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International Conference on Cell Biology and Genomics , will be organized around the theme “Engineering Biomolecules for Advancement of Drug Discovery and Molecular Therapeutics”
Cell Biology 2019 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Cell Biology 2019
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The cell is the basic structural, biological and functional unit of all known living organisms and it is the smallest unit of life. Cells are the study of building blocks of life .The human body is collected of trillions of cells they provide structure for the body take in nutrients from food transform those nutrients into energy, and carry out specialized functions. The cells die through infection, poisoning, overheating or lack of oxygen. Immunology is the important in medical and biological sciences also it protects us from infection through various lines of defence. As it should, it is not a functioning of immune system and it can result in diseases such as autoimmunity, cancer and allergy. When health conditions aggravate to emergency status, portions of immune system organs including the thymus, spleen, bone marrow, lymph nodes and other lymphatic tissues can be surgically excised for consideration while patients are still alive.
- Track 1-1Stem Cell and Immunology
- Track 1-2Gene regulation in Immune Cells
- Track 1-3Cell Death and Immune response
- Track 1-4Transplant Immunology
- Track 1-5Immunological Disorders
- Track 1-6Innate Immune Cell
- Track 1-7Lymphocytes and Mucosal Immunology
Cell Signaling is part of any communication process that governs coordinates all cell and basic activities of cells actions. The ability of cells to perceive and correctly respond to their microenvironment is the basis of development, immunity and tissue repair as well as normal tissue homeostasis. On studying individual parts of cell signaling pathways has focused on Traditional Work. Systems biology research helps us to understand the underlying structure of cell signaling networks and how changes in these networks may affect the flow and transmission of information. Modelling and Simulations analysis of cell signaling networks requires a combination of experimental and theoretical approaches including the analysis and development. There are two types of metabolic pathways that are characterized by their ability to either break down of complex molecule biology by releasing energy in the process or structure of molecules with the utilization of energy. The Energy is released from two pathways complement each other in that from one is used up by the other.
- Track 2-1Signal Transduction
- Track 2-2Cell signalling in Multicellular Organisms
- Track 2-3Signalling Pathways
- Track 2-4Cancer Cell Metabolism
- Track 2-5Interspecies and Intraspecies signalling
- Track 2-6Cellular Respiration
- Track 2-7Cell Origins and Metabolism
Selective barrier and it allows some things to pass through but stops others such things may be molecules, ions, or other small particles are called Membrane. The uses of Membrane covers all engineering approaches for with the help of permeable membranes the transport of substances between two fractions. In prevalent, mechanical separation processes for separating gaseous or liquid streams use membrane technology. There are four types of membrane filtration process classifications are Microfiltration, Ultrafiltration, Nanofiltration and Reverseosmosis. Membrane biochemistry processes cover a group of separation processes in which the characteristics of a membrane (porosity, selectivity, electric charge) are used to separate the components of a suspension or a solution. In these processes the feed stream is split into two, the fraction that permeates through the membrane called the Permeate and the fraction containing the components that have not been transported through the membrane usually called the Retentate.The size of the components to be separated and magnitude and the nature of the driving force provide criteria for a classification of the membrane separation processes. It should be noted that the boundaries between some of the processes, such as Ultrafiltration and Reverse osmosis are arbitrary.
- Track 3-1Membrane shapes and flow geometries
- Track 3-2Photosynthetic Chromatophore
- Track 3-3Membrane Separation Processes
- Track 3-4Mass transfer and configuration
- Track 3-5Fouling Control and Mitigation
- Track 3-6Pore size and Selectivity
Cell physiology is the biological study regarding the activities that take place in a cell to keep it alive. This comprise among animal cells, microorganisms and plant cells .The term physiology mention to all the normal functions that take place in a living organism. The function of Cell Physiology is Organ-systems are group of cells, tissues and organs, which have dedicated functions in the body. Biochemistry is the study of chemical processes within connection to living organisms. It was divided in three fields biochemical metabolism, Proteins and molecular genetics. Biochemistry focuses on understanding how biological molecules give rise to the processes that occur within living between cells and cells which in turn relates greatly to the understanding and study of tissues, organisms, organ structure and function. Foundations of cell physiology are animals, cells, plants, viruses and microorganisms.
