magnitudes - than those regulated by axial and principal strain. This thesis describes that a hyperelastic fibre-reinforced mechano-adaptive model regulated by axial or principal strain is generally capable of describing the mechanobiological behaviours of healing tendons, and that further experiments should focus on establishing the localised structural and material parameters of collagen fibres and their mechano-adaptive behaviours in the healing tissue.
54	Impact des contraintes physiques sur la maturation des mégacaryocytes : rôle de la rigidité de l'environnement / Impact of physical constraints on megakaryocytes’ maturation : role of the environmental stiffness Aguilar, Alicia 10 April 2017 (has links) La mégacaryopoïèse regroupe l’ensemble des processus de différenciation et de maturation des mégacaryocytes (MKs) dans le but de produire des plaquettes capables d’arrêter les saignements. Or ces mécanismes sont mal connus. Afin de mieux les comprendre, nous avons mimé l’environnement médullaire in vitro, en 3D à l’aide d’un hydrogel de rigidité comparable à celle de la moelle osseuse. Dans cette étude nous avons: i) caractérisé le comportement physique de l’hydrogel de méthylcellulose et mis au point la culture de progéniteurs mégacaryocytaires dans ce système, ii) montré la capacité du MK à ressentir les contraintes physiques de son environnement, ainsi que, iii) l’impact de ces contraintes sur la maturation des MKs et la génération des proplaquettes, et enfin, iv) mis en évidence l’existence d’une réponse cellulaire des MKs à la rigidité. Les MKs sont « mécanosensibles », c’est-à-dire capables de ressentir les modifications physiques de leur environnement et de s’y adapter. L’activation de voies de mécanotransduction (dont MKL1) et la réorganisation du cytosquelette en réponse aux contraintes physiques extracellulaires favorisent la maturation des MKs, en termes de ploïdie, d’ultrastructure et in fine de génération de proplaquettes. / Megakaryopoiesis is the process of differentiation and maturation of megakaryocytes (MKs) in the aim to produce platelets able to prevent hemorrhages. These mechanisms are not well known. To better understand the process of platelet formation, we mimicked the medullar microenvironment in vitro, in 3D using hydrogel of stiffness comparable to the bone marrow. In this study we: i) characterized the physical properties of the hydrogel and design the culture of hematopoietic progenitors in this system, ii) showed the MKs ability to feel the physical constraints of their environment, then iii) showed the impact of these constraints on the MK maturation and proplatelet generation, and finally iv) highlighted the MK response to stiffness. MKs are “mecanosensitives”, being able to feel and to adapt to the physicals modifications of the environment. The activation of mechanotransduction pathways (including MKL1) and the cytoskeleton reorganization in response to extracellular physical constraints improves MK maturation, in terms of ploïdy, ultrastructure and ultimately proplatelet generation. Mégacaryocyte Rigidité Environnement Mécanobiologie Culture 3D Megakaryocyte Stiffness Environment Mechanobiology 3D culture 571.4 571.8
55	Cellular Responses to Complex Strain Fields Studied in Microfluidic Devices Chagnon-Lessard, Sophie 25 July 2018 (has links) Cells in living organisms are constantly experiencing a variety of mechanical cues. From the stiffness of the extra cellular matrix to its topography, not to mention the presence of shear stress and tension, the physical characteristics of the microenvironment shape the cells’ fate. A rapidly growing body of work shows that cellular responses to these stimuli constitute regulatory mechanisms in many fundamental biological functions. Substrate strains were previously shown to be sensed by cells and activate diverse biochemical signaling pathways, leading to major remodeling and reorganization of cellular structures. The majority of studies had focused on the stretching avoidance response in near-uniform strain fields. Prior to this work, the cellular responses to complex planar strain fields were largely unknown. In this thesis, we uncover various aspects of strain sensing and response by first developing a tailored lab-on-a-chip platform that mimics the non-uniformity and complexity of physiological strains. These microfluidic cell stretchers allow independent biaxial control, generate cyclic stretching profiles with biologically relevant strain and strain gradient amplitudes, and enable high resolution imaging of on-chip cell cultures. Using these microdevices, we reveal that strain gradients are potent mechanical cues by uncovering the phenomenon of cell gradient avoidance. This work establishes that the cellular mechanosensing machinery can sense and localize changes in strain amplitude, which orchestrate a coordinated cellular response. Subsequently, we investigate the effect of multiple changes in stretching directions to further explore mechanosensing subtleties. The evolution of the cellular response shed light on the interplay of the strain avoidance and the newly demonstrated strain gradient avoidance, which were found to occur on two different time scales. Finally, we extend our work to study the influence of cyclic strains on the early stages of cancer development in epithelial tissues (using MDCK-RasV12 system), which was previously largely unexplored. This work reveals that external mechanical forces impede the healthy cells’ ability to eliminate newly transformed cells and greatly promote invasive protrusions, as a result of their different mechanoresponsiveness. Overall, not only does our work reveal new insights regarding the long-range organization in population of cells, but it may also contribute to paving the way towards new approaches in cancer prevention treatments. mechanobiology cyclic stretching microfluidic device mechanoresponse nonuniform strain field oncogenic transformed cells microfabrication strain gradient
