Differentiation Of Mesenchymal Stem Cells In Response To Mechanical And Chemical Factors
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Mesenchymal Stem Cell Therapy
| Author | : Lucas G. Chase |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 458 |
| Release | : 2012-12-12 |
| Genre | : Science |
| ISBN | : 1627032002 |
Over the past decade, significant efforts have been made to develop stem cell-based therapies for difficult to treat diseases. Multipotent mesenchymal stromal cells, also referred to as mesenchymal stem cells (MSCs), appear to hold great promise in regards to a regenerative cell-based therapy for the treatment of these diseases. Currently, more than 200 clinical trials are underway worldwide exploring the use of MSCs for the treatment of a wide range of disorders including bone, cartilage and tendon damage, myocardial infarction, graft-versus-host disease, Crohn’s disease, diabetes, multiple sclerosis, critical limb ischemia and many others. MSCs were first identified by Friendenstein and colleagues as an adherent stromal cell population within the bone marrow with the ability to form clonogenic colonies in vitro. In regards to the basic biology associated with MSCs, there has been tremendous progress towards understanding this cell population’s phenotype and function from a range of tissue sources. Despite enormous progress and an overall increased understanding of MSCs at the molecular and cellular level, several critical questions remain to be answered in regards to the use of these cells in therapeutic applications. Clinically, both autologous and allogenic approaches for the transplantation of MSCs are being explored. Several of the processing steps needed for the clinical application of MSCs, including isolation from various tissues, scalable in vitro expansion, cell banking, dose preparation, quality control parameters, delivery methods and numerous others are being extensively studied. Despite a significant number of ongoing clinical trials, none of the current therapeutic approaches have, at this point, become a standard of care treatment. Although exceptionally promising, the clinical translation of MSC-based therapies is still a work in progress. The extensive number of ongoing clinical trials is expected to provide a clearer path forward for the realization and implementation of MSCs in regenerative medicine. Towards this end, reviews of current clinical trial results and discussions of relevant topics association with the clinical application of MSCs are compiled in this book from some of the leading researchers in this exciting and rapidly advancing field. Although not absolutely all-inclusive, we hope the chapters within this book can promote and enable a better understanding of the translation of MSCs from bench-to-bedside and inspire researchers to further explore this promising and quickly evolving field.
Mechanical and Biological Mechanisms of Regulating Human Mesenchymal Stem Cell Differentiation
| Author | : Anne Kathryn Staples |
| Publisher | : |
| Total Pages | : 352 |
| Release | : 2006 |
| Genre | : |
| ISBN | : |
Knowledge of how hMSCs respond to different types of mechanical loading, how this response differs from a traditional growth factor approach of inducing cellular differentiation and how their responsiveness to mechanical stimulation varies with cell differentiation stage are all critical for the successful design of tissue engineering constructs that are optimally organized for a specific mechanical function.
Induced Differentiation of Adult Mesenchymal Stem Cells Via Fluid Shear Stimulation
| Author | : Adedayo E. Catlett |
| Publisher | : |
| Total Pages | : 115 |
| Release | : 2014 |
| Genre | : Cell differentiation |
| ISBN | : |
Tissue regeneration using autologous adult human mesenchymal stem cells(hMSCs) has become an attractive approach due to the reduced probability of transplant rejection. The classic differentiation approach involves a combination of mechanical and chemical stimulation. Use of a batch bioreactor flowing media containing differentiation growth factors while the hMSCs remain adhered to a rigid culture surface is widely accepted. However, this system of differentiation requires a significant amount of time. When in a clinical setting and quickly trying to treat and regenerate tissue for patients, time is considered an antagonist. The ability to differentiate hMSCs without a bioreactor or specific differentiation media would substantially contribute to the creation of more efficient biocompatible scaffolds that incorporate the differentiated hMSCs of the patient. In this dissertation, the differentiation of hMSCs via shear stimulation through biocompatible plastic tubing in a suspended flow was examined. The "in vitro" investigation of mechanically and chemically stimulated hMSCs in a suspension was performed by: (1) Determining the length of plastic tubing which induced a differentiation response of the hMSCs. (2) Examining intracellular receptors using fluorescent markers to resolve differentiation toward the adipogenic lineage. (3) Incubating the hMSCs with fluorescently tagged antibodies corresponding to differentiation along the adipogenic and chondrogenic lineages. (4) Analyzing the genetic fold changes related to the shear stimulation of hMSCs. At a flow rate equivalent to physiological shear stress, 15 dyn/cm2, undifferentiated hMSCs were exposed to an environment of shear through syringes connected to biocompatible tubing with varying lengths. The resulting fluid stimulation, which took place for approximately 20 minutes, was capable of accelerating the differentiation of hMSCs toward the adipogenic and chondrogenic lineages. Differentiation toward adipocytes was confirmed through the observations of accumulated lipid triglycerides and the increased fold change for adipogenic markers such as LPL1, CFL1, and SSP1. The increased concentration of Type 2 Collagen on the surface of shear stimulated hMSCs with the upregulation of MAPK1, SOX9, and FARP1, demonstrated the capabilities to induce sustained differentiation into the chondrogenic lineage. This work of shear stimulating hMSCs, in combination with chemical stimuli, illustrates ameliorated differentiation of hMSCs toward the adipogenic and chondrogenic lineages.
