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This invaluable resource discusses clinical applications with effects and side-effects of applications of stem cells in bone and cartilage regeneration. Each chapter is contributed by a pre-eminent scientist in the field and covers such topics as skeletal regeneration by mesenchymal stem cells, clinical improvement of mesenchymal stem cell injection in injured cartilage and osteoarthritis, Good manufacturing practice (GMP), minimal critera of stem cells for clinical applications, future directions of the discussed therapies and much more. Bone & Cartilage Regeneration and the other books in the Stem Cells in Clinical Applications series will be invaluable to scientists, researchers, advanced students and clinicians working in stem cells, regenerative medicine or tissue engineering.
The response of cells to biomaterials is critical in medical devices. Traditionally inert biomaterials were used to minimise the reaction in cells in contact with the material. However, it has been realised that specific cell responses may be beneficial in such areas as encouraging adhesion, healing or cell multiplication. Cellular response to biomaterials discusses the response of cells to a wide range of biomaterials targeted at specific medical applications. Part one discusses cell responses to a variety of polymers and ceramics with chapters on such topics as degradable polymers and biocompatibility. Part two covers cell responses and regenerative medicine with coverage of themes such as vascular grafts, nerve repair and Bioglass®. Part three examines the effect of surfaces and proteins on cell response. Specific chapters review nano-engineered surfaces, the influence of plasma proteins on bone cell adhesion and surface modification of titanium implants. With its distinguished editor and team of international contributors, Cellular response to biomaterials is an essential read for those researching or studying medical devices in industry and academia. Examines the response of cells to a wide range of biomaterials targeted at specific medical applications Discusses cell responses and regenerative medicine with specific chapters on vascular grafts and nerve repair Assesses the effect of surfaces and proteins on cell response including the influence of plasma proteins on cell adhesion and surface modification of titanium implants
The profound transformations occurred in our modern age have been made possible by the unique combination of new technologies. Among them, me- cine has completely changed our perception of life. Longevity has been signi- cantly extended and linked to new lifestyles. The negative impact that pathologies and ageing have always had on the quality of our life is now mitigated by the availability of treatments daily applied to many individuals worldwide. For many years, pharmacological and surgical treatments have been supported by the introduction of biomedical devices. Biomedical implants have played a key role in the development of these treatments and achieved the objective of replacing tissue and organ structures and functionalities. Gra- ally, the scientific and clinical communities have understood that replacement could be improved by materials able to interact with the tissues and to parti- pate in their metabolism and functions. This approach soon led to biomedical implants with improved clinical performances, but also to a new aspiration; rather than replacing damaged tissues and organs scientists and clinicians nowadays aim at their partial or complete regeneration. As a consequence of this ambition, the disciplines of tissue engineering and regenerative medicine have recently emerged. It is the dawn of a fascinating era where scientists from various disciplines, clinicians, and industry will need to intensify their col- borative efforts to provide our society with new and affordable solutions.
Animals have been used to model diseases or test new treatments since around 300 BC, and undoubtedly our ability to model disease in animals – including transgenic animals – has provided major breakthroughs in all fields of biomedical research. Due to their complexity and plurality of pathology and symptomatology, the study of neurodegenerative diseases relies heavily on animal models. These models have been developed in many species in the attempt to undercover the complex nature of the disease mechanisms involved. The ultimate goal is to test promising therapies and to manage, prevent or cure neurodegenerative disease. But because most animal models in this area do not reproduce the full phenotypical disease spectrum and the etiology and clinical presentation of neurodegenerative diseases differ from one patient to the next, the testing of these diseases in animal models often translates poorly to indices of efficacy when applied to the clinical population. Written by experts in the field with these advances and challenges in mind, this handbook provides an updated overview of the animal models being developed and used to study complex disease dynamics. The first part of the book presents an overview of animal models of various species and includes a review of new invertebrate animal models to study neurodegeneration. The second section presents the use of animal models to pinpoint disease mechanisms, and the last part of the handbook examines the various therapeutic interventions being used in models of neurodegenerative disease.
This book describes advances in implantable neural stimulation technology to restore partial sight to people who are blind from retinal degnerative diseases such as age-related macular degeneration and retintis pigmentosa. Many scientific, engineering, and surgical challenges must be surmounted before widespread practical applications can be realized. The book summarizes the state of research and clinical practice in the field and reviews the current ideas and approaches of its leading researchers and practitioners.
This issue of PET Clinics focuses on PET/MRI: Clinical Applications, and is edited by Drs. Drew Torigian and Andreas Kjaer. Articles will include: PET/MRI in Prostate Cancer; PET/MRI in Vascular Disease; PET/MRI in Lymphoma; PET/MRI in Head and Neck Cancer; PET/MRI in Brain Disease; PET/MR in Cancers of GI Tract; PET/MRI in Gynecologic Cancer; Clinical PET/MRI Systems and Patient Workflow; PET/MRI in Heart Disease; PET/MR in Breast Cancer and Lung Cancer; PET/MRI in Musculoskeletal Disorders; PET/MRI in Pediatric Oncology; Clinical PET/MRI: Future Perspectives; and more!
Comprising 26 chapters, this volume deals with the genetic transformation of medicinal plants. It describes methods to obtain plants resistant to insects, diseases, herbicides, and plants with an increased production of compounds of medicinal and pharmaceutical importance. The plant species included are Ajuga reptans, Anthemis nobilis, Astragalus spp., Atropa belladonna, Catharanthus roseus, Datura spp., Duboisia leichhardtii, Fagopyrum spp., Glycyrrhiza uralensis, Lobelia spp., Papaver somniferum, Panax ginseng, Peganum hamala, Perezia spp., Pimpinella anisum, Phyllanthus niruri, Salvia miltiorrhiza, Scoparia dulcis, Scutellaria baicalesis, Serratula tinctoria, Solanum aculeatissimum, Solanum commersonii, Swainsona galegifolia, tobacco, and Vinca minor. The book is of special interest to advanced students, teachers, and researchers in the fields of pharmacy, plant tissue culture, phytochemistry, molecular biology, biomedical engineering, and plant biotechnology in general.