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Author: Ryan Joseph Hickey Publisher: ISBN: Category : Languages : en Pages :
Book Description
Cells are complex active materials that display fascinating phenomena in response to changes in their physical environments. It is well established that the physical environment dictates cell fate and function; nevertheless, the standard method of culturing and studying cells is on stiff 2- dimensional Petri dishes and glass cover slips. The difference in the magnitude of the stiffness of the substrate in addition to the 2-dimensional character, leads to an incomplete and perhaps misleading picture of the cellular process under scrutiny. As such, an entire field has been dedicated to developing materials that more closely match the characteristics of the natural cellular milieu: biomaterials. Despite significant progress in the field, we are still far from fully recapturing the native environment. Importantly, many of the current strategies for engineering 3-dimensional biomaterials have specific applications yet lack flexibility to be adapted to a wide variety of functions. Our approach is to repurpose existing complex, readily available materials to create a platform for biomaterial production; our biomaterials are derived from plant tissue. Plants have evolved over millions of years to attain structures with intricate geometries for specialized functions. Due to the wide variety of plant structures, one can easily select a plant-based material with analogous features to the tissue of interest. A series of investigations are presented on these novel biomaterials to demonstrate this approach, quantify the mechanical properties, and study the cellular responses. First, we developed a method of processing plant materials to yield decellularized, cellulose-based, biocompatible scaffolds that can be repopulated with mammalian cells. We then created composite materials by casting hydrogels around the cellulose-based scaffolds, which allowed us to incorporate distinct temporal and spatial cues to the local cell populations. Spatial organization of tissues and tissue interfaces remains a primary challenge in biomedical engineering, as tissue interfaces mark complex transitional zones between distinct cell populations. Replicating and repairing this intricate delineation of cell types and mechanical profiles has proven to be a major concern in regenerative medicine. As such, we sought to develop a platform for engineered tissue interfaces, wherein components are combined in a modular fashion into a functional unit. The mechanical cues of the microenvironment affect a plethora of cellular processes, namely cell migration, proliferation, and differentiation. Consequently, the rheological properties of our decellularized, plant-based scaffolds were thoroughly investigated. An in-depth knowledge of the mechanics of the underlying substrate is required to guide future applications and refinements of this technology. The potential applications of these 3-dimensional constructs, as demonstrated through our findings, include designing in vitro models of tissue interactions, new biomaterials for in vivo applications, and studies on fundamental cellular processes. We highlight the significance of our results in a collection of scientific articles, which are presented in the body of this thesis (Chapters 2-5). This work is focused on the use of plant- derived cellulose materials, which forms a subsection of the cellulose biomaterial field. A review article centered on the use of cellulose materials for tissue engineering serves as an introductory chapter.
Author: Ryan Joseph Hickey Publisher: ISBN: Category : Languages : en Pages :
Book Description
Cells are complex active materials that display fascinating phenomena in response to changes in their physical environments. It is well established that the physical environment dictates cell fate and function; nevertheless, the standard method of culturing and studying cells is on stiff 2- dimensional Petri dishes and glass cover slips. The difference in the magnitude of the stiffness of the substrate in addition to the 2-dimensional character, leads to an incomplete and perhaps misleading picture of the cellular process under scrutiny. As such, an entire field has been dedicated to developing materials that more closely match the characteristics of the natural cellular milieu: biomaterials. Despite significant progress in the field, we are still far from fully recapturing the native environment. Importantly, many of the current strategies for engineering 3-dimensional biomaterials have specific applications yet lack flexibility to be adapted to a wide variety of functions. Our approach is to repurpose existing complex, readily available materials to create a platform for biomaterial production; our biomaterials are derived from plant tissue. Plants have evolved over millions of years to attain structures with intricate geometries for specialized functions. Due to the wide variety of plant structures, one can easily select a plant-based material with analogous features to the tissue of interest. A series of investigations are presented on these novel biomaterials to demonstrate this approach, quantify the mechanical properties, and study the cellular responses. First, we developed a method of processing plant materials to yield decellularized, cellulose-based, biocompatible scaffolds that can be repopulated with mammalian cells. We then created composite materials by casting hydrogels around the cellulose-based scaffolds, which allowed us to incorporate distinct temporal and spatial cues to the local cell populations. Spatial organization of tissues and tissue interfaces remains a primary challenge in biomedical engineering, as tissue interfaces mark complex transitional zones between distinct cell populations. Replicating and repairing this intricate delineation of cell types and mechanical profiles has proven to be a major concern in regenerative medicine. As such, we sought to develop a platform for engineered tissue interfaces, wherein components are combined in a modular fashion into a functional unit. The mechanical cues of the microenvironment affect a plethora of cellular processes, namely cell migration, proliferation, and differentiation. Consequently, the rheological properties of our decellularized, plant-based scaffolds were thoroughly investigated. An in-depth knowledge of the mechanics of the underlying substrate is required to guide future applications and refinements of this technology. The potential applications of these 3-dimensional constructs, as demonstrated through our findings, include designing in vitro models of tissue interactions, new biomaterials for in vivo applications, and studies on fundamental cellular processes. We highlight the significance of our results in a collection of scientific articles, which are presented in the body of this thesis (Chapters 2-5). This work is focused on the use of plant- derived cellulose materials, which forms a subsection of the cellulose biomaterial field. A review article centered on the use of cellulose materials for tissue engineering serves as an introductory chapter.
