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Embalming --- -Mummies --- -Surgical instruments and apparatus --- -Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Human mummies --- Dead --- Human remains (Archaeology) --- Undertakers and undertaking --- Mummies --- Equipment and supplies --- Instruments --- Egypt --- Antiquities. --- -Egypt --- Surgical instruments and apparatus --- Apparatus, Surgical --- Embaumement --- Médecine égyptienne --- Momies --- Égypte ancienne --- Égypte --- Antiquité --- Jusqu'à 332 av. J.-C. --- Religion
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Surgical instruments and apparatus. --- Nursing. --- Clinical nursing --- Nurses and nursing --- Nursing process --- Care of the sick --- Medicine --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Equipment and supplies --- Instruments
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This book provides step-by-step instructions on how to operate with 27G instrumentation in a wide range of surgical indications, including vitreous floaters, macular holes, dropped nucleus, retinal detachment, diabetic retinopathy, submacular hemorrhage, retinopathy of prematurity and much trauma. All surgeries are approached in cookbook fashion, with initial coverage of the “ingredients” (devices and instruments) and then meticulous description of preparation and performance with supporting photographs, drawings, and videos. In addition, the differences and benefits in comparison with 23G and 25G vitrectomy are highlighted. Small-gauge vitrectomy has radically changed the ways in which vitrectomy is performed. 27G vitrectomy is the most recent and most exciting development in small-gauge vitrectomy. The healing time is faster but the small diameter prolongs the duration of surgery. This obstacle has been overcome with powerful new vitrectomy machines and revolutionary vitreous cutters with two cutting blades making 27G vitrectomy as fast as 25G. This new equipment has expanded the indications for 27G surgeries immensely from detachment surgery to retinopathy of prematurity and the advent of new instruments may make 27G the gold standard in the future. This book, written by authors with huge experience in 27G vitrectomy, will enable surgeons to fully exploit its advantages.
Ophthalmology & Optometry --- Medicine --- Health & Biological Sciences --- Vitrectomy. --- Surgical instruments and apparatus. --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Equipment and supplies --- Instruments --- Medicine. --- Ophthalmology. --- Surgery. --- Medicine & Public Health. --- Vitreous body --- Medical instruments and apparatus --- Surgical technology --- Surgery, Primitive --- Eye --- Diseases
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Surgical instruments and apparatus. --- Nursing. --- Clinical nursing --- Nurses and nursing --- Nursing process --- Care of the sick --- Medicine --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Equipment and supplies --- Instruments --- Aparells i instruments quirúrgics
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"Engineering has been an essential collaborator in biological research and breakthroughs in biology are often enabled by technological advances. Decoding the double helix structure of DNA, for example, only became possible after significant advances in such technologies as X-ray diffraction and gel electrophoresis. Diagnosis and treatment of tuberculosis improved as new technologies -- including the stethoscope, the microscope, and the X-ray -- developed. These engineering breakthroughs take place away from the biology lab, and many years may elapse before the technology becomes available to biologists. In this book, David Lee argues for concurrent engineering -- the convergence of engineering and biological research -- as a means to accelerate the pace of biological discovery and its application to diagnosis and treatment. He presents extensive case studies and introduces a metric to measure the time between technological development and biological discovery. Investigating a series of major biological discoveries that range from pasteurization to electron microscopy, Lee finds that it took an average of forty years for the necessary technology to become available for laboratory use. Lee calls for new approaches to research and funding to encourage a tighter, more collaborative coupling of engineering and biology. Only then, he argues, will we see the rapid advances in the life sciences that are critically needed for life-saving diagnosis and treatment."
