Organizers: Jing Du, David Restrepo, Steven Naleway, Ning Zhang, Ling Li
Scope: The interaction of materials and biological systems is a rapidly growing, interdisciplinary frontier in materials science and engineering with boundless possibilities. Biological materials science involves the application of materials science and engineering principles to the study of biological materials, including the design, synthesis, and fabrication of materials systems from biological lessons. The Symposium on Biological Materials Science emphasizes the primacy of biological materials to the development of biomaterials and biomimetic materials. Biological materials comprise the inorganic and organic constituents of biological systems, whereas biomaterials are synthetic materials developed to replace, restore or augment biological materials. The structure and properties of biological materials exhibit a breadth and complexity unmatched in current biomaterials. Biological materials are formed under ambient conditions by living and adaptive biological systems for multifunctional performance. The structure and properties of biological materials are typically hierarchical, inhomogeneous, and anisotropic. Therefore, biological materials exhibit complex structure-property relationships which are only beginning to be elucidated. Biomimetic materials (or bioinspired materials) have unique, tailored structures and properties designed based upon the study of structure-property relationships in biological materials. Biomimetic materials most often utilize creative new methods of synthesis/processing and microstructure design in order to achieve the desired functionality.
Anticipated Number of Sessions: 6
Organizers: Candan Tamerler, Kalpana Katti, Hannes Schniepp, Terry Lowe, Po-Yu Chen
Scope: The symposium focuses on fundamental understanding of biological and biomimetic solid interfaces as well as their implementation into engineering applications. Interfacing biological molecules predic tably with solid materials at the nanoscale is the key for hybrid materials design leading to innovative functional properties. Exploiting such properties towards developing functional materials and devices depends on a better understanding and control of the interfacial interactions at the atomic to nanoscale. This symposium will address the synthesis, modelling, and design principles of the bionano interfaces and their implementation into practical medical and technical applications such as tissue engineering, catalysis, sensors, electronics, and photonics. While the solids may include metals, ceramics, semiconductors, polymers, and their composites, the biopolymers include proteins, peptides, DNA, RNA, polysaccharides, glycans, lipids and membranes as well as cells and viruses. A special emphasis will be given to the assembly processes at solid liquid interfaces that lead to specific surface phenomena and designed bionano solid self-assembled structures and organizations towards functional materials, systems and devices.
The symposium will encompass the following themes, but are not limited to:
Anticipated Number of Sessions: 7
Organizers: Bernd Gludovatz, Elizabeth Zimmermann, Steven Naleway
Scope: Biological tissues and materials self-assembled in nature have complex, hierarchical structures that can result in unique properties. These structure-property relationships are a wealth of information for materials scientists to explore for inspiration in designing the next generation of materials. Biological tissues and materials are, however, not always static entities. Often the dynamic structure is growing and/or adapting to the local biological or mechanical environment. Materials science investigations can offer great insight into how features in the multi-scale structure sense mechanical forces and biochemically promote adaptation. Materials-specific characterization techniques are then essential in quantifying the structure and related properties particularly for disease-related structural and functional modifications.
Topics that will be addressed:
Anticipated Number of Sessions: 2
Organizers: Tolou Shokuhfar, Jing Du
Scope: This symposium covers advances in new research directions for biomaterials for biomedical implants. It high- lights how researchers and clinicians are pushing the envelope in disease prevention, detection, and treatment. It covers more traditional areas such as hip, craniofacial, and spinal implants but also pushes us in new directions such as implantable sensors that can potentially determine changes in bone health and then respond to those changes to ensure strong healthy bones. It also emphasizes novel solutions to traditionally difficult tissue repair, such as meniscus repair and other organ tissue regeneration strategies. Most importantly, highlights the dynamic field of implant biomaterials as it introduces new chemistries to tissue regeneration, such as biodegradable metals and new polymers.
Anticipated Number of Sessions: 2
Organizers: Changxue Xu, Yifei Jin, Zhengyi Zhang, Jun Yin, Heqi Xu
Biomaterials have been widely utilized in a variety of biomedical applications, such as tissue engineering, regenerative medicine, biosensors and medical implants, due to their inherent physical and chemical properties including biocompatibility, tunable mechanical properties and biodegradability, and hierarchical internal structures. Additive manufacturing, based on layer-by-layer fabrication mechanism, possesses critical advantages in fabrication of 3D structures of biomaterials for various biomedical applications, including complex geometries, heterogeneity, porosities, and incorporation of different growth factors. Typical 3D printing techniques used for biomaterials include inkjet printing, microextrusion, laser-assisted printing, stereolithography, to name a few. The most common biomaterials used in 3D printing are ceramics, polymers, and composites. The post-printing properties and microstructures are of great importance to the biomaterial functionality, such as mechanical properties, physical properties including swelling and degradation properties, pore size and porosity. The symposium shall focus on the recent advances in the biomaterials for 3D printing of scaffolds and tissues. Specific topics of interest include, but are not limited to:
Sponsoring Committee: Materials Characterization Committee
Organizer: Henry A. Colorado
Number of Talks: 16
Sponsoring Committee: Advanced Characterization, Testing and Simulation Committee
Co-Sponsoring Committees: Alloy Phases Committee, Biomaterials Committee
Organizers:
Scope: Real time observations can provide important information needed to understand materials behavior, as these techniques can provide temporal and spatial insights free from artifacts otherwise induced from conventional experimental techniques. Traditional and emerging advanced imaging techniques, which may be optical or non-optical, would allow such observations. Methods may be enhanced with capabilities that enable heating and cooling, controlled atmospheres, and application of stresses; and can be used to generate real time thermodynamic and kinetic data needed to study a variety of materials and processes. This symposium encompasses a broad range of materials science topics enabling cross-cutting opportunities for multiple disciplines (biomaterials, energy materials, functional materials, structural materials, etc.) while topics will be separately categorized in the technical program. Presentations are solicited on the application of these methods to materials science and industrial processes, as well as on development of such techniques.
Topics include, but not limited to:
The symposium plans to have joint sessions with: