Preface
Page: ii-ii (1)
Author: Juhi Saxena, Abhijeet Singh and Anupam Jyoti
DOI: 10.2174/9789815123555123010002
PDF Price: $15
The Roles of Nanoparticles in Ovarian Cancer Treatment and Diagnosis
Page: 1-10 (10)
Author: Bitupon Gogoi, Devendra Jain, Madan Mohan Sharma, Rajeev Mishra* and Abhijeet Singh*
DOI: 10.2174/9789815123555123010004
PDF Price: $15
Abstract
Ovarian cancer, an aggressive epithelial cancer, remains a major cause of
cancer mortality worldwide among women, but it can be diagnosed at an early stage
also. Surgical removal of ovarian tumour is a good option for the initial treatment, but
this is suitable only at the early stage of cancer. Surgery and other therapies like
chemotherapy, hormone role therapy and immunotherapy alone are insufficient for the
treatment of today’s advanced ovarian cancer. The aim of this book chapter is to review
the use of nano-particles in the treatment of ovarian cancer, along with surgery. It is
believed that nano therapies have lots of advantages like they stabilize drugs in our
body, deliver and penetrate the drugs to tumour-specific cells and can profile the
toxicity of chemotherapy. This book chapter also covers the development of
nanotherapies, types of nanocarriers and their role in ovarian cancer diagnosis and
treatment.
Advances in Nano-remediation of Textile Dyes in Textile Industry Effluents: Current Developments and Future Prospects
Page: 11-35 (25)
Author: Baby Sharma, Nilima Kumari, Shruti Mathur* and Vinay Sharma*
DOI: 10.2174/9789815123555123010005
PDF Price: $15
Abstract
Environmental clean-up for the removal of recalcitrant pollutants is a global
concern, especially in the terms of industrial waste. Research over the years has led to
the development of various conventional physicochemical and biological methods for
the decontamination of numerous pollutants. These methods however are reported to be
extremely expensive and with limited success. Nano-remediation has been reported as
an effective alternative in this regard. The chapter outlines the use of various
nanoparticles as an innovative and cutting-edge technology for the clean-up of
environmental pollutants. It describes the use of fabricated nanoparticles to remove
pollutants. The chapter offers an overview of current research developments in the
emerging field of nano-remediation with special emphasis on textile dyes, elucidating
the mechanisms involved.
Interaction between Metal Oxide Nanoparticles and Terrestrial Plants: An Overview of the Mode of Action and Future Perspectives
Page: 36-87 (52)
Author: Poonam Patel, Prerna Dhingra, S. L. Kothari, Rohit Jain* and Sumita Kachhwaha*
DOI: 10.2174/9789815123555123010006
PDF Price: $15
Abstract
Nanotechnological interventions have extensively been used as an efficient non-invasive approach in agriculture for disease protection, to improve yield and many more. The use of engineered nanomaterials (like metal-oxide nanoparticles) as fertilizers,pesticides, carriers for genetic material/RNA/protein, sensors for detection of contaminants and toxic compounds etc. have been extensively studied and reported. Interaction between plants and nanomaterials plays an important role in their applications for various purposes in agriculture and otherwise. In this chapter, mechanisms of uptake and mode of action of three commonly used metal oxide (TiO2, CuO, ZnO) nanomaterials in plants have been reviewed. The chapter also summarises the various studies conducted on the effect of these nanomaterials on different agricultural food crops in the last 2 decades. The thorough review of existing literature on the aforementioned areas indicates that although the published data on terrestrial phytotoxicity of metal oxide NPs is increasing continuously but surprisingly the range of selected plants is still narrow (mostly agricultural crops and seed plants), thus random selection of plants (outside this narrow range) should be made to gain better insights into the various impacts of nanomaterials on plants.
