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2nd International Conference on Systems and Synthetic Biology, will be organized around the theme ““Systems and Synthetic Biology- Accomplish Impossible to Possible””
Systems and Synthetic Biology 2016 is comprised of 24 tracks and 138 sessions designed to offer comprehensive sessions that address current issues in Systems and Synthetic Biology 2016.
Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.
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is a relatively new field in biomedical research. It focuses on engineering new or modified signaling proteins to create desired signaling pathways in the cell. Every living cell is an extremely complex machine expressing thousands of different proteins. Due to superb regulation, many cells, such as photoreceptors and other neurons in vertebrates, can live for decades. Cells can also self-reproduce by division, where both daughter cells are perfectly viable. Natural selection (the “blind watchmaker”, to use Dawkins’ expression) spent hundreds of millions of year to achieve this perfection. Due to elucidation of the intricacies of cellular regulatory mechanisms we can now play evolution on our time scale: re-design proteins and signaling pathways to achieve our ends.
- Track 1-1Synthetic Biology
- Track 1-2Systems Biology
- Track 1-3Gene Signaling
- Track 1-4Genome Design
- Track 1-5Pathway Design
Synthetic genomics is an early field of engineered science that uses parts of hereditary alteration on prior life frames with the plan of delivering some item or wanted conduct with respect to the living thing so made.Synthetic genomics joins strategies for the fake amalgamation of DNA with computational methods to plan it. These strategies permit researchers and specialists to build hereditary material that would be inconceivable or illogical to deliver utilizing more routine biotechnological approaches. For instance, utilizing manufacturedgenomics it is conceivable to outline and amass chromosomes, qualities and quality pathways, and even entire genomes.
- Track 2-1Synthetic gene pathways
- Track 2-2Synthetic genomics algae
- Track 2-3BioBrick
- Track 2-4Regenomics
- Track 2-5Functional genomics
- Track 2-6Computational genomics
Plan and development of Synthetic gene network from secluded segments is a noteworthy objective of engineered science. Nonetheless, the development of quality systems with unsurprising capacities remains hampered by an absence of suitable segments and the way that amassed arranges regularly require broad, iterative retrofitting to function as proposed. Propels in the improvement of atomic devices for the inducible control of interpretation, interpretation, and protein debasement are the premise for the quickly developing configuration and development of engineered quality systems in mammalian cells. Nonetheless, progresses in manufactured science have been constrained by an absence of interoperable parts, strategies for powerfully testing organic frameworks and systems for the solid development and operation of mind boggling, higher-request systems. As these difficulties are tended to, manufactured scholars will have the capacity to develop helpful cutting edge engineered quality systems with certifiable applications in prescription, biotechnology, bioremediation and bioenergy. Artificial gene synthesis amalgamation is a strategy in Synthetic Biology that is utilized to make artificial genes in the research facilities.
- Track 3-1Gene translation
- Track 3-2Mathematical modeling of cellular systems
- Track 3-3Design and construction of synthetic gene networks
- Track 3-4Genetic network analysis
- Track 3-5Genetic network modeling
- Track 3-6Modeling and optimization
- Track 3-7Gene transcription
Gene synthesis is a strategy in synthetic biology that is utilized to make create artificial genes in the research center. Currently based on solid-phase DNA synthesis, it contrasts from molecular cloning and polymerase chain reaction (PCR) in that the client does not need in the first place prior DNA sequences. Accordingly, it is conceivable to make a totally synthetic double-stranded DNA molecule with no obvious cutoff points on either nucleotide sequence or size. The technique has been utilized to create utilitarian bacterial or yeast chromosomes containing around one million base sets. Late research likewise proposes the likelihood of making novel nucleobase pairs notwithstanding the two base pairs in nature, which could incredibly extend the likelihood of growing the genetic code. Gene editing or genome editing with built nucleases (GEEN) is a sort of genetic engineering in which DNA is inserted, deleted or replaced in the genome of an organism utilizing engineered nucleases, or "molecular scissors." These nucleases create site-specific double-strand breaks (DSBs) at craved areas in the genome. The induced double strand breaks are repaired through nonhomologous end-joining (NHEJ) or homologous recombination (HR), bringing about targeted mutations. There are at present four groups of engineered nucleases being utilized: Meganucleases, Zinc finger nucleases (ZFNs), Transcription Activator-Like Effector-based Nucleases (TALENs), and the CRISPR-Cas System.
