This edited collection focuses on performance practice and analysis that engages with medical and biomedical sciences. After locating the 'biologization' of theatre at the turn of the twentieth century, it examines a range of contemporary practices that respond to understandings of the human body as revealed by biomedical science. In bringing together a variety of analytical perspectives, the book draws on scholars, scientists, artists and practices that are at the forefront of current creative, scientific and academic research. Its exploration of the dynamics and exchange between performance and medicine will stimulate a widening of the debate around key issues such as subjectivity, patient narratives, identity, embodiment, agency, medical ethics, health and illness. In focusing on an interdisciplinary understanding of performance, the book examines the potential of performance and theatre to intervene in, shape, inform and extend vital debates around biomedical knowledge and practice in the contemporary moment.

A crucial element in ensuring patient safety and quality of care is the proper training of the next generation of doctors, nurses, and healthcare staff. To effectively serve their students, health science educators must first prepare themselves with competencies in pedagogy and curriculum design. Transformative Curriculum Design in Health Sciences Education provides information for faculty to learn how to translate technical competencies in medicine and healthcare into the development of both traditional and online learning environments. This book serves as a reference for health sciences undergraduate and graduate faculty interested in learning about the latest health sciences educational principles and curriculum design practices. This critical reference contains innovative chapters on transformative learning, curriculum design and development, the use of technology in healthcare training through hybrid and flipped classrooms, specific pedagogies, interprofessional education, and more.

One of the biggest questions in today's biochemistry is how biological molecules became essential for the processes that occur within living cells. This new book from outstanding Metal Ions in Life Science series gives an overview about biochemical evolution of organic molecules and metabolic pathways in living systems and outlines the vital biochemical processes in microbial cells in which metals are involved.

This book compiles recent research on the modification of nucleic acids. It covers backbone modifications and conjugation of lipids, peptides and proteins to oligonucleotides and their therapeutic use. Synthesis and application in biomedicine and nanotechnology of aptamers, fluorescent and xeno nucleic acids, DNA repair and artificial DNA are discussed as well.

Metal-Sulfur clusters play an essential role in living organisms through the unique character of sulfur-metal bonding. The new volume in prestigious Metal Ions in Life Sciences explores different transition metal complexes with sulfur, their biosynthesis and biological functions in regulation of gene expression, catalysis of important metabolic reactions and protein structure arrangement.

The book provides a detailed state-of-the-art overview of inorganic chemistry applied to medicinal chemistry and biology. It covers the newly emerging field of metals in medicine and the future of medicinal inorganic chemistry. Further it includes metal based medicines used in alternative systems of Ayurveda as well as Tibetan Zuotai to make it a holistic approach. It is an essential reading for every researcher and student in medicinal and bioinorganic chemistry.

During the past several years there has been a shortage of flight opportunities for biological and medical projects. And those that were available usually had severe restrictions on instrumentation, number of subjects, duration, time allotted for performing the experiments, a possibility for repetition of experiments. It is our hope and expectation that this will change once the international Space Station is in full operation. The advantages of a permanent space station, already demonstrated by the Russian Mir station, are continuous availability of expert crew and a wide range of equipment, possibility of long-term experiments where this is waranted, increased numbers of subjects through larger laboratory space, proper controls in the large 1-G centrifuge, easier repeatability of experiments when needed.
The limited number of flight opportunities during recent years probably explains why it has taken so long to acquire a sufficient number of high quality contributions for this seventh volume of Advances in Space Biology and Medicine. While initially the series wassailed at annually appearing volumes, we are now down to a biannual appearance. Hopefully, it will be possible to return to annual volumes in the future when results from space station experimentation at beginning to pour in.
The first three chapters of this volume deal with muscle. Fejtek and Wassersug provide a survey of all studies on muscle of rodents flown in space, and include an interesting demography of this aspect of space research. Riley reviews our current knowledge of the effects of long-term spaceflight and re-entry on skeletal muscle, and considers the questions still to be answered before we can be satisfied that long-term space missions, such as on the space station, can be safely undertaken. Stein reviews our understanding of the nutritional and hormonal aspects of muscle loss in spaceflight, and concludes that the protein loss in space could be deleterious to health during flight and after return. Strollo summarizes our understanding of the major endocrine systems on the ground, then considers what we know about their functioning in space, concluding that there is much to be learned about the changes taking place during spaceflight. The many problems of providing life support (oxygen regeneration and food supply) during extended stay on the Moon, on Mars, or in space by means of plant cultivation are discussed by Salisbury. The challenges of utilizing electrophoresis in microgravity for the separation of cells and proteins are illustrated and explained by Bauer and colleagues. Finally, the chapter on teaching of space life sciences by Schmitt shows that this field of science has come of age, but also that its multidisciplinary character poses interesting challenges to teaching it.

Breast cancer research has never been in such an exciting and hopeful phase as today. From a clinical perspective, the discovery of genetic markers of risk in a proportion of familial breast cancer cases has opened up new vistas for understanding and ultimately preventing this disease. On the other hand, aggressive - even daring - therapies are being proven to be effective against advanced breast cancer. For the breast cancer experimentalist, this is also a time of great advance. Although animal and cell culture breast cancer models have proven to be of great use, there are now increasing opportunities to test the concepts developed in these models in actual clinical samples and cases. It is gratifying to see how well these concepts "translate" into the clinical setting. A very active area of research that is linking the laboratory to the clinic is the dissection of the biology and elucidation of the significance of proliferate breast disease and the identification of true, "high risk" or "preneoplastic" legions within the previously ill-defined spectrum of fibrocystic or benign breast disease. One anticipates that discoveries made here will also lead to earlier detection, intervention and prevention of life-threatening cancer.
Even, however, as we look with optimism to the eventual eradication of breast cancer, we are once again forced to face the reality that we have not yet achieved our goal. Thus, we are saddened by the much too premature death of Dr. Helene Smith from breast cancer. Helena's work was at the forefront of efforts to understand the biology of human breast cancer at the molecular level. Her insight, open-mindedness, and refusal to sacrifice relevance for convenience will continue to set the standard for all breast cancer researchers. This volume is dedicated to her memory.

Reinforce your knowledge of physiology with this active, engaging, and relaxing review method! Netter's Physiology Coloring Book makes abstract concepts more concrete as you use color and tactile movement to reinforce your memory and understanding of challenging topics. It's a fun and interactive way to learn and review a complex but fascinating subject-whether you're taking a physiology course or lab, or preparing for a career in science or medicine and healthcare.More than "just" a coloring book, this unique learning tool offers: More than 100 key topics in physiology, using bold, clear drawings based on classic artwork by Frank Netter, MD and other master scientific and medical illustrators. Coloring exercises that emphasize pathways, processes, and cycles for a visual memory aid. Quick-reference tables and Pathophysiology Notes that bridge basic science with health care and medicine. Workbook review questions and drawing challenges to reinforce comprehension and retention. Enhanced eBook version included with purchase. Your enhanced eBook includes completed coloring and workbook pages for reference and allows you to access all of the text and figures, from the book on a variety of devices.