- Track 4-1Fermentation and Respiration
- Track 4-2Physiological Process
- Track 4-3General characteristics of Cell Physiology
- Track 4-4Metabolism and Biomolecules
- Track 4-5Cell Interaction and Communication
- Track 4-6Proteins of Actin and Myosin
The cell differentiation or cell cycle is the sequence of events that take place in a cell leading to its duplication and division of its DNA (DNA replication) to produce two daughter cells. It plays an important part in the growth of embryos, and for the development and growth of our bodies as well. Mitosis produces new cells, and replaces cells that are old, damaged or lost and in mitosis a cell divides to form two identical daughter cells. Cytogenetics is a branch of gene technology that is concerned with how the chromosomes relate to cell behaviour, particularly to their behaviour during meiosis and mitosis. Quinacrine banding was the first marking method used to produce specific banding patterns. This method requires a fluorescence microscope and is no anymore as widely used as Giemsa banding .The Causes of cell sorting is cancer by accelerating cell division rates or prevent normal controls on the system, such as cell cycle programmed cell death or arrest.
- Track 5-1Intermitosis and Quiescence
- Track 5-2Regulation of Eukaryotic Cell cycle
- Track 5-3Molecular Cytogenetics
- Track 5-4DNA replication and Origin Activity
- Track 5-5Inhibitors and Transcriptional Regulatory network
- Track 5-6Future of Cytogenetics and Techniques
- Track 5-7Human Abnormalities and Medical Applications
Human genomics is the study of provision as it occurs in human beings. The Human genome is the total set of nucleic acid sequences for humans, encoded as DNA within the 23 chromosome couple in cell nuclei and in a small DNA molecule found within own mitochondria. Human genomes involve both protein-coding DNA genes and noncoding DNA. Human genetics encompasses a differently of overlapping fields including classical genetics , cytogenetic, molecular genetics, biochemical genetics, genomics, developmental genetics, genetic counselling and clinical Ethic genetics. Human genetic variation is the genetic differences in whole populations, there may be multiple variants of any given gene in the human population, a situation called polymorphism. No two humans are genetically identical, even monozygotic twins having infrequent genetic differences due to mutations occurring during improvement and gene copy-number variation.
- Track 6-1Molecular organization and gene content
- Track 6-2Coding sequences (protein-coding genes)
- Track 6-3Coding vs. Noncoding DNA
- Track 6-4Genomic variation in humans
- Track 6-5Human genetic disorders
- Track 6-6Human mitochondrial DNA Haplogroups
- Track 6-7Genetic Recombination
Molecular and cell biology is a branch of biology that reads the function and structure of the cell, which is the basic unit of life. It concerned with the physiological properties and metabolic engineering.Its activity of biomolecules in the different systems of a cell, including the interactions between DNA, RNA, and proteins their biosynthesis, as well as the regulation of these interactions. Knowing the components of cells and how cells work is basic to all biological sciences, it is also essential for research in bio-medical fields such as cancer and other diseases. Research in cell biology is closely related to genetics, biochemistry, molecular, cytochemistry, biology and immunology. The techniques of molecular cell biology are Cloning, Polymerase chain reaction, Gel electrophoresis, Microarray, Allele-specific oligonucleotides.
