Chapter title |
Mechanical Properties and Failure of Biopolymers: Atomistic Reactions to Macroscale Response
|
---|---|
Chapter number | 643 |
Book title |
Polymer Mechanochemistry
|
Published in |
Topics in current chemistry, January 2015
|
DOI | 10.1007/128_2015_643 |
Pubmed ID | |
Book ISBNs |
978-3-31-922824-2, 978-3-31-922825-9
|
Authors |
GangSeob Jung, Zhao Qin, Markus J. Buehler |
Abstract |
The behavior of chemical bonding under various mechanical loadings is an intriguing mechanochemical property of biological materials, and the property plays a critical role in determining their deformation and failure mechanisms. Because of their astonishing mechanical properties and roles in constituting the basis of a variety of physiologically relevant materials, biological protein materials have been intensively studied. Understanding the relation between chemical bond networks (structures) and their mechanical properties offers great possibilities to enable new materials design in nanotechnology and new medical treatments for human diseases. Here we focus on how the chemical bonds in biological systems affect mechanical properties and how they change during mechanical deformation and failure. Three representative cases of biomaterials related to the human diseases are discussed in case studies, including: amyloids, intermediate filaments, and collagen, each describing mechanochemical features and how they relate to the pathological conditions at multiple scales. |
Mendeley readers
Geographical breakdown
Country | Count | As % |
---|---|---|
Unknown | 23 | 100% |
Demographic breakdown
Readers by professional status | Count | As % |
---|---|---|
Student > Master | 4 | 17% |
Researcher | 3 | 13% |
Student > Ph. D. Student | 3 | 13% |
Other | 2 | 9% |
Student > Bachelor | 1 | 4% |
Other | 4 | 17% |
Unknown | 6 | 26% |
Readers by discipline | Count | As % |
---|---|---|
Engineering | 3 | 13% |
Materials Science | 3 | 13% |
Chemistry | 2 | 9% |
Medicine and Dentistry | 2 | 9% |
Agricultural and Biological Sciences | 1 | 4% |
Other | 5 | 22% |
Unknown | 7 | 30% |