2^nd World Summit on Transcriptomics September 26-27, 2022 Singapore City, Singapore

Track 1: Transcriptomics

Transcriptomics is the field of biology that studies RNA transcripts on a large scale. The transcriptome is the set of RNAs transcribed by the genome from a specific tissue or cell type at a stage of development and/or in a certain physiological condition. RNAs are either coding or non-coding, which means that some RNAs code for proteins, while other types of RNAs do not. Specifically, mRNA is translated into proteins, while non-coding RNAs can be classified as housekeepers or as regulators. Housekeeping RNAs react as catalytic and structural elements. Regulatory RNAs can be short or long and act as regulatory elements during gene expression.

There are many ways to uncover the transcriptional response of the genome in different tissues and physiological or environmental conditions. Expressed sequence tag (EST, SAGE) based method, hybridization based gene microarray or gene array technology and NGS based RNA sequencing (RNA-seq) technology have been developed to quickly scan the transcriptome and obtain differentially expressed genes..

Track 2: Protein Biochemistry

biochemistry and enzymology encompass many areas of biology including molecular biology, cell biology, pharmaceutical research and development, food science, plant biology, etc. Applications include protein purification for research, manufacturing for biopharmaceutical development, molecular cloning, agriculture, and X-ray crystallography, among others. Tools and supplies for protein biochemistry include instruments such as mass spectrometers and chromatography systems, cloning, purification and enrichment kits, western blot systems and consumables. The tools needed for many protein biochemistry applications can be made "from scratch" or kits and other useful thing products can be used. Economy and time available are important considerations in choosing the right type of products. Proteins also vary greatly in size and profusion. The tools used to manipulate a large, very abundant protein will be different from those needed for very small, rare proteins.

Track 3:Epigenetics

Epigenetics is the study of how cells control gene activity without altering DNA sequence. "Epi-" means over or above in Greek, and "epigenetics" describes factors beyond the genetic code. Epigenetic changes are DNA modifications that regulate the activation or deactivation of genes. These modifications are attached to the DNA and do not change the sequence of the building blocks of DNA. In a cell's complete set of DNA (genome), all changes that regulate the activity (expression) of genes are known as the epigenome.

Track 4: Bioinformatics

Simply put, bioinformatics is the science of storing, retrieving, and analyzing large amounts of biological information. It is a highly multidisciplinary field involving many different types of specialists, including biologists, molecular life scientists, computer scientists, and mathematicians.

The term bioinformatics was coined by Paulien Hogeweg and Ben Hesper to describe "the study of trigonometric processes in anatomical systems" and it found early use when the first biological sequence data began to be shared. While the original analytical methods are still fundamental to many large-scale experiments in the molecular life sciences, today bioinformatics is seen as a much broader discipline, encompassing image modeling and analysis. in addition to the classical methods used for the comparison of linear sequences or three-dimensional structures.

Track 5: Metabolomics

Metabolomics is a collection of powerful tools for phenotype analysis, both by hypothesis generation and by hypothesis testing. Building on the strengths of “omics technologies that preceded it, proteomic uniquely includes analytical technologies that can provide characteristic models via fingerprinting, terrific dimension of targeted constructive metabolism via analysis of pool, the relative dimension of large portions of the metabolome using metabolite profiling, and the tracing of the biochemical fate of individual metabolites through a metabolic system via flux analysis. Each of these technologies is supported by the two most commonly used and powerful techniques currently available for biotransformation: mass chromatography and NMR.

Metabolomics techniques based on mass spectrometry are the most sensitive for the simultaneous analysis of a large number of compounds. Although limited in quantification capabilities without appropriate labeled standards, the amount of information available in a single LC-MS or GC-MS experiment can provide detailed insights into patterns of metabolite change throughout the metabolic network.

NMR metabolomics complements mass spectrometry. It is limited in terms of sensitivity, but is only able to elucidate molecular structure. An important additional characteristic of NMR is that it is quantitative, capable of providing absolute levels of detected compounds when appropriate techniques are used.

Interpretation and derivation of context from complex metabolomics datasets is very difficult and represents a major area of ​​research. Yet great strides are being made in integrating metabolome data with genomics and proteomics. Metabolomics offers the promise that in the future, biochemical analysis of the entire path from genotype to phenotype will be measured and explored for new insights in biology and medicine.

