Friday, 27 December 2019

Biopolymers 2020


About Conference

We would like to invite all the participants from all over the world to attend "10th World Congress on Biopolymers & Bioplastics" during August 03-04, 2020 in Zurich, Switzerland which includes prompt keynote presentations, Oral talks, Poster presentations and Exhibitions.
Biopolymers are chain-like molecules made up of repeating chemical blocks and can be very long in length. Depending on the nature of the repeating unit they are made of polysaccharides, proteins of amino acids, and nucleic acids of nucleotides. The studies are more concerned to Green Composites, Biopolymer Feed Stock Challenges, Biofibers & Microbial Cellulose, Biomaterials and Bioplastics. Advanced studies are being made to improvise developments in Biopolymer Technology, Waste Management, pharmaceutical and biomedical applications, Biodegrade ability, and many more.
Young Scientist Benefits
  • Our conferences provide best Platform for your research through oral presentations.
  • Share the ideas with both eminent researchers and mentors.
  • Young Scientist Award reorganization certificate and memento to the winners
  • Young Scientists will get appropriate and timely information by this Forum.
  • Platform for collaboration among young researchers for better development
  • Award should motivate participants to strive to realize their full potential which could in turn be beneficial to the field as whole.
 
 

Conference Highlights

 

Biomaterials are those materials which have been engineered to interact with biological systems for used in basically medical purpose. to augment or replace a natural function. As a science, it’s been about fifty years old. Study of biomaterials is called biomaterials science or biomaterials engineering. Many companies investing huge amounts of money for the development of new products. It holds within elements of medicine, biology, chemistry, tissue engineering and materials science.
A Biocomposite is a composite material composed of matrix (resin) and a reinforcement of natural fibers. These kinds of materials always providing biocompatibility. The matrix phase is formed by polymers derived from renewable and non-renewable resources. The matrix is important to protect the fibers from environmental degradation and mechanical damage, to hold the fibers together and to transfer the loads on it.
In addition, biofibers are the principal components of biocomposites, which are derived from biological origins, for example fibers from crops (cotton, flax or hemp), recycled wood, waste paper, crop processing byproducts or regenerated cellulose fiber(viscose/rayon). The interest in biocomposites is rapidly growing in terms of industrial applications (automobilesrailway coachaerospacemilitary applications, construction, and packaging) and fundamental research, due to its great benefits (renewable, cheap, recyclable, and biodegradable).
Biocomposites can be used alone, or as a complement to standard materials, such as carbon fiber.
 
