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24th European Biotechnology Congress (EBC_2020), will be organized around the theme “Novel Advancements and Progressing Technologies in Biotechnology”

Euro Biotech 2020 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Euro Biotech 2020

Submit your abstract to any of the mentioned tracks.

Register now for the conference by choosing an appropriate package suitable to you.

Pharmaceutical Biotechnology is the science that covers all innovations required for creating, assembling and enrollment of organic medications. Pharmaceutical organizations use biotechnology for assembling drugs, pharmacogenomics, quality treatment, and hereditary testing. Biotech organizations make biotechnology items by controlling and adjusting living beings, more often than not at atomic level. Pharmaceutical Biotechnology is an undeniably significant region of science and innovation. It contributes in plan and conveyance of new helpful medications, demonstrative specialists for therapeutic tests, and in quality treatment for revising the restorative side effects of genetic maladies. The Pharmaceutical Biotechnology is broadly spread, running from numerous moral issues to changes in medicinal services rehearses and a noteworthy commitment to the improvement of national economy. Euro Biotechnology 2020 will concentrate on Biopharmaceuticals Discovery, Biopharmaceutical Regulations and Validations, Biologics and Biosimilars and Clinical Research/Clinical preliminaries.

  • Track 1-1Biopharmaceuticals Discovery
  • Track 1-2Biopharmaceutical Regulations and validations
  • Track 1-3Biologics and Biosimilars
  • Track 1-4Clinical Research/Clinical preliminaries

Bioenergy describes any energy source based on biological matter – everything from an dung cooking fire or a biomass power station to ethanol-based car fuel. Unlike oil, coal or gas, bioenergy counts as a renewable energy option, because plant and animal materials can be easily regenerated.The term biofuels is sometimes used interchangeably with bioenergy, though more commonly it's used specifically to describe liquid bioenergy fuels such as biodiesel (a diesel substitute) and bioethanol (which can be used in petrol engines).

Biotechnology provides powerful tools for the sustainable development of agriculture as well as the food industry, improving the production of foods and making them more available and nutritious. Food biotechnology is a rapidly expanding field of science with many different applications, which is clear from the large number of scientific papers published in the last 10 years.  GM plants and animals are used to enhance taste, shell life, nutrition and quality of food. On the other hand GM yeast and Bacteria are used to produce enzymes for the sake of food industry. These GM foods are produced by using biotechnological techniques specifically genetic engineering. Genetic engineering purpose is to introduce foreign gene of interest in an organism. This foreign gene introduction is for the purpose of enhancement in quality and quantity of food. So these techniques can be used to erase hunger from poor people of third world specially Africa 

  • Track 3-1Food Biotechnology – brief history
  • Track 3-2Food Biotechnology today
  • Track 3-3Benefits of Food Biotechnology
  • Track 3-4Food Safety and quality control
  • Track 3-5Applications of Food Biotechnology
  • Track 3-6Potential risks of Genetically Modified foods

CRISPR (clustered regularly interspaced short palindromic repeats) is a family of DNA sequences found within the genomes of prokaryotic organisms such as bacteria and archaea. These sequences are derived from DNA fragments from viruses that have previously infected the prokaryote and are used to detect and destroy DNA from similar viruses during subsequent infections. Hence these sequences play a key role in the antiviral defence system of prokaryote. Cas9 (or "CRISPR-associated protein 9") is an enzyme that uses CRISPR sequences as a guide to recognize and cleave specific strands of DNA that are complementary to the CRISPR sequence. Cas9 enzymes together with CRISPR sequences form the basis of a technology known as CRISPR-Cas9 that can be used to edit genes within organisms. This editing process has a wide variety of applications including basic biological research, development of biotechnology products, and treatment of diseases

  • Track 4-1CRISPR-CAS 9 gene editing technology
  • Track 4-2Clinical and healthcare aspects of CRISPR genome editing
  • Track 4-3Implementation of CRISPR screening technique in drug discovery
  • Track 4-4Social, ethical and economic implications of CRISPR-based technology
  • Track 4-5CRISPR for developing better antibiotics

Advances in biotechnology have provided surgeons an alternative to help accelerate alveolar bone regeneration and enhance soft tissue growth using concentrated blood serum. By utilizing a small volume of Platelet Rich Plasma (i-PRF) obtained from the patient’s own blood, doctors can now add it to extraction sites and bone graft material to yield a 3 dimensional biocompatible fibrin matrix that releases a host of naturally occurring growth factors which contribute to rapid healing and bone regeneration. Once the plasma fraction is activated they play a fundamental role in revascularization and bone tissue regeneration. They work to induce mitogenic and proliferative activity of osteoprogenitor cells and endothelial cells hence improving healing time and accelerating implant Osseointegration. Together they work to increase bone remineralisation, produce collagen, and promote blood vessel growth.