- Track 7-1Macromolecule Blotting and Probing
- Track 7-2Microarrays and Cell Structure
- Track 7-3Polymerase Chain Reaction
- Track 7-4Molecular Cloning and Gel Electrophoresis
Cancer genomics is the study of the entirety of gene expression and DNA Sequence differences between normal host cell and tumour cells. It's the promise of precision cancer treatment a focus on the independent tumor in the individual patient. Cancers types are including breast cancer, ovarian, colorectal, and prostate cancer as well as some other, less common, rarely certain types of cancer can be passed down through generations and environment. The symptoms of cancer may become depressed and anxious post diagnosis the risk of suicide in people with cancer is a roughly double.
- Track 8-1Incidentations and Limitations
- Track 8-2Radiation, Physical agents, Autoimmune Diseases
- Track 8-3Gene expression and Change
- Track 8-4Diet, Medication and Vaccination
- Track 8-5Prognosis and Epidemiology
- Track 8-6DNA and Chromosomes
- Track 8-7Hereditary Cancer Syndromes
Epigenetics is the study of changes in organisms caused by modification of gene expression rather than alteration of genetic codes as heritable phenotype it does not involve alterations in the DNA sequence. We produce steroid hormones called glucocorticoids that affect many systems throughout the body in during stress, behaviour, physical activity, alcohol and smoking in situations. Metagenomics is a single pass tyrosine kinase receptor essential for embryonic development, organogenesis and wound healing ,it is the genetic mutations recovered directly from environmental samples .It most often indicates changes that affect gene activity and expression but can also be used to narrate any heritable phenotypic change. Such effects on physiological and cellular phenotypic traits may result from external or environmental factors.
- Track 9-1DNA Methylation
- Track 9-2Transgenerational Epigenetics
- Track 9-3Shotgun and Comparative Metagenomics
- Track 9-4Behaviour and Computational Epigenetics
- Track 9-5Gene prediction and Species Diversity
The transcriptome is the set of all molecules of RNA analysis in one population of cells or a one cells, it is used and also sometimes refers to all RNA depending on the particular experiment. Proteins are the large scale of the Proteomics and those vital parts of living organisms with many functions. The proteome is the entire set of proteins that are modified or produced by an organism or system. Proteomic technology generally refers to the large-scale experimental analysis of proteins and proteomes but is often specifically used to refer to protein mass spectrometry and purification. The proteome is the entire set of proteins that are modified or produced by an organism or system and proteomics has enabled the identification of ever increasing numbers of protein.
- Track 10-1Hybrid technologies and Contributors
- Track 10-2Protein Separations and Centrifugation
- Track 10-3Emerging and Miscellaneous Proteomics Technologies
- Track 10-4Transcriptomics Technologies
- Track 10-5Mass Spectrometry for Proteins and Peptides
- Track 10-6Bioinformatics for Proteomics
Structural biology is a branch of biophysics, molecular system biology and biochemistry concerned with the molecular biological macromolecules. Structural biology is important for carbohydrates, proteins and nucleic acids, structure and function are related in biological science because of a certain structure a living thing make contain and the object function the way it does. The bonding of a function and structure is structuring levels from molecules to organism ensure successful functioning in all living organism and living system. Many Researchers lack the background to fully utilize the property of solved three-dimensional biology of immune system.
- Track 11-1Structural Databases of Biological Macromolecules
- Track 11-2Philosophy of Biological Classification
- Track 11-3Mass spectrometry and Proteolysis
- Track 11-4Ultrafast laser spectroscopy
- Track 11-5Macromolecular crystallography
- Track 11-6Biological stoichiometry
Calcium is a mineral that is important for life, In addition to construction bones and keeping them healthy, calcium authorize our blood to clot, our muscles to contract and our heart to beat. About 99% of the calcium in our bodies is in our bones and teeth, when calcium is too low level may result from a problem with the parathyroid glands and cell culture, as well as from diet certain drugs or kidney disorders. Cell Functions are Toxic substances, contain receptors and channels that allow specific molecules, such as ions, nutrients, metabolic disorder and wastes products also nutrients and energy. The common cause of cell death is deficiency of oxygen and Hypoxia is an extremely important.