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Polylactide (PLA) the most promising one of Biopolymer these are a type of plastics which is being manufactured from petrochemicals, generated from sustainable feed stocks such as sugar, starch or Cellulose. Till date, the use of Biopolymer, includes the first generation PLA, has been limited by their Physical properties and relatively high cost to manufacture. Next generation Biopolymer, are the Plastics component fabrication, Polysaccharides second generation PLA, are to be cheaper and to improve their performance and a wide variety of application to capture an increasing share of the various markets for Biopolymer. Innovations has already achieved significant success with its early investments its $1.5m investment in obesity drug developer return up to $22m, following its sale for $100m in 2013, while the sale of a small molecule drug discovery company, resulted in Innovations realizing $9.5m, a 4.7 return on investment. In year 2015, Innovations invested $14.0m in 20 ventures, helping to launch three new companies.
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Track 3: Bioplastics and its Applications
Bioplastic are plastics derived from renewable biomass sources, such as vegetable fats and oils, corn starch, or microbiota. Bioplastic can be made from agricultural by-products and also from used plastic bottles and other containers using microorganisms. Common plastics, such as fossil-fuel plastics are derived from petroleum or natural gas. Production of such plastics tends to require more fossil fuels and to produce more greenhouse gases than the production of biobased polymers (Bioplastic). Some, but not all, Bioplastic are designed to biodegrade. Biodegradable plastics can break down in either anaerobic or aerobic environments, depending on how they are manufactured. Bioplastic can be composed of starches, cellulose, Biopolymer, and a variety of other materials.
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Track 4: Ocean Plastics
Ocean plastic research is a relatively new field, the billions upon billions of items of plastic waste choking our oceans, lakes, and rivers and piling up on land is more than unsightly and harmful to plants and wildlife. About 8 million metric tons of plastic are thrown into the ocean annually. Of those, 236,000 tons are micro plastics– tiny pieces of broken-down plastic smaller than our little fingernail. There is more plastic than natural prey at the sea surface of the Great Pacific Garbage Patch, which means that organisms feeding at this area are likely to have plastic as a major component of their diets. For instance, sea turtles by-caught in fisheries operating within and around the patch can have up to 74% (by dry weight) of their diets composed of ocean plastics. By 2050 there will be more plastic in the oceans than there are fish (by weight).
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Track 5: Natural polymers
Natural polymers include the RNA and DNA that are so important in genes and life processes. In fact, messenger RNA is what makes possible proteinspeptides, and enzymes. Enzymes help do the chemistry inside living organisms and peptides make up some of the more interesting structural components of skin, hair, and even the horns of rhinos. Other natural polymers include polysaccharides (sugar polymers), Cellulose, starch, ligninchitin and polypeptides like silk, keratin, and hair. Natural rubber is, naturally a natural polymer also, made from just carbon and hydrogen. These materials and their derivatives offer a wide range of properties and applications. Natural polymers tend to be readily biodegradable, although the rate of degradation is generally inversely proportional to the extent of chemical modification. US companies demand for natural polymers is forecast to expand 6.9 % annually to $4.6 billion in 2016. Cellulose ethers, methyl cellulose, will remain the largest product segment. This study analyses the $3.3 billion US natural biopolymer industries. It presents historical demand data for the years 2001, 2006 and 2011, and forecasts for 2016 and 2021 by market.
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Whole green composites are the composite materials that are made from both renewable resource based polymer (biopolymer) and bio-filler. Whole green composites are recyclable, renewable, triggered biodegradable and could reduce the dependency on the fossil fuel to a great extent when used in interior applications. Whole green composites could have major applications in automotive interiors, interior building applications and major packaging areas. Despite the large number of recent reviews on green composites defined as Biopolymer or bio-derived polymers reinforced with natural fibers for bioprocessing of materials, limited investigation has taken place into the most appropriate applications for these materials. Global composite materials industry reached $19.6B in 2011, marking an annual increase of 8.2% from 2010 and driven by recovering of majority of markets. Market value of end use products made with composites was $55.6B in 2011. North American composites industry accelerated by 9 % in 2014, Europe increased by 8%while Asia grew by 7% in 2015. By 2017, composite materials industry is expected to reach $ 29.9B (7% CAGR) while end products made with composite materials market value is expected to reach $85B  Global Automotive composite materials market was estimated to be around $ 2.8 B in 2015, and forecast to reach $ 4.3 B by 2017 @ CAGR of approx. 7%.
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Synthetic polymers are human-made polymers. They can be classified into four main categories: thermoplastics, thermosetting, elastomers, and synthetic fibers. They are commonly found in a variety of consumer products. synthetic polymers are used in home purpose and mainly in daily basic needs in house purpose. A wide variety of synthetic polymers are available with variations in main chain as well as side chains. The back bones of common synthetic polymers such as polythene, polystyrene and poly acrylates are made up of carbon-carbon bonds, whereas hetero chain polymers such as polyamides, polyesters, polyurethanes, polysulfides and polycarbonates have other elements (e.g. oxygen, sulfur, nitrogen) inserted along to the backbone. Also silicon forms similar materials without the need of carbon atoms, such as silicones through siloxane linkages; these compounds are thus said to be inorganic polymers. Coordination polymers may contain a range of metals in the backbone, with non-covalent bonding present.
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Organic polymers are macromolecules composed of many repeating monomer units. Both synthetic and natural polymers play a crucial role in everyday life. Polysaccharides, polypeptides, and polynucleotides are the main types of biopolymers in living cells. These polymers are synthesized by enzyme-mediated processes in cells. In general, synthetic polymers are derived from monomers that contain either a multiple bond, or two or more functional groups, or a three-to seven- membered ring.. The chemical properties of the polymers are derived from their monomer units, while the physical properties of polymers are different. Polymers, depending on their physical properties, are characterised as thermoplastics, thermo sets, elastomers and fibres. Organic polymers have wide variety of uses, for example: polystyrene resins are used in the production of home electronics and appliances; nylon-6 is used in textile and plastic industries. Organic polymers such as polyethylene terephthalate are in the manufacture of popular PET bottles. Others such as neoprene are used in shoe soles and wet suits, polyvinyl chloride in pipes and Teflon in non-stick pans.
 