Biomedical engineering. --- Medical instruments and apparatus --- Medicine --- Surgical instruments and apparatus --- Technological innovations. --- Research --- History. --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Apparatus, Medical --- Instruments, Medical --- Medical apparatus --- Medical devices --- Medical products --- Clinical engineering --- Medical engineering --- Equipment and supplies --- Instruments --- Apparatus --- Surgical technology --- Biomedical engineering --- Medical supplies --- Scientific apparatus and instruments --- Bioengineering --- Biophysics --- Engineering --- BIOMEDICAL SCIENCES/General --- INFORMATION SCIENCE/Technology & Policy --- Health Workforce
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Soft and Stiffness-controllable Robotics Solutions for Minimally Invasive Surgery presents the results of a research project, funded by European Commission, STIFF-FLOP: STIFFness controllable Flexible and Learn-able manipulator for surgical Operations. In Minimally Invasive Surgery (MIS), tools go through narrow openings and manipulate soft organs that can move, deform, or change stiffness. There are limitations on modern laparoscopic and robot-assisted surgical systems due to restricted access through Trocar ports, lack of haptic feedback, and difficulties with rigid robot tools operating inside a confined space filled with organs. Also, many control algorithms suffer from stability problems in the presence of unexpected conditions. Yet biological "manipulators", like the octopus arm can manipulate objects while controlling the stiffness of selected body parts and being inherently compliant when interacting with objects. STIFF-FLOP robot is an innovative soft robotic arm that can squeeze through a standard MIS, reconfigure itself and stiffen by hydrostatic actuation to perform compliant force control tasks while facing unexpected situations. Technical topics discussed in the book include:Soft actuatorsContinuum soft manipulatorsControl, kinematics and navigation of continuum manipulatorsOptical sensors for force, torque, and curvatureHaptic feedback and human interface for surgical systemsValidation of soft stiffness controllable robots
Endoscopic surgery --- Surgical instruments and apparatus --- Technological innovations. --- Design and construction. --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Endosurgery --- Minimal access surgery --- Minimally invasive surgery --- MIS (Minimally invasive surgery) --- Operative endoscopy --- Surgical endoscopy --- Endoscopy --- Microsurgery --- Surgery, Operative --- Equipment and supplies --- Instruments --- Energy;Robotics --- Surgical robots. --- Endoscopic surgery. --- Robotics. --- Automation --- Machine theory --- Manipulators (Mechanism) --- Robotics in medicine
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Medical devices and surgical tools that contain micro and nanoscale features allow surgeons to perform clinical procedures with greater precision and safety while monitoring physiological and biomechanical parameters more accurately. While surgeons have started to master the use of nanostructured surgical tools in the operating room, this book addresses for the first time the impact and interaction of nanomaterials and nanostructured coatings in a comprehensive manner. Surface Engineered Surgical Tools and Medical Devices presents the latest information and techniques in the emerging field of surface engineered biomedical devices and surgical tools, and analyzes the interaction between nanotechnology, nanomaterials, and tools for surgical applications. Chapters of the book describe developments in coatings for heart valves, stents, hip and knee joints, cardiovascular devices, orthodontic applications, and regenerative materials such as bone substitutes. Chapters are also dedicated to the performance of surgical tools and dental tools and describe how nanostructured surfaces can be created for the purposes of improving cell adhesion between medical devices and the human body.
Surgical instruments and apparatus. --- Medical instruments and apparatus. --- Nanotechnology. --- Molecular technology --- Nanoscale technology --- High technology --- Apparatus, Medical --- Instruments, Medical --- Medical apparatus --- Medical devices --- Medical products --- Medicine --- Biomedical engineering --- Medical supplies --- Scientific apparatus and instruments --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Apparatus --- Equipment and supplies --- Instruments --- Biomedical engineering. --- Biotechnology. --- Mechanical engineering. --- Surgery. --- Biomedical Engineering and Bioengineering. --- Biological and Medical Physics, Biophysics. --- Mechanical Engineering. --- Surgery, Primitive --- Engineering, Mechanical --- Engineering --- Machinery --- Steam engineering --- Chemical engineering --- Genetic engineering --- Clinical engineering --- Medical engineering --- Bioengineering --- Biophysics --- Biophysics. --- Biological physics. --- Biological physics --- Biology --- Medical sciences --- Physics
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From exoskeletons to neural implants, biomedical devices are no less than life-changing. Compact and constant power sources are necessary to keep these devices running efficiently. Edwar Romero's Powering Biomedical Devices reviews the background, current technologies, and possible future developments of these power sources, examining not only the types of biomedical power sources available (macro, mini, MEMS, and nano), but also what they power (such as prostheses, insulin pumps, and muscular and neural stimulators), and how they work (covering batteries, biofluids, kinetic and ther
Technology --- Equipment and Supplies --- Analytical, Diagnostic and Therapeutic Techniques and Equipment --- Technology, Industry, and Agriculture --- Technology, Industry, Agriculture --- Biomedical Technology --- Electric Power Supplies --- Electrical Equipment and Supplies --- Health & Biological Sciences --- Biomedical Engineering --- Medical instruments and apparatus. --- Surgical instruments and apparatus. --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Apparatus, Medical --- Instruments, Medical --- Medical apparatus --- Medical devices --- Medical products --- Medicine --- Biomedical engineering --- Medical supplies --- Scientific apparatus and instruments --- Equipment and supplies --- Instruments --- Apparatus --- Electrical Equipment and Supplies. --- Biomedical Technology. --- Electric Power Supplies. --- Biomedical materials. --- Electrical engineering --- Equipment and supplies.
