Book Volume 3
Preface
Page: i-i (1)
Author: Felipe López-Saucedo
DOI: 10.2174/9789815136920123030001
PDF Price: $15
Biomaterials Applied to Medical Devices and Pharmacy
Page: 1-13 (13)
Author: Tri-Dung Ngo*
DOI: 10.2174/9789815136920123030004
PDF Price: $15
Abstract
Biomaterials have been utilized in healthcare applications a number of
times. Nowadays, subsequent evolution and the increase in the life expectancy of
world’s population have made biomaterials more attractive and versatile, and have
increased their utility. Concerning the manufacturing of medical devices and pharmacy,
the development of new biomaterials, new manufacturing methods and techniques has
always been the researchers’ focus. Recently, nanotechnology and nanomedicine have
attracted a great deal of attention, which would further enhance the use of biomaterials
in medical devices and pharmacy. In the development of medical devices and
pharmacy, the selection of the proper material to be used is of utmost importance. This
chapter aims to provide a review of the most used biomaterials. After an explanation of
what biomaterials are and what defines them, a more in-depth approach to the major
types of biomaterials is presented, such as metal, polymer, ceramic, and composites;
also, the advantages and disadvantages of biomaterials, their main characteristics, and
preferred applications in the area of medical devices and pharmacy are discussed.
Material Synthesis, Structures and Characterization
Page: 14-59 (46)
Author: Luis Alberto Camacho Cruz, Marlene Alejandra Velazco Medel, Luis Ramón Ortega Valdovinos, Angélica Cruz Gómez and Emilio Bucio*
DOI: 10.2174/9789815136920123030005
PDF Price: $15
Abstract
Polymers have been employed for the development of medical devices and implants as some of them are biocompatible. Synthetic procedures and extraction techniques have allowed the obtention of different polymers, classified in this chapter as synthetic and natural polymers. In the process of synthesis of the polymer, its properties can be modulated to obtain more flexible or thermostable materials, nontoxic or transparent, depending on the desired properties of the final product. A wide range of polymers have been used for the manufacturing of catheters, valves, tubes, and other medical devices; therefore, in this chapter, there is a brief description of some of them, their chemical structure and properties, and finally, their application in medicine is shown.
Nanoengineering for Biomedical Devices
Page: 60-110 (51)
Author: David Romero-Fierro*, Moises Bustamante-Torres, Sophía Anchalí and Emilio Bucio*
DOI: 10.2174/9789815136920123030006
PDF Price: $15
Abstract
Nanomedicine aims to control, repair, or comprehensively improve all
human biological systems, working from a molecular level with engineering devices
and nanostructures to achieve medical benefits. This science has had a greater
development in recent years, thanks to the great technological advances achieved in
developed countries, which is due to the large investment that is made due to the
promising incursion of nanotechnology in the diagnosis and treatment of various
diseases. This chapter covers this topic from a technical point of view that involves the
synthesis of materials and the development of techniques with their respective
biomedical application. In addition, the ethical issues related to its application and the
actions that have been taken to regulate it are detailed.
Stimuli-responsive Biomaterials with Pharmacological Applications
Page: 111-139 (29)
Author: Julián Eduardo Sánchez-Velandia*, David Valverde, Raul Porcar and Aída Luz Villa
DOI: 10.2174/9789815136920123030007
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Abstract
Natural and synthetic biomaterials are useful for different biological and
industrial applications, and their impact, as well as the interest (in both academy and
industry) in those materials, have grown up in the last few years. This chapter presents
some advances in the synthesis of biopolymers and related materials using different
synthetic and non-synthetic strategies (from conventional chemical synthesis using
click reactions and more sophisticated ones, such as electrospinning) and their
applications in the field of medicine and biology. For the treatment of diseases and
tissue engineering, we describe several biomaterials prepared by different extraction
methodologies from natural sources (e.g., chitosan and collagen) and their benefits as
biodegradability, circular economy, and recycling. Several synthetic approximations
for the preparation of biopolymers and their potential in several applications are
discussed based on the available information about synthesis, application, and
biodegradability. As several approaches are currently applied for the synthesis of
biomaterials with different applications, in the second and last sections, we discuss
some of these strategies considering the green chemistry principles. In many cases, an
appropriate building and synthesis of biopolymers could optimize chemical and
physical properties, such as solubility, viscosity, adhesiveness, degradability, and in
vivo response. In this chapter, also the conditions of synthesis of monomers will be
discussed, focusing on some advanced and green strategies for replacing toxic solvents
(and even complexes) that are used and make the process of obtaining green materials
difficult according to the desired target biopolymers. Finally, some applications related
to pharmacology and tissue engineering will be presented.