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Linear Polymers are polymers in which monomeric units are linked together to form linear chains. These linear polymers are well packed and have high magnitude of intermolecular forces of attraction and therefore have high densities, high tensile strength and high melting points. Linear polymers have a specific set of physicochemical and mechanical properties. The most important properties are the ability to form highstrength anisotropic, highly oriented fibers and films; the capacity for large, slowly developing reversible deformations; the ability to swell in the hyperelastic state before dissolving; and the high viscosity of solutions. This set of properties results from the high molecular weight, the chain structure, and the flexibility of the macromolecules. In the transition from linear to branched, sparse threedimensional networks, and finally to dense cross linked structures, these properties become decreasingly pronounced. Strongly crosslinked polymers are insoluble, infusible, and incapable of hyperelastic deformations.
 
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cross-liked polymers are a kind of polymer, whose molecular chains are binded with each other. This bond is can either be a chemical or a physical one, but usually when we talk about a cross-linked polymer, we mean chemical bonds.
Cross-linked polymers, such as thermosets and elastomers, behave completely different than their counterparts, thermoplastic polymers. In cross-linked systems, the mechanical behavior is also best reflected by the plot of the shear modulus versus temperature. Figure 1 compares the shear modulus between highly cross-linked, coarsely cross-linked and uncross-linked polymers. The coarse cross-linked system, typical of elastomers, has a low modulus above the glass transition temperature. The glass transition temperature of these materials is usually below -50 °C, so they are soft and flexible at room temperature. In contrast, highly crosslinked systems, typical in thermosets, show a smaller decrease in stiffness as the material is raised above the glass transition temperature; the decrease in properties becomes smaller as the degree of cross-linking increases .crossed linked polymers are usually contains rubber in terms of flexibility.  One of the most important properties of Cross-linked Polymers is that, they are thermosetting, which means, they cannot be melted or dissolved. So it can be harder for us to process this kind of polymer. They are considered as ideal dressings as they clean, rehydrate dry and necrotic tissues and initiate autolytic debridement. It has been reported that they promote moist healing and are used to treat venous leg ulcers.
 
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Amorphous polymers may exist in three physical states: vitreous, hyperelastic, and viscous-flow. Polymers with a low temperature (below room temperature) for the transition from the vitreous to the hyperelastic state are called elastomers, and polymers with high transition temperatures are called plastics. The properties of polymers vary within a broad range, depending on chemical composition and the structure and mutual arrangement of the macromolecules. Thus 1,4-cis polybutadiene, which is composed of flexible hydrocarbon chains, is elastic at about 20°C and undergoes transition to the vitreous state at  60°C. Polymethyl methacrylate, which is composed of more rigid chains, is a hard, vitreous substance at about 20°C and undergoes transition to the hyperelastic state only at 100°C. Cellulose, which is a polymer with very rigid chains linked by intermolecular hydrogen bonds, cannot exist at all in the hyperelastic state at temperatures below its decomposition point. Great differences may be seen in the properties of polymers even if the differences in the macromolecular structures are not great at first glance. Thus, stereoregular polystyrene is a crystalline substance with a melting point of about 235°C, whereas its nonstereoregular (atactic) analogue is completely incapable of crystallizing and softens at about 80°C.
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Natural polymers include the RNA and DNA that are so important in genes and life processes. In fact, messenger RNA is what makes possible proteins, peptides, and enzymes. Enzymes help do the chemistry inside living organisms and peptides make up some of the more interesting structural components of skin, hair, and even the horns of rhinos. Other natural polymers include polysaccharides (sugar polymers), Cellulose, starch, lignin, chitin and polypeptides like silk, keratin, and hair. Natural rubber is, naturally a natural polymer also, made from just carbon and hydrogen. These materials and their derivatives offer a wide range of properties and applications. Natural polymers tend to be readily biodegradable, although the rate of degradation is generally inversely proportional to the extent of chemical modification. US companies demand for natural polymers is forecast to expand 6.9 % annually to $4.6 billion in 2016. Cellulose ethers, methyl cellulose, will remain the largest product segment. This study analyses the $3.3 billion US natural biopolymer industries. It presents historical demand data for the years 2001, 2006 and 2011, and forecasts for 2016 and 2021 by market.
 
