Preface
Page: i-i (1)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010001
Green Synthesis and Antibacterial Activity of Noble Metal Nanoparticles using Plants
Page: 1-29 (29)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010002
PDF Price: $15
Abstract
The emerging properties of noble metal nanoparticles (NPs) are attracting
huge interest from the translational scientific community and have led to an
unprecedented expansion of research and exploration of applications in biotechnology
and biomedicine. An array of physical, chemical and biological methods has been used
to synthesize nanomaterials. In order to synthesize noble metal NPs of particular shapes
and sizes, specific methodologies have been formulated. Although ultraviolet
irradiation, aerosol technologies, lithography, laser ablation, ultrasonic fields, and
photochemical reduction techniques have been used successfully to produce NPs, they
remain expensive and involve hazardous chemicals. Therefore, there is a growing
concern about developing environment-friendly and sustainable methods. Since the
synthesis of nanoparticles of different compositions, sizes, shapes and controlled
dispersity is an important aspect of nanotechnology, new cost-effective procedures are
being developed. Microbial synthesis of NPs is a green chemistry approach that
interconnects nanotechnology and microbial biotechnology. Biosynthesis of gold,
silver, gold–silver alloy, selenium, tellurium, platinum, palladium, silica, titania,
zirconia, quantum dots, magnetite, and uraninite nanoparticles by bacteria,
actinomycetes, fungi, yeasts, and viruses have been reported. However, despite
stability, biological NPs are not monodispersed, and the rate of synthesis is slow. To
overcome these problems, several factors, such as microbial cultivation methods and
extraction techniques, have to be optimized, and the combinatorial approach, such as
photobiological methods, may be used. Cellular, biochemical and molecular
mechanisms that mediate the synthesis of biological NPs should be studied in detail to
increase the rate of synthesis and improve the properties of NPs.
Analytical Methods in the Characterization of Green Nanomaterials
Page: 30-65 (36)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010003
PDF Price: $15
Abstract
A new class of diagnostic and therapeutic tools for various diseases has been
made possible by advancements in polymeric nanoparticles as innovative
nanomedicines. Although there are many benchtop studies in the nanoworld, their
application to already marketed goods is still in its infancy. Problems with
nanomedicine characterization cause this lack of transference, among other things.
Three nanoscale characterization approaches may be distinguished: physicochemical
property characterization, biological interactions of nanomaterials, and analytical
characterization and purification procedures. Physical qualities may be assessed using a
variety of methods in many situations. Choosing the best appropriate method is made
more difficult by many advantages and disadvantages of each methodology; frequently,
a combinatorial characterization approach is required. Scientists from many domains
must find answers to the difficulties in reliable characterization of the nanomaterials
after their fabrication and various systematic stages.
How Nanoparticles Enter the Human Body and their Effects
Page: 66-93 (28)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010004
PDF Price: $15
Abstract
The new scientific innovation of engineering nanoparticles (NPs) at the
atomic scale (diameter<100nm) has led to numerous novel and useful wide applications
in electronics, chemicals, environmental protection, medical imaging, disease
diagnoses, drug delivery, cancer treatment, gene therapy, etc. The manufacturers and
consumers of nanoparticle-related industrial products, however, are likely to be
exposed to these engineered nanomaterials, which have various physical and chemical
properties at levels far beyond ambient concentrations. These nanosized particles are
likely to increase unnecessary infinite toxicological effects on animals and the
environment, although their toxicological effects associated with human exposure are
still unknown. These ultrafine particles can enter the body through skin pores,
debilitated tissues, injection, olfactory, respiratory, and intestinal tracts. These uptake
routes of NPs may be intentional or unintentional. Their entry may lead to various
diversified adverse biological effects. Until a clearer picture emerges, the limited data
available suggest that caution must be exercised when potential exposures to NPs are
encountered. Some methods have been used to determine the portal routes of nanoscale
materials on experimental animals. They include pharyngeal instillation, injection,
inhalation, cell culture lines and gavage exposures.
