Anatomy and Physiology of the Brain: Pathophysiology of Brain Tumor
Page: 1-33 (33)
Author: Amitha Muraleedharan* and Nikhil Ponnoor Anto
DOI: 10.2174/9789815079722123010003
PDF Price: $15
Abstract
The brain is an efficient processor of information. It is the most complex and
sensitive organ in the body and is responsible for all functions of the body, including
serving as the coordinating center for all sensations, mobility, emotions, and intellect.
The magnitude of its myriad function is often realized usually when there is a
disruption of the nervous system due to injury, disease, or inherited predispositions.
Neuroscience is the field of study that endeavors to make sense of such diverse
questions; at the same time, it points the way toward the effective treatment of
dysfunctions. The two-way channel of information: findings from the laboratory
leading towards stricter criteria for diagnosing brain disorders and more effective
methods for treating them and in turn, the clinician's increasingly acute skills of
diagnosis and observation that supply the research scientist with more precise data for
study in the lab diligently expands the field of neuroscience. Tumors of the brain
produce neurological manifestations through several mechanisms. Stronger hypotheses
about the mechanism of a disease can point the way toward more effective treatments
and new possibilities for a cure. In highly complex disorders of the brain, in which
many factors genetic, environmental, epidemiological, even social and
psychological—play a part, broadly based hypotheses are exceedingly useful. With the
advancements in technology and a better understanding of brain anatomy and
physiology, the quest to discover an efficient cure for life-threatening tumors of the
brain is underway.
Barriers to Targeted Drug Delivery Strategies in Brain
Page: 34-59 (26)
Author: Payal Kesharwani, Kajal Kumari, Smita Jain and Swapnil Sharma*
DOI: 10.2174/9789815079722123010004
PDF Price: $15
Abstract
Brain tumor is considered to be the most detrimental disease found in
humans. Amongst the various brain tumors, glioblastoma has emerged as a highly
invasive malignant disease that has contributed to significant mortality worldwide.
Despite surgical and drug innovations, most of the patients suffering from brain
tumours have shown poor prognosis, with a median life span. The presence of the
blood-brain barrier (BBB) acts as a protective layer outside the brain for most of the
conventional, diagnostic and therapeutic agents, which in turn leads to poor diagnosis
and less efficacy in most clinical subjects. In recent years, multifunctional
nanotechnology systems have been employed to deliver theranostic agents to the brain,
showing promising outcomes in the treatment of various forms of cancer. The present
chapter provides comprehensive information on the most recent developments in BBB-crossing nanotechnology, with a slight focus on the thoughtful design of
multifunctional nanoplatforms for effective BBB penetration, accurate tumor imaging,
and substantial brain tumor inhibition. Besides, various physiological barriers and
transportation mechanisms, different drug delivery systems for brain tumors are also
highlighted. Furthermore, major advancements in brain tumor theranostics pertaining to
employing different nanosystems such as liposomes, polymeric nanoparticles, bio-nano
particles, and inorganic-nanoparticles for effective nano-drug delivery for theranostics
in brain tumors have also been discussed.
Theranostics Polymeric Nanoparticles for Brain Tumor Diagnosis and Treatment
Page: 60-99 (40)
Author: Sivadas Swathi Krishna, Ardra Thottarath Prasanthan, Nirdesh Salim Kumar, Manish Philip and Vidya Viswanad*
DOI: 10.2174/9789815079722123010005
PDF Price: $15
Abstract
Theranostics, a dual strategy, helps in better tumor imaging, the
biodistribution of drugs (the ability to direct therapeutic agents to the tumor site), and
understanding the progress and effectiveness of therapy. Theranostics is an emerging
technology for the diagnosis and management of brain tumors which differ from
peripheral tumors in several ways because of their complexity in the genesis of
oncogenes. Several factors must be considered for successful brain tumor-targeted drug
delivery. Nanotheranostics for brain cancer therapies have been identified now, and
polymeric nanoparticles (PNP) are one of the most efficient and promising
nanotechnological platforms. They can be utilized as a new imaging method to
optimize chemotherapeutic drug delivery into brain tumors while reducing the drug's
dissemination and toxicity in healthy people. Smart carriers and theranostic
nanoparticles can diagnose, deliver, and track the therapeutic response synchronized.
This chapter gives an insight into superparamagnetic, ultrasound-triggered radionuclide
bearing, and fluorescent PNPs as potential theranostic approaches for brain tumor
management.
