Cancer Pathophysiology
Page: 1-23 (23)
Author: Devang B. Sheth*, Chirag A. Patel and Sandip B. Patel
DOI: 10.2174/9789815079999123010004
PDF Price: $30
Abstract
Cancer prevalence across the globe has increased substantially in the last
two decades despite significant progress in inpatient care. Cancer, a multifactorial
disease, evolved several theories to establish pathophysiological conditions.
Uncontrolled proliferation, dedifferentiation and metastasis mainly describe the cancer
progression, which must be characterized by cellular and molecular changes.
Understanding these processes helps devise the strategy for effectively delivering the
drugs to the target sites. The present review described the essential features of cancer
pathophysiology and challenges to achieving drug concentration in the targeted area.
Recent Advances of Multifunctional Nanomedicine
Page: 24-38 (15)
Author: Pallavi M. Chaudhari*
DOI: 10.2174/9789815079999123010005
PDF Price: $30
Abstract
The revolution of nanomedicine has emerged as an array of biological
products in the pharmaceutical field. Their peculiarity of nanosize has been a benefit
for the detection and prevention of diseases by application of engineered nanodevices
and nanostructures. This presents range of opportunities, that are suitable for most
drugs, prevents side effects, and enhances patient compliance. Nanomedicine has
fascinated medical research in developing different multifunctional nanostructures like
dendrimers, nanoparticles, micelles, quantum dots, carbon nanotubes, etc. However,
there are still certain impedes to bringing out the best amongst these nanomedicines.
This chapter will spotlight the recent advances of multifunctional nanomedicine, solely
to combat cancer disease conditions, that can offer improvement in the
pharmacokinetic and pharmacodynamic profiles of the conventional approaches and
optimize the efficacy of the existing anticancer drugs. In recent years, combination
therapy has also shown good improvement in cancer therapy as compared to
monotherapy. The theranostic application can offer a good alternative to cancer
treatment. So, when the insights are combined with new nanotechnology-based
therapy, targeted drug delivery can be obtained to avoid the side effects, but the
concern of their toxicity should also be noted. Hence, nanomedicine represents one of
the advanced fields that combine nanotechnology and medicine for improved
efficiency and safety to human health, through the study of elucidation of cellular and
molecular mechanisms, to design performant nano-delivery as an efficient tool for the
treatment of cancer. Thus, the exploration of the properties needs to be understood to
execute the unmet needs and attain project cost benefits.
Dendrimers in Anticancer Drug Delivery
Page: 39-58 (20)
Author: Saloni Bhandari* and Kamal Singh Rathore
DOI: 10.2174/9789815079999123010006
PDF Price: $30
Abstract
Recent development and advances in the application of nanotechnology in
the field of medicine have led to the evolution of multifunctional “smart” nanocarriers
that are capable of delivering one or more therapeutic agents effectively, safely and
selectively to tumor cells, including intracellular gene-specific targeting. Dendrimers
have a high level of control over the synthesis of dendritic architecture, well-defined
size, shape, molecular weight, membrane interaction and monodispersity, making them
a perfect example of one such multifunctional smart nanocarrier.
The 3D nano-polymeric architecture of dendrimer makes it an appropriate choice for
drug and gene delivery vectors. The functional groups attached on the surface of
dendrimers permit the addition of other moieties that can actively target certain
diseases, which are now widely used as tumor-targeting strategies. Along with being
compact and globular in structure, dendrimers also exhibit interior cavity spaces and
multiple surface functional groups, which play a vital role in encapsulating drug
molecules both in the interior of the dendrimers (physical encapsulation) as well as in
the surface functional groups (covalent conjugations). The application of dendrimers in
biomedicine has recently attracted much attention worldwide. Dendrimers are
interesting in the field of biomedical applications due to their unique characteristics.
