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Mechanical stimulation by postnasal drip evokes cough / 後鼻漏による機械的刺激は咳嗽を誘発するIwata, Toshiyuki 23 March 2016 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19589号 / 医博第4096号 / 新制||医||1014(附属図書館) / 32625 / 京都大学大学院医学研究科医学専攻 / (主査)教授 大森 孝一, 教授 木村 剛, 教授 福田 和彦 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Optimisation and validation of a tri-axial bioreactor for nucleus pulposus tissue engineeringHussein, Husnah January 2015 (has links)
Mechanical stimulation, in combination with biochemical factors, is likely to be essential to the appropriate function of stem cells and the development of tissue engineered constructs for orthopaedic and other uses. A multi-axial bioreactor was designed and built by Bose ElectroForce to simulate physiologically relevant loading conditions of the intervertebral disc (IVD), including axial compression, hydrostatic pressure and perfusion flow to multiple constructs under the control of a software program. This research optimises the design and configuration of the perfusion system of the bioreactor and presents results of preliminary experimental work on the combined effects of axial compression and perfusion on the viability of mesenchymal stem cells encapsulated in alginate hydrogels and the ability of the cells to produce extracellular matrix (ECM). The results of this thesis illustrated the power of a design of experiments (DOE) approach as a troubleshooting quality tool. With a modest amount of effort, we have gained a better understanding of the perfusion process of the tri-axial bioreactor, improved operational procedures and reduced variation in the process. Furthermore, removing unnecessary tubing lengths, equipment and fittings has made cost savings. The steady flow energy equation (SFEE) was used to develop a numerical analysis framework that provides an insight into the balance between velocity, elevation and friction in the flow system. The pressure predictions agreed well with experimental data, thus validating the SFEE for fluid analysis in the bioreactor system. The numerical predictions can be used to estimate the pressures around the three-dimensional constructs with a given arrangement of the tubing and components of the bioreactor. The system can potentially support long-term cultures of cell-seeded constructs in controlled environmental conditions found in vivo to study the mechanobiology of nucleus pulposus tissue engineering and the aetiology of IVD degeneration. However, dynamic compression and perfusion with associated hydrostatic pressurization of culture medium resulted in significant loss of cell viability compared to the unstimulated controls. Due to a large number of factors affecting cell behaviour in the tri-axial bioreactor system, it is difficult to identify the exact parameters influencing the observed cell response. A strategy that could help to distinguish the effects of mechanical stimuli and specific physiochemical factors should combine experiments with mathematical modelling approaches, and use the sensing incorporated in the bioreactor design and process-control systems to monitor and control specific culture parameters. Optimisation of the cell passage and cell seeding density were identified as key areas to improve the production of GAG in future studies; since the production of ECM was not observed in both static and dynamic cultures. Further studies could also attempt to use other hydrogel scaffolds, such as agarose, which has been widely used in cartilage tissue engineering studies and hyaluronic acid - a component of the nucleus pulposus ECM.
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Controlled In Vivo Mechanical Stimulation of Bone Repair ConstructsDuty, Angel Osborne 12 April 2004 (has links)
Bone grafts are used to treat more than 300,000 fracture patients yearly, as well as patients with congenital defects, bone tumors, and those undergoing spinal fusion. Given the established limitations of autograft and allograft bone, there is a substantial need for bone graft substitutes. Tissue engineering strategies employing the addition of osteogenic cells and/or osteoinductive factors to porous scaffolds represent a promising alternative to traditional bone grafts. While many bone defects are in load-bearing sites, very little is known about the response of bone grafts and their substitutes to mechanical loading, despite vast documentation on the ability of normal bone to adapt to its mechanical environment. The goal of this research was to quantify the effects of controlled in vivo mechanical stimulation on bone graft repair and bone graft substitutes and identify the local stress/strain environment associated with load-induced changes in bone formation.