  • Track 5-1Nanodiagnostics
  • Track 5-2Nanomaterials in Dentistry
  • Track 5-3Dental Biomimetics
  • Track 5-4Nano Tissue Engineering
  • Track 5-5Role of Probiotics

Biomedical engineering is the application of engineering principles and design concepts to medicine and biology for healthcare purposes (e.g. diagnostic or therapeutic). This field seeks to close the gap between engineering and medicine, combining the design and problem solving skills of engineering with medical biological sciences to advance health care treatment, including diagnosis, monitoring, and therapy. Biomedical engineering has only recently emerged as its own study, as compared to many other engineering fields. Such an evolution is common as a new field transitions from being an interdisciplinary specialization among already-established fields, to being considered a field in itself. Much of the work in biomedical engineering consists of research and development, spanning a broad array of subfields.

Cell biology (also called cytology) is a branch of biology that studies the structure and function of the cell, which is the basic unit of life. Cell biology is concerned with the physiological properties, metabolic processes, signaling pathways, life cycle, chemical composition, and interactions of the cell with their environment. Molecular biology is a branch of biology that concerns the molecular basis of biological activity between biomolecules in the various systems of a cell, including the interactions between DNA, RNA, proteins and their biosynthesis, as well as the regulation of these interactions.

Microbial/Industrial biotechnology is the use of biotechnology for modern capacities, together with modern aging. The observation of exploited cells like microorganisms, or components of cells like compounds, to think of mechanically supportive item in segments like synthetic concoctions, nourishment and feed, cleansers, paper and mash, materials and biofuels. Modern Biotechnology offers a head discussion crossing over essential investigation and R&D with later-arrange advancement for supportable bio base for the most part of industrial and ecological applications.

  • Track 8-1Role of biotechnology in industry
  • Track 8-2 Biochemical Engineering
  • Track 8-3Upstream processing
  • Track 8-4Downstream processing

Biotechnology is a consistently rising field wherein natural procedures, creatures, cells and cell segments are exploited to create novel ability. In the course of recent decades there have been progressive biotech developments which helped the humanity. New devices and tools created by biotechnologists are convenient in research, horticulture, industry and the facility.Ongoing headways in the field of biotechnology will support our economy and give answers for obstinate issues of human and animal diseases, environmental change, fuel options, nourishment security just as improving our personal satisfaction.

  • Track 9-1Advancements in Genetic Engineering techniques
  • Track 9-2Soundness of Biotechnology advancements in Agriculture
  • Track 9-3Advancements in diagnosis and cure
  • Track 9-4Advancements in industry
  • Track 9-5Further requirements of advancements
  • Track 9-6Potential growth of Biotechnology by 2025

Genetic engineering is a broad term referring to manipulation of an organisms’ nucleic acid. Organisms whose genes have been artificially altered for a desired affect is often called genetically modified organism (GMO). Recombinant DNA technology (R-DNA) is technology that is used to cut a known DNA sequence from one organism and introduce it into another organism thereby altering the genotype (hence the phenotype) of the recipient. The process of introducing the foreign gene into another organism (or vector) is also called cloning. Sometimes these two terms are used synonymously.

  • Track 10-1DNA in Genetic Engineering
  • Track 10-2Generation of Recombinant DNA
  • Track 10-3Reasons to Manipulate DNA
  • Track 10-4Role of recombinant DNA technology to improve life

Agricultural biotechnology is a pile of tools, containing traditional breeding methods that alter living organisms, or parts of organisms, to make or modify products, improve plants or animals for specific agricultural uses. Plant Biotechnology is a set of techniques used to adapt plants for specific needs or opportunities. Plant Biotechnology applies technological methods to biological organisms. Plant biotechnology can be defined as the introduction of desirable traits into plants through genetic modification.

 

  • Track 11-1Organic Farming
  • Track 11-2Livestock Farming and Production
  • Track 11-3Plant Functional Biology and Biotechnology
  • Track 11-4Plant Pathology and Immunology
  • Track 11-5Plant Micropropagation

Environmental biotechnology is applied and used to study the regular habitat. Ecological/Environmental biotechnology could likewise suggest that one attempt to outfit natural procedure for business uses and exploitation. It is "the improvement, use and guideline of organic frameworks for remediation of contaminated environment and for environment friendly processes (green assembling innovations and feasible advancement). Ecological biotechnology can essentially be portrayed as the ideal utilization of nature, as plants, creatures, microorganisms, organisms and green growth, to deliver sustainable power source, sustenance and supplements in a synergistic incorporated cycle of profit making forms.

