Book Volume 9
Preface
Page: i-i (1)
Author: Israel Valencia Quiroz
DOI: 10.2174/9789815223163124090001
PDF Price: $15
Multi-omics Profiles are Applicable to Human Diseases and Drug Development
Page: 1-19 (19)
Author: Adriana Montserrat Espinosa-González, José del Carmen Benítez-Flores, Juan Carlos Gómez-Verjan, Nadia Alejandra Rivero-Segura, Ignacio Peñalosa Castro, Jose Cruz Rivera Cabrera and Edgar Antonio Estrella-Parra*
DOI: 10.2174/9789815223163124090003
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Abstract
Traditional medicine has been a reliable source for the discovery of
molecules with therapeutic activity against human diseases of clinical interest. In the
past, knowledge of traditional medicine was mainly transmitted orally and in writing.
Recently, the advent of “multiomics” tools (transcriptomics, metabolomics,
epigenomics, proteomics, and lipidomics, among others) has increased and merged our
knowledge, both traditional knowledge and that gained with these new multiomics
technologies. In this way, the development of medicines with these 'multiomics
technologies' has allowed pharmaceutical advances in the discovery of new drugs. In
addition, 'multiomics' technologies have made it possible to uncover new biological
activities of drugs that are currently used in clinical therapy. In the same way,
'multiomics' has allowed for the development of 'personalized medicine', that is, a
particular and specific treatment and/or diagnosis of a patient with respect to a disease.
Therefore, 'multiomics' technologies have facilitated the discovery of new clinical
therapeutics for disease, as well as allowing for the diagnosis and/or treatment of
diseases in an individual and personalized way.
Utilizing in silico Methods in New Drug Design
Page: 20-51 (32)
Author: Olivia Pérez-Valera, Yuri Córdoba-Campo, Rafael Torres-Martínez, Yesica R. Cruz-Martínez and Israel Valencia Quiroz*
DOI: 10.2174/9789815223163124090004
PDF Price: $15
Abstract
The current chapter offers a highly informative and enlightening overview of
the practical implementation of molecular docking in the field of biotechnology, with a
specific focus on drug discovery for a variety of ailments. Molecular docking, an
incredibly powerful computational methodology, has increasingly been utilized as an
essential instrument in the elucidation of drug-receptor interactions, providing
invaluable insights into the process of designing drugs. This chapter delves into the
fundamentals of molecular docking algorithms, offering a comprehensive
understanding of their theoretical underpinnings, methodologies, and typical
applications. Furthermore, this chapter elaborates on how this method is used to predict
the binding affinity and orientation of potential small-molecule therapeutics to their
protein targets, emphasizing the crucial role that molecular docking plays in the quest
for new medications to treat various diseases. By presenting case studies across a range
of diseases, this chapter effectively demonstrates the remarkable versatility of
molecular docking in advancing our knowledge of disease pathogenesis and therapeutic
interventions. In addition, specific diseases and their corresponding drugs are carefully
examined, along with an in-depth review of molecular docking studies performed on
these drugs. This detailed exploration serves as a robust foundation for researchers
seeking to understand the utility of molecular docking in the development of more
effective, targeted therapeutics. This chapter thus positions molecular docking as an
indispensable tool in the field of biotechnology, propelling drug discovery into a new
era of precision and efficiency. Overall, this chapter presents a comprehensive and informative overview of the diverse applications of molecular docking in biotechnology,
providing an essential resource for researchers in the field.
