Mechanics of Biomaterials

'Mechanics of Biomaterials is the textbook I have been waiting for. This comprehensive work synthesizes the science and engineering of biomaterials that has developed over the past three decades into a highly useful textbook for training students … as I reviewed this work it felt like I was reviewing my own lecture notes developed over 20 years. [It] combines materials science, mechanics and medical device design and analysis in a seamless and thorough manner incorporating many critical studies from the literature into a clear and comprehensive work … Pruitt and Chakravartula have succeeded in developing an outstanding text and reference book that should be required reading for all who aspire to design, develop and evaluate medical devices.' Jeremy L. Gilbert, Syracuse University

'… a detailed yet easy-to-read book that can be used by materials scientists and biomedical engineers, from both the budding biomedical engineering student to the seasoned medical device designer. It combines the fundamentals of plastics, metals, and ceramics behavior with the required properties for the often challenging loading and environmental conditions found in the body. I particularly liked Pruitt and Chakravartula's technique of introducing a detailed discussion of the theoretical explanation of a particular material class's response to a loading environment, and then providing a real-life case study demonstrating how the theoretical response translates to clinical performance … The book is rich in practical examples of biomaterials used in permanent implants currently on the market. Sufficient historical information is provided on implant successes and failures to appreciate the challenges for material and design selection in the areas of both hard and soft tissue replacement.' Stephen Spiegelberg, Cambridge Polymer Group, Inc.

'Mechanics of Biomaterials: Fundamental Principles for Implant Design provides a much needed comprehensive resource for engineers, physicians, and implant designers at every level of training and practice. The book includes a historical background which outlines the engineering basis of traditional implant designs, and interactions of materials, biology, and mechanics resulting in clinical success or failure of these devices. Each chapter contains a detailed description of the engineering principles which are critical to understand the mechanical behavior of biomaterials and implants in vivo. The scope of the text covers orthopaedics, cardiovascular devices, dental, and soft tissue implants, and should help considerably in our efforts to improve the function and durability of biomaterials and implants used in clinical practice.' Michael Ries, University of California, San Francisco