Conducting polymer
Conductive biopolymers are obtained by structuring a network of conductive Nano fillers, carbon or metallic into insulating biopolymer matrices. It has many potential biomedical applications, ranging from a coating on neural electrodes, as a material in bio sensing and drug delivery, and as an electrically active platform for tissue engineering

• conductive paths
• electrical conductivity
• conductive fillers
• conductive particles
• Mechanical stress
• Sensor response

Biopolymer Nano composite
Polymer Nano composites or Nano filled polymers are polymer matrices containing organic or inorganic fillers with a homogeneous Nano scale distribution. It is prepared by physical blending or chemical polymerizing technologies .

• Polymer Nanocomposites
• Polymerizing technologies
• Inorganic filters
• Nano
• organic

Biodegradable and non-biodegradable polymer
These are the polymers which could decompose under aerobic or anaerobic situations, Due to the movement of microorganism/enzymes. Aliphatic polyesters are the maximum used polymers of this kind. Non-biodegradable polymers are proof against environmental degradation accordingly emerge as to build up in shape of waste, that has long chains such as Carbon and Hydrogen atoms. The interatomic bonding of those polymers is very strong and adamant, as a result making them proof against microbes which attempt to interrupt their bonds and digest them is very easy.

• Biodegradation
• Monomer
• Decomposed
• Eco friendly
• Recyle

Polylactic acid and biopolymer
PLA or Polylactic acid is crafted from dextrose (sugar) extracted from bio based substances. It is very famous and simplest biopolymer which is currently produced on a world scale plan. It is utilized in biomedical applications, for bottle production and in compostable food packaging. It is also being evaluated as a fabric for tissue engineering

• Polymerization
• Aliphatic polyester

Chemistry of bio polymer
When individual organic molecules are joined together in long chains, polymers are formed which have distinctly different characteristics in comparison to the smaller starting materials. The most important bio-polymers are DNA and RNA, proteins and polysaccharides. The building blocks for these molecules are respectively nucleotides, amino acids and carbohydrates

• • Biomolecules
• Polynucleotides
• Monomeric
• Polysaccharides
• Polypeptides

Nanotechnology for bio polymer
Biopolymer nanoparticles have been first designed using albumin and non-biodegradable synthetic polymers together with polyacrylamide. The risks of chronic toxicity due to the intracellular and/or tissue overloading of non-degradable polymers have been soon considered as a prime obstacle for the systemic management of polyacrylamide and poly nanoparticles in people. Therefore, the sort of nano particles that obtained a great deal interest turned into designed with artificial biodegradable polymers which includes polyalkylcyanoacrylate, poly (lactic-co-glycolic acid) and polyanhydride.

• Nano particle
• Nano filler
• Nano scale
• Nano materials
• Nano meter

Thermoplastic & thermosetting bio polymer
The main variance between this two polymer is thermoplastics can be re melted again right into a liquid, while thermosetting plastics continually stay in everlasting strong state, thermosetting plastics can only be heated and fashioned as soon as however in case of thermoplastics it might not manifest. Molecular weight of thermoplastic polymer is very excessive. In case of thermoplastic polymer chains are associated with intermolecular forces while thermosetting plastics bureaucracy chemical bonds.

• Infusible
• Pre polymer
• Elastomer
• Thermoplastic
• Thermosetting

3D printing of biopolymer
Driven via the development of three-D printing technology, printable thermoplastics have been advanced to fulfill the wide range of viable applications, which includes purposeful prototyping, molds and tooling, and final element manufacturing but, the few printable thermoplastics made from biological substances have confined packages, main to worries over environmental issues much like the ones faced in traditional production.

• Bioinks
• Rapid prototyping
• Binder material
• Inkjet-printer
• Biomaterials

Bio based Re Invention of plastics
By way of editing plastics we are able to improve and add a spread of characteristics. for instance, we will make the bio based polymers which are moisture resistant, extra soluble in water, extra sustainable, extra bendy, more clean, and extra well suited and/or biodegradable. Biopolymers may also have unique characteristics inclusive of antimicrobial effects, which may be used to add worth to cease products. modifying plastics is realised chemically by means of converting the structure of polymer chains, via processing or by way of adding additives together with plasticisers.

