Book Volume 4
Preface
Page: i-i (1)
Author: Felipe López-Saucedo
DOI: 10.2174/9789815136951123040001
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List of Contributors
Page: ii-ii (1)
Author: Felipe López-Saucedo
DOI: 10.2174/9789815136951123040002
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Molecular Imaging and Contrast Agents
Page: 1-25 (25)
Author: Dimitri Stanicki, Lionel Larbanoix, Sébastien Boutry, Robert N. Muller and Sophie Laurent*
DOI: 10.2174/9789815136951123040003
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Abstract
As an emerging technology, molecular imaging combines advanced imaging
technology with cellular and molecular biology to highlight physiological or
pathological processes in living organisms at the cellular level. The main advantage of
in vivo molecular imaging is its ability to characterize pathologies of diseased tissues
without invasive biopsies or surgical procedures. Such technology provides great hope
for personalized medicine and drug development, as it can potentially detect diseases in
early stages (screening), identify the extent of a disease/anomaly, help to apply directed
therapy, or measure the molecular-specific effects of a given treatment. Molecular
imaging requires the combination of high-resolution/sensitive instruments with targeted
imaging agents that correlate the signal with a given molecular event. In ongoing
preclinical studies, new molecular targets, which are characteristic of given diseases,
have been identified, and as a consequence, sophisticated multifunctional probes are in
perpetual development. In this context, the discovery of new emerging chemical
technologies and nanotechnology has stimulated the discovery of innovative
compounds, such as multimodal molecular imaging probes, which are multiplex
systems that combine targeting moieties with molecules detectable by different
imaging modalities.
Synthetic Biology and Tissue Engineering
Page: 26-74 (49)
Author: Betül Mutlu*, Selcen Arı-Yuka, Ayça Aslan and Rabia Çakır-Koç
DOI: 10.2174/9789815136951123040004
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Abstract
Advanced approaches that can mimic the structure and function of natural
tissue in tissue engineering applications that use multidisciplinary engineering
approaches to repair damaged or dysfunctional tissues are fed forward by current
engineering applications. Manipulating cells or cell groups in an integrated manner into
the scaffold, similar to the native tissue composition, is the main challenge in these
approaches. Synthetic biology approaches, originating from genetic engineering, based
on the use of advanced tools in the manipulation of cells at the molecular level, are one
of the most current issues in tissue engineering that shed light on the programming of
cells. Synthetic biology tools allow the reprogramming of cells whose transcriptional,
translational, or post-translational molecular mechanisms have been engineered by
stimulating them with intrinsic or extrinsic signals. Combining these advanced and
excellent tools from synthetic biology with materials engineering applications of tissue
engineering is the latest fashion. This chapter discusses going beyond conventional
tissue engineering applications, synthetic biological molecular tools, circuit designs
that allow the complex behavior of cells to be manipulated with these tools, and
approaches that enable the integration of these tools into the material component of
tissue engineering
Innovative Approaches to Prosthetics and Implants
Page: 75-115 (41)
Author: Sıtkı Kocaoğlu* and Erhan Akdoğan
DOI: 10.2174/9789815136951123040005
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Abstract
The use of prosthesis plays an important role in rehabilitation in the case of
congenital absence or loss of an extremity. Apart from lower and upper extremity
prostheses, there is a wide variety of prostheses used in different parts of the body.
Unlike limb prostheses, these are permanently placed in the body by surgical
intervention and are also called implants. New studies emerge every day in the
development of innovative prostheses and implants. These innovations include material
selection, new material development, control strategies, feedback system development,
sensor and actuator development, power supply methods, and power equipment
development work. Besides, many studies aim to increase user comfort as well as
acceptance rate and the useful life of prostheses. Some researchers are working to
develop prostheses exclusively for the use of children. Innovative developments in
prostheses and implants are examined in this section. Developments are presented from
various aspects, and information is given about the research that has made significant
contributions to the field. As an example of technological development in prosthetics,
an autonomic tumor prosthesis developed for children with bone cancer is introduced at
the end of the section as a case study.
