Track Categories
The track category is the heading under which your abstract will be reviewed and later published in the conference printed matters if accepted. During the submission process, you will be asked to select one track category for your abstract.
Biotechnology is a scientific industry that creates medical goods by combining live creatures and molecular biology. Therapeutics and procedures are also developed by biotechnology companies (such as DNA fingerprinting). Biotechnology is best known for its use in medicine and pharmaceuticals, the sector is additionally utilized in genomics, food production, and biofuel generation.
Determining how living organisms behave at the molecular level is important to biotechnology, which brings together a variety of disciplines such as biology, physics, chemistry, mathematics, science, and technology.
Agricultural Biotechnology refers to a set of scientific methods for improving plants, animals, and microbes.
Scientists have discovered methods to enhance agricultural production based on their understanding of DNA. Biotechnology improves breeders' capacity to improve crops and livestock by allowing them to discover genes that may provide benefits on certain crops and the ability to work with such features very precisely.
Medical Biotechnology is a field of medicine that studies and then manufactures pharmaceutical and diagnostic products using living cells and cell components. These products assist in the treatment and prevention of illnesses. Medical biotechnology is making enormous advances and benefiting many people, from the Ebola vaccine to mapping human DNA to agricultural consequences.
Work in genetic testing, pharmacological therapies, and artificial tissue development are some of the most recent applications of biological technology. New problems have arisen as a result of the numerous developments in medical biotechnology. When it comes to this fast-paced business, there are numerous things to establish and control, from finance to ethics.
Plant Biotechnology is a collection of approaches that permits plants to be adapted to fulfil specific requirements or possibilities. Multiple needs and opportunities are frequent in situations like these. for example, one crop could also be necessary to supply sustainable food and nutritious nutrition, environmental protection, and employment and income possibilities. Finding or growing appropriate plants could be a difficult task in most cases.
Genetics and genomics, marker-assisted selection (MAS), and transgenic (genetic modified) crops are examples of plant biotechnologies that aid in the development of novel varieties and characteristics. Researchers may use these biotechnologies to find and map genes, learn about their roles, select for specific genes in genetic resources and breeding, and transfer genes for specific characteristics into plants where they are needed.
In the food processing industry, microorganisms are used to preserve food and produce a variety of value-added products such as enzymes, flavor compounds, vitamins, microbial cultures, and food components. As a result, biotechnology applications in the food processing industry focus on the selection and manipulation of microorganisms with the goal of enhancing process control, product quality, safety, stability, and yield while increasing process efficiency.
It is important to create a Food Biotechnology Department in order to meet the future expectations of stakeholders in the post-harvest management and food processing sectors through food biotechnological research and development innovations. By using the potential of biotechnology, recombinant gene technology, genetically modified (GM) microbes/food for sustainable development for food and nutrition will be addressed. Biotechnology is also used widely in diagnostics to monitor food safety, prevent and diagnose food-borne diseases, and authenticate food sources.
Animals are becoming more involved in the advancement of biotechnology, as well as benefiting from it. All animals are included in animal biotechnology: poultry, fish, insects, companion animals, and laboratory animals.
Animal genomics, animal cloning, and genetic engineering of animals are three scientific agricultural animal biotechnology industries that have emerged as a result of the study.
Animals have been utilized to create medicines for humans for many years. Animal-made pharmaceuticals (AMPs) turn biotech animals into "factories" that generate therapeutic proteins in their milk, eggs, and blood that may be utilized in biopharmaceutical development. Moreover, biotechnology may be utilized in pigs to create human-compatible transplant organs, tissues, and cells, which could be critical to improving human health.
The use of enzymes, microbes, and plants to produce energy, industrial chemicals, and consumer products is known as industrial biotechnology or microbial biotechnology. It is an industrial paradigm based on the belief that renewable plant-derived carbohydrates, lipids, and other compounds would be able to replace a large portion of the petroleum and other fossil fuels that are now the raw material and energy foundation of modern industrial civilizations.
The goal is to create biotechnology techniques that will result in cost-effective and long-term "green" industrial processes.
Metabolic engineering has grown increasingly essential as industrial processes based on biotechnology have become more common. The objective of metabolic engineering is to increase the synthesis of chemicals of industrial interest in microorganisms that function as cell factories in this context by manipulating their genes.
The use of biotechnology techniques on marine resources is referred to as marine or blue biotechnology. Biotechnology is defined as the application of science and technology to measure creatures and their components, products, and models to modify living or non-living materials to make knowledge, goods, and services. The live organisms utilized in marine biotechnology come from aquatic sources.
Marine Biotechnology is an emerging field focused on the exploitation of marine natural resources. The oceans comprise about 71 percent of our planet's surface, but over 99 percent of the biosphere (since organisms may live anywhere in the water column), and they represent the most extremes of temperature, light, and pressure that life has ever encountered.
Adapting to those harsh environments has resulted during a rich marine bio- and genetic diversity with biotechnological applications, from drug discovery to environmental remediation to increasing seafood availability and safety to developing new resources and industrial processes.
By providing crucial information regarding the evidence collected at the crime scene, forensic science is an important tool for the discovery or investigation of crime and the administration of justice. Forensic biotechnology is a field of medicine where new discoveries are made on a regular basis.
In criminal investigations, forensic examination of biological evidence utilizing biotechnology methods is becoming increasingly important. Traditional forensic procedures include the study of proteins in the blood (serology), other body fluids, and body tissues.
