Dedication
Page: ii-ii (1)
Author: Faris Q.B. Alenzi*
DOI: 10.2174/9789815080384123010002
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Introduction
Page: 1-11 (11)
Author: Abdulaziz Bin Saeedan*, Mohd. Nazam Ansari and Amal Almohisen
DOI: 10.2174/9789815080384123010004
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Abstract
Cancer is a complex family of diseases that usually begins with
carcinogenesis, in which abnormal cells divide or develop wildly by not following the
regular path of cell division and likewise can invade nearby tissues. Cancer cells
demonstrate transformations in metabolism, which is frequently more anaerobic than
normal and probably can tolerate hypoxic surroundings. The remarkable variability of
the disease, at all levels, is the major challenge for cancer medicine. Six biological
abilities gained during the multi-stage advances of human tumors are the maintenance
of proliferative signaling, the prevention of growth suppressors, cell death resistance,
replicative immortality allowance, angiogenesis induction, invasion, and metastasis
activation. In this chapter, we discuss the features of cancer cells and the epidemiology
of cancer for better understanding.
Cancer Traits; Present and Future
Page: 12-51 (40)
Author: Khalid A. Asseri* and Afaf Ahmed Aldahish
DOI: 10.2174/9789815080384123010005
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Abstract
This chapter on “Cancer Traits; Present and Future” begins with a description of the process of carcinogenesis and, finally, the abnormal process leading to carcinogenesis.
Cancer is a multi-step mechanism in which cells undergo biochemical and behavioral changes, causing them to proliferate in an unnecessary and untimely manner. These changes occur from modifications in mechanisms that regulate cell proliferation and longevity, relationships with neighboring cells, and the ability to escape the immune system. Modifications that contribute to cancer require genetic modifications that alter the DNA sequence. Another way to alter the program of cells is to adjust the conformation of chromatin, the matrix that bundles up DNA and controls its access through DNA reading, copying and repair machinery. These modifications are called “epigenetic. The abnormal process that leads to carcinogenesis includes early mutational events in carcinogenesis, microRNAs in human cancer and cancer stem cell hypothesis, Contact inhibition of proliferation, autophagy, necroptosis, signaling pathways, telomere deregulation, microenvironment, growth suppressors evasion, resisting cell death and sustained cell survival, enabling replicative immortality through activation of telomeres, inducing angiogenesis, ability to oppose apoptosis, and activating invasion and metastasis. Intensive research efforts during the last several decades have increased our understanding of carcinogenesis and have identified a genetic basis for the multi-step process of cancer development. Recognition and understating of the prevalent applicability of cancer cell characterization will increasingly affect the development of new means to treat human cancer.
Exogenous Factors and Cancer
Page: 52-85 (34)
Author: Baraa T. Alhajhussein*, Majed H. Wakid, Najwa Mohamad Alsawi, Hesham Hamdy Amin and Fahad Nasser Alonazi
DOI: 10.2174/9789815080384123010006
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Abstract
The causation of cancer, whether exogenous or endogenous, is a cornerstone
of cancer prevention and treatment. Many intrinsic factors are discussed in other
chapters of this book; this chapter will shed light on exogenous factors influencing
cancer with detailed specific examples of microbial, physical and chemical factors.
Microbial role in cancer has been debated over many centuries, whether as an
antagonist or a cause, since Imhotep’s time through the mid-17th century when cancer
was considered contagious, and later cancer hospitals were forcefully moved out of the
cities as isolation camps. There are now vivid evidences that specific microbial
pathogens are causing up to 25% of cancer cases (lymphoma, solid or others), and in
some cases, a single pathogen was found in association with many types of cancer,
such as HPV and EBV, to a lesser extent.
Also, several non-biological factors are classified as carcinogens as humans are
exposed to millions of chemicals whether in environment or smoke processed food.
Biology of Cancer
Page: 86-186 (101)
Author: Rawiah A. Alsiary*, Hanadi A. Katouah, Hiba S. Al-Amodi and Mashael Al-Toub
DOI: 10.2174/9789815080384123010007
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Abstract
Loss of genomic stability in the cell due to defects in the checkpoint of DNA
damage, mitotic checkpoint, and telomere maintenance led to increased incidences of
base pair alterations. Therefore, that genomic instability plays a critical role in tumor
initiation and progression. Tumor progression requires a dynamic tumor/normal
exchange in their microenvironment to support tumor growth. The histological
alteration seen in the tumor at early stages confirms that the surface between the
epithelium and the stroma undergoes progressive disturbance. Tumor progression is
also affected by the immune system in which chronic inflammations promote the
growth of tumor. Tumor cells experience altered metabolic profiling to support their
growth. Cancer cells are characterized by uncontrolled cell division. For that, they
utilize glucose as a source of energy to help them grow faster than normal cells. Hence,
Glycolysis is a key metabolomics pathway consumed at a high rate during
carcinogenesis.
