Cantitate/Preț
Produs
Total produse
Vezi coșul
Virtual Prototyping & Bio Manufacturing in Medical Applications de Bopaya Bidanda

Virtual Prototyping & Bio Manufacturing in Medical Applications

Editat de Bopaya Bidanda, Paulo Jorge Bártolo
en Limba Engleză Paperback – 7 oct 2014
The original role of RP was to confirm the shape and feel of concept design, but innovations in RP now allow for the development of sophisticated medical devices such as catheters, stents, drug delivery systems, syringes and cardio-vascular devices, and more. RP has moved beyond medical devices, as surgeons now regularly use RP models to brainstorm strategies for surgeries. This book presents new uses for rapid prototyping in state-of-the-art medical applications.
Citește tot Restrânge

Toate formatele și edițiile

Toate formatele și edițiile Preț Express
Paperback (2) 83641 lei  43-57 zile
  Springer International Publishing – 23 oct 2021 83641 lei  43-57 zile
  Springer Us – 7 oct 2014 120352 lei  38-44 zile
Hardback (2) 109561 lei  43-57 zile
  Springer Us – 17 dec 2007 109561 lei  43-57 zile
  Springer International Publishing – 22 oct 2020 115644 lei  43-57 zile

Preț: 120352 lei

Preț vechi: 126687 lei
-5% Nou

Puncte Express: 1805
Preț estimativ în valută:
23050 23748$ 19308£

Carte tipărită la comandă

Livrare economică 19-25 februarie

 Adaugă în coș

Wish list
Gift list
Am citit!
Adaugă în listă
Preluare comenzi: 021 569.72.76

Specificații

ISBN-13: 9781489973597
ISBN-10: 1489973591
Pagini: 320
Dimensiuni: 155 x 235 x 17 mm
Greutate: 0.45 kg
Ediția:2008
Editura: Springer Us
Colecția Springer
Locul publicării:New York, NY, United States

Public țintă

Research

Descriere

We are especially pleased to present our edited book in an area that is quickly emerging as one of the most active research areas that integrate both engineering and medicine. Preliminary research results show signi?cant potential in effecting major breakthroughsranging from a reduction in the number of corrective surgeries needed to the ‘scienti?c miracle’ of generating tissue growth. Over $600 million has been in invested in tissue engineering last year alone—a large and signi?cant component of this is in the area of virtual and physical prototyping. Virtual & Physical prototyping can broadly be divided into three categories: Modeling, Manufacturing& Materials. This book focuses on the ?rst part and some areas of the second.The second bookin this series will focuson the areas in the s- ondandthird categories.As youwill see fromthis book,the principlesutilizeddraw heavily from the more traditional engineering?elds including mechanical engine- ing, industrial engineering, civil engineering (structures), electrical engineering and bio engineering. The ?rst chapter by Winder provides an insight into the practicalities of creating custom made implants for the skull details. The concept of cranioplasty, describing the correction of a bone defect or deformity in the cranium using a bio-compatible material, is described and explored from a computational point of view In Chapter 2, Ming Leu and his group of researchers review the use of virtual reality technology for the development of a virtual bone surgery system, which can be used for training in orthopedic surgery and planning of bone surgery procedures.

Cuprins

Computer Assisted Cranioplasty.- Virtual Bone Surgery.- Medical Imaging Challenges Photogrammetry.- Computer Aided Tissue Engineering Scaffold Fabrication.- CAD Assembly Process for Bone Replacement Scaffolds in Computer-Aided Tissue Engineering.- Computational Design and Simulation of Tissue Engineering Scaffolds.- Virtual Prototyping of Biomanufacturing in Medical Applications.- Advanced Processes to Fabricate Scaffolds for Tissue Engineering.- Rapid Prototyping to Produce POROUS SCAFFOLDS WITH CONTROLLED ARCHITECTURE for Possible use in Bone Tissue Engineering.- Laser Printing Cells.- Selective Laser Sintering of Polymers and Polymer-Ceramic Composites.- Design, Fabrication and Physical Characterization of Scaffolds Made from Biodegradable Synthetic Polymers in combination with RP Systems based on Melt Extrusion.

Textul de pe ultima copertă

Virtual and physical prototyping is rapidly emerging as an active research area that integrates fundamental principles of engineering with a view towards solving complex problems in the human body in a medical environment.  Preliminary research results show significant potential in effecting major breakthroughs ranging from a reduction in the number of corrective surgeries needed to the ‘scientific miracle’ of generating tissue growth. Virtual & Physical prototyping can broadly be divided into three categories: Modeling, Manufacturing, and Materials. Virtual Prototyping & Bio Manufacturing in Medical Applicationsfocuses primarily on the modeling and manufacturing in the field.
The principles utilized draw heavily from the more traditional engineering fields including mechanical engineering, industrial engineering, civil engineering (structures), electrical engineering and bio engineering.
Written for researchers, professionals, engineers and academics seeking a comprehensive overview of virtual prototyping and rapid prototyping,Virtual Prototyping & Bio Manufacturing in Medical Applications, discusses in detail applications related to surgery, medical imaging, tissue engineering, bone replacement, and more.

Caracteristici

Brings together all the important aspects of virtual and rapid prototyping relative to medical applications in a cohesive manner
Provides a comprehensive overview of virtual prototyping and rapid prototyping techniques
Covers applications of rapid prototyping in detail including the dental, cardiovascular and biomaterial areas

Notă biografică

Bopaya Bidanda is the Ernest E. Roth Professor and Chairman of the Department of Industrial Engineering at the University of Pittsburgh. His research is in the area of manufacturing systems with a special focus on group technology, reverse engineering, cellular manufacturing, lean manufacturing, human issues in manufacturing, product development, and manufacturing modernization. 

Paulo Bartolo is Professor of Advanced Manufacturing Processes at the Polytechnic Institute of Leiria (Portugal), Adjunct Professor at Queensland University of Technology (Australia), Visiting Professor at Nanyang University (Singapore), and Professor of Biomaterials (Catedra UNESCO) at the University of Habana (Cuba). He is a CIRP (The International Academy of Production Engineering) member, Vice-Chairman of the CIRP Scientific Technical Committee on Electro-Physical and Chemical Processes, GARPA (Global Alliance of Rapid Prototyping Associations) Portuguese Representative a
nd Member of the Direction Board of the International Society of Biomanufacturing, Scientific advisor of the Research Institute in Biofabrication (BIOFABRIS) funded by the Brazilian Government and regional coordinator of the working group of Rapid Manufacturing Platform.