Book Volume 12
Recent Drugs Tested in Clinical Trials for Alzheimer´s and Parkinson´s Diseases Treatment: Current Approaches in Tracking New Drugs
Page: 1-58 (58)
Author: Fernanda Majolo, Lavynia Ferreira Hoffmann, Wilian Luan Pilatti Sant’Ana, Celso Alves, Joana Silva, Alice Martins, Rui Pedrosa, Bruno Dahmer, Guilherme Liberato da Silva, Luís Fernando Saraiva Macedo Timmers and Márcia Inês Goettert*
DOI: 10.2174/9789815179842124120003
PDF Price: $15
Abstract
Affecting more than 50 million people worldwide and with high global costs
annually, neurological disorders such as Alzheimer's disease (AD) and Parkinson’s
disease (PD) are a growing challenge all over the world. Globally, only in 2018, AD
costs reached an astonishing $ 1 trillion and, since the annual costs of AD are rapidly
increasing, the projections estimate that these numbers will double by 2030.
Considering the industrial perspective, the costs related to the development of new
drugs are extremely high when compared to the expected financial return. One of the
aggravating factors is the exorbitant values for the synthesis of chemical compounds,
hindering the process of searching for new drug candidates. In the last 10-year period,
an average of 20 to 40 new drugs were approved per year, representing a success rate
of less than 6%. However, the number of referrals for new drug orders and/or
applications remained at approximately 700 each year, reinforcing the difficulty in the
process of identifying and developing novel drugs. Regarding neurodegenerative
diseases, the FDA (USA) approved 53 new therapies in 2019, including 48 new
molecules and, from these, three are medicines and two are vaccines. The main drugs
recommended for the treatment of these disorders are included in the following classes:
Dopamine supplement (Levodopa), Monoamine oxidase (MAO) inhibitor (Selegiline,
Rasagiline), Dopamine agonist (Apomorphine, Pramipexole), and Acetylcholinesterase
inhibitor (Donepezil, Rivastigmine, Galantamine). Additionally, the current
pharmacological treatments are not able to cure these patients and considering the
etiological complexity and the prevalence of neurological disorders, scientists have a great challenge in exploring new therapies and new molecules to find an adequate and
viable treatment for these diseases. Clinical trials are essential in this process and thus,
this chapter describes the most important drugs that were targets of phase III and IV
clinical studies in the last five years, associated with the most common neurological
disorders worldwide, AD and PD. Information about mechanisms of action,
experimental studies in other diseases that support their use, and chemical structure of
the drugs are included in this chapter. Additionally, nature as a source of valuable
chemical entities for PD and AD therapeutics was also revised, as well as future
advances in the field regarding tracking new drugs to get successful results and critical
opinions in the research and clinical investigation.
Neurobiology of Placebo: Interpreting its Evolutionary Origin, Meaning, Mechanisms, Monitoring, and Implications in Therapeutics
Page: 59-79 (21)
Author: Akash Marathakam, Vimal Mathew and MK Unnikrishnan*
DOI: 10.2174/9789815179842124120004
PDF Price: $15
Abstract
Placebo is defined as the therapeutic response to inert treatment. However,
this is a bit simplistic because comprehending the biological basis of the placebo effect
requires understanding the entire therapeutic context and the patient immersed in it.
Placebo does not cure the disease but alleviates symptoms. The placebo impact must be
seen in the context of the recipients’ cultural milieu, psychosocial background, the tone
and tenor of the accompanying verbal communication (caring, indifferent, unfriendly),
therapeutic rituals (e.g., tablet, injection, or a procedure, including diagnostic tests),
symbols (white coat, syringe, the diagnostic paraphernalia), and its meanings to the
patient (past experiences and personal hope). Placebo is the inert treatment juxtaposed
against the broad context of the accompanying sensory and sociocultural inputs that
signal benefit. It could also be the harm in the case of nocebo. A major objective of a
standard clinical trial is to eliminate or at least minimise the influence of placebo.
Many methods have been devised to measure and eliminate placebo responders in the
trial populations. The neurological basis of the placebo effect is complex and must
have an evolutionary basis because the susceptibility to placebos may be traced back to
animals and birds. The placebo effect probably owes its evolutionary origin to
signalling sickness and the ability to draw comfort from winning sympathetic attention
and care from conspecifics. Pain being a complex sensory experience with a strong
affective component, the neuronal pathways that reflect both sensory experience and
the affective components have been explored in the study of the placebo effect. Placebo
research, having expanded from psychology to neurology, presently involves research
tools that include pharmacology, brain imaging, genetics, animal models, etc. This
review will discuss multiple dimensions of the placebo effect, including evolutionary,
cultural, psychosocial, and neurological aspects, in addition to providing cues for
transformational implications in clinical trials and therapeutic modalities that benefit society. Contemporary medicine is demonising placebo because it is a confounder in
clinical trials. It would be much more useful if the healthcare system can harness the
therapeutic potential of the placebo effect by manipulating the therapeutic context.