The global hypothesis that cyclic in vivo mechanical loading improves mineralized matrix formation within bone grafts and bone graft substitutes was addressed in this work using orthotopic and ectopic models specifically designed to facilitate modeling of local stresses and strains. In the first study, a bone defect repair model utilizing an orthotopic implant capable of supplying a controlled mechanical stimulus to a trabecular allograft showed a significant reduction in new bone formation with controlled in vivo mechanical loading. Although the reason remains unclear, loading conditions may not have been ideal for increased bone formation or potential micromotion may have influenced the results. A second study demonstrated for the first time that controlled in vivo mechanical stimulation enhances mineralized matrix production on a mesenchymal stem cell-seeded polymeric construct using a novel subcutaneous implant system. In addition, the local stresses and strains associated with this adaptive response were predicted. The novel subcutaneous implant represents technology which may be adapted for the preparation of tissue-engineered bone constructs, capitalizing on the benefits of mechanical loading and a vascularized in vivo environment. Such an approach may produce larger, stronger, and more homogeneous constructs than could be developed in a static culture system subject to diffusional limitations.
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Mechanical and Hydromechanical Stimulation of Chondrocytes for Articular Cartilage Tissue EngineeringPourmohammadali, Homeyra 01 May 2014 (has links)
Tissue engineering approaches have attempted to address some of the problems associated with articular cartilage defect repair, but grafts with sufficient functional properties have yet to reach clinical practice. Mechanical loads are properly controlled in the body to maintain the functional properties of articular cartilage. This inspires the inclusion of mechanical stimulation in any in vitro production of tissue engineered constructs for defect repair. This mechanical stimulation must improve the functional properties (both biochemical and structural) of engineered articular cartilage tissue. Only a few studies have applied more than two loading types to mimic the complex in vivo load/flow conditions. The general hypothesis of the present thesis proposes that the generation of functional articular cartilage substitute tissue in vitro benefits from load and fluid flow conditions similar to those occurring in vivo. It is specifically hypothesized that application of compression, shear and perfusion on chondrocyte-seeded constructs will improve their properties. It is also hypothesized that protein production of the cell-seeded constructs can be improved in a depth-dependent manner with some loading combinations.
Thus, a hydromechanical stimulator system was developed that was capable of simultaneously applying compression, shear and perfusion. Functionality of system was tested by series of short-term pilot studies to optimize some of the system parameters. In these studies, agarose-chondrocytes constructs were stimulated for 2 weeks. Then, longer-term (21- 31 days) studies were performed to examine the effects of both mechanical (compression and dynamic shear) and hydromechanical (compression, dynamic shear and fluid flow) stimulation on glycosaminoglycan and collagen production. The effects of these loading conditions were also investigated for three layers of construct to find out if protein could be localized differently depth-wise.
In one of the longer-term studies, the chosen mechanical and hydromechanical stimulation conditions increased total collagen production, with higher amount of collagen for hydromechanical compared with mechanical loading condition. However, their effectiveness in increasing total glycosaminoglycan production was inconclusive with the current loading regimes. The hydromechanically stimulated construct could localize higher collagen production to the top layer compared with middle and bottom layers. Some effectiveness of hydromechanical stimulation was demonstrated in this thesis. Future studies will be directed towards further optimization of parameters such as stimulation frequency and duration as well as fluid perfusion rate to produce constructs with more glycosaminoglycan and collagen.
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Signaling Pathways Involved in Mechanical Stimulation and ECM Geometry in Bone CellsJiang, Chang 27 July 2010 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The proliferation and differentiation of osteoblasts are influenced by mechanical and geometrical growth environments. A specific aim of my thesis was the elucidation of signaling pathways involved in mechanical stimulation and geometric alterations of the extracellular matrix (ECM). A pair of questions addressed herein was (a) Does mechanical stimulation modulate translational regulation through the phosphorylation of eukaryotic initiation factor 2 (eIF2)? (b) Do geometric alterations affect the phosphorylation patterns of mitogen-activated protein kinase (MAPK) signaling? My hypothesis was mechanical stress enhances the proliferation and survival of osteoblasts through the reduction in phosphorylation of eIF2, while 3-dimensional (3D) ECM stimulates differentiation of osteoblasts through the elevation of phosphorylation of p38 MAPK.