- Track 12-1Role of Calcium in Meiosis and Photosynthesis
- Track 12-2Dependent Proteinase of Human Erythrocytes
- Track 12-3Peptides as Useful Calmodulin Antagonists
- Track 12-4Geochemical Cycling
- Track 12-5Biological and Pathological role
- Track 12-6Food and Metallic Calcium
Structural genomics seeks to report the 3-dimensional structure of every protein encoded by a given genomics. This genome-based nearer to allows for a high-throughput method of structure determination by a compound of modelling and experimental approaches. Functional genomics is a field of Structural molecular biology that attempts to make use of the vast wealth of data given by genomic and transcriptomic to describe gene interaction and functions. Unlike structural genomics, functional genomics focuses on the dynamic aspects such as gene transcription, translation, protein–protein interactions and regulation of gene expression, as opposed to the static feature of the genomic information such as DNA structures or sequence.
- Track 13-1Molecular Enzymology and Immunology
- Track 13-2Threading and Modelling of Genomics
- Track 13-3Genome Annotation
Glycobiology is the study of the structure, biology and biosynthesis of saccharides that are widely distributed in nature. Saccharides or sugars are essential components of all living things and aspects of the different roles they play in biology are researched in various medical, biotechnological and biomedical fields. Microbial is the ecology protection of microorganisms their state of being connected with one another and with their environment. It concerns the three major domains of life Eukaryota, Bacteria and Archaea as well as viruses. As a consequence of microbial genetics the relating to magnitude of microbial life microbes, by virtue of their biomass alone, constitute a significant carbon sink, Aside from carbon fixation, microorganisms key collective metabolic control global biochemical cycling.
- Track 15-1Bacterial Cell Envelop Peptidoglycan
- Track 15-2Applications of Genomics
- Track 15-3Metabolic and Covalent labelling of Glycan’s
- Track 15-4Microbial Resource Management
- Track 15-5Microtechnological and Medical Applications
- Track 15-6Pathogenesis and Bacterial Polysaccharides
Yeast artificial chromosomes are beginning to engineered chromosomes obtain from the DNA of the yeast and Saccharomyces cerevisiae which is then ligated into a bacterial plasmid. By placing large fragments based drug design of DNA and sequences can be cloned and physically survey using a process called chromosome walking. This is the procedure that was initially used for the Human Genetics, however due to stability issues, YACs were deserted for the use of Bacterial artificial chromosomes. The main components of a YAC are the ARS, telomeres and centromere from Saccharomyces cerevisiae. Additionally, selectable target genomics such as antibiotic resistance and a visible marker are utilized to select change yeast cells.
- Track 16-1Bacterial artificial chromosome
- Track 16-2Autonomously replicating sequence(ARS)
- Track 16-3Cosmid and Phasmid
- Track 16-4Cloning Vector in Chromosome
- Track 16-5Human artificial chromosome
- Track 16-6Shuttle plasmid and Fosmid in YAC
Biological cells are called Stem cells that can differentiate into other types of cells and can divide to produce more of the same type of stem cells .They are past participle in multicellular organisms., it consists of more than one cell in contrast to unicellular organisms. Tissue culture engineering is the use of a combination of cells, materials and engineering methods and suitable biochemical and physicochemical factors to become better or replace biological tissues. Tissue engineering involves the use of a tissue scaffold for the being formed of new viable tissue for a medical purpose. While it was once categorized as a sub-field of biomaterials, having grown in importance and scope it can be considered as a field in its own. Bone marrow has been used to treat people with cancer and with conditions such as leukaemia and lymphoma, this is the only form of stem-cell therapy that is widely repeated.