56	Quantifying Mechanical Heterogeneity in 3D Biological Systems with the Atomic Force Microscope January 2015 (has links) abstract: The atomic force microscope (AFM) is capable of directly probing the mechanics of samples with length scales from single molecules to tissues and force scales from pico to micronewtons. In particular, AFM is widely used as a tool to measure the elastic modulus of soft biological samples by collecting force-indentation relationships and fitting these to classic elastic contact models. However, the analysis of raw force-indentation data may be complicated by mechanical heterogeneity present in biological systems. An analytical model of an elastic indentation on a bonded two-layer sample was solved. This may be used to account for substrate effects and more generally address experimental design for samples with varying elasticity. This model was applied to two mechanobiology systems of interest. First, AFM was combined with confocal laser scanning fluorescence microscopy and finite element analysis to examine stiffness changes during the initial stages of invasion of MDA-MB-231 metastatic breast cells into bovine collagen I matrices. It was determined that the cells stiffen significantly as they invade, the amount of stiffening is correlated with the elastic modulus of the collagen gel, and inhibition of Rho-associated protein kinase reduces the elastic modulus of the invading cells. Second, the elastic modulus of cancer cell nuclei was investigated ex situ and in situ. It was observed that inhibition of histone deacetylation to facilitate chromatin decondenstation result in significantly more morphological and stiffness changes in cancerous cells compared to normal cells. The methods and results presented here offer novel strategies for approaching biological systems with AFM and demonstrate its applicability and necessity in studying cellular function in physiologically relevant environments. / Dissertation/Thesis / Doctoral Dissertation Physics 2015 Biophysics Physics Biomechanics Atomic force microscopy Cell mechanics Mechanobiology Metastasis Microrheometry
57	Characterizing the Phenotypic and Transcriptional Responses of Salmonella Typhimurium at Stationary and Lag Phases of Growth in Response to a Low Fluid Shear Environment January 2020 (has links) abstract: The discovery that mechanical forces regulate microbial virulence, stress responses and gene expression was made using log phase cultures of Salmonella Typhimurium (S. Typhimurium) grown under low fluid shear (LFS) conditions relevant to those encountered in the intestine. However, there has been limited characterization of LFS on other growth phases. To advance the growth-phase dependent understanding of the effect of LFS on S. Typhimurium pathogenicity, this dissertation characterized the effect of LFS on the transcriptomic and phenotypic responses in both stationary and lag phase cultures. In response to LFS, stationary phase cultures exhibited alterations in gene expression associated with metabolism, transport, secretion and stress responses (acid, bile salts, oxidative, and thermal stressors), motility, and colonization of intestinal epithelium (adherence, invasion and intracellular survival). Many of these characteristics are known to be regulated by the stationary phase general stress response regulator, RNA polymerase sigma factor S (RpoS), when S. Typhimurium is grown under conventional conditions. Surprisingly, the stationary phase phenotypic LFS stress response to acid and bile salts, colonization of human intestinal epithelial cells, and swimming motility was not dependent on RpoS. Lag phase cultures exhibited intriguing differences in their LFS regulated transcriptomic and phenotypic profiles as compared to stationary phase cultures, including LFS-dependent regulation of gene expression, adherence to intestinal epithelial cells, and high thermal stress. Furthermore, the addition of cell-free conditioned supernatants derived from either stationary phase LFS or Control cultures modulated the gene expression of lag phase cultures in a manner that differed from either growth phase, however, these supernatants did not modulate the phenotypic responses of lag phase cultures. Collectively, these results demonstrated that S. Typhimurium can sense and respond to LFS as early as lag phase, albeit in a limited fashion, and that the lag phase transcriptomic and phenotypic responses differ from those in stationary phase, which hold important implications for the lifecycle of this pathogen during the infection process. / Dissertation/Thesis / Transcriptomic Data / Doctoral Dissertation Microbiology 2020 Microbiology Fluid Shear Lag Phase Mechanobiology RpoS Salmonella Typhimurium Stationary Phase
58	The Role of the Extracellular Matrix in Schwann Cell Phenotype Xu, Zhenyuan 30 September 2021 (has links) No description available. Cellular Biology Schwann cell Extracellular matrix Mechanobiology Rho GTPase YAP-TAZ Peripheral nerve