Nanomedicine-based use of SiRNA in Cancer
Page: 59-88 (30)
Author: Jay M. Nimavat*, Vaibhav D. Bhatt and Devyani Dave
DOI: 10.2174/9789815079999123010007
PDF Price: $30
Abstract
People have been suffering from cancer and associated problems for many
years. A great amount of improvement has occurred in the field of medical science, and
it certainly has benefitted humankind to help live a happy and prosperous life. Despite
all these things, cancer treatment remains a provocative question as every year cases
are increasing; on the contrary, there are a lot of difficulties associated with cancer
treatment. To cope with these unique and mischievous problems, nanotechnology is
considered a boon. Various nanoparticle facilitates the required characteristics to
deliver a specific active therapeutic agent against the cancer cells. They can be targeted
and even modified to fulfill specific pharmacokinetic parameters vital for in vivo
delivery of drugs along with Nano-systems. This chapter here focuses on various types
of nanoparticles and nanoparticle-mediated drug delivery of certain therapeutic agents.
Ligands for Tumor Targeting
Page: 89-139 (51)
Author: Akashdeep Singh and Vikas Rana*
DOI: 10.2174/9789815079999123010008
PDF Price: $30
Abstract
Cancer is the world's second leading cause of death, and new cancer cases
are expected to increase dramatically in the next decades. Many biotechnologists and
medical researchers are actively involved in finding issues related to cancer detection
and treatment efficacy. Given the difficulties of traditional chemotherapy, the targeted
drug delivery system (DDS) of chemotherapeutics for cancer therapy through
nanoparticles (NPs) carriers is a growing field of research. Researchers have
concentrated on surface modification of NPs or nanocarriers using biological ligands in
addition to optimizing their physicochemical characteristics. Several in-vivo
investigations have shown that virus-sized stealth NPs may circulate in the blood for a
longer period and preferentially concentrate at tumor sites due to the increased
permeability and retention (EPR) effect, also known as the passive targeting strategy.
Surface modification of stealth NPs with specific biological ligands may result in
enhanced retention and accumulation of NPs in tumor sites, referred to as an “active
targeting strategy”. This chapter outlined some key points regarding each strategy's
impact and how combining some or all of them has proven beneficial in tumor
targeting. After a brief introduction to existing cancer treatments and their drawbacks,
we discussed the biological obstacles that NPs must overcome, followed by several
forms of DDS to increase drug accumulation in the tumor site. Then, using active
targeting strategies, we also describe various receptors present on cancer cells that
enhance cellular drug targeting. A substantial quantity of information has been
summarized in tables on different polymeric NPs conjugated with selective targeting
ligands such as proteins, polysaccharides, peptides, and aptamers to small molecules.
With the potential of maximizing therapeutic efficacy and reducing side effects, ligandmediated-DDS has emerged as an essential platform for safe and effective tumor
treatment.
Nanotechnology-Based Inhalation Approach for Lung Cancer
Page: 140-165 (26)
Author: Priya Patel*, Mansi Faladia and Mihir Raval
DOI: 10.2174/9789815079999123010009
PDF Price: $30
Abstract
Ever since the success of producing inhalable insulin, drug delivery via
pulmonary administration has been an intriguing way to treat chronic disorders.
Pulmonary delivery system for nanotechnology is a relatively recent approach,
especially when related to lung cancer therapy. The therapeutic ratio is increased by
inhalation delivery, which delivers a high dose of the drug directly to the lungs without
damaging other body organs. Despite extensive studies into targeted delivery and
specific molecular inhibitors (gene delivery), cytotoxic drug delivery via inhalation is
still considered a critical component of lung cancer treatment. Nanotechnology-based
inhalation chemotherapy has been proven to be practical and more successful than
conventional chemotherapy, with fewer adverse effects. Many nanocarriers have
recently been studied for inhalation treatments of lung cancer, including liposomes,
polymeric micelles, polymeric NPs, solid lipid NPs, and inorganic NPs. The potential
for NPs-based local lung cancer targeting via inhalation, as well as the challenges that
come with it, are explored here.