The Roles of Farnesol and Farnesene in Curtailing Antibiotic Resistance
Page: 52-69 (18)
Author: Axel R. Molina-Gallardo, Yesica R. Cruz-Martínez, Julieta Orozco-Martínez, Israel Valencia Quiroz and C. Tzasna Hernández-Delgado*
DOI: 10.2174/9789815223163124090005
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Abstract
In the extensive domain of “biotechnology and drug development for
targeting human diseases”, essential oils have long been revered for their therapeutic
potential. Among these, farnesol and farnesene stand out due to their pharmacological
attributes. As the challenge of antibiotic resistance intensifies, the scientific community
is increasingly exploring the potential of these traditional remedies. Using the KirbyBauer agar diffusion method, a qualitative assessment was conducted on two grampositive and two gram-negative bacterial strains. The broth microdilution technique
further determined the Minimum Inhibitory Concentration (MIC), Minimum
Bactericidal Concentration (MBC), and the sensitizing impacts of these compounds.
Both farnesol and farnesene exhibited antibacterial efficacy against all evaluated
strains. Their synergistic potential was highlighted when combined with clavulanic
acid, cefuroxime, and cefepime. Among these combinations, farnesene paired with
cefepime showed pronounced efficacy against Escherichia coli 82 MR, with an MIC of
0.47 μg/mL. In contrast, in the investigation of Staphylococcus aureus 23MR, it was
observed that this particular strain exhibited an increased sensitivity when exposed to
combinations containing farnesol. Notably, the Minimum Inhibitory Concentration
(MIC) was determined to be 0.03 µg/mL in the presence of both antibiotic agents. To
gain deeper molecular insights, docking experiments were performed with the βlactamases of E. coli and S. aureus, focusing on the most effective combinations. All
tested compounds—cefuroxime, cefepime, farnesene, and farnesol—acted as noncompetitive inhibitors, suggesting their potential mechanisms of action.
Application of Viruses as Carriers in Biotechnology
Page: 70-89 (20)
Author: Viridiana R. Escartín-Alpizar*, Julieta Orozco-Martínez and Israel Valencia Quiroz
DOI: 10.2174/9789815223163124090006
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Abstract
Currently, the development of new vaccine technologies for the treatment of
diseases is vital. The use of biotechnology in the application of viruses for the
development of vaccines is a relatively new research platform. Viruses have become an
important tool in biotechnology, and they are being used in the development of
vaccines and anticancer drugs. Some of the viral vectors commonly used to develop
vaccines are adenoviruses, adeno-associated viruses, herpes simplex viruses,
retroviruses and lentiviruses, among others. Viral vectors have been used as vaccines
against a variety of infectious diseases, such as COVID-19, influenza, HIV and
malaria. Viruses have also been used to target drugs to cancer cells by using engineered
viral vectors that can selectively target and infect cancer cells. In this way, viral vectors
can also be used to deliver antitumor drugs. This will selectively target cancer cells.
Thus, vectors can be used to deliver therapeutic drugs directly to the tumor, resulting in
reduced side effects and improved efficacy.
Phenolic Compounds with Photo-Chemoprotective Activity
Page: 90-114 (25)
Author: Erick Nolasco-Ontiveros*, María del Socorro Sánchez-Correa, José Guillermo Avila-Acevedo, Rocío Serrano-Parrales and Adriana Montserrat Espinosa-González
DOI: 10.2174/9789815223163124090007
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Abstract
Skin cancer has one of the highest incidence rates among all types of cancer
and is predominantly caused by exposure to ultraviolet radiation from the sun, which
reaches the Earth's surface due to the well-known phenomenon of thinning of the ozone
layer in the stratosphere. To reduce the risk of developing this malignancy, the use of
sunscreens is recommended; however, the synthetic compounds in sunscreens can
cause side effects and harm the environment. To avoid damage to human health and the
environment, the use of different plant secondary metabolites with
photochemoprotective potential has been investigated in recent decades. For this
reason, phenolic compounds are useful alternatives since many of them are capable of
absorbing ultraviolet radiation (UVR). Moreover, some of these compounds have antiinflammatory, antioxidant, and even anticancer activities. This chapter explores the
progress in the study of different phenolic compounds extracted from plants with
potential for use in sunscreen formulations.