Track 6: Next Generation Sequencing(NGS) Technologies

Next-generation sequencing (NGS) is a term that broadly encompasses several related technologies that enable massively parallel or deep sequencing coverage for a selected region or the entire genome of an organism. Essential in the discipline of genomics-based research, sequencing technologies have been around for decades. However, continued advances in NGS or massively parallel DNA and RNA sequencing technologies have provided researchers with increased coverage of genome-wide sequencing and data analysis tools while rapidly reducing costs. The applications of NGS extend beyond whole genome analysis, as they have important implications for recent advances in basic genomics and disease research.

Track 7: Genome Sequencing

Genome sequencing (GS) covers the entire genome, including non-coding regions. Compared to ES, GS is generally PCR-free in the library preparation step, therefore is more uniform in its coverage and is better able to detect larger deletions or duplications (up to about 2 kb). The read depth for GS is lower (30–50×), so it is less susceptible to mosaicism. GS is also able to detect structural variations as well as repeated tandem expansions, if the appropriate software is used. Generally, the diagnostic rate of GS over ES is around 10-15% (Palmer et al., 2021), mainly due to the detection of structural variants and larger deletions and duplications.

Due to the large amount of variation in DNA sequences detectable by GS, data analysis and data storage are more difficult. Non-coding regions are also generally more variable than exon regions, complicating the difficulty. For this reason, it is even more important to include parental samples as comparators in GS.

Track 8: Transcriptome Analysis & Gene Expression

Transcriptome analysis experiments allow researchers to characterize transcriptional activity (coding and non-coding), focus on a subset of target genes and relevant substantiation, or profile thousands of genetic code at once to create an overall picture of cellular function. Gene expression analysis studies can provide actively expressed genes and transcripts under various conditions.

Next-generation sequencing (NGS) capabilities have shifted the scope of transcriptomics from interrogating a few genes at a time to profiling genome-wide gene expression levels in a single experiment. Learn how NGS-based RNA sequencing (RNA-Seq) compares to other common gene expression and transcript profiling methods, gene expression microarrays, and qRT-PCR. Learn how to analyze gene expression and identify novel transcripts using RNA-Seq.

Track 9: Single Cell Genomics

Molecular and cellular technologies have evolved into the era of single-cell genomics, which allows the simultaneous measurement of thousands of genes in thousands of "single" cells from a single specimen. . Advances in microfluidic and molecular cloning technologies have revolutionized our understanding of complex biological processes by improving resolution at the single cell level. Single-cell sequencing technology has also evolved over time, from processing dozens of cells simultaneously to millions of cells. New approaches to well-established models are being explored at the single-cell level in medical science, and new rare cell types are being reported, one after another.

The Human Cell Atlas (HCA) project represents an organized international collaborative effort to develop a comprehensive reference dataset covering all cell types in the human body1. The Functional Annotation of the Mammalian Genome (FANTOM)2 and Genotype-Tissue Expression (GTEx)3 consortia represent earlier global efforts to profile the transcriptomes of various human cell types. These public transcriptome data on several major organs can be used as a reference in biological studies, as they provide single-cell genomic data for mice and humans. In particular, the HCA introduced the concept of modification and equity in data collection and analysis, thereby promoting single-cell genomics. Ando et al. discussed the introduction of single-cell genomic consortia that consider regional environments to develop the universal reference dataset of human cells4.

Track 10: Gene Expression Profiling

Gene expression profiling measures which genes are expressed in a cell at a given time. This method can measure thousands of genes at once; some experiments can measure the whole genome at once. Gene expression profiling measures mRNA levels, showing the pattern of genes expressed by a cell at the transcriptional level. This often means measuring relative amounts of mRNA under two or more experimental conditions and then evaluating which conditions resulted in the expression of specific genes.

Gene expression profiling is used by a variety of biomedical researchers, from molecular ecologist to environmental genotoxicity . This technology can provide precise information about gene expression, towards countless experimental goals.

Different techniques are used to determine gene expression. These include DNA chips and sequencing technologies. The first measures the activity of specific genes of interest and the second allows researchers to determine all active genes in a cell.

Once a genome has been sequenced, we know the potential of a cell - what its characteristics and function are - based on the genes it contains. However, genome sequencing does not tell us which genes a cell is expressing, or what functions or processes it is performing at any given time. To determine them, we need to determine its gene expression profile. If a gene is used to make mRNA, it is considered "turned on"; if it is not used to make mRNA, it is considered "inactivated".