Many aspects of criminal investigation, including DNA fingerprinting, DNA foot printing, and DNA profiling, are currently being revolutionized by DNA forensics. DNA samples are subjected to polymerase chain reaction (PCR) analysis, which enables for accurate identification of extremely small pieces of evidence obtained at the crime scene.
Biotechnology is the use of biological systems, living organisms, or their derivatives in the production or alteration of goods or processes for specific applications. Agriculture, food science, and medicines are just a few of the sectors where biotechnology is utilized. Biotechnology is used by pharmaceutical companies for drug development, pharmacogenomics, gene therapy, and genetic testing.
Biotech companies manipulate and change organisms, generally at the molecular level, to create biotechnology products (more especially, biotech pharmaceutical products).
Pharmaceutical biotechnology companies create biotechnological products using recombinant DNA technology, which involves genetic manipulation of cells, or monoclonal antibodies. These biotech pharmaceutical products are widely used in the prevention, diagnosis, and treatment of a wide range of illnesses.
Molecular Biotechnology is the study and modification of nucleic acids and proteins in laboratories for applications in human and animal health, agriculture, and the environment. Many fields of science, including molecular biology, microbiology, biochemistry, immunology, genetics, and cell biology, have come together to form molecular biotechnology. It's an exciting area that is really fuelled by the ability to transfer genetic information across organisms in order to better understand essential biological processes or create a valuable product.
The completion of the human genome project has opened offers a wider of possibilities for developing novel medications and treatments, as well as ways to enhance current ones. The subject of molecular biotechnology is one that is constantly developing and evolving. Its effect will grow as the speed of development increases. Molecular biotechnology's importance and effect are being felt all throughout the country.
Environmental Biotechnology is a multidisciplinary combination of sciences and engineering aimed at using the enormous biochemical potential of microbes, plants, and portions thereof for environmental restoration and preservation as well as resource sustainability.
Environmental Biotechnology is described as the creation, use, and regulation of biological systems, such as cells, cell compartments, and enzymes, for the remediation of polluted environments (land, air, water, and soil), as well as eco-friendly activities (green manufacturing technologies and sustainable development).
The fundamental goal of environmental biotechnology is to create better approaches to sustainable development and to understand natural processes. The ability of microorganisms to utilize diverse carbon sources as naturally occurring pollutants is the driving factor behind biotechnology.
Bioinformatics is a branch of biology and computer science that deals with collecting, storing, analysing, and distributing biological data, most often DNA and amino acid sequences. Bioinformatics makes use of computer algorithms to determine gene and protein functions, identify evolutionary links, and forecast the three-dimensional structures of proteins, among other things.
Most large biological molecules are polymers, which are organized chains of smaller molecular modules known as monomers. This is a statistically interesting characteristic. Consider the monomers as beads or construction pieces that, despite their many colors and forms, all have the same thickness and join in the same way.
Initially, the term genetic engineering applied to a variety of approaches for modifying or manipulating organisms through the processes of heredity and reproduction. As a result, the phrase included both artificial selection and all biological methods interventions, including as artificial insemination, in vitro fertilizations (e.g., "test-tube" babies), cloning, and gene modification.
However, by the late twentieth century, the phrase had come to apply more specifically to recombinant DNA technology (or gene cloning), in which DNA molecules from two or more sources are joined either within cells or in vitro, and then introduced into host species where they can spread.
Nanotechnology is the study and management of matter at the nanoscale, where unique phenomena offer innovative applications, with diameters ranging from 1 to 100 nanometres. Nanotechnology includes imaging, measuring, modelling, and manipulating materials at this length scale, and it encompasses nanoscale science, engineering, and technology.
At the nanoscale, matter such as gases, liquids, and solids can have unique physical, chemical, and biological characteristics that differ significantly from bulk materials and single atoms or molecules. When compared to other forms or sizes of the same material, certain nanostructured materials are stronger or have different magnetic characteristics.
Biochemistry is a field of biology that studies the chemical processes that occur within and around living organisms. It is a science that combines biology and chemistry in a laboratory environment. Biochemists can understand and address biological issues by applying chemical knowledge and procedures.
Biochemistry is concerned with processes that occur at the molecular level. It studies proteins, lipids, and organelles to learn more about what goes on inside our cells.
Genetics, microbiology, forensics, plant science, and medicine are among the scientific fields covered by biochemistry. Biochemistry is highly significant because of its breadth, and developments in this branch of research have been astonishing during the last 100 years. It's an exciting moment to be involved in this interesting field of research.
Bioscience is a broad field of research and business with a common thread using knowledge to create biological solutions that preserve, repair, and improve the quality of life for humans, plants, and animals across the planet. Bioscience has improved society's quality of life in many ways, from life-saving medicines and surgeries to healthier meals and cutting-edge research.
Biological sciences include all disciplines of natural science that study various aspects of living things. The idea encompasses anatomy, physiology, cell biology, biochemistry, and biophysics, and it applies to all species from bacteria to animals and plants.
Biomedical engineering, often referred to as medical engineering, is the application of engineering principles and style concepts to medicine and biology for healthcare purposes (e.g., diagnostic or therapeutic).
Biomedical engineering has only recently emerged as a definite subject of study in compared to several other engineering topics. This sort of development is usual when a new topic grows from being an interdisciplinary specialty among already-established disciplines to being designated a field in its own right.