The need for the development of biomaterials as scaffold for tissue regeneration is driven by the increasing demands for materials that mimic functions of extracellular matrices of body tissues. Unfolding the Biopolymer Landscape provides a unique account of “biopolymeric interventions” inherent to biotechnological applications, soft tissue engineering, ophthalmic drug delivery, biotextiles, environmentally responsive systems, neurotherapeutics, and emulsions-based formulations for food and pharmaceutical applications. Chapters in this volume also cover biomedical applications and implications of cationic polymers, collagen-based substrates, multifunctional polymers, shape memory biopolymers, hybrid semisynthetic biomaterials, microbial exopolysaccharides, biomaterials mimicking the extracellular microenvironment, derivatized polysaccharides, and metallic biomaterials. Each chapter is distinctly written by experts in the respective fields and emphasis is given on the mechanistic profile of the performance of biopolymers and biomedical applications. This book provides both basic and advanced biopolymer information for scientific experts and early career researchers in the field of drug delivery, tissue engineering, nanomedicine, food technology, peptide science, biomaterial design, and nutrition. This volume provides a unique account of “biopolymeric interventions” inherent to biotechnological applications, soft tissue engineering, ophthalmic drug delivery, biotextiles, environmentally responsive systems, neurotherapeutics, and emulsions-based formulations for food and pharmaceutical applications.

3D Printing and Microfluidics in Dermatology provides a thorough exploration and applications of three-dimensional (3D) printing and microfluidics within the field of dermatology. It investigates various methods utilized in these fields, such as 3D bioprinting, nano-transporters, microscopic fabrication, and device development. The book not only examines practical applications but also delves into the design principles crucial for implementing these techniques using specific materials tailored to their intended purposes. Additionally, it addresses ethical concerns and regulatory considerations pertinent to these evolving technologies. Key highlights include the following: A detailed insight into the utilization of 3D printing and microfluidic technologies for treating skin disorders. Exploration of design concepts necessary for effective implementation, considering the unique properties of materials involved. Coverage of diverse methodologies, ranging from 3D bioprinting to nano-transporters, microscopic fabrication, and device engineering. In-depth discussion on ethical considerations vital for the sustainable development of the industry. Investigation into advancements in material development, device design, fabrication techniques, and performance evaluation through preclinical and clinical studies. This book targets graduate students and researchers in fields such as 3D printing, dermatology, drug delivery, bioengineering, and pharmaceutical sciences.

This book covers pharmaceutical residue dispersion in the aquatic environment and its toxic effect on living organisms. It discusses conventional and advanced remediation technologies such as the use of biomaterials for the sequestration of contaminants, nanotechnology, and phytoremediation. The book includes topics such as the removal of pharmaceutical and personal care product residues from water bodies, green chemistry, and legal regimens for pharmaceuticals in the aquatic environment. It also covers the application of modified biochar in pharmaceutical removal. FEATURES Explores the management of the environment through green chemistry Describes phytoremediation technology for decontamination of pharmaceutical-laden water and wastewater Covers the detection methods and quantification of pharmaceutical residues in various contaminated sources Discusses ecotoxicological aspects and risk assessment of pharmaceuticals in the aquatic environment Reviews degradation and treatment technologies including nanotechnology, biomaterials, and biochar This book is meant for pharmaceutical, toxicology, and environmental science industry experts and researchers.

This book examines the commercial role of various microbial polysaccharides and recent advances in their production. Offering an overview of the physiological role, biosynthetic pathways and regulatory mechanisms, it also explores the current challenges regarding bioprocessing for the production of polysaccharides.

Until the late 20th century, computational studies of biomolecules and nanomaterials had considered the two subjects separately. A thorough presentation of state-of-the-art simulations for studying the nanoscale behavior of materials, Simulations in Nanobiotechnology discusses computational simulations of biomolecules and nanomaterials together. Th

Information on our detailed genetic code is increasing at a dramatic pace. We need to understand how that is translated into the three-dimensional structure of proteins in order to make use of the information. Progress in this field is hampered by the lack of precise force fields and of efficient codes for finding equilibrium configurations of heteropolymers. However, there has been rapid advance in recent years, and this volume discusses that.

This book contains the proceedings of the AMS Special Session on Topology of Biopolymers, held from April 21–22, 2018, at Northeastern University, Boston, MA. The papers cover recent results on the topology and geometry of DNA and protein knotting using techniques from knot theory, spatial graph theory, differential geometry, molecular simulations, and laboratory experimentation. They include current work on the following topics: the density and supercoiling of DNA minicircles; the dependence of DNA geometry on its amino acid sequence; random models of DNA knotting; topological models of DNA replication and recombination; theories of how and why proteins knot; topological and geometric approaches to identifying entanglements in proteins; and topological and geometric techniques to predict protein folding rates. All of the articles are written as surveys intended for a broad interdisciplinary audience with a minimum of prerequisites. In addition to being a useful reference for experts, this book also provides an excellent introduction to the fast-moving field of topology and geometry of biopolymers.