Theranostic Liposome for Brain Tumor Diagnosis and Treatment
Page: 100-120 (21)
Author: Payal Kesharwani, Shiv Kumar Prajapati, Devesh Kapoor, Smita Jain and Swapnil Sharma*
DOI: 10.2174/9789815079722123010006
PDF Price: $15
Abstract
The treatment of brain tumours is often a challenging task due to the low
permeability of drugs through the blood-brain barrier and their poor penetration into
the tumour tissues. Liposomes enhance the delivery of chemotherapeutics to the brain
without using any invasive approach. Liposomes are biomimetic nanocarriers that
exhibit good biocompatibility, high loading capacity, and the ability to reduce the
amount of encapsulated drugs. It is a promising candidate performing a dual function
of both drug delivery and diagnosis. This approach helps to locate the tumour tissue
with appropriate biodistribution of liposomes. The theranostic liposomes provide a
platform for imaging tumour cells for early diagnosis and simultaneously, delivery to
the brain enhances the targeting delivery. Fluorescent dyes, magnetic resonance
imaging, and nuclear imaging are the few approaches used in the diagnosis of tumour
cells. A new approach involving semi-conductor-based quantum dots has emerged as
an imaging reagent for brain tissues. The theranostic application of liposomes provides
the real-time monitoring of the administered drug, reducing the risk of under-or overdosing and allowing for more customized therapy regimens. This chapter highlights the
techniques for directing liposomes to solid tumours in-depth, potential targets in cancer
cells, such as extracellular and intracellular targets, and targets in the tumour
microenvironment or vasculature. Additionally, this chapter also concludes recent
efforts for improving anticancer drug delivery at the tumour site using surface
functionalization techniques, and the different contrast agents which help in diagnosis
are discussed.
Theranostics Dendrimer for Brain Tumor Diagnosis and Treatment
Page: 121-139 (19)
Author: Aseem Setia, Ram Kumar Sahu*, Ayodeji Folorunsho Ajayi and Emmanuel Tayo Adebayo
DOI: 10.2174/9789815079722123010007
PDF Price: $15
Abstract
Brain tumors have become one of the deadliest types of cancer. Tragically,
the blood-brain barrier (BBB), an astringent regulatory, well-coordinated, and effectual
obstacle, prevents most substances from passing through it. As a result, breaking
through this hurdle is amongst the most difficult challenges in devising effective CNS
therapies. In the USA, approximately seven lakh people have a principal brain
malignancy, with an ample eighty-five thousand predicted to be afflicted by 2021.
Capillaries are essential for delivering oxygen and nutrients to all body tissue and vital
organs. The capillaries that vascularize the CNS have a special feature known as the
blood-brain barrier, which enables such vessels to firmly enforce the transfer of ions,
substances, and cells in-between the blood-brain barrier. This accurate estimation of
CNS homeostasis leads to proper neuronal function while also protecting neural tissue
from toxic substances and microorganisms, and changes in such mechanical strength
are a major aspect of the pathology and transformation of various neurological
diseases. Theranostic strategies were also postulated and deemed enticing in recent
times. Due to the smaller size, better topical functionalization, and capability to
integrate various processing elements in one system, nanotechnology is beneficial for
this system. For cancer therapy, the structure of nanotherapeutic systems focusing on
diagnostic and therapeutic applications is increasing tremendously. This dual system is
extremely useful for personalized medicine-based clinical applications because it seeks
to analyze the position of malignancy, the biodistribution of nanosized systems, along
with an advanced and efficacious therapy. Proteins, molecular markers, and genes are
some of the theranostic strategies that could be used to amplify the surface of the
nanotheranostics particle and make benefit of the features of the micro-environment
utilising stimulus-based triggers. The current chapter focused on the theranostic
approach of dendrimer for brain tumor treatment. It also enlightened about various
diagnostic techniques for brain tumors with a special emphasis on nanotherapeutics.
Theranostics Nanoemulsion for Brain Tumor Diagnosis and Treatment
Page: 140-154 (15)
Author: Deepak Prashar*, Ram Kumar Sahu, Jiyauddin Khan, Oluwadunsin Iyanuoluwa Adebayo and Grace Fumilayo Adigun
DOI: 10.2174/9789815079722123010008
PDF Price: $15
Abstract
Cancer or malignancy is the most widely occurring ailment in the recent
scenario. Brain tumor is considered to be one of the most fatal among all types of
tumors. The brain-related tumors are numerous and need to be treated and diagnosed
in different ways. The diagnosis of brain tumor is done by various methods like MRI,
CT scan and neurological testing. In the recent past, a number of nanoemulsion
formulations have been formulated and developed to treat and diagnose brain cancer.
The present work presents the present status of anti-cancer drugs, the parameters
related to their working and the advancement in technology.