Natural Products in Wound Regeneration
Page: 115-136 (22)
Author: Nallely Álvarez-Santos, Rocío Serrano-Parrales, Patricia Guevara-Fefer, Felix Krengel and Ana María García-Bores*
DOI: 10.2174/9789815223163124090008
PDF Price: $15
Abstract
The skin is the largest organ in the body that provides protection. When a
wound occurs, the skin structure and its function are damaged, and it can even
compromise life. Damage repair can occur through two mechanisms: healing and
regeneration. When a scar forms, fibrosis occurs in the area, and the skin appendages,
which include the glands and hair follicles, are lost. In regeneration, the functionality of
the skin is partially or totally recovered. Medicinal plants and their active principles
favor the regeneration of skin wounds because they have direct effects on the different
phases of the process. They favor hemostasis, and modulate inflammation, which
allows the following stages of healing to occur in less time, such as proliferation and
remodeling. They favor hemostasis, modulate inflammation, and that the following
stages of healing to occur in less time (proliferation and remodeling). Natural products
can also reduce the risk of wound infections by having antibacterial activity. However,
the bioavailability of the extracts and their metabolites may be limited, and a solution
to this problem is to integrate them into preparations such as hydrogels, nanoparticles,
nanofibers, and nanoemulsions. Research on the therapeutic properties of various
natural products and their integration into the formulations mentioned above for wound
regeneration is described below according to their effect on epithelialization,
regeneration of epidermal appendages, vascularization, and in some cases their
mechanism of action.
Antimicrobial Effect of Natural Products against Bacteria, Fungi, and Yeasts
Page: 137-164 (28)
Author: Mai M. Badr* and Israel Valencia Quiroz
DOI: 10.2174/9789815223163124090009
PDF Price: $15
Abstract
Antibiotics are compounds that either halt or destroy bacterial growth. They
may be natural, semi-synthetic, or synthetic. Secondary metabolites, such as those
produced by plants, animals, and microorganisms, are known as natural antimicrobials.
The antibacterial/antimicrobial properties of secondary metabolites have been
investigated over the past 30 years. Compounds derived from plants and culinary
seasonings, including essential oils (EOs), are widely utilized in the food industry as
organic agents to inhibit microbial growth in foods and prolong the shelf life of food
products. Animal peptides (i.e., polypeptides) also exhibit antimicrobial properties.
Certain pathogenic and decaying bacteria may be inhibited by various chemicals
produced by numerous microorganisms. Most microbially-derived antibacterial
compounds are produced as intermediate byproducts of food fermentation. Numerous
factors influence the antibacterial efficacy potential of natural products, including the
source of the biological agent, harvesting time, the stage at which it is cultivated, and
production methods.
Human Diseases and Recent Biotechnology Breakthroughs in Curbing Diseases
Page: 165-187 (23)
Author: Ana K. Villagómez-Guzmán* and Israel Valencia Quiroz
DOI: 10.2174/9789815223163124090010
PDF Price: $15
Abstract
Medical biotechnology represents a field in continuous progress and today
has revolutionized how illnesses are diagnosed and treated. A look at the latest medical
biotechnological breakthroughs shows how biotechnology innovations are changing
medicine. Recently, we saw how biotechnology affected efforts to combat the
coronavirus disease 2019 (COVID-19) pandemic on the world's health. The scientific
community has been working assiduously to develop effective treatments for the
prevention and management of other diseases, such as cancer, human
immunodeficiency virus (HIV), cardiovascular disease, diabetes mellitus, and
neurodegenerative disorders such as Alzheimer's disease, along with other dementia
variants that stand out among the leading causes of mortality worldwide. This effort
has recently resulted in the development of RNA vaccines. Some of the most promising
biotechnological developments include gene therapy to alter an individual's genetic
makeup through diverse techniques, immunotherapeutic methods that bolster the body's
natural immune defense mechanisms, and precision medicine strategies in which
treatment is personalized to a patient's genetic profile. This chapter provides an
overview of the most prevalent and deadly human diseases with a focus on recent
biotechnological breakthroughs.