First, mechanical stimulation reduced the phosphorylation of eIF2. Furthermore, flow pre-treatment reduced thapsigargin-induced cell mortality through suppression of phosphorylation of protein kinase RNA-like ER kinase (Perk). However, H2O2-driven cell mortality, which is not mediated by Perk, was not suppressed by mechanical stimulation. Second, in the ECM geometry study, the expression of the active
(phosphorylated) form of p130Cas, focal adhesion kinase (FAK) and extracellular signal-regulated protein kinase (ERK) was reduced in cells grown in the 3D matrix. Conversely, phosphorylation of p38 MAPK was elevated in the 3D matrix and its up-regulation was linked to an increase in mRNA levels of dentin matrix protein 1 and bone sialoprotein.
In summary, our observations suggest the pro-survival role of mechanical stimulation and the modulation of osteoblastic fates by ECM geometry.
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La modulation du réflexe de toux par l’exercice chez le lapin sensibilisé à l’ovalbumine / Lack of desensitization of the cough reflex in ovalbumin-sensitized rabbits during exerciseTiotiu, Angelica 14 December 2016 (has links)
Introduction : La toux est un symptôme fréquent dans l’asthme, en particulier à l’effort mais peu des choses sont connus quant aux mécanismes impliqués. L’objectif de cette étude a été d’établir le rôle de l’exercice dans la modulation du réflexe de toux (RT) sur un modèle de lapin anesthésié en ventilation spontanée, présentant une inflammation éosinophilique des voies aériennes. Méthode : Nous avons étudié 10 lapins sensibilisés à l’ovalbumine (OVA) et 8 lapins contrôles. La réponse ventilatoire à la stimulation mécanique trachéale (ST) a été analysée pour chaque lapin en conditions de repos et à l’exercice pour quantifier l’incidence et la sensibilité de la toux. Le lavage bronchioloalaveolaire (LBA) et le comptage cellulaire a été réalisé pour vérifier la présence d’une inflammation à éosinophiles chez les lapins sensibilisés à l’OVA. Pour reproduire l’exercice, des contractions musculaires au niveau des pattes arrière ont été induites par stimulation électrique (CME). Résultats : Au total, 494 ST ont été réalisées, 261 en repos et 233 à l’exercice. Le taux d’éosinophiles dans le LBA a été retrouvé significativement plus élevé chez les lapins sensibilisés à l’OVA (vs contrôles, p=0.008). La CME a permis une augmentation similaire de l’ordre de 35% de la ventilation minute chez les lapins sensibilisés à l’OVA et chez les lapins contrôles par rapport au repos. La sensibilité du RT a été retrouvée significativement diminuée à l’exercice par rapport au repos pour les lapins contrôles (p=0.0313) contrairement aux lapins sensibilisés à l’OVA pour lesquels elle reste inchangée. Conclusion : Le phénomène de “down-regulation” du RT à l’exercice décrit chez les lapins contrôles n’a pas été observé chez les lapins sensibilisés à l’OVA. D’autres études sont nécessaires afin d’établir le rôle spécifique de l’inflammation bronchique sur la disparition du phénomène de “down-regulation” de la toux à l’exercice chez les patients asthmatiques / Introduction: Cough is a major symptom of asthma frequently experienced during exercise but little is known about interactions between cough and exercise. The goal of our study was to clarify the potential modulation of the cough reflex (CR) by exercise in a spontaneously breathing anaesthetized animal model of airway eosinophilic inflammation. Materials & methods: Ten ovalbumin (OVA) sensitized rabbits and 8 controls were studied. The ventilatory response to direct (TS) performed both at rest and during exercise was determined to quantify the incidence and the sensitivity of the CR. Broncho-alveolar lavages (BAL) and cell counts were performed to assess the level of the airway inflammation following OVA-induced sensitization. Exercise was mimicked by electrically induced hind limb muscular contractions (EMC). Results: Among 494 TS were performed, 261 at rest and 233 at exercise. The OVA sensitized rabbits have a higher level of eosinophil (p=0.008) in BAL. EMC increased minute ventilation by 36% in OVA rabbits vs 35% in control rabbits, compared to rest values. The sensitivity of the CR decreased during exercise compared to baseline in control rabbits (p=0.0313) while it remained unchanged in OVA rabbits. Conclusion: The down-regulation of the CR during exercise in control rabbits was abolished in OVA rabbits. The precise role of airway inflammation in this lack of CR downregulation needs to be further investigated but it might contribute to the exercise-induced cough in asthmatics
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Oscillatory Compressive Loading Effects On Mesenchymal Progenitor Cells Undergoing Chondrogenic Differentiation In Hydrogel SuspensionCase, Natasha D. 15 April 2005 (has links)