Hydrogels and Nanohydrogels
Page: 140-182 (43)
Author: Moises Bustamante-Torres*, David Romero-Fierro, Bryan Chiguano- Tapia, Estefani Chichande-Proaño and Emilio Bucio
DOI: 10.2174/9789815136920123030009
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Abstract
Hydrogels and nanogels are exciting and promising materials for many
applications due to their versatile features, such as interacting and absorbing a
significant amount of water and other solvents, excellent mechanical properties, and
adhesiveness. These materials are obtained based on the nature of the raw materials
(natural or synthetic) and the synthesis route. There are many ways to synthesize
hydrogels and nanogels; however, these routes can be classified as physical or
chemical. Physical synthesis forms a reversible cross-linking. In contrast, chemical
synthesis can generate a stable, rigid, and irreversible polymeric structure. Nowadays,
the term “smart hydrogel” has gained significant attention due to its response to
external factors, such as pH, temperature, light, electricity, and magnetic, and even an
internal approach as substrate. Besides, the characteristics and properties of these
polymeric matrices can be enhanced through the synergic relationship with
nanoparticles. The inner and outer structure and the behavior of these materials can be
studied through characterization techniques, such as light scattering, gel permeation
chromatography, viscometry, thermal analysis, spectroscopies, microscopies, and
swelling.
Self-healing and Regenerative Materials
Page: 183-206 (24)
Author: Lorena Duarte-Peña* and Emilio Bucio
DOI: 10.2174/9789815136920123030010
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Abstract
Self-healing systems have a high capacity for regeneration, managing to regain their functionality after suffering structural damage. This characteristic provides the materials with high durability and security in their use. Living organisms are the ideal self-healing systems, which is why they have served as inspiration for the development of these materials. Self-healing synthetic systems also show biomimetic characteristics and are widely studied as biomaterials. Different ceramic, metallic and polymeric materials can show self-healing capacity, although the polymeric selfhealing systems have versatility, adaptability, and ease of synthesis. This chapter describes the general aspects, properties, and classification of polymeric self-healing materials, focusing on extrinsic and intrinsic self-healing materials. The self-healing behavior of extrinsic materials depends on microcapsules and vascular structures that act as healing agents’ delivery systems. The self-healing behavior of intrinsic materials is governed by the presence of a dynamic crosslinking based on dynamic covalent bonds or non-covalent intermolecular interactions. In addition, examples of current developments in this field are shown.
Computational and Theoretical Techniques in Biomedicine
Page: 207-221 (15)
Author: Saikat Mukherjee*, Wayenbam Sobhachandra Singh and Sumita Banerjee
DOI: 10.2174/9789815136920123030011
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Abstract
Biomedicine research has gained momentum for the development of various
computational and theoretical techniques. Researchers working in biomedicine and
bioinformatics depend on computational intelligence and its widespread applications.
New algorithms have been described that enable computational simulations and
mathematical modelling in coordination with analytical methods to comprehensively
study biological systems. Many algorithms, such as Artificial Neural Networks
(ANNs), Rough Sets (RS), Fuzzy Sets (FS), Particle Swarm Optimization (PSO),
Evolutionary Algorithm (EA), etc., allow reliable and accurate analysis of vast data sets
in biomedicine. Computational techniques analyse gene expression data obtained from
microarray experiments, predict protein-protein interactions, model the human body in
disease conditions, such as Alzheimer’s disease or cancer, follow the progression of the
diseases, classify tumours, analyse which genotype responds to certain drugs, etc.
Multiscale modelling of the human body in various disease conditions is a topic of
interest in this context. Relevantly, the “Virtual Human” project has initiated the study
of human organs and systems in disease conditions based on computational modelling.
Therefore, many computational and theoretical techniques have been developed for
intelligent information processing to lead an expansion in biomedicine research.
Microencapsulation
Page: 222-258 (37)
Author: Anh Thuy Vu and Tuyen Chan Kha*
DOI: 10.2174/9789815136920123030012
PDF Price: $15
Abstract
It is well-known that bioactive compounds have many positive advantages
for human health. The extension of their shelf life and their applications in the food and
pharmaceutical sectors are important issues. Microencapsulation is one of the proven
methods to protect bioactive compounds and enable various applications. In this
chapter, microencapsulation technology, including the important steps of understanding
the physicochemical properties of the bioactive compounds, selection of suitable
encapsulation, and microencapsulation methods, is presented. Understanding of
physicochemical properties of bioactive compounds and wall materials is the first
important step. There are a variety of microencapsulation methods that can be selected
to encapsulate the bioactive compounds, depending on the application purpose of the
resultant microencapsulated product. In addition, the release rate and release
mechanism of microencapsulated particles also play an important role, determined by
the selection of wall materials and microencapsulation methods. Finally, methods to
evaluate the physicochemical stability of the solution before microencapsulation and
the characterization of the microencapsulated particles are also presented. Several
examples of successful encapsulation technology and recommendations for further
studies of the bioactive compounds are also reported throughout the chapter.
Subject Index
Page: 259-263 (5)
Author: Felipe López-Saucedo
DOI: 10.2174/9789815136920123030013
PDF Price: $15
Introduction
Synthesis of Nanomaterials is a beginner's guide to the synthesis and characterization of biomaterials for medical devices and implants. It presents 8 chapters explaining the use of biomaterials in medicine and pharmacology. The concepts are explained with the guidance of specialists who present the principal techniques and methods to obtain high-performance polymers and composite materials. Starting with an introduction to the subject, the book explains nanomaterials synthesis and progresses towards engineering applications. The chapters also cover modern biomaterials such as stimuli-responsive biomaterials, hydrogels, and self-healing materials. One chapter is dedicated to computational and theoretical techniques in biomedicine and a final chapter covering microencapsulation for advanced drug delivery rounds up the contents. Synthesis of Nanomaterials is a primary reference book for undergraduate and graduate students as well as professors involved in multidisciplinary research and teaching programs.