Spatially Controlled Multi-phenotypic Differentiation of Stem Cells in 3D Via an Engineered Mechanical Gradient
| Author | : Christopher Bowman Horner |
| Publisher | : |
| Total Pages | : 222 |
| Release | : 2016 |
| Genre | : Osteoarthritis |
| ISBN | : 9781369087741 |
The goal of this research was to engineer a scaffold composed of a mechanical gradient and understand the effects of dynamic stimulation on the morphogenesis of the interfacial tissue via spatially controlled differentiation of a single stem cell source. Osteoarthritis is a degenerative joint disease affecting articular cartilage and the underlying subchondral bone resulting in severe pain and disability of the joints. While current clinical treatments provide limited efficacy in long-term success, tissue engineering strategies prove to be a viable option to address regeneration of the osteochondral gradient interface. To address this challenge spatial patterning of mechanical factors are essential for the development of a gradient tissue structure in three dimensions. Here, the overarching goal of this work was to examine (1) the preferential differentiation capacity of MSCs towards multi-phenotypic lineages when subjected to variations in compressive strain, (2) the control of micro- and macro-scale scaffold mechanics through utilizing a core-shell microfiber electrospinning technique, and finally (3) the engineering of a dynamic mechanical gradient that can spatially control the local strain that MSCs will sense and differentiate into multi-phenotypic lineages. My findings demonstrate that MSCs differentiate in a magnitude-dependent and phenotype-specific manner in response to different magnitudes of dynamic compressive strain suggesting that MSCs are mechano-responsive and their multi-phenotypic differentiation can be controlled by varying the strain regimens. Furthermore, it was demonstrated that the mechanical properties of core-shell electrospun fibers can be modulated by controlling the composition and the dimension of core, decoupled from the cell-interfacing surface chemistry. More importantly, it was shown that mechanical properties of such fibers/scaffolds at the micro- and macroscale can be independently regulated by modulating micro- and macro-structure. Finally, spatial control of the mechanical properties of individual core-shell fibers in a monolithic scaffold was able to modulate the preferential multi-phenotypic differentiation of MSCs when subjected to dynamic compressive strain. Thus, these findings provide an additional avenue for directing stem cell differentiation in lieu of biochemical cues commonly used for osteochondral tissue regeneration. Addressing the influence of mechanical stimulation on spatially controlled multi-phenotypic MSC differentiation is the basis behind the work presented in the following dissertation.
Differentiation Induces Dynamic Alterations in Mesenchymal Stem Cell Nuclear Architecture and Mechanotransduction
| Author | : Su Chin Heo |
| Publisher | : |
| Total Pages | : 572 |
| Release | : 2015 |
| Genre | : |
| ISBN | : |
Mesenchymal stem cells (MSCs) are a promising cell source and widely used in a variety of regenerative applications given their multipotent nature. MSCs are subjected to various types of mechanical forces during tissue development and repair, and it is clear that, along with soluble factors, physiological forces play an important role in determining their lineage specification. However, the molecular mechanisms by which external mechanical stimuli are converted to a biological response remain unclear, and few studies have been performed to probe alterations in cell and nuclear architecture in response to physiological loading. In this thesis, we investigated relationships between MSC cellular/nuclear biophysical properties and mechanosensitivity, and determined their importance in MSC mechanotransduction. Our findings demonstrate that MSC differentiation mediated by either a soluble factor, TGF-beta 3 or resulting from dynamic tensile loading (DL) is accompanied by reorganization of nuclear structural elements (i.e. lamin A/C and chromatin). These changes increased nuclear mechanical properties, resulting in changes tto he manner in which MSCs respond to external mechanical perturbation. In addition, through a series of micromechanical experiments, the molecular mechanisms by which nuclear structure was altered as a consequence of load-induced MSC differentiation were elucidated. DL resulted in a rapid increase in chromatin condensation in MSCs, which depended on the activity of the histone-lysine N-methyltransferase EZH2. The ATP/purinergic signaling was a key regulator of this load induced chromatin condensation, and was mediated by acto-myosin cellular contractility. In follow on studies, we demonstrated that chromatin condensation in MSCs was regulated by interplay between purinergic signaling and RhoA/Rock activity, and that baseline TGF superfamily signaling played a role in establishing cell contractility and mediating this load-induced chromatin remodeling response. Overall, this thesis identified novel signaling pathways and mechanisms that regulate the mechanical properties of the nucleus in progenitor cells as they transition towards a differentiated state, and elucidated how dynamic loading regulates chromatin condensation to increase mesenchymal stem cell (MSC) nuclear mechanics in the absence of exogenous differentiation factors. This work has broad implications in the field of mesenchymal stem cell biology and mechanobiology, and will inform the development of engineered tissues, medical devices, and biological materials for tissue repair and regeneration.