Role of Nanofertilizers in Agriculture-Futuristic Approach
Page: 88-111 (24)
Author: Ali Asger Bhojiya*, Abubakar Yahaya Muhammad, Aliyu Ahmad Mahmud, Umar Salisu Ahmad, Monica Sen and Devendra Jain*
DOI: 10.2174/9789815123555123010007
PDF Price: $15
Abstract
Chemical fertilizers are crucial in the production of cost-effective
agricultural crops. However, long-term usage of chemical fertilizers will deteriorate the
soil quality and it is hazardous to human health. Scientists and researchers across the
globe are seeking the help of nanotechnology as a possible solution to combat the
hazardous effect of chemical fertilizers. Nanotechnology is a branch of science and
engineering concerned with the matter at the nanoscale or one billionth of a meter.
Nanofertilizers are modified fertilizers that are synthesized using techniques of
nanotechnology involving various physicochemical and biological methods. These
methods aid in enhancing their attributes and composition, which leads to a positive
effect on crop productivity. Nanofertilizers are far more beneficial when compared to
chemical fertilizers as the former are cost-effective, less toxic and show controlled and
regulated release of nutrients to plants. This chapter is primarily concerned with the
various methods employed in nanofertilizer synthesis, the economic importance of
nanofertilizers and their advantage over conventional chemical fertilizers.
Nanobiotics for the Treatment of MDR Infections
Page: 112-133 (22)
Author: Mrinalini Roy, Surbhi Mewara, Prashant Sharma, Anupam Jyoti, Vijay Kumar Srivastava and Sanket Kaushik*
DOI: 10.2174/9789815123555123010008
PDF Price: $15
Abstract
Nanoparticles are those agents that are made-up of single or a combination of single or multiple materials which are very small in size ranging from 1 to 100 nanometers. Several studies reveal that nanoparticles have features that interact effectively with microorganisms and can help in treating multidrug-resistant organisms. These have intrinsic antimicrobial activity and are of various types broadly divided into organic and inorganic nanoparticles. Nanoparticles can engage with bacteria and travel across the bacterial cells and host cell membranes, and help treat ESKAPE pathogens which are among the most notorious multidrug resistant superbugs. These pathogens have MDR features and have multiple types of MDR mechanisms including drug inactivation/alteration, modification of drug binding sites/targets, reduced intracellular drug accumulation and biofilm formation. For targeting different types of MDR, there are multiple types of nanoparticles such as metal nanoparticles, nanostructures, leukocyte membrane-coated nanoparticles, red blood cell membrane-coated nanoparticles, cancer cell membrane-coated nanoparticles, and platelet membranecoated nanoparticles among others. Antimicrobial nanobiotics identified and synthesized to date harbor a vast diversity of intrinsic and modified physicochemical properties and have applications in diagnostics. No technology is without its challenges and the same is true for nanobiotics. The major challenges in this field of nanobioticbased therapeutics are their allergic responses, assembly and pharmacokinetics. This chapter will elaborate on the mechanisms of action of various types of nanobiotics present as cost-effective solutions useful in a variety of applications in the treatment of MDR pathogens with a special focus on ESKAPE pathogens.
Metallic Nanoparticles as Antibacterial Agents
Page: 134-156 (23)
Author: Samridhi Sharma, Monika, Dong Wen-Liang, Shavkatjon Azizov and Deepak Kumar*
DOI: 10.2174/9789815123555123010009
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Abstract
Metallic nanoparticles against bacteria have increased recently due to their unique properties. Many metals like silver, gold, copper, aluminum, zinc and their oxides have been shown to have antibacterial properties. The activity of the nanoparticles is affected by their physico-chemical properties. Different types of mechanisms are proposed for the antibacterial actions against various types of bacteria. The metal-based nanoparticles are synthesized by the top-down methods and bottomup methods. However, the latter methods are used effectively against many types of bacteria including antibiotic-resistant bacteria.
Promises of Nanobiosensors in Pathogen Detection
Page: 157-162 (6)
Author: Anurag Jyoti*, Neha Shrivastava, Vikas Shrivastava and Rajesh Singh Tomar
DOI: 10.2174/9789815123555123010010
PDF Price: $15
Abstract
Rapid and accurate identification of pathogens has always been challenging.