59	Effects of substrate stiffness, cadherin junction and shear flow on tensional homeostasis in cells and cell clusters Xu, Han 30 August 2019 (has links) Cytoskeletal tension plays an important role in numerous biological functions of adherent cells, including mechanosensing of the cell’s microenvironment, mechanotransduction, cell spreading and migration, cell shape stability, and in stem cell lineage. It is believed that for normal biological functions the cell must maintain its cytoskeletal tension stable, at a preferred set-point level, under external perturbations. This is known as tensional homeostasis. Any breakdown of tensional homeostasis is closely associated with disease progression, including cancer, atherosclerosis, and thrombosis. The exact mechanism and the relevant environmental conditions for the maintenance of tensional homeostasis are not yet fully understood. This thesis investigates the impacts of substrate stiffness, availability of functional cadherin junctions and steady shear stress on tensional homeostasis of cells and cell clusters. We define tensional homeostasis as the ability of cells to maintain a consistent level of tension with low temporal traction field fluctuations. Traction forces of isolated cells, multicellular clusters, and monolayer are measured using micropattern traction microscopy. Temporal fluctuations of the traction field are calculated from time-lapsed traction measurements. Results demonstrated that substrate stiffness, cadherin cell-cell junctions and shear stress all impact tensional homeostasis. In particular, we found that stiffer substrates promoted tensional homeostasis in endothelial cells, but were detrimental to tensional homeostasis in vascular smooth muscle cells. We also found that E-cadherins were essential for tensional homeostasis of gastric cancer cells and that extracellular and intracellular mutations of E-cadherin had domain-specific effects on tensional homeostasis. Finally, laminar flow-induced shear stress led to increased traction field fluctuations in endothelial cell monolayers, contrary to reports of physiological shear promoting vascular homeostasis. A possible reason for this discrepancy might be the limitation of our approach which could not account for mechanical balance of traction forces in the monolayers. Through the exploration of these environmental factors, we also found that tensional homeostasis was a length scale-dependent and cell type-dependent phenomenon. These insights suggest that future studies need to take a more comprehensive approach and aim to make observations of different cell types on multiple length scales, in order decipher the mechanism of tensional homeostasis and its role in (patho)physiology. / 2021-08-30T00:00:00Z Biomedical engineering Cytoskeletal tension Mechanobiology Mechanosensing Mechanotransduction Tensional homeostasis Traction microscopy
60	MAGNETIC ACTUATORS FOR BIOMEDICAL APPLICATIONS Angel G Enriquez (15334162) 20 April 2023 (has links) <p>The untethered transfer of energy and scalability of magnetic actuators enables functionality to an otherwise passive system. For example, wireless magnetic actuation can turn static 2D and 3D cell cultures into a more physiologically-relevant dynamic environment while limiting contamination. Moreover, indwelling catheters and implantable sensors are typically stationary devices that are notorious for their short lifespan when implanting into the body due to immune responses. Magnetic microactuators may be used for wireless actuation for in situ removal of biological materials accumulated on chronically implanted devices. In this dissertation, I will demonstrate examples of novel biomedical microdevices enabled by magnetic actuation for added functional benefits. First, I will describe a soft polymer magnetic actuator that can facilitate the study of a physiologically relevant cell culturing system. By cyclically stretching an extracellular matrix protein in a 3D cell culture, this system can elucidate the process by which breast cancer cells respond to a dynamic environment in the lungs. The fibrillar fibronectin suspended across the body of the magnetic actuator provides a matrix representative of early metastasis for 3D cell culture that has not yet been recapitulated in vitro until now. Our results demonstrate a clear suppressive cellular response due to cyclic stretching that has implications for a mechanical role in the dormancy and reactivation of disseminated breast cancer cells to macrometastases. As a second application, I will demonstrate the use of magnetic microactuators to remove biofouling on an implantable biosensor in order to prolong its functionality. The results of our work suggest that the motion of the actuator on the sensor surface can maintain biosensor signal integrity and prevents the downstream effects of the foreign body response. Additionally, I will present the design and proof of concept testing of a novel aspiration thrombectomy catheter meant to improve the engagement between the catheter and the blood clot being removed. Preliminary results demonstrate the added benefit of incorporating a microstructure in the inner diameter of the catheter meant to increase the retraction force aspiration catheters have when retrieving corked emboli at the catheter tip. </p> <p><br></p> Biofabrication Mechanobiology Medical devices electrochemical sensors

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