- Track 17-1Assembly methods and Scaffolding
- Track 17-2Totipotent, Pluripotent Stem cells
- Track 17-3Tissue culture and Bioartificial Organs
- Track 17-4Embryonic, Fetal and Induced pluripotent
- Track 17-5Lultipotent, Oligopotent and Unipotent Stem Cells
- Track 17-6Stem cell Preservation and Biobanks
- Track 17-7Translation Opportunities in Stem Cell Research
- Track 17-8Clinical Applications of Stem Cells
Gene expression is the operation by which information from a genome biology is used in the synthesis of a functional gene product. These products are often proteins, but in non-protein coding gene such as move from one place to RNA or small nuclear RNA genes, the product is a functional RNA. The procedure of gene synthesis expression is used by all known life eukaryotes prokaryotes and utilized by viruses to generate the macromolecular machinery for life. Several steps in the gene technology expression process may be modulated, including the transcription, RNA splicing, post-translational and translation modification of a protein. A gene mutation is a permanent alteration in the DNA sequence that makes up a gene, such that the sequence various from what is found in most people. Mutations range in size they can make a difference to anywhere from a single DNA building block to a large segment of a chromosome that includes multiple genes.
- Track 18-1Expression system and Measurement
- Track 18-2Regulation of Gene Expression
- Track 18-3Mechanism and Transcription
- Track 18-4Epigenetics in Bacteria
- Track 18-5Gene Networks and Mechanisms
- Track 18-6Three Prime translated regions and MicroRNAs
Plant biology is the study of genes, heredity and genetic variation specifically in Plants. These observed that organisms that cause infectious disease include plants and fungi, oomycetes, bacteria, viruses, viroid’s, virus-like organisms, phytoplasmas, protozoa, parasitic plants and nematodes inherit traits by way of discrete units of inheritance and this term still used today is a somewhat ambivalent. A plant phylogenetics gathering represents the complete plant genetics sequence of a plant species, which is gathered into chromosomes and other organelles by using DNA fragments that are obtained from various types of sequencing technology. Plants like all other known living organisms move on their traits using DNA and however are same from other living organisms in the fact that they have Chloroplasts.
- Track 19-1Modern ways to Genetically Modify Plants
- Track 19-2Genome analysis and DNA
- Track 19-3Genetically Modified Crops
- Track 19-4Diversity and Plant Specific Genetics
- Track 19-5Signals, Regulators and Plant Disease
- Track 19-6Structure, Growth and Development
- Track 19-7Applications of Genomics
Animal cells are representative of the eukaryotic cell, enclosed by a plasma membrane and containing a membrane-bound nucleus and organelles and different from the eukaryotic cells of plants and fungi, animal cells do not have a cell wall. Microbial genetics Interaction between various microorganisms and include both positive and negative interaction, also it is an assemblage of species living close enough for potential interactions and within a community different consortia may be found. The various types of microbes in an interaction are identified and characterized by several methods. Interaction may change over time, Bioleaching and waste water treatment plants are non-sterile environments. Therefore various types of microorganisms will live common in a community, the interactions between the microbes matter much for the outcome of the processes.
- Track 20-1Nuclear Envelope and Pores
- Track 20-2Ribosomes and Cilia
- Track 20-3Bioinformatics and computational biology
- Track 20-4Microbial Ecology and symbiosis
- Track 20-5Altruism and Mutualism
- Track 20-6Molecular Ecology and Methanotrophy
The Single cell biology is also called as a unicellular organism. It is the study of the function and structure of the cell. Single cell organisms are composed and microscopic of a single cell gene expression, unlike multicellular organisms that are made of many cells. They can carry and live out all of their life processes as one single cell. All prokaryotes, some fungi and most protists are unicellular. Some of these organisms do live in large colonies, but every individual dendrites cell biology is a simple living organism. Let's look at some examples of unicellular organisms. Valonia ventricosa is a protist, Transcriptomics and their Techniques.