Handbook of Stem Cells
| Author | : Anthony Atala |
| Publisher | : Academic Press |
| Total Pages | : 1076 |
| Release | : 2012-12-31 |
| Genre | : Technology & Engineering |
| ISBN | : 0123859433 |
New discoveries in the field of stem cells increasingly dominate the news and scientific literature revealing an avalanche of new knowledge and research tools that are producing therapies for cancer, heart disease, diabetes, and a wide variety of other diseases that afflict humanity. The Handbook of Stem Cells integrates this exciting area of life science, combining in two volumes the requisites for a general understanding of adult and embryonic stem cells. Organized in two volumes entitled Pluripotent Stem Cells and Cell Biology and Adult and Fetal Stem Cells, this work contains contributions from the world’s experts in stem cell research to provide a description of the tools, methods, and experimental protocols needed to study and characterize stem cells and progenitor populations as well as a the latest information of what is known about each specific organ system. Provides comprehensive coverage on this highly topical subject Contains contributions by the foremost authorities and premiere names in the field of stem cell research Companion website - http://booksite.elsevier.com/9780123859426/ - contains over 250 color figures in presentation format
Mesenchymal Stem Cell Derived Exosomes
| Author | : Yaoliang Tang |
| Publisher | : Academic Press |
| Total Pages | : 287 |
| Release | : 2015-09-02 |
| Genre | : Science |
| ISBN | : 0128004975 |
Mesenchymal stem cell-derived exosomes are at the forefront of research in two of the most high profile and funded scientific areas – cardiovascular research and stem cells. Mesenchymal Stem Cell Derived Exosomes provides insight into the biofunction and molecular mechanisms, practical tools for research, and a look toward the clinical applications of this exciting phenomenon which is emerging as an effective diagnostic. Primarily focused on the cardiovascular applications where there have been the greatest advancements toward the clinic, this is the first compendium for clinical and biomedical researchers who are interested in integrating MSC-derived exosomes as a diagnostic and therapeutic tool. Introduces the MSC-exosome mediated cell-cell communication Covers the major functional benefits in current MSC-derived exosome studies Discusses strategies for the use of MSC-derived exosomes in cardiovascular therapies
In Situ Tissue Regeneration
| Author | : Sang Jin Lee |
| Publisher | : Academic Press |
| Total Pages | : 460 |
| Release | : 2016-07-17 |
| Genre | : Medical |
| ISBN | : 012802500X |
In Situ Tissue Regeneration: Host Cell Recruitment and Biomaterial Design explores the body’s ability to mobilize endogenous stem cells to the site of injury and details the latest strategies developed for inducing and supporting the body’s own regenerating capacity. From the perspective of regenerative medicine and tissue engineering, this book describes the mechanism of host cell recruitment, cell sourcing, cellular and molecular roles in cell differentiation, navigational cues and niche signals, and a tissue-specific smart biomaterial system that can be applied to a wide range of therapies. The work is divided into four sections to provide a thorough overview and helpful hints for future discoveries: endogenous cell sources; biochemical and physical cues; smart biomaterial development; and applications. Explores the body’s ability to mobilize endogenous stem cells to the site of injury Details the latest strategies developed for inducing and supporting the body’s own regenerating capacity Presents smart biomaterials in cell-based tissue engineering applications—from the cell level to applications—in the first unified volume Features chapter authors and editors who are authorities in this emerging field Prioritizes a discussion of the future direction of smart biomaterials for in situ tissue regeneration, which will affect an emerging and lucrative industry
The TGF-[beta] Family
| Author | : Rik Derynck |
| Publisher | : CSHL Press |
| Total Pages | : 1108 |
| Release | : 2008 |
| Genre | : Transforming growth factors-beta |
| ISBN | : 0879697520 |
Transforming growth factor-[beta] (TGF-[beta]), identified nearly three decades ago, is a secreted polypeptide that functions in critical cell cycle processes, including cellular proliferation, differentiation, and development: It belongs to a large protein family that, in humans, contains 33 members, including activins, inhibins, bone morphogenetic proteins, growth and differentiation factors, and Mullerian inhibiting substance. This volume draws on the world's leading laboratories to comprehensively cover all aspects of the biology of TGF-[beta] and related factors. In addition to providing historical and background information, it describes the cell biology and signaling pathways of TGF-[beta] members in detail, including the roles of TGF-[beta] factors in the development and physiology of humans and model organisms. The last few chapters are devoted to the role of TGF-[beta] members in cancer and other diseases, as well as the possibilities for therapeutics based on knowledge of signaling pathways and macromolecular structures. It serves as a comprehensive reference work for both specialists and researchers less familiar with the field.