- Track 4-1Custom gene synthesis
- Track 4-2Recombinant genes
- Track 4-3Codon optimization
- Track 4-4Artificial gene synthetic
- Track 4-5Methods in gene synthesis
- Track 4-6DNA synthesis
- Track 4-7Gene Editing
The field of molecular biology covers with biology and chemistry and specifically, genetics and biochemistry. A key territory of molecular biology concerns seeing how different cell systems connect as far as the way DNA, RNA and protein synthesis function. Molecular biology takes a gander at the molecular mechanisms behind procedures, for example, replication, transcription, translation and cell function. The Scientist must decide how biological traits are conveyed starting with one generation to another. Molecular biologists also analyse. They utilize this data to help with the determination and treatment of infections found in humans, plants and animals.
- Track 5-1metabolic networks
- Track 5-2Cell signaling
- Track 5-3Molecular systems biology
- Track 5-4Plant systems biology
- Track 5-5Cell and systems biology
- Track 5-6Bioinformatics and systems biology
As name "Integrative Biology" reflects conviction that the investigation of biological systems is best drawn nearer by fusing numerous points of view. We unite assorted qualities of controls that supplement each other to disentangle the complexity of biology. The idea incorporates anatomy, physiology, cell and stem cell biology, molecular biology, developmental biology, biochemistry and biophysics. We work with animals, plants and microorganisms and our exploration traverses the levels of the organic chain of command from molecules to ecosystems. Our expansive scope of mastery incorporates: geneticists, paleontologists, physiologists, behaviorists, systematists, morphologists, microbiologists, bioinformatician, evolutionary biologists, ecologists, biophysicists and biotechnologists.
- Track 6-1Computational Bio modeling
- Track 6-2Computational Pharmacology
- Track 6-3Computational Evolutionary biology
- Track 6-4Cancer Computational Biology
Stem cells will be cells begin in all multi-cell organisms. They were detached in mice in 1981 and in people in 1998. In people there are a few sorts of stem cells, each with variable levels of strength. Stem cell treatments are a sort of therapy that brings new cells into grown-up bodies for conceivable treatment of cancer, diabetes, neurological disorders and other medical conditions. Stem cells have been utilized to repair tissue damaged by infection or age. In a creating embryo, stem cells can separate into all the specific cells ectoderm, endoderm and mesoderm, additionally keep up the ordinary turnover of regenerative organs, for example, blood, skin, or intestinal tissue
- Track 7-1Synthetic chemistry
- Track 7-2Synthetic organic chemistry
- Track 7-3Green chemistry
- Track 7-4Synthetic Biochemistry
Protein engineering is the procedure of creating helpful or profitable proteins. It is a youthful control, with much research occurring into the comprehension of protein folding and acknowledgment for protein design principles. There are two general systems for protein engineering, rational protein design and directed evolution. These systems are not fundamentally unrelated; specialists will frequently apply both. Later on, more itemized learning of protein structure and capacity, and also headways in high-throughput innovation, might incredibly grow the abilities of protein engineering. In the long run, even unnatural amino acids might be incorporated, because of another strategy that permits the consideration of novel amino acids in the genetic code.
- Track 8-1Seed synthetic biology
- Track 8-2Plant gene modification
Industrial biotechnology is a standout amongst the most encouraging new ways to deal with contamination counteractive action, asset protection, and cost lessening. It is frequently alluded to as the third wave in biotechnology. On the off chance that created to its maximum capacity, modern biotechnology might largely affect the world than human services and agriculture biotechnology. It offers organizations an approach to diminish costs and make new markets while securing the earth. Additionally, since a hefty portion of its items don't require the long audit times that medication items must experience, it's a speedier, less demanding pathway to the business sector. The utilization of biotechnology to modern procedures is changing how we make items as well as giving us new items that couldn't be envisioned a couple of years back. Since modern biotechnology is so new, its advantages are still not surely understood or comprehended by industry, policymakers, or customers.
- Track 9-1Medical applications
- Track 9-2Therapeutic Cells
Biomedical Device Engineering includes instrumentation for diagnosing, preventing or treating diseases. The study and design of engineering methods without any chemical action in the body can be achieved through the Medical imaging devices. Photo detectors and Biomedical Chromatography are recently obtaining their importance in the science field through its advancements.