Articular cartilage functions to maintain joint mobility. The loss of healthy, functional articular cartilage due to osteoarthritis or injury can severely compromise quality of life. To address this issue, cartilage tissue engineering approaches are currently in development. Bone marrow-derived mesenchymal progenitor cells (MPCs) hold much promise as an alternative cell source for cartilage tissue engineering. While previous studies have established that MPCs from humans and multiple other species undergo in vitro chondrogenic differentiation, additional research is needed to define conditions that will enhance MPC differentiation, increase matrix production by differentiating cultures, and support development of functional tissue-engineered cartilage constructs. Mechanical loading may be an important factor regulating chondrogenic differentiation of MPCs and cartilage matrix formation by chondrogenic MPCs. This thesis work evaluated the influence of oscillatory unconfined compressive mechanical loading on in vitro MPC chondrogenic activity and biosynthesis within hydrogel suspension. Loading was conducted using MPCs cultured in media supplements supporting chondrogenic differentiation. Possible interactions between the number of days in chondrogenic media preceding loading initiation and the ability of the MPC culture to respond to mechanical stimulation were explored in two different loading studies. The first loading study investigated the effects of 3 hour periods of daily oscillatory mechanical stimulation on subsequent chondrogenic activity, where chondrogenic activity represented an assessment of cartilage matrix production by differentiating MPCs. This study found that oscillatory compression of MPCs initiated during the first seven days of culture did not enhance chondrogenic activity above the level supported by media supplements alone. The second loading study evaluated changes in biosynthesis during a single 20 hour period of oscillatory mechanical stimulation to assess mechanoresponsiveness of the MPC cultures. This study found that MPCs modulated proteoglycan and protein synthesis in a culture time-dependent and frequency-dependent manner upon application of oscillatory compression. Together the two loading studies provide an assessment of dynamic compressive mechanical loading influences on MPC cultures undergoing chondrogenic differentiation. The information gained through in vitro studies of differentiating MPC cultures will increase basic knowledge about progenitor cells and may also prove valuable in guiding the future development of cartilage tissue engineering approaches.
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Manipulation of the embryoid body microenvironment to increase cardiomyogenesisGeuss, Laura Roslye 10 September 2015 (has links)
Myocardial Infarction (MI) is one of the most prevalent and deadliest diseases in the United States. Since the host myocardium becomes irreversibly damaged following MI, current research is focused on identification of novel, less invasive, and more effective treatment options for patients. Cellular cardiomyopathy, in which viable cells are transplanted into the necrotic tissue, has the potential to regenerate and integrate with the host myocardium. Stem cells, specifically pluripotent stem cells such as embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSC), are ideal candidates for this procedure because they are pluripotent; however, ESCs must be predifferentiated to avoid teratoma formation in vivo. In this dissertation, our goal was improve upon current protocols to direct differentiation of ESCs into cardiomyocytes using an embryoid body (EB) model. We immobilized pro-cardiomyogenic proteins, specifically Sonic Hedgehog (SHH) and Bone Morphogenetic Protein 4 (BMP4) to paramagnetic beads and delivered them in the interior of the EB. While lineage commitment was indiscriminate, the presence of the beads alone appeared to guide differentiation into cardiomyocytes: there were significantly more contracting areas in EBs containing beads than in the presence of SHH or BMP4. To take advantage of this result, we immobilized Arginine-Glycine-Aspartic Acid (RGD) peptides to the beads and magnetized them following incorporation into the EB. Magnetically mediated strain increased the expression of mechanochemical markers, and in combination with BMP4 increased the percentage of cardiomyocytes. Finally, PEGylated fibrin gels were used to investigate the effect of seeding method and fibrinogen concentration on cardiomyocyte behavior and maturation. Cells seeded on top of compliant hydrogels had the most contracting regions compared to stiffer PEGylated fibrin gels, whereas cardiomyocytes seeded within the hydrogels could not remodel the matrix or maintain contractility. As an alternative to 3D culture, we seeded cardiomyocytes within gel layers, which maintained viability as well as contractile activity. We observed that PEGylated fibrin gels can maintain ESC-derived cardiomyocytes; however, the ratio of cardiomyocytes and non-cardiomyocytes should be optimized to maintain contractile phenotypes. Therefore, this dissertation presents novel methods to differentiate ESCs into cardiomyocytes, and subsequently promote their maturation in vitro, for the treatment of MI. / text