Exploring the Intersection of Omics Technologies and Biotechnology in Drug Interaction Studies
Page: 188-203 (16)
Author: Israel Valencia Quiroz*
DOI: 10.2174/9789815223163124090011
PDF Price: $15
Abstract
The integration of omics tools with biotechnology has led to a paradigm
shift in our comprehension of drug interactions, providing profound insights into the
molecular mechanisms underlying these interactions. We explore the crucial functions
of genomes, transcriptomics, proteomics, and metabolomics in this chapter to decode
pharmacological interactions at various molecular levels. Notably, significant emphasis
is placed on the application of omics tools in areas such as high-throughput screening
for unveiling novel drug targets, personalized medicine, pharmacogenomics,
understanding drug-drug and drug-metabolite interactions, drug repurposing,
polypharmacology, and systems biology. Furthermore, the paper explores the potential
of integrating omics data with computational approaches to study complex biological
networks, highlighting the instrumental role of microbial biotechnology in drug
interactions. Importantly, alongside these advancements, there is also an in-depth
discussion of the ethical, legal, and societal ramifications of the use of omics
technologies in biotechnology. Moreover, the text presents an in-depth examination of
the emerging trends, challenges, and prospective developments in the realm of omics
research. As the field continues to evolve, overcoming challenges related to data
integration, reproducibility, and standardization are underscored as crucial for the
translation of these pioneering discoveries into improved patient care and the
development of more effective, personalized therapeutic strategies. It is crucial to
remember that the combination of omics tools and biotechnology will have significant
effects on how medicine and healthcare are delivered in the future. As a result, it is
essential to maintain research and development in this field to ensure that all future
healthcare-related exigencies can be met with the most advanced and innovative
solutions possible.
Sharing is Caring: Drug Repurposing among Leading Diseases
Page: 204-215 (12)
Author: Verónica García-Castillo, Eduardo López-Urrutia, Carlos Pérez-Plasencia and Adriana Montserrat Espinosa-González*
DOI: 10.2174/9789815223163124090012
PDF Price: $15
Abstract
The process of drug development is time-consuming and resource-intensive,
but drug repurposing offers an alternative by using already approved drugs to treat
different diseases. Drug repurposing candidates can be identified through
computational and experimental approaches, which are often combined. Traditionally,
drug repurposing is considered when developing a custom drug is not feasible, but
recent findings regarding the cross-talk between cellular mechanisms and pathways
that are altered among disease states suggest that multipurpose drugs may be the key to
simultaneously treating multiple diseases. This chapter reviews published reports on
drug repurposing for five of the most threatening diseases to human health today:
Alzheimer's disease, arthritis, diabetes mellitus, cancer, and COVID-19, highlighting
promising candidates, challenges, and potential future directions for research.
Subject Index
Page: 216-221 (6)
Author: Israel Valencia Quiroz
DOI: 10.2174/9789815223163124090013
PDF Price: $15
Introduction
Biotechnology and Drug Development for Targeting Human Diseases is an insightful compendium on drug development technologies for professionals and students in biotechnology and pharmacology. This book meticulously explores the intersection of biotechnology with drug development, emphasizing its crucial role in creating new therapies for human disease. Central to the book is the innovative use of biotechnology in understanding and treating diseases. It begins with an exploration of multi-omics profiles, shedding light on disease mechanisms and drug development. Subsequent chapters explain in silico methods for drug design, the role of natural products in antimicrobial applications and wound healing, and the use of viruses as carriers in biotechnology. Key features of this reference include a blend of theoretical knowledge and practical insights, detailed analyses of molecular docking in drug discovery, the repurposing of drugs for various diseases, and the emerging field of omics technologies in drug interaction studies. Each chapter is comprehensive, offering current information backed by extensive references, making the book both a foundational and advanced resource.