- Track 10-1Biomaterials (or) Synthetic Materials
- Track 10-2Synthetic Lethality Cancer
- Track 10-3Synthetic Biology Drugs
- Track 10-4Synthetic Cell
- Track 10-5Advanced DNA Sequencing
- Track 10-6Synthetic Enzymes
- Track 10-7Artificial Organs and Tissues
- Track 10-8Synthetic Protein
- Track 10-9Synthetic RNA
- Track 10-10Synthetic DNA
- Track 10-11Synthetic Circuits
Biotechnology advances is the utilization of systems and organisms to create or make product, or any innovative application that uses biological, living organism’s forms or derivatives thereof, to make or alter products or procedures for particular use. Depending on the instruments and applications, it regularly covers with the (related) fields of bioengineering, biomedical building, biomanufacturing, and so forth.
- Track 11-1BioMedical Device Engineering
- Track 11-2Bio-Medical & Healthcare Engineering
- Track 11-3Bio-Medical Technology
Metabolomics is the experimental investigation of concoction procedures including metabolites. In particular, metabolomics is the deliberate investigation of the exceptional substance fingerprints that particular cell forms desert, the investigation of their little molecules metabolite profiles. The metabolome speaks to the accumulation of all metabolites in a biological cell, tissue, organ or living being, which are the end products of cell processes. mRNA quality expression data and proteomic examinations uncover the set of gene products being created in the cell, data that speaks to one part of cell function. On the other hand, metabolic profiling can give an immediate depiction of the physiology of that cell. One of the difficulties of system biology and functional genomics is to integrate proteomic, transcriptomic, and metabolomic data to give a superior comprehension of cell biology.
- Track 12-1Cell system definition
- Track 12-2Cell immune system
- Track 12-3Human cell system
Molecular Evolution combines basic ideas fundamental to the field with discussions of cutting-edge methodologies, and is therefore relevant to researchers with a range of different experience levels. Topics covered include uses and interpretations of molecular phylogenies, sequence alignments and genomics resources, Markov models of sequence evolution, phylogeny reconstruction, hypothesis testing in molecular phylogenetics and evolution, coalescent models and inference from population data.
- Track 13-1Biomedical Robotics
- Track 13-2NanoBio Technology
- Track 13-3Biosensors and Bioelectronics
- Track 13-4Computational Biological Systems
Synthetic biology tries to apply the standards of engineering to the act of biology and make conceivable the advancement of biological systems, including whole organassims, that have never been found in nature and fill correctly indicated human needs. The principle lines of examination in manufactured science depend on genetic engineering strategies that were initially created in the 1970s, however synthetic biology would like to bring these systems numerous progressions forward. To make genetic engineering truly experience its name, synthetic biology goes for the improvement of genetic sequencing that can serve as institutionalized modules and be utilized in institutionalized stage creatures to bring about those life forms to show unsurprising practices. More compelling medicines, intelligent tumor-seeking bacteria, and modest biofuels are only a couple of the sought after applications while new weapons of terror are one of the apprehensions.
- Track 14-1Synthetic biology business
- Track 14-2Synthetic biology companies
- Track 14-3Synthetic biology start-ups
- Track 15-1Cancer, antibiotic resistance and drug discovery
- Track 15-2Drug discovery and disease modeling
- Track 15-3Cell growth and metabolite production
- Track 15-4Biomedicine modeling
- Track 15-5DNA microarray technologies
- Track 15-6Structure of the network systems
- Track 15-7Constructing gene regulatory network
The pharmaceutical biology is a gathering of interdisciplinary zones of study concerned with the desigin, activity, delivery, and disposition of drugs. Applying the knowledge from chemistry such as inorganic, physical, biochemical and analytical from one end and from another end of Biology is dealing with life structures, physiology, organic chemistry, cell science, and molecular biology, epidemiology, statistics, chemometrics, mathematics, physics, and chemical engineering. As new disclosures progress and amplify the pharmaceutical biology, subspecialties keep on being added to this list. These shared fundamental concepts further to the understanding of their applicability to all aspects of pharmaceutical research and drug therapy.