A gene expression profile tells us how a cell is operating at a specific time. Indeed, the expression of cellular genes is influenced by external and internal stimuli, including whether the cell is dividing, what factors are present in the cell's environment, the signals it receives from other cells and even the time of day.

Track 11: Biostatistics & Systems biology

Biostatistics and computational biology involve the development and application of data-analytical and theoretical methods, mathematical modeling techniques, and computer simulation for the study of biological, behavioral, and social systems. Biostatics and computational biology consist of expertise in the mathematical sciences applied to biology, including statistics, probability, biomathematics, and computer science. His interdisciplinary research provides expert advice on experimental design, analysis of large-scale datasets, data collection, data warehousing, data integration, causal inference, data design. clinical trials, longitudinal data analysis, modeling and analysis of data derived from biological and social networks.

Track 12: Transcriptome Analysis & Gene Expression

A review of the transcriptome and gene expression review is the first and most fundamental of the points to address. While going in and out of the topic, it is important to understand the transcriptome as key players in gene expression. For this, we need to know the basics of learning how the focal doctrine works. This can be accomplished by increasing legitimate information about how mRNA, tRNA, and rRNA work. Investigative analyzes of quality expression can focus on a subset of relevant target qualities. The quality zone and the relative separations between qualities on a chromosome can be resolved through sequence mapping. Indeed, even without the reference genome, the transcriptome can be made using again the transcriptome joining technique. All around, a large number of universities and foundations transmit research on gene expression and investigation of the transcriptome. University of Leeds, Case Western Reserve University, Arizona State University, Tempe are among them. Foundations like The Genome Institute - St. Louis, Missouri and NIH - National Human Genome Research Institute are working hard towards a similar approach where scientists have a database of over 40,000 quality successions that they can use to this reason.

Track 13: Micro array                                                                                       

The DNA chip is one of the most recent advances used in cancer research; it provides assistance in the pharmacological approach to treat various diseases including oral lesions. Microarray helps to analyze a large amount of samples that have been recorded previously or new samples; it even helps to test the incidence of a particular marker in tumors. Until recently, the use of DNA chips in dentistry was very limited, but in the future, as the technology becomes affordable, its use may increase. Here we discuss the different techniques and applications of microarrays.

Track 14: RNA Sequencing

RNA-seq (RNA sequencing) is a technique to examine the amount and sequences of RNA in a sample using next-generation sequencing (NGS). It analyzes the transcriptome, indicating which of the genes encoded in our DNA are turned on or off and to what extent. Here we look at why RNA-seq is useful, how the technique works, and the basic protocol commonly used today.

Track 15: Protein Synthesis

Proteins are large molecules that can perform many different tasks. They can facilitate chemical reactions (eg enzymes), provide structural support (eg cytoskeleton), transmit signals from the cell surface (eg membrane receptors) and much more. But where do they come from?

The genes in our DNA are similar to the recipes used to make proteins. But since the recipes are coded using potassium-nitrate bases (ATCG), they must first be translated. Many proteins work together on this translation task. The strands of the DNA double helix must first give way for the targeted gene to be accessible. The proteins then produce an identical copy of the targeted DNA sequence: a messenger RNA.

This copy of the recipe, now transcribed as messenger RNA, is then sent outside the cell nucleus since proteins are made elsewhere in the cell. From there, the ribosomes, small particles present in large numbers around the nucleus, will serve as leaders by reading the recipe to make the protein. Amino acids are the basic ingredients that go into the protein recipe and ribosomes use the blueprint provided by messenger RNA to put amino acids in the correct order and form a long chain. But proteins in this linear form are not yet ready. To function, it must fold back on itself in an origami fashion. It is then that it changes from a single chain to a complex three-dimensional structure.

