Book Volume 1
Preface
Page: ii-ii (1)
Author: Vivek Kumar Chaturvedi, Dawesh P. Yadav and Mohan P. Singh
DOI: 10.2174/9789815123739123010002
Nanomaterials for Biosensing Applications
Page: 1-29 (29)
Author: Abhay Dev Tripathi, Soumya Katiyar, Avinash K. Chaurasia and Abha Mishra*
DOI: 10.2174/9789815123739123010004
PDF Price: $15
Abstract
A biosensor is a device that detects the presence of analytes with its biological receptor entity, having unique specificities corresponding to their analytes. Most of these analytes are usually physical in nature, such as DNA, proteins, antibodies, and antigens, but they may also be simple compounds, including glucose, H2O2, toxins, and so on. Biosensors’ significance rises in providing real-time quantitative and qualitative information on analyte composition. The sensing mechanism involves the transduction of target binding interactions into optical, electrochemical signals, etc ., which can be amplified and detected.
Nanomaterials (NMs) have shown significant potential in biological sensing—these allow close interactions with target biomolecules due to their extremely small size and suitable surface modifications. Nanomaterials appear to be potential possibilities because of their capacity to immobilize a greater number of bioreceptor units in confined devices and even act as a transduction element, allowing for enhanced sensitivity and reduced detection limits down to specific molecules. Nanomaterials have been widely used for in vitro detection of disease-related molecular biomarkers and imaging, contrasts to map out the distribution of biomarkers in vivo. This chapter summarizes nanomaterials such as gold nanoparticles, quantum dots, polymeric nanoparticles, carbon nanotubes, nanodiamonds, and graphene nanostructured materials that are currently being researched or utilized as biosensors.
Carbon-Based Nanomaterials for Sensing Applications
Page: 30-44 (15)
Author: Rakesh Kumar Ameta*
DOI: 10.2174/9789815123739123010005
PDF Price: $15
Abstract
Recently, carbon-based nanomaterials (CBNM) have been widely used for
chemical and biosensing applications due to their outstanding physicochemical
properties, such as mechanical, thermal, optical, electrical and structural diversity. Such
materials include carbon nanotubes, graphene oxide, graphene quantum dots and
fullerene. As a consequence of inimitable features, these give superior strength,
electrical conductivity, and flexibility toward numerous chemical and biological
objects, which is valuable for chemical sensing and biosensing purposes. However, the
specific intrinsic property makes graphene and carbon nanotubes (CNTs) most
attractive among the various allotropes of carbon. Since the environmental
contaminants in ppm level affect the people, therefore the use of CBNM for
environmental sensing provides an accessible cache of data for modelling, which
makes it easy to monitor environmental challenges. Thus, the biological, chemical,
thermal, stress, optical, strain and flow sensors deliver a larger surface area, excellent
electrical conductivity with chemical constancy, as well as mechanical difficulty with
straightforward functionalization pathways of CNTs to improve old-style carbon
electrode sensor platforms. Therefore, in this chapter, the CBNM for sensing purposes
are focused in detail on their mechanism.
Graphene-Based Nanomaterials and Their Sensing Application
Page: 45-77 (33)
Author: Vikash Kumar Vaishnav*, Khageshwar Prasad, Rashmi Yadav, Amitabh Aharwar and Bhupendra Nath Tiwary
DOI: 10.2174/9789815123739123010006
PDF Price: $15
Abstract
Carbon-based materials (CBMs) like graphene, hybrid graphene compounds
(HCOGs), graphene nanoplatelets (GNPs), graphene oxide (GO), reduced graphene
oxide (RGO), and graphene quantum dots (GQDs), as well as their derivatives like
graphane, graphone, graphyne, graphdiyne, and fluorographene, are the direct
descendants of graphene-based nanomaterials (GBNs). GBNs are graphene derivatives
with single and multilayered graphene products. Their doped versions have marked
remarkable significance over the past decade in scientific fields for applications due to
their physical as well as their chemical properties. Graphene has emerged as a
promising application for sensing, gas separation, water purification, biotechnology,
disease diagnosis, bioengineering, and biomedicine. Graphene nanomaterials also play
an important role in surface engineering (bioconjugation), improving their performance
in vitro/in vivo stability and elevating the functionality of graphene-based
nanomaterials, which can enable single/multimodality image optical imaging, positron
emission tomography, magnetic resonance imaging and therapy photothermal therapy,
photodynamic therapy, and drug/ gene delivery in cancer. Graphene nanoparticles have
the natural fluorescence properties of graphene, which helps to bioimage cancer cells.