Mesoporous Based Drug Delivery: A Smart and Promising Approach for Prostate Cancer
Page: 166-198 (33)
Author: Nasir Vadia* and Priya Patel
DOI: 10.2174/9789815079999123010010
PDF Price: $30
Abstract
Mesoporous silica has been gaining popularity as a drug delivery medium in
recent years. Materials scientists have used these inorganic carriers successfully in
other fields, including catalysis, purification, and adsorption. A major challenge in
medicine is delivering drugs to defective cells or tumor cells in a way that has minimal
toxic side effects. Due to the poor physicochemical and biological properties of a drug
molecule like solubility, permeability, absorption and bioavailability, patients may
have to take high doses of the drug to achieve the desired therapeutic effect. Various
drug carriers are available in the pharmaceutical industry to help solve this problem.
Biocompatible, chemically, and thermally stable nanoparticles, mesoporous silica
nanoparticles (MSNs), are ideal for this application. During the last few years, research
on the mesoporous-based delivery system has been studied vigorously. These materials
act as drug carriers for the delivery of different therapeutic agents. This versatility is
because they are used for the loading of small molecules and macromolecules such as
proteins and siRNA. Mesoporous materials as a drug delivery system were discussed in
this chapter. Specifically, it provides an overview of the synthesis, structural
configurations, and their roles in loading and delivering therapeutic agents for the
anticancer agents used in prostate cancer. The applications of these materials in
prostate cancer for the detection, diagnosis, and treatment, were explored.
Abridgment of Nanotechnology in Skin Cancer Treatment: Current Trends and Future Outlook
Page: 199-236 (38)
Author: Chetna Modi*, Nikita Udhwnai, Pranav Shah and Arjun Joshi
DOI: 10.2174/9789815079999123010011
PDF Price: $30
Abstract
This chapter focuses on skin cancer, which is represented by the
accumulation of cells in one part of the skin. It enhances the form of the cells which
line up along the membrane and separates the deep layer of the skin from the
superficial layer. The recent skin cancer treatment includes surgical or excision biopsy,
chemotherapy, targeted therapy, Mohs micrographic surgery, radiation therapy,
photodynamic therapy, therapeutic hyperthermia, immunotherapy, etc. The drawback
of skin cancer treatment with these therapies are skin irritation at the site of treatment
and variation in the skin color or dark pigmentation after treatment, chances of cancer
reoccurrence, longer treatment period and many more. Whereas, nanotechnology
materials are used to deliver controlled and sustained drug dosage to skin cancer
through the skin over a period of time without any skin irritation and other problems
associated with recent treatments. The various kinds of nanotechnology products
mentioned in this chapter offer numerous advantages for skin cancer, such as increased
solubility, drug release in a sustained and controlled manner, better penetration through
skin layers and precise site of action. This chapter discusses the various types and
causes of skin cancer, current treatments and their limitations, as well as the role of
nanotechnology and its products in skin cancer with its future outlook.
Nanofibers Approach for Gastro Retentive Cancer
Page: 237-254 (18)
Author: Anand J. Patel*, Bhavin R. Patel and Pranav Shah
DOI: 10.2174/9789815079999123010012
PDF Price: $30
Abstract
Gastric cancer is the world's second leading cause of cancer-related death.
Due to inadequate drug release and limited residence time at the absorption site,
traditional oral dose forms have poor/low bioavailability. GRDDS is particularly useful
for increasing the bioavailability of medications with a narrow absorption window in
the gastrointestinal tract and for treating local diseases. Polymeric nanofibers have
sparked a lot of attention among the numerous nanomaterials used in high-tech
applications because of their simplicity of production, controlled size/shape, and
characteristics. Filtration, barrier fabrics, wipes, personal care, and biological and
pharmaceutical applications have been intensively researched with polymeric
nanofibers. Electrospun polymeric nanofibers have recently been demonstrated to be a
promising approach for drug delivery systems. The nanofiber method allows for
stomach-specific drug release for a more extended period and improves local drug
action due to the drug's extended contact time with the gastric mucosa. As a result,
nanofiber technology appears to be a promising strategy for gastric retention drug
delivery systems.