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This new edition presents information and knowledge on the field of biomedical devices and surgical tools. The authors look at the interactions between nanotechnology, nanomaterials, design, modeling, and tools for surgical and dental applications, as well as how nanostructured surfaces can be created for the purposes of improving cell adhesion between medical devices and the human body. Each original chapter is revised in this second edition and describes developments in coatings for heart valves, stents, hip and knee joints, cardiovascular devices, orthodontic applications, and regenerative materials such as bone substitutes. There are also 8 new chapters that address: Microvascular anastomoses Inhaler devices used for pulmonary delivery of medical aerosols Surface modification of interference screws Biomechanics of the mandible (a detailed case study) Safety and medical devices The synthesis of nanostructured material Delivery of anticancer molecules using carbon nanotubes Nano and micro coatings for medical devices This book is appropriate for engineers, material scientists, chemists, physicists, biologists, medical and dental professionals with an interest in biomedical devices and tools, and researchers in the same fields.
Engineering. --- Mechanical engineering. --- Nanotechnology. --- Manufacturing industries. --- Machines. --- Tools. --- Biomedical engineering. --- Manufacturing, Machines, Tools. --- Nanotechnology and Microengineering. --- Biomedical Engineering. --- Mechanical Engineering. --- Surgical instruments and apparatus. --- Medical instruments and apparatus. --- Apparatus, Medical --- Instruments, Medical --- Medical apparatus --- Medical devices --- Medical products --- Medicine --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Apparatus --- Equipment and supplies --- Instruments --- Biomedical engineering --- Medical supplies --- Scientific apparatus and instruments --- Medical instruments and apparatus --- Surgical technology --- Manufactures. --- Manufacturing, Machines, Tools, Processes. --- Biomedical Engineering and Bioengineering. --- Engineering, Mechanical --- Engineering --- Machinery --- Steam engineering --- Clinical engineering --- Medical engineering --- Bioengineering --- Biophysics --- Construction --- Industrial arts --- Technology --- Manufactured goods --- Manufactured products --- Products --- Products, Manufactured --- Commercial products --- Manufacturing industries --- Molecular technology --- Nanoscale technology --- High technology
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Within the past twenty years, the field of robotics has been finding many areas of applications ranging from space to underwater explo rations. One of these areas which is slowly gaining popularity among the users group is the notion of service robotics. This book is an in vestigation and exploration of engineering principles in the design and development of mechanisms and robotic devices that can be used in the field of surgery. Specifically the results of this book can be used for designing tools for class of Minimally Invasive Surgery (MIS). Generally, Minimal Invasive Surgery (MIS), e. g. laparoscopic surgery, is performed by using long surgical tools, that are inserted through small incisions at the ports of entry to the body (e. g. abdominal wall) for reaching the surgical site. The main drawback of current designs of en doscopic tools is that they are not able to extend all the movements and sensory capabilities of the surgeon's hand to the surgical site. By im proving surgical procedures, training, and more practice, it is possible for surgeons to reduce completion time for each task and increase their level of skill. However, even in the best cases the level of performance of a surgeon in Minimally Invasive Surgery is still a fraction of the con ventional surgery. Any dramatically improvement is usually driven by introduction of new tools or systems that in turn bring totally new pro cedures and set of skills.
Surgical instruments and apparatus --- Endoscopic surgery --- Robotics in medicine --- Biomedical engineering --- Chirurgie --- Chirurgie endoscopique --- Robotique en médecine --- Génie biomédical --- Design and construction --- Appareils et matériel --- Robotique en médecine --- Génie biomédical --- Appareils et matériel --- Apparatus, Surgical --- Equipment, Surgical --- Instruments, Surgical --- Surgery --- Surgical apparatus --- Surgical equipment --- Surgical instruments --- Medical instruments and apparatus --- Surgical technology --- Medicine --- Endosurgery --- Minimal access surgery --- Minimally invasive surgery --- MIS (Minimally invasive surgery) --- Operative endoscopy --- Surgical endoscopy --- Endoscopy --- Microsurgery --- Surgery, Operative --- Clinical engineering --- Medical engineering --- Bioengineering --- Biophysics --- Engineering --- Equipment and supplies --- Instruments --- Engineering design. --- Mechanical engineering. --- Surgery. --- Electrical engineering. --- Control engineering. --- Robotics. --- Mechatronics. --- Engineering Design. --- Mechanical Engineering. --- Electrical Engineering. --- Control, Robotics, Mechatronics. --- Mechanical engineering --- Microelectronics --- Microelectromechanical systems --- Automation --- Machine theory --- Control engineering --- Control equipment --- Control theory --- Engineering instruments --- Programmable controllers --- Electric engineering --- Surgery, Primitive --- Engineering, Mechanical --- Machinery --- Steam engineering --- Design, Engineering --- Industrial design --- Strains and stresses --- Design
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