Various genetic or epigenetic changes cause autoimmune disorders, infectious
diseases, transplantation, and even cancer by DNA methylation and altered miRNA
expression. Mutated epigenetic regulators, such as histone acetylation and methyla-
tion, are the most impaired epigenetic pathways in cancer. These abnormal epige-
netic modifications in cancer have been revealed by sequencing chromatin
modifications with deep sequencing technologies. Scientists are focusing on devel-
oping personalized drugs using “omics technologies.” Appropriate biomarkers are
needed to carry out specific therapies with each patient. Scientists are highly
optimistic about “omics-based” healthcare interventions because knowledge in the
fields of genomics and transcriptomics as well as understanding of the potentials of
modified proteomes has grown significantly. Some of the essential biomarkers, such
as altered gene expression signatures, germline or somatic gene variations (i.e.,
polymorphisms, mutations), chromosomal defects, and chosen protein biomarkers,
functional disorders with a genetic etiology, are used to select therapies for patients;
which are linked to pharmacogenomic knowledge available in medication labeling
(Chow 2017). New advancements in proteomics have the potential not only to
improve health outcomes but also to reduce the expense of therapies (Matthews
et al. 2016; Aravanis et al. 2017; Quezada et al. 2017). One such technique is liquid
biopsy, which involves collecting and analyzing molecules from body fluid, such as
urine, sweat, whole blood, serum, and plasma. A large number of biomarkers, such
as circulating tumor cells (CTC); circulating tumor proteins; cell-free DNA
(cf-DNA); cell-free RNA (cf-RNA), including microRNAs (miRNAs); and extra-
cellular vesicles, especially exosomes, have been identified as circulating molecules.
These biomarkers effectively recognize the very early stages of cancer, preneoplastic
disorders, etc., demonstrating their practical necessity for patient survival
(Moutinho-Ribeiro et al. 2019) (Fig. 1.1).
1.5
Speedy Drug Discovery with Artificial Intelligence
(AI) and Machine Learning
Artificial intelligence is widely used in the drug discovery process due to its many
capabilities. AI will gather and interpret biomedicine knowledge quite effectively to
adopt patient-driven biology and accumulate data for deriving more predictive
hypotheses. It helps in the development of novel patient-specific drugs by specifi-
cally identifying and validating drug targets. It may also be used to repurpose
medications, thus increasing research and development quality (R&D). Artificial
intelligence is being used to track down drug targets and therapies for disorders such
as Parkinson’s disease and diabetes. It can solve both simple and complicated
problems by learning from its past solutions and personified experience. As a result,
advances in AI technology, along with dramatically increased computational
resources, are revolutionizing the drug discovery process (Fleming 2018; Mak and
Pichika 2019).
1
Emerging Technologies: Gateway to Understand Molecular Insight of. . .
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