Role of Gut Microbiota in Neuroinflammation and Neurological Disorders
Page: 80-137 (58)
Author: Khadga Raj*, Navneet Arora, Rohit, Anupam Awasthi, Mayank Patel, Ankit Chaudhary, Shamsher Singh and G.D. Gupta
DOI: 10.2174/9789815179842124120005
PDF Price: $15
Abstract
The prevalence of neurological diseases such as Alzheimer’s disease (AD),
Parkinson’s disease (PD), and Multiple sclerosis (MS) are growing in the world, but
their pathogenesis is unclear and effective treatment does not exist. Neuroinflammation
is associated with many neurodegenerative mechanisms involved in neurodegenerative
diseases. The human gut microbiota is an aggregate of microorganisms that live in the
gastrointestinal tract (GIT) that plays a crucial role in maintaining human health and
the pathogenesis disease condition. The microbiota can affect neuronal function
through neurotransmitters, vitamins, and neuroactive microbial metabolites like shortchain fatty acids. The change in gut microbiota architecture causes increased
permeability of the intestine and immune system activation, contributing to systemic
inflammation, neurological injury, and eventually neurodegeneration. Available data
suggest that the microbiota send signals to the central nervous system (CNS) by
activating afferent neurons of the vagus nerve via neuroendocrine and neuroimmune
pathways. The molecular interaction between the gut/microbiome and CNS is complex
and bidirectional, ensuring gut homeostasis and proper digestion. Evidence suggests
that dysfunction of the gut-brain axis could be a significant factor leading to many
disorders of CNS. In this chapter, we explore how the gut microbiome may affect brain
function and the development of neurological disorders. In addition, we are also trying
to highlight the recent advances in improving neurological disease by supplemental
probiotics and faecal microbiota transplantation via the concept of the gut-brain axis to
combat brain-related dysfunction.
The Role of Age in Pediatric Tumors of the Central Nervous System
Page: 138-170 (33)
Author: Nesibe S. Kutahyalioglu* and Dylan V. Scarton
DOI: 10.2174/9789815179842124120006
PDF Price: $15
Abstract
Pediatric tumors of the central nervous system (CNS) are the second most
common type of solid childhood cancer. As such, they have a major effect on the rates
of morbidity and mortality in children. CNS tumors originate from abnormal cells in
the brain and/or spinal cord, which can be classified as either benign or malignant.
They can be further subdivided into different categories based on several principal
aspects, such as tumor location, histopathology, and developmental age. Among these
various characteristics, age is one of the most consequential determinants for CNS
tumors. Specific groups between 0 and 21 years of age, for instance, have radically
divergent landscapes in terms of their tumor incidence and unique biology. Depending
on the age of the child, key case features may differ like the clinical evaluation,
medical diagnosis and prognosis, recommended therapy and treatment courses,
anticipated responses and tolerability to treatment, and management of side effects.
Effective teamwork is another crucial component for the successful management of
pediatric CNS tumors. In patient-and-family-centered care, ensuring a detailed
education of the children and their families, as well as their involvement in the
decision-making process where appropriate, is imperative. To determine the best
available options for the patient, multidisciplinary medical teams will often deliberate
over all of the possible procedures. The holistic care provided by these interprofessional collaborations for this vulnerable population will depend on the age of the
child, in addition to the level of patient and family participation. Evidence shows that
support and counseling of the patient and their family during the entire treatment
process can have a significant impact on outcomes. This chapter will review the
essential diagnostic and prognostic considerations of childhood CNS tumors, with
special emphasis placed on favorable therapies and treatments, including in-depth
discussions around the multi-faceted responses to treatment and the management of its
side effects. In particular, this content will highlight the critical role that age, and
interdisciplinary healthcare teams play in comprehensive disease management.
Drug Repurposing in CNS and Clinical Trials: Recent Achievements and Perspectives Focusing on Epilepsy and Related Comorbidities
Page: 171-202 (32)
Author: Gabriela Machado Parreira, Antonio Carlos Pinheiro de Oliveira, Leonardo de Oliveira Guarnieri* and Rafael Pinto Vieira*
DOI: 10.2174/9789815179842124120007
PDF Price: $15
Abstract
Central Nervous System (CNS) disorders are a massive burden on the global
health system, including a broad range of clinical conditions, such as epilepsies,
depression, dementia, multiple sclerosis, and Parkinson’s disease. Permanent efforts are
being made to find early, non-invasive, and effective diagnostic methods, as well as
efficient and safe drug-based treatments for CNS conditions. Nevertheless, many
patients displaying these clinical conditions still face the lack of an effective
pharmacotherapy to cure the diseases or at least to properly control the progression of
symptoms. Currently, epilepsies present an estimated prevalence of 0.5%–1%
worldwide, and around 30% of the patients remain refractory to the available drug
treatment. The comorbidities that affect epileptic patients, such as cognitive
impairment and depression, are major public health challenges. This scenario
highlights the urgent need for approving new therapeutic tools for CNS diseases. A
successful development process of a new compound presenting therapeutic potential
can range up to 20 years and cost hundreds of millions of US dollars, from the initial
characterization of the in vitro chemical and biological properties until clinical trials.