Role of Nanomedicine in Ocular Parasitic Infections
Page: 116-147 (32)
Author: Nagham Gamal Masoud, Nagwa Mostafa El-Sayed* and Manar Ezzelarab Ramadan
DOI: 10.2174/9789815136951123040006
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Abstract
Ocular parasites cause serious vision-threatening diseases. An early
diagnosis and effective treatment are crucial to avoid side effects, such as blindness or
eye removal. The first important step in diagnosing ocular parasite infections is to
suspect them. Diagnosis is aided by ophthalmic examination, direct parasite
identification in clinical samples and/or pathological lesions, immunoassays, and
molecular methods. Despite this, ocular parasite infection diagnosis is fraught with
difficulties in terms of sensitivity, specificity, and accuracy. The usage of nanoparticles
may improve diagnosis by providing precise procedures for parasitic DNA, antigens,
and antibodies detection in a variety of body specimens with fast, sensitive, and
specific results. Low tolerability, long therapeutic duration, multiple adverse effects,
and the emergence of medication resistance are all problems with existing anti-parasitic
medications. Nanoparticles represent a promising way for the successful treatment of
parasitic diseases by developing innovative drug carriers to target medications to
infected sites while limiting high doses and adverse effects. They can also overcome
the limitations of antiparasitic medications' low bioavailability, poor cellular
permeability, non-specific distribution, and fast elimination from the body. The aim of
the present chapter is to throw light on possible nanotechnology applications in ocular
parasitic diseases caused by Toxoplasma gondii, Acanthamoeba spp. and Toxocara spp.
with a focus on diagnosis, treatment, and vaccination.
Anticancer Delivery: Nanocarriers and Nanodrugs
Page: 148-208 (61)
Author: Hatice Feyzan Ay, Zeynep Karavelioglu*, Rabia Yilmaz-Ozturk, Hilal Calik and Rabia Cakir-Koc
DOI: 10.2174/9789815136951123040007
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Abstract
Cancer is a disease in which cells grow uncontrollably and spread to
different tissues. Existing treatment methods developed for cancer do not allow this
disease to be completely cured, and these methods have various side effects. The search
for effective cancer treatment has encouraged scientists to produce new ideas with
nanotechnological methods. With the help of nanotechnological methods, which are
becoming more popular day by day, the material is reduced to nano size, where it
shows quantum effect, and gains unique physicochemical, mechanical, and biological
properties. Thanks to the large surface area of the nanocarriers, more drug loading can
be achieved on the unit surface, and their easy modification procedures enable these
materials to be conjugated with biological molecules to become more specific
structures. Due to the several advantages of nanocarriers, such as different synthesis
methods, being open to modification, and relatively easy production, these materials
can provide effective delivery of cancer drugs and even increase their efficacy.
Moreover, there are also many nanodrugs approved for different routes of
administration. Thanks to all these features, nanocarriers are promising ways to
develop new drug formulations for cancer treatment. In this chapter, the anticancer
activity of nanocarriers synthesized by different methods is clarified. Besides, the
effects of the nanocarriers on different types of cancer, the targeting strategies of
nanocarriers, and the effects of their size, surface charge, and shape, on their anticancer
activity are summarized.
Application of Bioceramics to Cancer Therapy
Page: 209-246 (38)
Author: Shirin B. Hanaei and Yvonne Reinwald*
DOI: 10.2174/9789815136951123040008
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Abstract
Despite the great medical developments, cancer remains the main cause of
death amongst individuals under 85 years. Novel therapeutic approaches for cancer
therapy are constantly being developed, and bioactive ceramics show great promise in
this respect. Bioceramics contain inorganic components, which help in the repair,
replacement, and regeneration of human cells; for that reason, their use is growing in
scope. Bioceramics have a flexible nature and can be modified with biologically active
substances for a particular treatment or improvement of tissue or organ functionality.