Market Analysis

Global Transcriptomics Market, By Product & Services (Instruments, Consumables, Software, Services), Technology (DNA Microarray, Real-Time PCR (qPCR), Sequencing), Application (Disease Diagnosis & Profiling, Drug Discovery and Others) ), end-user (Pharmaceutical and biotechnology companies, government institutes and academic centers, contract research organizations (CROs)) and countries (United States, Canada, Mexico, Germany, Italy, United Kingdom, France, Spain, Netherlands- Bas, Belgium, Switzerland, Turkey, Russia, Rest of Europe, Japan, China, India, South Korea, Australia, Singapore, Malaysia, Thailand, Indonesia, Philippines, Rest of Asia-Pacific, Brazil, Argentina, Rest of South America, South Africa, Saudi Arabia, United Arab Emirates, Egypt, Israel, Rest of Middle East and Africa) Industry Trends and Forecasts to 2028

Market Analysis insight

                   The Transcriptomics Market is expected to witness market growth at a rate of 9.68% during the forecast period from 2021 to 2028. The Data Bridge Market Research report on the Transcriptomics Market provides analysis and insights on the various factors that are expected to prevail throughout the forecast period while providing their impacts on market growth. The boom in biomedical research is accelerating the growth of the transcriptomics market.

Transcriptomics can be referred to as the study of the complete set of RNA transcripts formed by the genome of any organism. Transcriptomics includes the assortment and exploration of transcriptomes and finds varied applications, primarily in molecular genetics.

The major factors that are expected to drive the growth of the transcriptomics market over the forecast period are increasing need for personalized medicine. Additionally, rising pharmaceutical and biotechnology research and development expenditures and government investments are expected to further propel the growth of the transcriptomics market. Additionally, increasing applications of RNA sequencing in transcriptomics are further estimated to dampen the growth of the transcriptomics market. On the other hand, increasing capital investment is expected to further hamper the growth of the transcriptomics market over the period.

PRESENTATION REQUIREMENTS:

Participating authors are answerable for registration, travel, and hotel costs. Note: Those with submitted abstracts will get an acknowledgment mail enabling them to enroll for the gathering.

Abstracts will be compiled, and conference books are made available to participants at the conference.

Any presenter who is unable to attend should arrange for another qualified individual to present the paper/poster in question. If such a change is necessary, please notify our conference team

SUBMISSION OPTIONS:

Oral paper introductions will have 30-minute schedule time slot. The keynote session will have for 45-minute presentation duration, workshop/special session will have 1-hour long schedule opening and symposium will have 1-hour long availability followed by 5-minute Q&A session.

Graduate and master’s understudies are qualified to present their abstracts under poster and e-poster presentation category.

Ph.D. understudies are qualified to submit their abstract under special YRF (Young Researcher's Forum), poster and e-poster presentation category.

NOTE: YRF category includes short oral presentation especially for Ph. D. students

Extended abstract: Submissions should utilize the Abstract Template. Papers submitted in this category may represent original empirical research, theoretical development, reviews, or critiques.

 

PARTICIPATION OPTIONS: Physiotherapy Conference provides the participants with different modes or ways to participate such as Delegate or Speaker under either  ACADEMIC / STUDENT / BUSINESS Category. Mode of participation is Online through Power Point Presentation/ Video Presentation on Cisco Webinars.

Keynote speaker: 45-50 minutes

Speaker (oral presentation): 25-30 minutes (only one person can present)

Speaker (workshop): 45-50 minutes (more than 1 can present)

Speaker (special session): 45-50 minutes (more than 1 can present)

Speaker (symposium): more than 45 minutes (more than 1 can present)

Delegate(only registration): will have access to all the sessions with all the benefits of registration

Poster presenter:  can present a poster and enjoy the benefits of delegate

Remote attendance:  can participate via video presentation or e-poster presentation

Exhibitor: can exhibit his/her company’s products by booking exhibitor booths of different sizes

Media partner

Sponsor

Collaborator

For more details about each mode, kindly contact: https://transcriptome.conferenceseries.com/

Benefits of Joining Conference :

• Get your abstract published with DOI
• Get Certified for your participation
• Reduced Costs Affordability
• Knock Down Geographical Barriers
• Convenience from comfort of your own home or from work
• They’re Archived: Ability to view events in the recording
• Great resource for learning new career skills
• Learn from the Pros
• Global exposure to your research
• Make new connections
• Significant time saving
• Increased engagement
• Wider Reach
• More Engaging
• Position yourself as the expert
• Get your abstracts published with unique DOI in International Journals
• Get up to 50% discounts for publishing your entire article in our open access International Journals
• Get Handbooks and conference kits
• Get an access to the network with eminent personalities from worldwide.