They are perspective drug carriers appropriate for their target selectivity, easy
chemosensitization, functionalization, and excellent drug-loading capacity. Iron-based
graphene composites are with other companionable materials of exploration to make
novel hybrid complexes with preferred uniqueness for biointerfacing.
SPR-Based Biosensors in the Diagnostics and Therapeutics
Page: 78-96 (19)
Author: Anjali Bhargav and Neeraj Kumar Rai*
DOI: 10.2174/9789815123739123010007
PDF Price: $15
Abstract
To analyze the physio-chemical measures of the cellular environment and display them in digital units, transducing methods are applied in biosensors. The labelfree biosensors employ biophysical characteristics such as spectroscopic methods, crystallization, and Surface plasmonic resonance (SPR) to determine the availability or concentration of substances. SPR is a method to elucidate interaction among biomolecules exhibiting affinity binding, structural changes, or alteration in pathological conditions. SPR methods are now employed in conjunction with a variety of transducer topologies, including optical fibers, nanoparticle-based SPR, immobilized or localized SPR (LSPR), long-range SPR, image SPR, immune-assay-based SPR, and phase sensing SPR biosensors' versatile configuration allows for the early detection of several illnesses, such as COVID-19, dengue, non-invasive cancer, biomarker-based fetuses identification, therapeutic antibody characterization, drug monitoring, etc. SPR system is leading in diagnostics and therapeutics with various advantages, such as their portable size, cost-effectiveness, quick result, and easy-to-handle method, but at extension, this technique needs development to ensure high sensitivity, averting background effect and evolution of label-free direct detector to quantify real sample. This chapter reviews the model’s instrumentation and bioassay of clinical samples from SPR and its associated biosensor.
Implication of Biosensors For Cancer Diagnosis And Therapeutics
Page: 97-111 (15)
Author: Shubha Gupta, Navitra Suman and Neeraj Kumar Rai*
DOI: 10.2174/9789815123739123010008
PDF Price: $15
Abstract
“Caution is the parent of Safety”. Early-stage diagnosis of Cancer can
provide better medicinal therapeutic responses. Currently, a majority of cancer is
diagnosed after having metastasized throughout the body. This led to the urgent
requirement for potent and precise cancer detection methods for clinical diagnosis.
Over the last several decades, the majority of researchers have concentrated their
efforts on developing a potential rapid detection technique based on Biosensor
technology for a variety of frightening human health-related disorders, such as
cardiovascular disease, cancer, diabetes, and others. Significant advances were made in
a wide range of fields attributed to the designed techniques having enhanced
sensitivity, specificity, and repeatability. The development of diagnostic treatments in
medicine was aided by noteworthy advancements in other scientific fields, including
genetics, chemistry, micro-electrical engineering, and computational biology. As a
result, efficient, accurate, rapid, and steady sensing platforms have been successfully
developed for specific and ultrasensitive biomarker-based disease diagnostics.
Biosensors are analytical devices designed to detect biological analytes by converting
biological entities’ responses (DNA, RNA, Protein) into potent electrical signals. The
biosensor device combines a biological component with a physiochemical detector for
sensing an analyte (biological samples). The discovery of the Biosensor boosted the
potential clinical diagnosis of cancer at a large scale. Biosensors can be designed to
detect emerging cancer biomarkers and determine drug efficacy at various target sites.
Biosensor technology has the potential to be used as a diagnostic tool for accurate and
impressive cancer cell imaging, tracking cancer cell angiogenesis and metastasis, and
evaluating the efficacy of treatment for the disease. This chapter will provide a quick
overview of the challenges facing the early diagnosis of cancer, get through the depth
of how biosensor technology may be used as a reliable diagnostic tool, and highlight
potential uses for biosensor technology in the future.