Materials, including glass-ceramics and calcium phosphate, can be loaded with specific
drugs, growth factors, peptides, and hormones in a particular fashion. Also, for the
elimination of infections and inflammations after surgery, the surface of bioceramics
can be modified, and antibiotics can be introduced to prevent bacterial biofilm
formation. In the context of bone cancer diagnosis and treatment, mesoporous
bioceramics have demonstrated excellent properties not only for being osteoinductive
and osteoconductive but also for drug delivery, therefore, being rendered as a
remarkable platform for the creation of bone tissue engineering scaffolds for the
purpose of bone cancer treatment. Furthermore, the creation of ceramic magnetic
nanoparticles as thermoseeds for hyperthermia exhibits promising development for
cancer treatment. The conjugation of ceramic nanoparticles with therapeutic agents and
heat treatment via different magnetic fields improve the efficacy of hyperthermia to the
extent that it makes them an alternative to chemotherapy. This chapter discusses the
therapeutic value of bioceramics.
Advanced Materials and Processing Techniques
Page: 247-271 (25)
Author: Smita S. Bhuyar-Kharkhale, Sudhir S. Bhuyar, Ajay K. Potbhare, Manjiri S. Nagmote*, Nakshatra B. Singh and Ratiram G. Chaudhary*
DOI: 10.2174/9789815136951123040009
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Abstract
Advanced materials and processing techniques are the backbone of the smart
industry. The smart industry could not be run without a furnish of raw materials.
Further, the raw materials could become advanced materials by employing good
processing technology. Owing to this, new advanced materials exhibit compelling
properties and applications in various fields. In the present chapter, we have provided
insight into the current development of advanced materials comprising different
fabrication methodologies and their incorporation with nanofillers, as well as their
advanced processing techniques. Moreover, advanced materials’ applications have
been emphasized in different fields, like tissue engineering, biomedical, agriculture
sector, and pesticides.
Regulators of Biomedical Devices
Page: 272-293 (22)
Author: Umut Beylik and Erhan Akdoğan*
DOI: 10.2174/9789815136951123040010
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Abstract
Regulators of medical devices in the world regulate global competition in
the medical device sector, and on the other hand, they play a decisive role in security,
performance, and access issues. Technological development has also increased in the
medical device industry, and medical devices have become more important in the
diagnosis and treatment of health services. However, it is important that legal
regulations must be implemented correctly and effectively in order to prevent public
health or unethical behaviors. In this context, the regulations of the United States of
America (USA) and the European Union (EU), the leaders in the sector, along with
their high markets are discussed. In addition, medical device regulations in Japan,
China, and Brazil, which have an important position in technological development and
competition and have high potential, are also included. Considering the urgency and
possible consequences of healthcare services, it is necessary to consider the fund and
the regulations of the medical device sector separately in individual, national and
global dimensions, from macro to micro. In addition to the safety, cost, and
effectiveness of medical devices, it is important to discuss the conformity assessment,
approval system processes, and how long it takes for a medical device to be put on the
market. Considering the rapid technology change, regulations should be made to carry
out the licensing and approval processes effectively and quickly in medical device
regulations.
Subject Index
Page: 294-298 (5)
Author: Felipe López-Saucedo*
DOI: 10.2174/9789815136951123040011
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Introduction
Applications of Nanomaterials in Medical Procedures and Treatments is a primer to the industrial use of nanomaterials. It presents 8 chapters explaining the use of nanomaterials in clinical medicine. Basic to advanced concepts are explained with the guidance of specialists who present the principal techniques and methods to obtain high-performance polymers and composite materials. The book starts with chapters on new contrast agents that help in molecular imaging, followed by chapters on prosthetics and artificial tissues. The next 3 chapters cover the applications of nanomaterials in the treatment of cancer and eye infections. This includes a chapter on innovative bioceramics with anticancer properties. The concluding chapters focus on biomedical device regulators and processing techniques for advanced materials. This book is a primary reference book for undergraduate and graduate students as well as professors involved in multidisciplinary research and teaching programs.