Additionally, drug development has a low success rate in the case of CNS conditions.
In this context, drug repurposing (or drug repositioning, DR) is an alternative way to
reduce the cost and accelerate the process of a drug-based treatment approach since it
identifies a novel clinical application for an existing compound already approved for a
distinct indication. In the present chapter, we aim to describe recent outcomes of DR aiming at CNS pathological conditions, especially discussing the recent clinical trials
and their impacts on future endeavors in the search for the management of epilepsies
and related comorbidities.
Progress on the Development of Oxime Derivatives as a Potential Antidote for Organophosphorus Poisoning
Page: 203-255 (53)
Author: Manjunatha S. Katagi*, M.L Sujatha, Girish Bolakatti, B.P. Nandeshwarappa, S.N. Mamledesai and Jennifer Fernandes
DOI: 10.2174/9789815179842124120008
PDF Price: $15
Abstract
Nowadays, organophosphorus poisoning is the most common emergency
throughout the world. Two functionally different types of drugs are used in common to
treat such intoxication cases. The first type includes the reactivators of
acetylcholinesterase (AChE)-oximes, which have the capability to restore the
physiological function of inhibited AChE. The second type includes anticholinergic,
such as atropine that antagonizes the effects of excessive ACh by blocking muscarinic
receptors. Alternatively, anticholinergic and reactivators may be co-administered to get
synergistic effects. At muscarinic and nicotinic synapses, organophosphorus
compounds inhibit AChE release by phosphoryl group deposition at the enzyme's
active site very quickly. AChE regenerative process can be accelerated by detaching
the OP compound at -OH group of the enzyme. OP compound combines with the
AChE enzyme forming a complex and making it inactive. After ageing of the inactive
state of AChE, it is difficult to break the complex to regenerate the enzyme resulting in
acetylcholine accumulation at synapses. To counter the effect of OP compound, oximes
catalyse the reactivation of active AChE by exerting nucleophilic attack on the
phosphoryl group. Oximes theoretically remove OP compound from the complex by
acting on phosphoryl bond resulting in enzyme reactivation. Reactivation of AChE
inhibited by OP compounds through the above mentioned approach poses certain
limitations. There is no universal antidote capable of effectively restoring AChE inhibited by wide-ranging OP compounds. The oxime reactivators are efficient only when
administered before the “ageing” of AChE-OP complex. Anticholinergic drugs, like
atropine, are effective only on muscarinic receptors but not on nicotinic receptors
(nAChRs).
Subject Index
Page: 256-261 (6)
Author: Zareen Amtul
DOI: 10.2174/9789815179842124120009
PDF Price: $15
Introduction
Frontiers in Clinical Drug Research - CNS and Neurological Disorders is a book series that brings updated reviews to readers interested in advances in the development of pharmaceutical agents for the treatment of central nervous system (CNS) and other nerve disorders. The scope of the book series covers a range of topics including the medicinal chemistry, pharmacology, molecular biology and biochemistry of contemporary molecular targets involved in neurological and CNS disorders. Reviews presented in the series are mainly focused on clinical and therapeutic aspects of novel drugs intended for these targets. Frontiers in Clinical Drug Research - CNS and Neurological Disorders is a valuable resource for pharmaceutical scientists and postgraduate students seeking updated and critical information for developing clinical trials and devising research plans in neurology and allied disciplines. The twelfth volume of this series features these reviews: Chapter 1: Recent Drugs Tested in Clinical Trials for Alzheimer's and Parkinson's Diseases Treatment: Current Approaches in Tracking New Drugs Chapter 2: Neurobiology of Placebo: Interpreting Its Evolutionary Origin, Meaning, Mechanisms, Monitoring, and Implications in Therapeutics Chapter 3: Role of Gut Microbiota in Neuroinflammation and Neurological Disorders Chapter 4: The Role of Age in Pediatric Tumors of the Central Nervous System Chapter 5: Drug Repurposing in CNS and Clinical Trials: Recent Achievements and Perspectives Focusing on Epilepsy and Related Comorbidities Chapter 6: Progress on the Development of Oxime Derivatives as a Potential Antidote for Organophosphorus Poisoning .