  • Track 12-1Climate change mitigation
  • Track 12-2Climate change adaptation and realisation of the millennium development goals.
  • Track 12-3Environmental pollution and health
  • Track 12-4Recycling and waste management
  • Track 12-5Biodiversity conservation and ecosystem management
  • Track 12-6Renewable energy technology

Artificial intelligence could very well be the future of biotechnology, and it has become a crucial part of life sciences. Artificial intelligence is now making headway into biotech and such related industries, but it is not the only one making progress and bringing change. Artificial intelligence has made some exciting improvements to medicine, and biotech companies and pharmaceutical companies are employing artificial intelligence in drug discovery with a lot of positive results.

  • Track 13-1Introduction to Artificial Intelligence
  • Track 13-2AI in clinical diagnosis
  • Track 13-3AI in Cancer and Drug discovery
  • Track 13-4Artificial Neural network as a Biotech tool

Blue biotechnology, in more specific terms, is the application of molecular biological methods to marine and freshwater organisms. Blue biotechnology is thus associated with applications such as preservation of a variety of marine species, restoring the aquatic wildlife to its original state of habitat, use of marine species to develop new medicines genetic study of plants to engineer other plants to become resistant to environmental extremes, et cetera.

  • Track 14-1Marine Microbiology and Biotechnology
  • Track 14-2Disease and Immunology in Aquaculture
  • Track 14-3Blue Innovation, Science to Policy
  • Track 14-4Algal Biotechnology
  • Track 14-5Marine Biotechnology for Environmental Conservation

The evolution and spread of drug resistant pathogens presents a growing problem worldwide.  The fact that virtually all anti-microbials lose efficacy over time because of the development and spread of resistance in the target organism could be greatly reduced by creating novel and affordable approaches to optimal drug delivery tools, by developing drugs that target critical host components essential to infection and disease, as well as drugs that target components of the pathogen that are implicated in disease rather than infection, or that are so highly constrained that resistant variants cannot be easily selected.

 

Stem cell biotechnology is a field of biotechnology that creates tools and therapeutics through adjustment and designing of undeveloped cells. Stem/undifferentiated cell biotechnology is significant in regenerative medication. Regenerative drug is an Inter disciplinary branch that will in general fix or recover harmed cells or tissues to recapture or re-establish their typical capacity.

 

  • Track 16-1Tissue Engineering
  • Track 16-2Regenerative Medicine
  • Track 16-3Stem cell transplant for cancer treatment
  • Track 16-43D Bioprinting and stem cell research

Nano Biotechnology is a discipline wherein tools from nanotechnology are created and connected to think about organic marvels. Nano biotechnology, bio nanotechnology, and Nano science are terms that allude to the crossing point of nanotechnology and science. Bio nanotechnology and Nano biotechnology fill in as cover terms for different related advancements. The most significant goals that are habitually found in Nano science include applying Nano instruments to important restorative/natural issues and refining these applications. Growing new instruments, for example, peptide Nano sheets, for medicinal and organic designs is another essential target in nanotechnology.

  • Track 17-1Advanced Nano Research and Nano-tech applications
  • Track 17-2Nanomaterial science
  • Track 17-3Advances in Nano science and Nano technology
  • Track 17-4Future potential of Nano technology

Gold Biotechnology/Bioinformatics is an interdisciplinary field that addresses biological problems using computational techniques, and makes the rapid organization as well as analysis of biological data possible. The field may also be referred to as computational biology, and can be defined as, "conceptualizing biology in terms of molecules and then applying informatics techniques to understand and organize the information associated with these molecules, on a large scale. Bioinformatics plays a key role in various areas, such as structural genomics, and proteomics, and forms a key component in the biotechnology and pharmaceutical sector.

  • Track 18-1Gold Biotechnology in drug discovery
  • Track 18-2Functional Genomics
  • Track 18-3Structural Genomics
  • Track 18-4Proteomics and Protein Engineering

Biodegradation is the biological process in which a material is biologically degraded. It is a natural process that takes place without human intervention. Bioremediation is the engineered process of application of biological means (including bacteria, algae, fungi, etc.) to degrade a material. Biodegradation is a slow process process, while bioremediation is a faster process. Human intervention is used to control the rate of bioremediation, by control of temperature, availability of food or nutrients, etc. Biodegradation, on the other hand, is controlled by nature. Biodegradation takes place anywhere and everywhere, while bioremediation is planned at a contaminated site. Biodegradation can be both beneficial and harmful (such as degradation of metals in biofouling), while bioremediation is designed to be beneficial to us.

Animal biotechnology is a branch of biotechnology in which molecular biology techniques are used to genetically engineer (i.e. modify the genome of) animals in order to improve their suitability for pharmaceutical, agricultural or industrial applications. It covers the identification and manipulation of genes and their products, stressing applications in domesticated animals. Animal biotechnology has been used to produce genetically modified animals that synthesize therapeutic proteins, have improved growth rates or are resistant to disease.