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Polymer Nano composites (PNC) are made of a polymers or copolymers having nanoparticles or Nano fillers dispersed in the polymer matrix. The plastic used for food packaging and non-food applications is non-biodegradable, and also of valuable and scarce non-renewable resources like petroleum. With the current research on exploring the alternatives to petrol and priority on reduced environmental impact, research is increased in development of biodegradable packaging from biopolymer-based materials. A biomaterial is a surface, or construct that interacts with biological systems. These biomaterials are about fifty years old. The study of such materials is called biomaterials science. It has been seen a strong growth over its past period, were many companies have been investing large amounts in the development of new products. Biomaterials science is the elements of medicine, biology, chemistry, tissue engineering and materials science. The Biomaterial market over the forecast period of 2016-2021 market for biomaterials is likely to predict to USD 70.90 Billion in 2012 and is steady to grow at a CAGR of 16.0% from 2016 to 2021 to reach USD 149.17 Billion by 2021.
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Tissue engineering is the immense area of research in recent years because of its vast potential in the repair or replacement of impaired tissues and organs. The present research will focus on scaffolds as they are one of the three most important factors, including seed cells, growth hormones and scaffolds in tissue engineering. Among the polymers used in tissue engineering, polyhydroxy esters (such as PLA, PGA, and PLGA) have extensive attention for a variety of biomedical applications. Besides, PCL has been widely used as a tissue engineering scaffold. Scaffolds have been used for tissue engineering such as bone, cartilage, ligament, skin, vascular tissues, neural tissues, and skeletal muscle and as vehicle for the delivery of drugs, proteins, and DNA. The worldwide market for tissue engineering and regeneration products is expected to reach USD 11.5 billion by 2022.
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Cellulose the most generous natural biopolymer on the earth, synthesized by plants, algae and also some species of bacteria and microorganisms. The Plant derivative cellulose and Black Carbon (BC) have the same chemical composition but differ in structure and physical properties. The BC network structure comprises cellulose Nano fibrils 3-8 nm in diameter, and the crystalline regions are been the normal cellulose I. The properties such as the Nano metric structure, unique physical and mechanical properties together produce higher purity that lead to great number of commercial products. Lignocellulosic agricultural byproducts are an extensive and cheap source for cellulose fibers. Agro-based Biofibers have the architecture, properties and design that make them suitable for use as composite, textile, pulp and paper manufacture. In addition, Biofibers can be used to produce biofuel, chemicals, enzymes and food. The global bio-fiber composites market reached $ 3.8 billion in 2016, with CAGR of 10% in last three years. Among them, the automotive and construction industry were the greater application segments. By 2023, this natural fiber composite market is expected to reach $7.6 billion (7.9% CAGR).
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Biodegradable polymers are a specific type of polymer that breaks down after its intended purpose to result in natural by-products such as gases (CO2, N2), water, biomass, and inorganic salts. These are found both naturally and synthetically made, and largely consist of ester, amide, and ether functional groups. Their properties and breakdown mechanism are determined by their exact structure. These polymers are often synthesized by condensation reactions, ring opening polymerization, and metal catalysts. There are vast examples and applications of biodegradable polymers.
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Polymer processing is the technique of converting raw polymeric materials into completed products having desirable shape, microstructures and properties. The raw form of polymers is available initially as pellets which are heated to its glass transition temperature to form into a viscous fluid. The fluid is then subjected to moulding and rapid solidification by cooling which results in the development of the required shape and microstructures. This method has been a standard since for thermoplastic processing since the 1960s. Thermosetting plastics utilize a similar processing method but with additives and cross-linking agents. The crosslinking formed after cooling are and irreversible and re-heating will not be effective in liquefying the polymers.
Polymers modeling process has become prominent since the last decade, especially for processing soft materials. New sampling methods are developed to increase the exploration of configuration space, which has been still continues to be of paramount importance in the determining the properties of polymeric materials. The time duration and scaling issues are being addressed with new coarse-grained methods, while more traditional methods are being applied in increasing chemical complexity and reality.
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Synthetic polymers are man-made polymers. For utility, it can be classified into four main categories: thermoplasticsthermosetselastomers and synthetic fibers. These polymers are commonly found in a variety of consumer products such as money, glue, etc.