Growth Factors and Cancer
Page: 187-241 (55)
Author: Aisha Al Anazi*, Ravi Teja Chitturi Suryaprakash, Kate Shearston and Omar Kujan
DOI: 10.2174/9789815080384123010008
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Abstract
Cancer causes major patient morbidity and mortality and is a critical health
concern worldwide. The recent GLOBOCAN 2019 factsheet recorded nearly 19.2
million new cancer cases, 9.9 million cancer deaths and 50.55 million people suffering
from different kinds of cancer globally within 5 years after diagnosis. Growth factors
(GF) are a group of proteins that can affect cellular processes, including differentiation,
division, intravasation, extravasation and dissemination. The circulating tumor cells in
the bloodstream can populate distant tissues and organs and believe to be the primary
cause of metastasis. Extravasation is a crucial phase in the metastasis process, in which
tumor cells leave the bloodstream and enter the host tissue. The progress of metastasis
is triggered by the tendency of cancer cells to disseminate to target organs from the site
of the primary tumor. Despite extensive basic scientific and clinical investigations,
cancer is still a major clinical and public health problem. The development of cancer
can be influenced by genetics, environmental factors, gene-environment interaction,
lifestyle, age and a number of other factors. The harnessing and enhancement of the
body’s own cytotoxic cells to prevent basement membrane rupture and the intervening
dissemination processes can provide useful insight into the development of cancer. The
mutation in oncogenes and tumour suppressor genes, and chromosomal aberration is a
cornerstones of the molecular basis of cancer. The basement Membrane (BM) acts as a
cell invasion shield, thus identification of processes that underlie in breaching of BM
can contribute to understanding the disease pathogenesis. TGF-β is known for its dual
function; it requires inhibition in the advanced stage however, the growth inhibitory
properties are displayed in the early stages of tumorigenesis. Therefore, inhibition of
TGF-β signalling in the CD8+ T cell compartment may be necessary for tumor
immunity to be restored. Quantitation of tumour cell dissemination is important and
plays significant role in elucidating mechanisms of cancer and strategies for therapeutic
intervention.
Cell Signaling Pathways in Cancer
Page: 242-272 (31)
Author: Hajir A. Al-Saihati*, Mashael Al-Toub, Hanaa I. Sharaf, Manjari Singh, Mohd. Nazam Ansari and Abdulaziz Bin Saeedan
DOI: 10.2174/9789815080384123010009
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Abstract
Cancer is characterized by atypical cell proliferation that has the possibility
of dissemination to different body parts. Tumor formation is influenced by genetic
mutations and environmental pollutants. The formation and progression of
malignancies have been linked to a diversity of molecular paths. The JAK/STAT,
NOTCH, PI3K/AKT pathway, mitogen-activated protein kinase (MAPK), transforming
growth factor-beta (TGF-beta) (TGF-), NF-B, and Wnt signaling pathways will be
highlighted in this chapter. Cancer development has been linked to various changes to
the signaling pathways' components. As a result, various initiatives to target signaling
pathways in order to build distinct treatment lines have been approved. In this chapter,
we discuss the role of signal transduction in cancer-associated processes and how their
targets influence the behavior of the tumor cells.
Transcription Factors in Cancer
Page: 273-319 (47)
Author: Rawiah A. Alsiary*, Talat Abdullah Albukhari and Waheed A. Filimban
DOI: 10.2174/9789815080384123010010
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Abstract
Different types of signalling pathways have been approved to be involved in
cancer imitation and progression. These signalling pathways include the JAK-STAT
signalling, NF-κB signalling, Wnt, Notch and Hedgehog. STAT (Signal Transducer
and Activator of Transcription) transports signals between proteins from the cell
membrane into the nucleus to contribute to cancer progression. NF-κB signalling is
essential for the survival of the B cell tumor types. The Wnt, Notch, and Hedgehog
signalling pathways play a significant role in carcinogenesis by upregulating the genes
associated with these pathways. Hence, pharmacological inhibitors of WNT, NOTCH,
and HH pathways are required in clinical studies. Such inhibitors have features that
make them important during the clinical trial since they offer great potential as novel
therapeutics for cancer. They also have an antitumor response which should be taken
into consideration. The three signalling pathways are also known to shape cell fate
determination and differentiation. In case of depletion of a single molecular component
within the three pathways, embryonic lethality will form.
Epigenetic and Genetics Factors
Page: 320-366 (47)
Author: Abeer A. Alsofyani* and Yazan Samih Said
DOI: 10.2174/9789815080384123010011
PDF Price: $30
Abstract
Despite variations in the morphology and behaviors of human body cells,
every single cell in our body is composed of identical DNA material. The variation in
cell phenotypes is a result of a specific regulatory mechanism known as epigenetics, by
which gene expression undergoes some modifications without the actual nucleotide
sequence being affected [1]. This phenomenon is accomplished through several
mechanisms, such as cytosine residue methylation, modifications of histone units, and
RNA interference. Therefore, epigenetics performs a key function in embryonic growth
and development, cellular RNA expression, gene imprinting, and silencing of females’
X chromosomes [2]. Any impairment in these mechanisms may cause various human
disorders, including cancer [3]. In carcinogenesis, defective epigenetic machinery at
several distinct levels results in abnormal cellular functions [4].
This chapter highlights epigenetics' importance in cancer development and its potential
applications for cancer treatment.
Subject Index
Page: 367-372 (6)
Author: Faris Q.B. Alenzi*
DOI: 10.2174/9789815080384123010012
PDF Price: $30
Introduction
Today, treatment options for cancer patients typically include surgery, radiation therapy, immunotherapy, and chemotherapy. While these therapies have saved lives and reduced pain and suffering, cancer still takes millions of lives every year around the world. Researchers are now developing advanced therapeutic strategies such as immunotherapy, targeted therapy, and combination nanotechnology for drug delivery. In addition, the identification of new biomarkers will potentiate early-stage diagnosis. Molecular Targets and Cancer presents information about cancer diagnosis and therapy in a simple way. It covers several aspects of the topic with updated information on par with medical board levels. The book features contributions from experts and includes an overview of cancer from basic biology and pathology, classifications, surveillance, prevention, diagnosis, types of cancer, treatment and prognosis. The first part of this book introduces the reader to cancer epidemiology, genetic alterations in cancer, exogenous and endogenous factors in carcinogenesis, roles for growth factors in cancer progression, cell signaling in cancer, transcription factors in cancer, and cancer genetics and epigenetics. This comprehensive guide is a valuable resource for oncologists, researchers, and all medical professionals who work in cancer care and research.