Theranostics Micelles for Brain Tumor Diagnosis and Treatment
Page: 155-200 (46)
Author: Nidhal Khazaal Maraie*, Zainab H. Mahdi and Zahraa Amer Al-Juboori
DOI: 10.2174/9789815079722123010009
PDF Price: $15
Abstract
Brain cancer is considered one of the most vicious and devastating tumors
owing to its poor prognosis and high mortality rate. Common strategies for
treatment include surgery, radiation, and chemotherapy. Unfortunately, these are
limited due to their invasive nature and the inherent difficulties of brain surgery, given
there is a high possibility of tumor relapse. Further, radiation and chemotherapy have a
non-selective harmful effect on normal tissues, accompanied by limited drug delivery
due to the presence of various barriers, including the blood-brain barrier. For this
reason, the theranostic approach was developed by incorporating one or more
therapeutic and diagnostic agents in a single nanocarrier moiety which could be
modulated at its surface with certain proteins, legend, surface markers, or a stimuli-responsive agent that is capable of selectively targeting the tumor site after passing
through the blood-brain barrier. This new field will permit the early and precise
detection of cancer tissue, facilitate the process of drug delivery and assist in
monitoring treatment outcomes. Micelles are considered one of the most commonly
used nanocarriers due to their high stability and loading capacity, along with efficient
release controlling properties. This chapter will present brief information about brain
anatomy and cancer, and will discuss the main strategies implemented in the diagnosis
and treatment of brain cancers. Furthermore, it will introduce the theranostic micelle
approach by highlighting micelles types and preparation techniques, as well as explain
the different barriers and approaches to targeting.
Theranostics Inorganic Nano-particles for Brain Tumor Diagnosis and Treatment
Page: 201-221 (21)
Author: Krishna Yadav, Swati Dubey, Shalini Singh, Geetika Sharma, Madhulika Pradhan, Narayana Subbiah Hari Narayana Moorthy and Sunita Minz*
DOI: 10.2174/9789815079722123010010
PDF Price: $15
Abstract
Brain tumors pose a major threat to human health due to difficult treatment,
rapid progression, and poor prognosis, resulting in a terrible fatality rate that has
remained high over the years. As arteries have limited drug permeability into brain
tumor tissue, the success rate of chemotherapy remains low. Considering the anatomic
concerns of brain tumors and the interaction between the blood-brain barrier (BBB)
and nano-particles (NPs), nanotechnology is deemed an attractive approach as it has the
potential to increase brain drug distribution. Theranostic strategies have also been
proposed in recent years and they are seen promising. NPs are considered ideal due to
their size, ease of surface modification and, adaptability to integrating several
functional components in one system. In lieu of this, the design of nano-particles with
therapeutic and diagnostic uses has increased tremendously, particularly in cancer
treatment. This two-pronged technique aids in understanding tumor tissue location,
treatment progress, nanoparticle’s bio-distribution and, its efficacy as it is particularly
valuable for personalized medicine-based treatments. In this chapter, we will focus on
the properties of the blood-brain barrier and the blood-brain tumor barrier (BBTB), two
important hurdles in brain-tumor targeted delivery, and the targeting strategies that aim
at different stages of brain tumor growth and development as well as their recent
advances in brain tumor-targeted novel nano-drug delivery systems.
Subject Index
Page: 222-226 (5)
Author: Ram Kumar Sahu
DOI: 10.2174/9789815079722123010011
PDF Price: $15
Introduction
Brain Tumor Targeting Drug Delivery Systems: Advanced Nanoscience for Theranostics Applications is a comprehensive reference focused on the latest advancements in nanotechnology for brain tumor therapy. With practical insights and cutting-edge research, this book equips readers with the knowledge to develop innovative drug delivery systems for effective brain tumor diagnosis and treatment. Structured into insightful chapters, this book covers the anatomy, physiology, and pathophysiology of the brain, addressing barriers to targeted drug delivery strategies. Chapters explore theranostics-based delivery systems, including polymeric nanoparticles, liposomes, dendrimers, nanoemulsions, micelles, and inorganic nanoparticles, for precise brain tumor diagnosis and treatment. This informative resource is designed for students and research scholars in pharmacology, pharmaceutical industry scientists, professors, and clinical medicine researchers. With comprehensive chapters and references for further reading, this book facilitates easy understanding of the intricate nanomedical technology, empowering researchers to make significant strides in the field of brain tumor therapy. Key Features: - Structured chapters for easy understanding of nanotechnology concepts - In-depth coverage of theranostics-based delivery systems for brain tumor diagnosis and treatment - References for further reading and exploring new advances in drug delivery systems