- Track 16-1Pharmacology
- Track 16-2Pharmacogenomics
- Track 16-3Pharmaceutical chemistry
- Track 16-4Pharmaceutics
- Track 16-5Pharmacodynamics
- Track 16-6Pharmacokinetics
- Track 16-7Pharmacognosy
Design and construction of Synthetic gene networks from modular components is a major goal of synthetic biology. However, the construction of gene networks with predictable functions remains hampered by a lack of suitable components and the fact that assembled networks often require extensive, iterative retrofitting to work as intended. Advances in the development of molecular tools for the inducible control of transcription, translation, and protein degradation are the basis for the rapidly emerging design and construction of synthetic gene networks in mammalian cells. However, advances in synthetic biology have been limited by a lack of interoperable parts, techniques for dynamically probing biological systems and frameworks for the reliable construction and operation of complex, higher-order networks. As these challenges are addressed, synthetic biologists will be able to construct useful next-generation synthetic gene networks with real-world applications in medicine, biotechnology, bioremediation and bioenergy. Artificial gene synthesis is a method in synthetic biology that is used to create artificial genes in the laboratories.
International Conference on Molecular EvolutionJuly 21-23, 2016, Bangkok, Thailand, 4th International Conference on Integrative Biology July 18-20, 2016, Berlin, Germany, International Conference on Genetic Counseling and Genomic Medicine August 11-12, 2016 | Birmingham, UK, International Conference on Clinical and Molecular Genetics November 28-30, 2016 | Chicago, USA, 6th International Conference on Genomics & Pharmacogenomics September 12-14, 2016, Diffraction Methods in Structural Biology, July 17-22, 2016, Lewiston, ME, DNA Damage, Mutation & Cancer, March 12-13, 2016, Ventura, CA, "Drug Carriers in Medicine & Biology, August 17-22, "Single Molecule Approaches to Biology (GRS), July 2-3, 2016, Hong Kong, China, Drug Carriers in Medicine & Biology, July 2-3, 2016, Hong Kong, China.
- Track 17-1Yeast structural biology
- Track 17-2Structural biology in medicine
- Track 17-3Molecular structure of biological macromolecules
- Track 17-4Different dimensions of structures
- Track 17-5Alteration in protein structure
- Track 17-6Structural modification in nucleic acids
- Track 17-7Structural molecular biology
Synthetic genomics is a nascent field of synthetic biology that uses aspects of genetic modification on pre-existing life forms with the intent of producing some product or desired behavior on the part of the life form so created.
Synthetic genomics combines methods for the artificial synthesis of DNA with computational techniques to design it. These methods allow scientists and engineers to construct genetic material that would be impossible or impractical to produce using more conventional biotechnological approaches. For example, using synthetic genomics it is possible to design and assemble chromosomes, genes and gene pathways, and even whole genomes.
International Conference on Molecular EvolutionJuly 21-23, 2016, Bangkok, Thailand, 4th International Conference on Integrative Biology July 18-20, 2016, Berlin, Germany, International Conference on Genetic Counseling and Genomic Medicine August 11-12, 2016 | Birmingham, UK, International Conference on Clinical and Molecular Genetics November 28-30, 2016 | Chicago, USA, 6th International Conference on Genomics & Pharmacogenomics September 12-14, 2016, Berlin, Germany. 5th International Sc2.0 and Synthetic Genomes meeting, July 8-9, 2016, SynBioBeta London 2016, April 6-7 2016, London, UK, Genome Engineering and Synthetic Biology: Tools And Technologies, 28-29 January 2016, Ghent, Belgium, 2016 Synthetic Biology: Engineering, Evolution & Design (SEED), 4th Annual Sc2.0 and Synthetic Genomes Conference.
- Track 18-1Advance Applications of Integrative Biology
In the field of biology, regeneration is the progression of renewal, regeneration and growth that makes it feasible for genomes, cells, organ regeneration to natural changes or occasions that cause damage or disturbance. This study is completed as craniofacial tissue engineering, in-situ tissue regeneration, adipose-derived stem cells for regenerative medicine which is also a breakthrough in cell culture technology. The study is not ceased with the regeneration of tissue where it is further done in connection with cell signaling, morphogenetic proteins. The greater part of the neurological disorders happened inadvertent having an extent of recuperation by substitution or repair of intervertebral discs repair, spinal fusion and numerous more progressions.
