Preface
Page: i-i (1)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage
DOI: 10.2174/9789815238815124010001
Fundamentals of Nanotechnology
Page: 1-34 (34)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010002
PDF Price: $15
Abstract
Nanomaterials, a category of materials with a dimension in the nanometric
range (1 nm-100 nm), were first recognized in 1959. They have unique physical,
chemical, and mechanical properties, with nanoparticle size affecting properties like
melting temperature, ionization potential, colour, electron affinity, electrical
conductivity, and magnetism which is different from their bulk material.
Nanotechnology improves biomarker development and aids in developing more
sensitive treatments in medicine using nanodevices which enhances drug discovery by
improving the understanding of biological processes, disease mechanisms, and
signalling pathways.
This chapter provides an overview of nanomaterials and examines their distinct
properties. The key top-down and bottom-up methods for synthesizing nanomaterials
are also explained along with specific examples. The chapter will also include a
summary of several nanoparticle characterization methods and the attributes associated
with each method. In addition, comprehensive information about advanced devices that
have been inspired by nanotechnology to increase the efficiency of the drug
development process through a better understanding of the biological mechanisms
underlying diseases, signalling pathways, and the precise effects of medications have
also been discussed. The chapter will conclude by outlining the advantages and
challenges of using nanotechnology in drug development and treatment.
Nanotechnology in Drug Development
Page: 35-65 (31)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010003
PDF Price: $15
Abstract
Nanotechnology plays a key role in the development of new drugs, from
start to end through target identification, lead identification, lead optimization, and
synthesis of active pharmaceutical ingredients (API) as well. Nanodevices and
nanoparticles have been extensively utilized in discovering new drug targets in illness
sites or blood and for swift screening of interactions of molecular compounds with
therapeutic targets for lead identification/optimization. In addition, API development
employing nanoparticle catalysts to expedite the drug development process and
investigating pure nanomaterials as drugs are two further areas on which the
pharmaceutical industry is concentrating. This chapter will go into great detail on how
nanotechnology is used in the drug development process, starting with the
identification of drug targets, moving on to the identification and optimization of leads,
and concluding with the synthesis of API.
Development of Nanomaterials as Drug Candidates
Page: 66-107 (42)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010004
PDF Price: $15
Abstract
Nanomaterials, with their unique therapeutic traits such as antioxidant, antiinflammatory, antibacterial, antiviral, and anticancer properties, can be used as drug
candidates to treat a wide range of diseases. Nano complexes like dendrimers, carbon
nanotubes, fullerenes, graphene-based nanomaterials, carbon quantum dots,
nanohydrogels, peptide nanostructures, MXenes, Silicene, and Antimonene have been
distinguished by researchers, among the many nanomaterials because of their lower
toxicity, ease of tuning to the desired end use, complex interactions with biological
macromolecules, and solubility properties. This chapter will present the most recent
research details on nanomaterials that have been developed as therapeutic candidates to
treat a number of illnesses.
Nanotechnology for Drug Design and Drug Delivery
Page: 108-147 (40)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010005
PDF Price: $15
Abstract
The development of ideal, secure, efficient, non-invasive drug delivery
systems is now a top priority in this field of drug delivery. Nanoparticles are being
employed more frequently for effective medication delivery, exerting the desired
therapeutic effect at the expected site of action with the least amount of activity or
volume loss. Size, surface chemistry, biological destiny, toxicity, in vivo dispersion,
and targeting capabilities all play a role in these systems. The stability and interactions
of nanoparticles with cells are regulated by their surface chemistry, and they can access
a greater variety of targets. The development of nano-drug delivery systems has opened
up new avenues for the treatment and prevention of disease, as well as for enhancing
pharmacological properties, enhancing targeting, overcoming drug resistance, and
lowering immunogenicity and toxicity. This chapter will first discuss the desirable
characteristics of an effective drug delivery system and will cover recent developments
in nano drug delivery systems used in clinical research, including dendrimers, solid
lipid nanoparticles, nanogels, nanoemulsions, polymeric micelles, and polymer
nanofibers.