- Track 22-1Single-cell Sequencing
- Track 22-2Metabolomics of Techniques and Purpose
- Track 22-3Single-cell thunderstorm and Orchestra
- Track 22-4Mass spectroscopy–based methods
- Track 22-5Single cell Analysis and Isolation
- Track 22-6Cell Migration, Growth and Polarity
- Track 22-7Cellular Imaging
Clinical pharmacology is the science of drugs and their clinical use also it is underpinned by the main science of pharmacology with an added focus on the application of pharmacological principles and quantitative methods in the real world, therefore clinical pharmacology is not specific to medicine. The purpose of pharmacogenitics analyses how the genetic makeup of an individual effects on human response to drugs. Pharmacogenomics aims to improve rational means to optimize drug therapy, with regard to the patient’s genotype to ensure maximum efficiency with minimal adverse effects.
- Track 23-1Cardiovascular Diseases and Drugs
- Track 23-2Personalized Vaccines and Immunity
- Track 23-3Drug Labeling and Controversies
- Track 23-4Ethical, Legal and Social Implications
- Track 23-5Small Molecules for Future Medicine
- Track 23-6Heredatory and Neurodegenerative Disorders
- Track 23-7Cancer Chemotherapy and personalized medicine
Population genetics is the study of the changes and distribution of allele frequency in a population, as the population health is subject to the four main evolutionary processes: natural selection, genetic drift, gene flow and mutation. Population genomics is a subfield of genetics that deals with genetic various within and between populations is a part of evolutionary biology. Population genetic models are used couple for statistical inference from DNA sequence data. Human evolutionary genetics refers how one human genome differs from another human genome, the evolutionary past that gave rise to it, and its current effects. Differences between genomes have anthropological, historical, forensic implications, applications and medical. Genetic data can provide mainly insight into human evolution.
- Track 24-1Evolution of genetic systems
- Track 24-2Gene inversion potentiates bacterial Evolvability and Virulence
- Track 24-3Neutral theory and origin-fixation Dynamics
- Track 24-4Proteome Evolution under Non-Substitutable Resource Limitation
- Track 24-5Causes of Evolvability and Evolution
- Track 24-6Pseudogenes and Mutations, Cladistics
The transcriptome is the set of all RNA molecular biology in a population of cells or one cell. It vary from the exome in that it includes only those RNA molecules found in a specified cell population, and usually covers the amount or concentration of each RNA molecule in addition to the molecular identities. Transcriptome techniques comprise DNA microarrays and next-generation sequencing technologies called RNA-Seq, transcription can also be studied at the level of individual cells by single-cell transcriptome. One of the most primary techniques of molecular biology to study protein function is molecular cloning. In this technique, DNA coding for a protein of heed is cloned using polymerase chain reaction (PCR), and restriction enzymes into a plasmid.
- Track 25-1Macromolecule blotting and probing
- Track 25-2Bacterial Transcriptome
- Track 25-3Relationship to other biological sciences
- Track 25-4Techniques of Molecular Biology
- Track 25-5Transcriptomics Technologies
- Track 25-6Construction and methods of Transcriptomics
- Track 25-7Microarrays, Gene therapy and functional Genomics
Molecular biology techniques are familiar methods used in molecular biology, biochemistry, genetics and biophysics which mostly involve manipulation and analysis of DNA, RNA, protein, and lipid. One of the main basic techniques of molecular biology to study protein function is molecular cloning and in this technique, DNA coding for a protein of interest is cloned using polymerase chain reaction the level of molecular is very smallest units that make up organisms or elements and tests done by sample of blood, hair, skin, amniotic fluid or other tissue. Gene amplification is a methodology in which a certain gene or DNA sequence is replicated many times in a process called DNA.