In the field of Polymer science and nanotechnologyNano polymers and nanoclays have gained massive interests from researchers and in recent literatures. Nanotechnology is included in the most popular areas for today’s research and development and basically in all areas of technical disciplines. This also includes polymer science, which includes an wide range of sub-fields. Nanopolymers are used in microelectronics and the micro-devices are now below 100 nm. Both Nanopolymers and Polymer based Biomaterials are used for drug delivery, miniemulsion particles, fuel cell electrode polymer bound catalysts, polymer films, inprint lithography, electrospun nanofibers and polymer blends. Nanopolymers include various physical properties that are applied in composite reinforcement for imparting abilities to the composite such as barrier strength, electro-optical properties, flame resistance. Recent enthusiasm in polymer matrix based nanocomposites was emerged initially with interesting observations involving exfoliated clay and more recent studies with carbon nanotubes, carbon nanofibers, exfoliated graphite (graphene), nanocrystalline metals and a host of additional nanoscale inorganic filler or fiber modifications.
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Biobased polymers lead not only on the raw materials side but also on the other side through certain promising end-of-life (EOL) options. Exclusively waste disposal with energy recovery has an added advantage, which lies in benefiting carbon neutral energy while allowing multiple uses of possible recycling. The recent commission after research said that all of the composts contain biodegradable polymers materials could be classified using a risk assessment system at a higher toxicity position. Biodegradable polymers waste can serve for aerobic degradation, composting, or anaerobic digestion. When Biopolymer are propagated or digested, their individual elements are recycled naturally in particular in their carbon and hydrogen content. The greater segment of the market, packaging, is expected to reach nearly $980 billion in 2022. The second-largest market segment, made up of fibers/fabrics is expected to increase in volume from an estimated 435 million pounds in 2016 to USD 93.27 billion by 2025, growing at a CAGR of 12.1%.
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Bio related products can restore petroleum-related products, new methodologies, where various types of lignocellulosic biomass experience bioprocessing to commercially important products, must be devised. A relatively low value lignocellulosic biomass that could be used to produce bio based co-products is grass. Currently, many grasses are largely took the advantage for cropping by livestock or harvested as hay. To exploit this opportunity, the feasibility of using microbial bioconversion for the production of chemicals and polysaccharide gums from the fermentable sugars present in hydrolysates of various grass species. The production of 2.5 g/l was obtained when the cells were grown on medium containing 70 mM sucrose and 0.2% (w/v) Casamino Acids. It enriched medium is maximum Biopolymer production of up to 3.4 g/laws was obtained.
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Futures of Biopolymer demand the manufacturer for new materials is overwhelming. However the cost-effectiveness of the materials must progress as they are contributed specifically for sustainable development. Applications by the use of new materials should utilize the properties of these polymers, and the products should be developed based on those properties. They are onset to arrive as a result to be more responsible in taking care of the world we live in. Thus, the recent development for the bio-based products rather than petroleum or natural gas based products. The use of Biopolymer could markedly increase as more reliable form for the development and the cost to manufacture these Bioplastic continues to go fall. Bioplastic can be replaced with conventional plastics in the field of application which can be used in various categories such as food packaging, plastic plates, cups, cutlery, plastic storage bags, storage containers or other plastic or composite materials items you are buying and therefore can help in making environment sustainable. Bio-based polymers are adjacent to the conventional polymers than ever before. Now a day, biobased polymers are commonly found in various applications from commodity to hi-tech applications due to advance research development in biotechnology and public awareness.
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Polymer physics deals with the structure and properties of polymers and also the reaction kinetics of polymerization of monomers and degradation of polymers that are in the form of solids, glasses, elastomers, gels, solutions, melt and semi-crystalline. These properties are of great interests in polymer technologies such as optoelectronicscoatings, medicine, food and pharmacy. Polymer chemistry is a vast field that involves the study of monomers and polymerization and the synthesis of new materials from various combinations and characteristics. The composition of monomers and the applied chemical and processing techniques can largely affect the properties the polymer will possess at the end of the production.
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The Bioeconomy is the production of renewable biological resource and the conversion of these resources and waste into value products, like food, bio-based products, feed and bioenergy. These sectors have a strong potential for innovation due to their wide range of sciences that allows for industrial technologies. The shift to a feasible bio-based economy implies that the historically developed structures and the traditional way of life need to be completely reconsidered. Therefore, it is critical to bring into line researches into a broad basis to the solution of the budding societal challenges and to progressively integrate social and economic sciences, as well as cultural and humanities disciplines. The communal transition towards a bioeconomy raises questions around the ethical fundamentals as of the political and institutional framework conditions, in short, the regulating resources of such a comprehensive change.
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 Special Issues


  •  Journal of Chemical Engineering & Process Technology
  • Journal of Bioremediation & Biodegradation
  • Journal of Advanced Chemical Engineering
  • Journal of Material Sciences & Engineering
All accepted abstracts will be published in respective Conferenceseries International Journals.Abstracts will be provided with Digital Object Identifier by Cross Ref.
 
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