- Track 19-1Proteomics and proteome
- Track 19-2Protein synthesis and folding
- Track 19-3Protein prediction
- Track 19-4Computational protein design
- Track 19-5Application of engineered proteins
- Track 19-6Structure-Based Combinatorial Protein Engineering (SCOPE)
- Track 19-7Fast parallel proteolysis
Biophysics covers the natural association, from the atomic level to entire life forms level in a biological processes. It depicts how creatures get sustenance, imparting, detecting nature, and repeating. Biophysical research requires some crucial standards from natural chemistry, nanotechnology, bioengineering, computational science and frameworks science.
- Track 20-1Current Trends in Biotechnology
A biosensor is an analytical device, used for the detection of an analyte,that combines a biological component with a physicochemical detector. Electrochemical biosensors are normally based on enzymatic catalysis of a reaction that produces or consumes electrons (such enzymes are rightly called redox enzymes). The sensor substrate usually contains three electrodes; a reference electrode, a working electrode and a counter electrode. Amperometric biosensors function by the production of a current when a potential is applied between two electrodes. They generally have response times, dynamic ranges and sensitivities similar to the potentiometric biosensors. The potentiometric biosensor, (potential produced at zero current) gives a logarithmic response with a high dynamic range. Such biosensors are often made by screen printing the electrode patterns on a plastic substrate, coated with a conducting polymer and then some protein (enzyme or antibody) is attached. They have only two electrodes and are extremely sensitive and robust. A microbial biosensor is an analytical device which integrates microorganism(s) with a physical transducer to generate a measurable signal proportional to the concentration of analytes.
- Track 21-1NMR spectral databases
- Track 21-2MS or MS/MS spectral databases
- Track 21-3Compound databases
- Track 21-4Pathway databases
- Track 21-5Comprehensive metabolomic databases
- Track 21-6Yeast metabolome database
- Track 21-7The human serum metabolome database
- Track 21-8The urine metabolome database
Next-generation sequencing alludes to non-Sanger-based high-throughput DNA sequencing technologies. Millions or billions of DNA strands can be sequenced in parallel, yielding considerably more throughput and minimizing the requirement for the fragment cloning techniques that are frequently utilized as a part of Sanger sequencing of genomes. DNA sequencing industry is sectioned into instruments and consumables, administrations, and workflow products.
- Track 22-1Biochemistry
- Track 22-2Quantum biology
- Track 22-3Biophysical chemistry
- Track 22-4Medical biophysics
- Track 22-5Membrane biophysics
- Track 22-6Molecular biophysics
- Track 22-7Neurophysics
- Track 22-8Physiomics
Computational biology includes hypothetical strategies, mathematical and computational reenactment procedures to investigation of biological and social frameworks. The field is incorporates establishment in computer science, animation, biochemistry, biophysics, molecular biology, genetics, genomics, ecology, evolution, anatomy, neuroscience and visualization computational biology. Here and there alluded to as bioinformatics, is the investigation of utilizing natural information to create calculations and relations among different organic frameworks. Preceding the approach of computational biology, researcher were not able have entry to a lot of data. Systems Biology concentrates on analytical and computational models that are unequivocally bolstered and propelled by genuine biological systems and that incorporate current exact learning.
- Track 23-1Physiomics
- Track 23-2Immunomics
- Track 23-3Cheminformatics
- Track 23-4Computational genomics
- Track 23-5Applications of genomics in Synthetic biology and bioengineering
- Track 23-6Mathematical modeling of cellular systems
- Track 23-7Modeling and optimization
- Track 23-8Identification, expansion and testing of the BAC clone
- Track 23-9Designing of the targeting vector
- Track 23-10Pathogenomics
A biomaterial is any matter, surface, or build that cooperates with living systems. The investigation of biomaterials is called biomaterials engineering or biomaterials science. It has encountered unfaltering and solid development over its history, with numerous organizations putting a lot of money into the improvement of new products. Biomaterials science envelops components of medication, science, biology, chemistry, tissue engineering and materials science.
- Track 24-1Electrochemical Biosensors
- Track 24-2Amperometric Biosensors
- Track 24-3Potentiometric Biosensors
- Track 24-4Microbial Biosensors
- Track 24-5Enzymatic Biosensors