Protein–Nanoparticles Interactions
Page: 94-139 (46)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010005
PDF Price: $15
Abstract
Large surface area, small size, strong optical properties, controllable
structural features, variety of bioconjugation chemistries, and biocompatibility make
many different types of nanoparticles (NPs), such as gold NPs, useful for many
biological applications, such as biosensing, cellular imaging, disease diagnostics, drug
delivery, and therapeutics. Recently, interactions between proteins and NPs have been
extensively studied to understand, control, and utilize the interactions involved in
biomedical applications of NPs and several biological processes, such as protein
aggregation, for many diseases, including Alzheimer's. These studies also offer
fundamental knowledge on changes in protein structure, protein aggregation
mechanisms, and ways to unravel the roles and fates of NPs within the human body.
Toxicity of Nanomaterials-Physicochemical Effects
Page: 140-167 (28)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010006
PDF Price: $15
Abstract
Nanoparticles (NPs) have the potential to produce deleterious effects on
organ, tissue, cellular, subcellular, and protein levels due to their peculiar
physicochemical features. Metal NPs are gaining prominence and are being used in a
variety of medicinal, consumer, industrial, and military applications. Furthermore, as
particle size falls, some metal-based NPs become increasingly poisonous, despite the
fact that the same substance is rather innocuous in its bulk form. NPs can also interact
with proteins and enzymes within human cells, causing reactive oxygen species to be
produced, an inflammatory response to be initiated, and mitochondrial disruption and
destruction, ending in apoptosis or necrosis. As a result, deciding whether the
advantages of NPs outweigh the hazards presents various challenges.
Nanoparticles in Environmental Pollution Remediation of Xenobiotics
Page: 168-196 (29)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010007
PDF Price: $15
Abstract
Environmental deterioration is currently a major problem for both emerging
and wealthy nations. Extensive industrialization and intensive agricultural activity are
the main causes of land, water, and air contamination. There are numerous
conventional treatments for various environmental contaminants, but each has
drawbacks. As a result, a different approach is necessary, one that is efficient, less
harmful, and produces better results. In terms of cleaning up the environment,
nanomaterials have garnered much interest. Nanomaterials outperform more traditional
methods for environmental remediation due to their enormous surface area and strong
reactivity. For particular applications, they can be altered to include new
functionalities. Nanoscale materials can be very reactive due to the high surface-areato-volume ratio and a greater number of reactive sites. These traits enable greater
contaminant interaction, which prompts a rapid decrease in pollutant concentration. In
order to remove toxins from diverse environmental media (e.g., soil, water, and air),
environmental remediation primarily uses various methods.
Subject Index
Page: 197-201 (5)
Author: Seyed Morteza Naghib* and Hamid Reza Garshasbi*
DOI: 10.2174/9789815179156123010008
Introduction
The convergence of nanotechnology with agriculture has transformed farming, while also impacting medicine, biotechnology and environmental science. Plant extracts isolated using new technologies have been used to successfully create new medicines for specific diseases. This book focuses on the eco-friendly synthesis of plant extracts. It provides information about multifunctional nanoparticles, and their versatile applications, including agriculture, food safety, and environmental remediation. The book aims to bridge the gap between nanotechnology and public perception, addressing concerns related to health and environmental impact. Themes within the book span across green synthesis techniques for noble metal nanoparticles, the crucial role of analytical methods in characterizing these &amp;quot;green nanomaterials,&amp;quot; and the comprehensive examination of how nanoparticles interact with the human body. Furthermore, the intricate relationships between proteins and nanoparticles is highlighted to explain the physicochemical effects and toxicity of nanomaterials. Readers will learn about sustainable and environmentally friendly approaches for synthesizing nanoparticles, while getting a glimpse of the promising future of nanotechnology in agriculture and beyond.