• More heat or moisture resistant
• More soluble in water
• More sustainable
• More flexible
• More clear, and more compatible and/or biodegradable

Application of bioplastics in medicine
Research and development of bioplastics materials for medical, dental and pharmaceutical use have hovered at the front strains for years. In some times, products are already to be had, and are actively being used by pharmaceutical organizations, field hospitals, trauma centers , surgeries, and clinics. Gelatin-based totally capsules product of animal or vegetable rely , for example, which evidently dissolve inside the digestive tract, are in commonplace use to govern dosages for many OTC (over-the-counter) and prescription medicinal drugs. Biodegradable stitches, which do not require manual removal after recovery, are regularly used to suture wounds and surgical incisions. Biodegradable bandages designed to promote clotting and proactive skin regeneration also are actively in use for traumatic wound care.

• Biomedical Applications
• Tissue engineering
• Wound management
• Drug delivery
• Orthopedic devices
• Manufacturing of fibrous and porous scaffolds

Poly saccharides in bio polymer
Polysaccharides are the most essential and famous bio based polymers used to make bioplastics in particular constitute starch and cellulose. Lesser regarded polysaccharides are Chitin located within the shells of insects and animals.

• Polymeric carbohydrate
• Glycosidic linkages
• Hydrolysis
• Amorphous
• Monosaccharide

Synthetic polymer
This is human-made polymer. Nylon and polyethylene are two famous example of synthetic polymer. The polymers which can be formed with the aid of linking monomer gadgets, without the any trade of fabric, are recognized to as addition polymers or additionally called as chain-boom polymers.

• Synthetic fibers
• Elastomers
• Vulkanization
• Inorganic polymers
• Bakelite

Relevance of bioplastics in food preservation
Bioplastics are used as alternatives to standard fossil fuel based plastics and are increasingly more being used in meals contact materials (FCMs).Biomass used for the production of bioplastics may be extracted from plant life (starch, cellulose) or produced by using microorganisms in fermentative processes. It is able to also be produced by further chemical changes and aren't always biodegradable.

• Oxidation
• Rancidity
• Enzymatic browning
• Carbon footprint
• Carcinogenic

Biopolymer composites
In the modern era, there's a burgeoning call for easy, pollutants-unfastened environment and excessive urgency for minimizing fossil fuel. This ends in an increasing call for manufacture of excessive performing cultured products from organic and renewable resources. Polymer biocomposites are the precise exchange to fulfil such alarming urgency. Those have residences of high mechanical resistance, thermogravimetric, oxygen barrier, biodegradation and chemical resistance. There may be no single material that could obtain such huge variety of residences for which layout of composites, mainly with biopolymers, is an strive for significant improvement of residences. The biopolymers can be functionalized for higher compatibility throughout guidance of composites.

• Composite material
• Natural fibers
• Cellulose fiber
• Green composites
• Hybrid composites
• Biorefinery

Bioplastic Engineering
Due to the developing amounts of plastic collecting in the Earth's oceans, not to mention landfills, there may be a actual want for a few form of biodegradable opportunity. Through the usage of engineering strategies bioplastics are crafted from combining a sugar referred to as thymidine with CO2 at low pressures and at room temperature. Bioplastic boxes may be made from rice, bioplastic meals wrappers may be fit for human consumption, waste frying oil may be transformed to bioplastic. It also can crafted from shrimps now and seaweed can be the limitless raw material for bioplastics.

• Environmental degradation
• Global production capacities
• Biopolymer commercialization
• Fossil fuel

Recycling Processing in Plastic Engineering and Waste Management
Plastic recycling is the process of improving unique varieties of plastic cloth to be able to reprocess them into various other merchandise, in contrast to their original form. An item constructed from plastic is recycled into a different product, which normally cannot be recycled again.