Recent Advances in the Application of Nano-Biosensor in Tissue Engineering
Page: 112-146 (35)
Author: Soumya Katiyar, Shikha Kumari, Ritika Singh, Abhay Dev Tripathi, Divakar Singh, Pradeep K. Srivastava and Abha Mishra*
DOI: 10.2174/9789815123739123010009
PDF Price: $15
Abstract
Nanotechnology has a profound influence on environmental research,
infrastructure, energy, food standards, information technology, and medicine. In
biomedicine, nanotechnology primarily aims to provide solutions for preventive care,
diagnosis, and therapy. Biosensors have significantly revolutionized the medical sector
by offering on-site diagnostic capabilities. Since 1962, the combination of biosensors
with nanotechnology has made a significant contribution to therapeutics and tissue
engineering. Biosensors are diagnostic devices that monitor biochemical interactions
and translate them into measurable electrical, optical, or mechanical signals. The
tissue-engineered technology has gained popularity in the postmodern era to confront
the shortcomings of biomedical applications, graft rejection, challenges in the
recuperation of functional tissue, and specificities in the tissue regeneration site. The
multitude of techniques for evaluating cell counts, growth, metabolic activity, and
viability across the scaffolding of regenerated organs is reportedly labor-intensive and
time-consuming. Biosensors have been rapidly advancing and influencing the field of
tissue engineering in the last several decades. Recent developments in nanomedicine
and biomaterial science have enabled them to overcome long-standing challenges.
Biosensors used in tissue engineering and regenerative medicine (TERM), unlike the
other biological systems, must comply with the requirements mentioned above: (i)
biocompatible, causing no or little response to foreign materials; (ii) non-invasive
while probing the whole three-dimensional structure for targeted biomarkers; and (iii)
should offer long-term monitoring (days to weeks). This chapter offers a
comprehensive set of biosensors as well as their implementations in the field of tissue
engineering and regenerative medicine (TERM). This chapter reviews current
breakthroughs in nanobiosensors, their implementations in tissue engineering, and their
promise for diagnostic purposes.
DNA Biosensors: Effective Tool in Biotechnology
Page: 147-162 (16)
Author: Arpita Mishra, Avanish Kumar Shrivastav* and Vivek Kumar Chaturvedi
DOI: 10.2174/9789815123739123010010
PDF Price: $15
Abstract
A biosensor is a device that converts a biological response into a detectable
electrical signal. In recent years, biosensors have gained significant interest due to a
plethora of applications in the field of disease diagnosis, detection of various
environmental pollutants, food quality analysis, and pharmaceutical drug research.
Among various types of biosensors, (such as enzyme-based, immunosensors, DNA
biosensors, thermal and piezoelectric biosensors) DNA biosensors are being widely
employed because of superior biocompatibility, thermal stability and alternative
functionalization. DNA biosensors introduced in recent years include an aptamer-based
sensor, molecular beacon-based biosensors, fluorescence-based sensors,
hybridizationbased sensors and electrochemical-based DNA biosensors. This chapter
highlights the fundamental knowledge and recent advances in the field of DNA-based
biosensors. This chapter also focuses on the significance and wide application of DNAbased biosensors in the diverse areas of biotechnology and allied fields.
Biosensors for the Diagnosis and Therapeutics of Cardiovascular Diseases
Page: 163-177 (15)
Author: Avanish Kumar Shrivastav, Dhitri Borah* and Sudeshna Mandal
DOI: 10.2174/9789815123739123010011
PDF Price: $15
Abstract
Biomedical diagnostic research is becoming increasingly important in the
modern medical profession. Infectious disease inspection, initial detection, chronic
disease treatment, clinical services and well-being hunt down are the various
applications of biosensors. Advanced biosensor technology permits the identification of
the disease and the examination of the patient’s responses to medication. Sensor
technology is crucial for a broad range of low-cost and practicable developed medical
appliances. Biosensors offer many possibilities because they are unambiguous,
ascendable and capable of synthesizing procedures. Cardiovascular disease(CVD) is
now recognized as the leading cause of death. It is estimated that the number of people
dying from heart disease and stroke will approach 20 million by 2015. The risk event
of unexpected death associated with it can be minimized by recognizing the challenges
involved in its beginning, symptoms, and early detection. Therefore, this chapter aims
to provide an idea for the diagnosis and therapeutics of CVD. Biosensors, created to be
utilized as quick screening instruments to detect disease biomarkers early on and
classify the condition, are revolutionizing CVD diagnosis and prognosis. Biosensors
have become faster, more accurate, portable, and environmentally friendly diagnostic
equipment as a result of advances in interdisciplinary study domains.