There are a number of methods for the detection of pathogens, but still they face
critical challenges. In general, rapidity, sensitivity, and accuracy are the important
criteria that limit the applicability of classical methods. Nanomaterials-based
biosensors have been proven to be effective for the early and accurate quantification of
pathogens. Interactions between target pathogen and nanomaterials are very important,
as they provide a measurable signal in biosensors. Nanobiosensors are effective in
detecting pathogenic bacteria in various samples, including food, water, blood, and
other matrices. In this chapter, we intend to discuss the existence and importance of
electrochemical-based biosensors for quantification.
Breaking the Barriers of Nanotoxicological Assessments: The Importance of Available Models and Future Perspectives
Page: 163-184 (22)
Author: Abhinoy Kishore, Indranil De, Prashant Sharma and Manish Singh*
DOI: 10.2174/9789815123555123010011
PDF Price: $15
Abstract
Nanoparticles (NPs) and nanotechnology have penetrated every walk of life.
The nanotechnology-based products include pharmaceuticals, cosmetics, electronic
goods, food, food packaging, and household products of daily use. The unique
physicochemical properties of nanoparticles also make them a potent toxicant. The
evidence suggests that nanoparticles are used in humans' neurological disorders,
pulmonary disorders, and other ailments. The situation is alarming as NPs may make
their way to the human fetus. The regulations for checking the use of NPs are still in
their early stages. The NP toxicity has not only affected the human race but the entire
Biosphere. The chapter discusses the different assays and models to study nanotoxicity.
The models used in deciphering the molecular mechanism are primarily in vitro
models, particularly 2D and 3D cell cultures of primary, cancerous and normal cell
lines. 2D cultures are monolayers, while 3D cultures can be spheroids and organoids
derived from stem cells. Cell culture models serve to be a good assessment model but
due to lack of systemic complexity, results may not be explicitly extrapolated to
humans. In order to fill the gap, in vivo models are available. In vivo models are helpful
in assessing the systemic toxicity in organisms. The in vivo models are further
categorized as models to study human nanotoxicity and the models to study
nanoecotoxicity. Out of the plethora of models, certain specific models are briefly
discussed here. The ethical regulations for the usage of animal models are stringent
which sometimes make it challenging to acquire animal models. Such challenges can
be overcome by developing futuristic models like a lab or animal on a chip, and other
computation models which may make nanotoxicological assessments easy and
accurate, thereby helping in making efficient regulatory policies for NPs usage in
various consumer products safeguarding the mankind and the biosphere.
Subject Index
Page: 185-191 (7)
Author: Juhi Saxena, Abhijeet Singh and Anupam Jyoti
DOI: 10.2174/9789815123555123010012
PDF Price: $15
Introduction
Nanobiotechnology is the application of nanotechnology in biological fields. Nanobiotechnology is a multidisciplinary field that currently engages researchers in conventional as well as advanced avenues of engineering and natural sciences.The recent developments in nanobiotechnology have impacted various socio-economic sectors, including medical, agriculture, food, textile, and other industries. Although the integration of nanomaterials with biology has led to the development of diagnostic devices, contrast agents, analytical tools, therapy, and drug-delivery vehicles, bionanotechnology research is still in its infancy. The full potential of developments in this field have yet to be realized. This book discusses various nano-engineered materials or nanocarriers that are used in different situations. It presents 8 chapters that cover the application of nanobiomaterials in environmental remediation, nanofertilisers, nanobiotics against antimicrobial resistance, nanobiosensors in pathogen detection, and nanotoxicity assessments. Each chapter is structured into easy-to-read sections that explain fundamental and applied concepts of nanobiomaterials. Readers will gain a current view of the biotechnological application of modern nanomaterials and nanoparticles. The book is intended to be a primer for students and researchers in agriculture, biotechnology, and biomedical engineering courses.