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Manipulating the Mechanical Microenvironment: Microdevices for High-throughput Studies in Cellular MechanobiologyMoraes, Christopher 18 January 2012 (has links)
Determining how biological cells respond to external factors in the environment can aid in understanding disease progression, lead to rational design strategies for tissue engineering, and contribute to understanding fundamental mechanisms of cellular function. Dynamic mechanical forces exist in vivo and are known to alter cellular response to other stimuli. However, identifying the roles multiple external factors play in regulating cell fate and function is currently impractical, as experimental techniques to mechanically stimulate cells in culture are severely limited in throughput. Hence, determining cell response to combinations of mechanical and biological factors is technically limited. In this thesis, microfabricated systems were designed, implemented and characterized to screen for the effects of mechanical stimulation in a high-throughput manner. Realizing these systems required the development of a fabrication process for precisely-aligned multilayer microstructures, and the development of a method to integrate non-traditional and clinically-relevant biomaterials into the microfabrication process. Three microfabricated platforms were developed for this application. First, an array was designed for experiments with high mechanical throughput, in which cells cultured on a surface experience a range of cyclic, uniform, equibiaxial strains. Using this array, a novel time- and strain-dependent mechanism regulating nuclear β-catenin accumulation in valve interstitial cells was identified. Second, a simpler system was designed to screen for the effects of combinatorially manipulated mechanobiological parameters on the pathological differentiation of valve interstitial cells. The results demonstrate functional heterogeneity between cells isolated from different regions of the heart valve leaflet. Last, a microfabricated platform was developed for high-throughput mechanical stimulation of cells encapsulated in a three-dimensional biomaterial, enabling the study of mechanical forces on cells in a more physiologically relevant microenvironment. Overall, these studies identified novel biological phenomena as a result of designing higher-throughput systems for the mechanical stimulation of cells.
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Manipulating the Mechanical Microenvironment: Microdevices for High-throughput Studies in Cellular MechanobiologyMoraes, Christopher 18 January 2012 (has links)
Determining how biological cells respond to external factors in the environment can aid in understanding disease progression, lead to rational design strategies for tissue engineering, and contribute to understanding fundamental mechanisms of cellular function. Dynamic mechanical forces exist in vivo and are known to alter cellular response to other stimuli. However, identifying the roles multiple external factors play in regulating cell fate and function is currently impractical, as experimental techniques to mechanically stimulate cells in culture are severely limited in throughput. Hence, determining cell response to combinations of mechanical and biological factors is technically limited. In this thesis, microfabricated systems were designed, implemented and characterized to screen for the effects of mechanical stimulation in a high-throughput manner. Realizing these systems required the development of a fabrication process for precisely-aligned multilayer microstructures, and the development of a method to integrate non-traditional and clinically-relevant biomaterials into the microfabrication process. Three microfabricated platforms were developed for this application. First, an array was designed for experiments with high mechanical throughput, in which cells cultured on a surface experience a range of cyclic, uniform, equibiaxial strains. Using this array, a novel time- and strain-dependent mechanism regulating nuclear β-catenin accumulation in valve interstitial cells was identified. Second, a simpler system was designed to screen for the effects of combinatorially manipulated mechanobiological parameters on the pathological differentiation of valve interstitial cells. The results demonstrate functional heterogeneity between cells isolated from different regions of the heart valve leaflet. Last, a microfabricated platform was developed for high-throughput mechanical stimulation of cells encapsulated in a three-dimensional biomaterial, enabling the study of mechanical forces on cells in a more physiologically relevant microenvironment. Overall, these studies identified novel biological phenomena as a result of designing higher-throughput systems for the mechanical stimulation of cells.
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