Fate of Nanoparticles
Page: 148-173 (26)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010006
PDF Price: $15
Abstract
Gaining insight into the process that ingested nanoparticles/nanodrugs is
crucial to maximize therapeutic advantages and avoid side effects. In the process of
drug development, it is critical to consider how nanodrugs are ingested, how they
interact with body fluids, how particles are absorbed by cells, and how they are
eliminated to achieve effective treatments. In addition, consideration of the toxicity of
the ingested nanoparticles is of utmost significance.
Hence the fate of ingested nanoparticles within the body will be covered in this chapter,
including ingestion, endocytosis, exocytosis, and lastly the toxicity of the ingested NPs
in vivo and in vitro. Initially, the chapter will brief about how the ingested
nanoparticles undergo interactions with proteins in body fluids to form a protein corona
and then will discuss comprehensively the different endocytic routes. Then the
nanoparticle’s excretion from cells which is essential for preserving homeostasis and
receptor function will be discussed. Finally, the toxicity such as DNA damage, protein
damage, cell membrane damage, oxidative stress, inflammation, impaired protein
synthesis, deregulated cellular functions, and neurotoxicity of some commonly used
nanoparticles will be outlined.
Regulation, Development, and Commercialization of Nano-Based Drugs
Page: 174-190 (17)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010007
PDF Price: $15
Abstract
Nanopharmaceuticals necessitate rigorous, costly testing to address safety
concerns, including cytotoxic effects. The lack of toxicity testing protocols and
understanding of the interactions of nanomaterials make it difficult to make accurate
assessments of health risks. To meet the purpose of regulating and monitoring nano
products in pharmaceuticals, various nations have devised their suitable regulatory
processes. Approximately two decades are required for drug development, which
includes drug discovery, clinical testing, and production approval. However, only when
a novel pharmaceutical product can be mass manufactured in industrially substantial
quantities is its development considered to be accomplished. At present, nanodrugs
have already been introduced successfully to the market, demonstrating their future
potential. This chapter will provide comprehensive details about the drug development
process covering regulations, development, and commercialization of nano-based drugs
Future of Nanotechnology-Based Drug Discovery
Page: 191-207 (17)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010008
PDF Price: $15
Abstract
By enhancing drug administration and diagnostics, nanotechnology is
transforming the healthcare industry. Novel approaches to drug design are being driven
by combining cutting-edge technologies such as nanorobots and artificial intelligence.
Healthcare can benefit from the potential of nanotechnology through the development
of multifunctional nanotherapeutics, which could close gaps in the current therapeutic
field.
Powered by integrated circuits, sensors, and data storage, nanorobots can increase
efficiency and lessen systemic effects while follow-up care for cancer patients is made
simpler by nanosensors. Additionally, nanotherapeutics have gained their way in
developing novel therapeutics to overcome cancer drug resistance by targeting the
mechanisms that induce the drug resistance. Another upcoming field in nanomedicine
is the utilization of 3D printing techniques in order to create solid dosage forms based
on nanomedicine. By enabling flexible design and on-demand manufacture of
customized dosages, enhancing bioavailability, and other attributes, 3D printing
technology has revolutionized the pharmaceutical industry. The futuristic applications
of nanotechnology hybridized with novel techniques will be discussed in this chapter.
Subject Index
Page: 208-212 (5)
Author: Laksiri Weerasinghe*, Imalka Munaweera* and Senuri Kumarage*
DOI: 10.2174/9789815238815124010009
Introduction
This book provides a compressive overview of nanotechnology in modern drug discovery for students and researchers. The book starts with the fundamentals of nanotechnology followed by nanomaterials in pharmaceutical drug design, drug delivery applications, regulatory aspects, formulation and nanoparticle biotransformation. It provides a step by step guide through the drug development process while conveying information about the benefits of nanomaterials for therapy. The book concludes with perspective on the future of nanotechnology-based drug discovery, summarizing current knowledge on nanotherapeutics and translational medicine. Key Features - Explains the fundamentals of nanotechnology in drug discovery - Includes up-to-date information on modern nanopharmaceutical manufacturing, nanomaterials, and nanoparticle-based drug therapy - Practice questions for learners and a list of references for advanced readers for each chapter