• Heat compression
• Conservation of Energy and Natural Resources
• Clears Landfill Space
• Cleaner and greener environment
• Identification and Classification of Plastic

Functional biopolymer
Functional polymer bearing different functional groups which have a extra polarity or reactivity than a traditional hydrocarbon chain .These macromolecular functional reagents may also be coupled with reactive groups on different oligomeric or polymeric chains to supply block or graft copolymers.

• Chemical heterogenecity
• Anionic Polymerization
• • Cationic Polymerization
• Free-radical polymerization
• Coordination Polymerization

Renewable resoures and biobased polymer
The continuous decline in fossil fuel resources combined with increase in oil prices has initiated a look for alternatives which can be primarily based on renewable resources for energy production. The production organic chemical substances from the software of petroleum and carbon based chemistry has created a variety of initiatives to update fossil resources with renewable materials. Tremendous efforts are being conducted in polymer science and technology to produce macromolecular polymers from renewable resources.

• Bio composites from renewable resources
• Technology of poly lactic acid
• Development of biodegradable plastics from renewable sources
• Biopolymers from microbial sources
• Production of biopolymers from vegetable oils

Super molecular Bio polymer
They are polymeric arrays of monomer units, held together by reversible and highly directional secondary interactions — that is, non-covalent bonds, such as hydrogen bonds. The resulting materials therefore maintain their polymeric properties in solution. The directions and strengths of the interactions are precisely tuned so that the array of molecules behaves as a polymer

• Monomeric units
• Non-covalent interactions
• π-π interaction
• Self-healing
• Host–guest interaction

Optoelectronics Bio polymer
By examining the effects of polymer thickness, salt type and salt concentration on the optical contrast and current a device is produced. The optical contrast of the device is the difference in transmission between the colored state and the uncolored state, which can help us understand many things about the physics of the devices such as the doping process and the band structure of the material

• Photonics
• Transducer
• Quantum mechanical effect
• Semiconductor
• Electric field

Conjugated micro porous Bio polymer
Conjugated microporous bio polymers (CMPs) are a class of organic porous polymers that integrate π-conjugated skeletons with permanent nanopores, in sharp assessment to different porous materials that are not π-conjugated and with traditional conjugated polymers which are nonporous. As an rising material platform, This provide a high flexibility for the molecular design of conjugated skeletons and nanopores. various chemical reactions, constructing blocks and artificial techniques have been developed and a broad style of CMPs with specific structures and unique properties were synthesized, driving the fast growth of the field

• Porous materials
• microporosity
• Metal-organic frameworks
• Rigidity
• Crystalline

BioPolymer Rhenology
Polymer rheology examining is look at of how the strain in a material or force carried out is related to deformation and glide of the material.Information the rheological properties of polymers thru laboratory checking out can help to optimize products and process conditions, thereby saving prices and minimizing capability waste.

• Junction Zone
• Viscoelastic Modulus
• Mechanical Spectrum
• Apparent Yield Stress
• • Newtonian Plateau

Bio catalysis in polymer chemistry
Biocatalysts are increasingly being utilized in polymer science, resulting in many new reactions, new techniques, and new commercial possibilities. each enzymatic and complete-cellular strategies have received much attention, and new or progressed methodologies appear often. Ongoing biocatalytic paintings appears to be focused alongside several issues: polymerization, polymer amendment reactions, polymer degradation, and synthesis of monomers and reactive oligomers. a top level view is furnished herein of this interesting region of research. The papers included in this symposium volume are mainly highlighted.

• Chemoenzymatic reactions
• Chemoselectivity
• Regioselectivity
• Diastereoselectivity
• Enantioselectivity

Thermally stable bio polymer
Polyimides (PI) are a class of thermally stable polymers. According to the composition of their main chain PI can be aliphatic, semi-aromatic, and the most used aromatic. Thermosetting PIs have outstanding thermal stability, good chemical resistance, and excellent mechanical properties.

• Thermal stability
• Decomposition
• Thermogravimetric Analysis