- Track 26-1DNA directed RNA polymerase
- Track 26-2DNA Replication and Cell Division
- Track 26-3Eukaryotic RNA polymerases and Transcription
- Track 26-4Denaturation and Hybridization
- Track 26-5Polymerase Chain Reaction
- Track 26-6Molecular cloning
Genomic Medicine is also known as personalized medicine, and it is a way to customize medical care to your body's common genetic makeup. Each of the cells in the body contains DNA, the molecules, you receive from your parents that determine how your body looks and functions. Each and every one responds to stress and the environment differently and they also respond to disease and to treatments differently. Although greater than 99% of a DNA sequence is identical from one person to another person, the last 1% helps to describe these differences. Various people may have small variations in specific gene expression, and some people may have genes that others don’t. These may develop susceptibility to a specific disease or provide protection from that illness. Scientists continue to discover new ways that subtle gene flow various cause large differences in health, this understanding can lead to better ways to prevent, diagnose, and treat many types of health conditions.
- Track 27-1Genetic Counselling
- Track 27-2Genetic Testing and Discrimination
- Track 27-3Drug Development and Usage
- Track 27-4Cancer Genomics
- Track 27-5Respiratory Proteomics
- Track 27-6Assessment of Disease Risk
Recombinant DNA technology, relate together of DNA molecules from two various species that are inserted into a host organism to produce new genetic combinations that are of value to science, medicine, agriculture, and industry. The Processes of Recombinant gene DNA Technology is joining DNA molecules from two different interesting and sources them into a host organism, to generate products for human use. The applications of health and nutrition, in medicine it is used to create pharmaceutical products such as human insulin and In agriculture it is used to impart approving characteristics to plant to increase their yield and improve nutritional content of Recombinant DNA technology.
- Track 28-1Production of clotting factors and insulin
- Track 28-2Creation of Recombinant DNA with DNA ligase
- Track 28-3Selection of organisms containing vector sequences
- Track 28-4Production of recombinant pharmaceuticals
- Track 28-5DNA-Binding Proteins
- Track 28-6Recombinant Virus
- Track 28-7Germ line and Somatic Gene Therapy
Next Generation Sequencing is used to rule the primary structure of an unbranched biopolymer it results in a symbolic linear depiction known as a sequence which succinctly summarizes much of the atomic-level structure of the sequenced molecule. Computational molecular Biology, which comprises many aspects of bioinformatics tools, is the science of using biological data to improve modes or algorithms to understand biological systems and relationships. Next generation sequencing works by reading the nucleotide sequences at the single cell molecule level, in contrast to existing methods that need breaking long strands of DNA into small segments then inferring nucleotide sequences by synthesis and amplification.
- Track 29-1Computational Biomodeling
- Track 29-2Protein Structure, Function and Interaction
- Track 29-3Cancer computational biology
- Track 29-4Enrichment and Experiments of Next generation
- Track 29-5Genome assembly and Bioinformatics
- Track 29-6Techniques and tools in Clinical Genetics
- Track 29-7Statistical Applications in Computational biology
Data integration is the procedure of combining data generated using a variety of different research various in order to enable detection of underlying themes and in Computational biology and bioinformatics, biological principles. Data Analysis in this arena is dataintensive, which means data sets are large and highly heterogeneous, to create knowledge from data, researchers must integrate these large and diverse datasets. Predictive genomics is at the intersection of multiple disciplines as predictive medicine, translational bioinformatics and personal genomics. Specifically, predictive genomics deals with the future phenotypic outcomes through prediction in areas such as complex multifactorial diseases in humans. Prediction and Modelling involves the use of computer simulations of biological systems, including cellular subsystems, such as the networks of enzymes and metabolites which comprise metabolism, signal transduction pathways and gene technology regulatory networks, to both visualize and analyze the complex connections of these cellular processes.
- Track 30-1Data Modelling Process and Virtualization
- Track 30-2Generic Data Modelling
- Track 30-3Presenting and using the Results of a Predictive model
- Track 30-4Propagation and Consolidation
- Track 30-5Scientific Hypothesis and Prediction
- Track 30-6Judgement-based Prediction
- Track 30-7Supernatural Prediction
- Track 30-8Ecological Models