Regulatory Aspects of Nanomaterials: Current and Future Perspective
Page: 255-277 (23)
Author: Mihir Raval*, Pratibha Chavda and Priya Patel
DOI: 10.2174/9789815079999123010013
PDF Price: $30
Abstract
Nanotechnology and its applications have been a rapidly growing area of
research in the previous two decades. In the domain of pharmaceutical research,
nanotechnology is applied in the study and preparation of nano-size range materials
ranging from 1-100nm. Nanoparticulate medications or nano drug delivery systems are
not a novel concept, but they are a rapidly evolving nanoscience. In nanomedicine,
nanoscale materials are used to develop diagnostic tools or to deliver active substances
to a particular place in a consistent and controlled manner. Nanoparticles have groveled
in many different forms, including liposomes, niosomes, solid lipid nanoparticles,
emulsions, suspension nanocrystals, micelles, and dendrimers. When compared to pure
drugs or other conventional formulations, these all have improved medication efficacy
or therapeutic effect. Nanoparticles are being employed in a variety of fields, including
cosmetics. However, as nanotechnology progressed, numerous controversies arise
concerning nanoparticles. Consumer safety, as well as environmental repercussions,
must be regulated. Nanotechnology has life-changing applications, yet nanoparticle
regulation has been inconsistent and insufficient. Failure in biotechnology regulation in
recent years has resulted in several negative consequences for the environment and
human health. This article aims to raise knowledge about the importance of regulatory
frameworks for nanotechnology and nanoparticles.
Recent Development and Advancement in Microneedle-Assisted Drug Delivery System Used in the Treatment of Cancer
Page: 278-322 (45)
Author: Vaishali Thakkar* and Saloni Dalwadi
DOI: 10.2174/9789815079999123010014
PDF Price: $30
Abstract
Cancer is one of the most common and distressing diseases. Cancer-related
mortality and prevalence have both grown in the last 50 years. Due to its intricacy and
progressive nature, cancer remains one of the most debilitating diseases in humans, and
clinical care for this lethal disease remains a challenge in the twenty-first century. New
and better cancer medicines are constantly needed. Due to the rising global incidence
of cancer, the development of novel alternatives to traditional medicines is unavoidable
to overcome constraints, such as limited efficacy, comorbidities and high cost.
Microneedle arrays (MNs) have just been introduced as an innovative, low-cost, and
minimally invasive technique. MNs can safely and precisely deliver micromolecular
and macromolecular pharmaceuticals, as well as nanoparticles (NPs), to tumor tissue.
However, only a few lipophilic pharmacological compounds with low molecular
weight and a rational Log P value were able to pass the skin barrier. Microneedles
(MNs) can circumvent these constraints by piercing the body's outermost skin layer and
delivering a variety of medications into the dermal layer. MN patches have been made
with a variety of materials and application methods. Recently, three-dimensional (3D)
printing “A touch button approach” gives the prototyping and manufacturing methods
the flexibility to produce the MN patches in a one-step manner with high levels of
shape complexity and duplicability.
Introduction
Role of Nanotechnology in Cancer Therapy gives an overview of the innovative nanocarrier-based approaches for managing various cancers such as gastric, skin, lung, and prostate cancers. The book also explores the evolving targeting approaches specific to cancer and the immunotherapy-based nanomedicinal approach. Several drug-delivery systems which reduce the overall toxicity of cytotoxic drugs and increase their effectiveness and selectivity are also discussed in this book. Key Features - Discusses the potential benefits and therapeutic applications of nanoparticles in cancer management - Provides information about therapy in a range of cancers - Discusses recent developments in cancer nanomedicine including targeted therapy, immonotherapy nanoparticles and dual drug delivery - Includes safety and toxicity considerations - Provides references for advanced readers This book will inform a broad range of readers including undergraduate and postgraduate students, oncologists, pharmacists, and researchers involved in nanomedicine and nano-drug delivery about current advancement in cancer nanomedicine.