This book addresses surface modification techniques, which are critical for tailoring and broadening the applications of naturally occurring biopolymers. Biopolymers represent a sustainable solution to the need for new materials in the auto, waste removal, biomedical device, building material, defense, and paper industries. Features: First comprehensive summary of biopolymer modification methods to enhance compatibility, flexibility, enhanced physicochemical properties, thermal stability, impact response, and rigidity, among others Address of a green, eco-friendly materials that is increasing in use, underscoring the roles of material scientists in the future of new "green" bioolymer material use Coverage applications in automotive development, hazardous waste removal, biomedical engineering, pulp and paper industries, development of new building materials, and defense-related technologies Facilitation of technology transfer

"Covers most of the recent technical accomplishments in the area of surface modification of biopolymers for different applications"--

The demand for functional biosubstrates increased substantially in the last decades through the advances in biomedicine and biosensor development. In the current thesis the modification of biosurfaces, such as cellulose and hyaluronan, via several thermally and photochemically induced ligation techniques is pioneered. The thesis is methodologically driven and aims at establishing toolbox technologies for biosurface modification. Highly efficient and mild conjugation methodologies are employed such as (hetero) Diels-Alder protocols, photoenol and phenacyl sulfide chemistry as well as the nitrile imine mediated tetrazole-ene cycloaddition (NITEC) approach to ligate polymers, peptide strands and proteins. The demonstrated arsenal of ligation protocols features mild and catalyst-free conditions, which is a vital point when handling sensitive biomolecules. Cellulose – as the most abundant and most prominent biopolymer – was placed into the focus of the current work as a platform for the establishment of a new set of ligation techniques applicable for a wide range of biosubstrates.

Applications of synthetic materials in medicine date back over 4000 year2. The Egyptians used linen as sutures. In the Roman Empire, gold was used in dentistry. Perhaps even earlier, ivory and bone may have been used in the body by practitioners of the healing arts. The historical origins of modem biomaterials science are also hard to precisely trace, but many of the ideas that define biomaterials as we know them today evolved in the late 1950s and early 1960s. Surface modification technology has played a prominent role in biomaterials science, and has paralleled the evolution of the modem field. In a symposium organized by the Artifical Heart Program of the NIH National Heart Institute and the Artificial Kidney program of the NIH National Institute of Arthritis and Metabolic Diseases, held in Atlantic City, New Jersey, in 1968, there were already a number of presentations on surface modification. Surface characterization at that time included scanning electron microscopy, ellipsometry, contact angle methods, and infrared internal reflection methods.

This book on biopolymers offers a comprehensive source for biomaterial professionals. It covers all elementary topics related to the properties of biopolymers, the production, and processing of biopolymers, applications of biopolymers, examples of biopolymers, and the future of biopolymers. Edited by experts in the field, the book highlights international professionals’ longstanding experiences and addresses the requirements of practitioners and newcomers in this field in finding a solution to their problems. The book brings together several natural polymers, their extraction/production, and physio-chemical features. The topics covered in this book are biopolymers from renewable sources, marine prokaryotes, soy protein and humus oils, biopolymer recycling, chemical modifications, and specific properties. The book also focuses on the potential and diverse applications of biogenic and bio-derived polymers. The content includes industrial applications of natural polymeric molecules and applications in key areas such as material, biomedical, sensing, packaging, biomedicine, and biotechnology, and tissue engineering applications are discussed in detail. The objective of this book is to fill the gap between the researchers working in the laboratory to cutting-edge technological applications in related industries. This book will be a very valuable reference material for graduates and post-graduate students, academic researchers, professionals, research scholars, and scientists, and for anyone who has a flavor for doing biomaterial research. The books are designed to serve as a bridge between undergraduate textbooks in biochemistry and professional literature. The book provides universal perspectives for an emerging field where classical polymer science blends with molecular biology with highlights on recent advances.

Polymers are widely used in bioengineering for a wide range of applications, including substrates for in vitro cell culture and scaffolds for in vivo tissue engineering. Because polymer surfaces are usually non-polar and exhibit low biocompatibility, surface chemical modification must be used to enhance biocompatibility. In this study, biopolymer surfaces were modified by various plasma treatments and the resulting surface properties were characterized in detail by various microanalysis techniques. Although surface chemistry modification of biopolymers is important, modification of the near-surface structure of biopolymers is also critical because it affects cell attachment, proliferation, and infiltration, which is of paramount importance in the fabrication of scaffolds for tissue engineering. Plasma polymerized fluorocarbon (FC) films grafted onto Ar plasma-treated low-density polyethylene surfaces were shown to increase the surface shear strength while maintaining low friction. These surface characteristics illustrate the potential of FC films as coating materials of bioinstruments, such as catheters used for the treatment of diseased arteries where blood flow is restricted by plaque deposits onto the inner wall of the vessel. In addition to FC film grafting, plasma polymerization with diethylene glycol dimethyl ether monomer was used to graft non-fouling polyethylene glycol (PEG)-like films on various substrates to prevent both protein adsorption and cell attachment, which is of great importance to the fabrication of non-clotting artificial grafts for bypass surgery. Non-fouling PEG-like films were used to chemically pattern substrate surfaces for single-cell culture. Polystyrene culture dishes coated with a PEG-like film were chemically patterned using a silicon shadow mask or a poly(dimethyl siloxane) (PDMS) membrane mask, fabricated by standard lithography methods, to locally remove the PEG film by Ar plasma etching through the mask windows. Another surface chemical patterning method for long-term single-cell culture was accomplished with polystyrene and parylene C surfaces by taking advantage of the change in surface hydrophilicity induced by plasma treatment. These surface chemical patterning methods were used to regulate the shape and size of smooth muscle cells (SMCs). A strong effect of the shape and size of SMCs on proliferation rate was observed, which was correlated to changes in nuclei shape and volume of the SMCs. In contrast to solid polymers, plasma surface treatment of fibrous polymer materials to improve biocompatibility has received relatively less attention. Thus, another objective of this dissertation was to explore how plasma surface modification with inert (e.g., Ar) and reactive (e.g., NH3) gas plasmas can be used to enhance cell attachment, growth and infiltration into fibrous polymer scaffolds. Poly(L-lactide) (PLLA) microfibrous scaffolds synthesized by electrospinning were plasma treated with Ar and NH3 gases to improve cell affinity and incorporate functional groups for biomolecule immobilization. Both Ar and NH3 plasma treatments were shown to improve the cell attachment and growth onto the fabricated microfibrous scaffolds, while surface functional groups produced by NH3 plasma treatment were also effective in immobilizing biomolecules. In addition to the surface chemistry, the structure of biopolymer materials also impacts the effectiveness of tissue engineering scaffolds. Using microfabrication technology to produce a patterned PDMS template for electrospinning, patterned PLLA microfibrous scaffolds with different structures were fabricated and their potential for tissue engineering was demonstrated by in vitro and in vivo cell culture experiments. The results of this thesis indicate that surface chemistry and structure modification of biopolymers by combining plasma treatment with microfabrication/micropatterning techniques is an effective method of engineering surfaces for single-cell culture and scaffold materials with tailored two- and three-dimensional structures that enhance cell growth and infiltration. The findings of this work have direct application in the development of patterned surfaces for controlled single-cell attachment, which is of particular value to studies of individual cell behavior, and scaffolds for tissue engineering and repair.