Biosensors for Food Analysis, Food Additives, Contaminants and Packaging
Page: 178-202 (25)
Author: Amitabh Aharwar, Khageshwar Prasad, Annpurna Sahu and Dharmendra Kumar Parihar*
DOI: 10.2174/9789815123739123010012
PDF Price: $15
Abstract
It is essential to manage the food requirement for the growing population.
Food safety is important for health, but maintaining nutrients and food quality is also
necessary for better health. Food storage and packing should be done carefully in order
to avoid food contamination and ensure long-term food storage. There are various types
of food hazards (biological, chemical, and others) that may contaminate food and cause
food poisoning, foodborne diseases, allergies, and other health issues. For food quality
examination, traditional procedures, such as chromatographic methods, are used, but
these are time-consuming, labour-intensive and require an expert in instrumentation. It
is critical to inspect the quality of food on a regular basis and as quickly as feasible.
The greatest approach for overcoming these issues is the use of biosensor. As food
additives and pollutants, the biosensor is extremely quick, sensitive, and selective.
Biosensors are equipped with a transducer and a biological identification element,
allowing them to evaluate food quality. Pesticides, poisons, microbial growth, protein,
metals, fatty acids, antibiotics, vitamins, and other compounds can all be detected in
food using biosensors. Biosensors have a wide range of applications in the food
industries but there is also the demand for novel, inexpensive, simple, small-sized,
portable, and multifunctional biosensors for food analysis. Biosensor can also detect
food additives and pollutants throughout the packaging process
Biosensors For Monitoring Heavy Metals Contamination In The Wastewater
Page: 203-211 (9)
Author: Gaurav Kumar Pandit, Ritesh Kumar Tiwari, Ashutosh Kumar, Veer Singh, Nidhi Singh and Vishal Mishra*
DOI: 10.2174/9789815123739123010013
PDF Price: $15
Abstract
Several anthropogenic activities, chemical manufacturing, mining, nuclear
waste, painting, metal processing, agricultural activities, cosmetic products and
industrial activities are associated with heavy metal contamination in the wastewater.
Heavy metals, such as arsenic, cadmium, chromium, lead mercury and nickel, are
nonbiodegradable and highly toxic. They can directly or indirectly enter the food chain
and cause several health issues, such as cancer, liver and kidney, asthma and mental
retardation. Analytical methods such as inductively coupled plasma mass spectrometry
(ICP-MS), atomic absorption spectroscopy (AAS), ultraviolet-visible spectroscopy and
chromatography are widely used for heavy metal monitoring in heavy metal
contaminations. These methods provide a sufficient level of sensitivity and selectivity,
but these methods are costly, time-consuming and require sample preparation.
Currently, biosensors are considered an alternative to conventional heavy metal
monitoring methods due to high sensitivity, selectivity, inexpensiveness and simplicity.
Herein, the authors report several biosensors and their application in monitoring heavy
metal contaminations.
Subject Index
Page: 212-216 (5)
Author: Vivek K. Chaturvedi, Dawesh P. Yadav and Mohan P. Singh
DOI: 10.2174/9789815123739123010014
Introduction
Recent Advances in Biosensor Technology (Volume 1) is a comprehensive guide to the latest developments in biosensor technology, written by experts in the bioengineering and biosensor development. The book is an essential resource for researchers and biomedical engineers interested in the latest developments in biosensor technology. It covers a wide range of topics, including nanomaterials for biosensing applications, carbon-based nanomaterials for sensing applications, graphene-based nanomaterials, SPR-based biosensors in diagnostics and therapeutics, biosensors for cancer diagnosis and therapeutics, tissue engineering and more. One of the key features of this book is its detailed discussion of the novel research findings in biosensor technology, providing readers with the most up-to-date information in the field. Each chapter includes a comprehensive review of relevant literature, as well as practical examples to demonstrate the potential applications of biosensors in various fields. Furthermore, this book includes detailed references for further reading, making it an excellent resource for readers looking to deepen their understanding of biosensor technology.