Author: Ying Deng Publisher: Woodhead Publishing ISBN: 0081009801 Category : Technology & Engineering Languages : en Pages : 484
Book Description
In order to grow replacement tissues, 3D scaffolds are widely used as a template for tissue engineering and regeneration. These scaffolds, which are typically ‘seeded’ with cells, support the growth of new tissues. However, in order to achieve successful tissue growth, the scaffold must meet specific requirements and are often ‘functionalized’ to accentuate particular properties. Functional 3D tissue engineering scaffolds: materials, technologies, and applications, is a comprehensive review of functional 3D scaffolds, providing information on the fundamentals, technologies, and applications. Part 1 focuses on the fundamentals of 3D tissue scaffolds, examining information on materials, properties, and trends. Part 2 discusses a wide range of conventional technologies for engineering functional 3D scaffolds, leading the way to a discussion on CAD and advanced technologies for functional 3D scaffold engineering. Chapters in part 3 study methods for functionalizing scaffolds to support a variety of in vivo functions whilst the final set of chapters provides an important review of the most significant applications of functional 3D scaffolds within tissue engineering. This book is a valuable resource for biomaterial scientists and biomedical engineers in academia and industry, with interests in tissue engineering and regenerative medicine. Provides a self-contained work for the field of biomaterials and tissue engineering Discusses all the requirements a scaffold must meet and a wide range of strategies to create them Highlights significant and successful applications of functional 3D scaffolds
Author: Claudio Migliaresi Publisher: CRC Press ISBN: 9814463205 Category : Medical Languages : en Pages : 701
Book Description
Scaffolds for tissue engineering are devices that exploit specific and complex physical and biological functions, in vitro or in vivo, and communicate through biochemical and physical signals with cells and, when implanted, with the body environment. Scaffolds are produced mainly with synthetic materials, and their fabrication technologies are derived from already well-established industrial processes, with some new specific technologies having been developed in the last years to address required complexities. Often, a generalist approach is followed for the translation of materials and technologies designed for other applications, without considering the specific role of scaffolds from a physical and biological point of view. The book illustrates scaffold design principles, with particular relevance to the biological requirements needed to control and drive the biological cross talk, and reviews materials and fabrication and validation methods.
Author: Princeton Carter Publisher: Elsevier Inc. Chapters ISBN: 0128072652 Category : Medical Languages : en Pages : 59
Book Description
The fabrication of three-dimensional (3D) scaffold architectures that closely approximate or effectively mimic native tissue extracellular matrix (ECM) is essential for regenerative success. In tissue engineering, native differentiable cells are incorporated into 3D scaffolds along with growth factors and other proteins. Materials used for the 3D scaffold construction must be biocompatible and bioresorbable to minimize adverse reactions during tissue regeneration. A 3D architecture is created by utilizing materials with specific surface properties, porosity, mechanical strength, etc., to improve desired cell activity and enhance tissue growth. Ideal 3D scaffolds should also not only have hierarchical macroporous structures comparable to those of living tissue, but they should also have surface features on the nanometer scale to improve cell adhesion and accelerate cell in growth.
Author: Chiara Gualandi Publisher: Springer Science & Business Media ISBN: 3642192726 Category : Technology & Engineering Languages : en Pages : 132
Book Description
The development and application of bioactive nano-structured constructs for tissue regeneration is the focus of the research summarised in this thesis. Moreover, a particular focus is the rational use of supercritical carbon dioxide foaming and electrospinning technologies which can lead to innovative polymeric bioresorbable scaffolds made of hydrolysable (both commercial and ‘ad-hoc’ synthesized) polyesters. Mainly, the author discusses the manipulation of polymer chemical structure and composition to tune scaffold physical properties, and optimization of scaffold 3D architecture by a smart use of both fabrication techniques. The multidisciplinary nature of this research is imperative in pursuing the challenge of tissue regeneration successfully. One of the strengths of this thesis is the integration of knowledge from chemistry, physics, engineering, materials science and biomedical science which has contributed to setting up new national and international collaborations, while strengthening existing ones.
Author: Subhas C. Kundu Publisher: Elsevier ISBN: 012818129X Category : Technology & Engineering Languages : en Pages : 773
Book Description
Biomaterials for 3D Tumor Modeling reviews the fundamentals and most relevant areas of the latest advances of research of 3D cancer models, focusing on biomaterials science, tissue engineering, drug delivery and screening aspects. The book reviews advanced fundamental topics, including the causes of cancer, existing cancer models, angiogenesis and inflammation during cancer progression, and metastasis in 3D biomaterials. Then, the most relevant biomaterials are reviewed, including methods for engineering and fabrication of biomaterials. 3D models for key biological systems and types of cancer are also discussed, including lung, liver, oral, prostate, pancreatic, ovarian, bone and pediatric cancer. This book is suitable for those working in the disciplines of materials science, biochemistry, genetics, molecular biology, drug delivery and regenerative medicine. Reviews key biomaterials topics, including synthetic biomaterials, hydrogels, e-spun materials and nanoparticles Provides a comprehensive overview of 3D cancer models for key biological systems and cancer types Includes an overview of advanced fundamental concepts for an interdisciplinary audience in materials science, biochemistry, regenerative medicine and drug delivery
Author: Dong-Woo Cho Publisher: Royal Society of Chemistry ISBN: 1788016645 Category : Technology & Engineering Languages : en Pages : 369
Book Description
3D tissue modelling is an emerging field used for the investigation of disease mechanisms and drug development. The two key drivers of this upsurge in research lie in its potential to offer a way to reduce animal testing with respect to biotoxicity analysis, preferably on physiology recapitulated human tissues and, additionally, provides an alternative approach to regenerative medicine. Integrating physics, chemistry, materials science, and stem cell and biomedical engineering, this book provides a complete foundation to this exciting, and interdisciplinary field. Beginning with the basic principles of 3D tissue modelling, the reader will find expert reviews on key fabrication technologies and processes, including microfluidics, microfabrication technology such as 3D bioprinting, and programming approaches to emulating human tissue complexity. The next stage introduces the reader to a range of materials used for 3D tissue modelling, from synthetic to natural materials, as well as the emerging field of tissue derived decellularized extracellular matrix (dECM). A whole host of critical applications are covered, with several chapters dedicated to hard and soft tissues, as well as focused reviews on the respiratory and central nervous system. Finally, the development of in vitro tissue models to screen drugs and study progression and etiologies of diseases, with particular attention paid to cancer, can be found.
Author: Gilson Khang Publisher: World Scientific Publishing Company ISBN: 9813101601 Category : Science Languages : en Pages : 289
Book Description
Tissue engineering has been recognized as offering an alternative technique to whole-organ and tissue transplantation for diseased, failed, or malfunctioned organs. To reconstruct a new tissue via tissue engineering, the following triad components are needed: (1) cells which are harvested and dissociated from the donor tissue; (2) biomaterials as scaffold substrates in which cells are attached and cultured, resulting in implantation at the desired site of the functioning tissue; and (3) growth factors which promote and/or prevent cell adhesion, proliferation, migration, and differentiation. Of these three key components, scaffolds play a critical role in tissue engineering. This timely book focuses on the preparation and characterization of scaffold biomaterials for the application of tissue-engineered scaffolds. More importantly, it serves as an experimental guidebook on the standardization of the fabrication process and characterization of scaffolding technology.
Author: Koichi Nakayama Publisher: Springer Nature ISBN: 303058688X Category : Technology & Engineering Languages : en Pages : 186
Book Description
This is the first book about the “Kenzan” method for scaffold-free biofabrication, which does not rely on biomaterials as scaffolds to ensure correct multicellular spheroid positioning for building three dimensional construct only made from cells. The book explains the basic principles and concepts of the microneedle-based (“Kenzan”) method of building surgically-implantable tissue constructs using robotic cell spheroid-based three-dimensional bioprinting, a novel technology that opens up unique opportunities for the bioengineering of tissues and organs. First book on the novel Kenzan method of tissue engineering; Explains basic concepts and applications for organ regeneration modeling; Introduces a unique robotic system for scaffold-free cell construction.
Author: Jin-ye Wang Publisher: World Scientific ISBN: 9814551945 Category : Technology & Engineering Languages : en Pages : 328
Book Description
With the increasing worldwide prevalence of tissue damage, there is an urgent, growing demand for tissue engineering materials to mimic autologous tissue for surgical repair. Many attempts have been made to produce long-lasting, biocompatible implants. To overcome the mechanical and biological limitations of synthetic implants, the development of native macromolecule-based 3D substitutes as alternatives has been the latest focus. Advances in nanofabrication and controlled-release technology have vastly improved the potential of such 3D substitutes in influencing cell and tissue performance. This book is an overview of the current state of knowledge in the field of native macromolecule-based 3D substitutes for the repair of several tissue types, including bone, cartilage, vascular, and many more.
Author: Ryan Joseph Hickey
Author: Ryan Joseph Hickey
Author: Ying Deng
Author: Claudio Migliaresi
Author: Princeton Carter
Author: Chiara Gualandi
Author: Subhas C. Kundu
Author: Dong-Woo Cho
Author: Gilson Khang
Author: Koichi Nakayama
Author: Jin-ye Wang