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The use of polymers in biological applications is defined by the interactions promoted between living organisms and polymeric chains, which are generally associated with the polymers’ hydrophilic and hydrophobic behaviors. However, these water-friendly structures are also very useful for other applications, such as the adsorption of pollutants from sewage water. The modulation of the final properties of water-soluble and insoluble polymers tends to define the spectra of features associated with their final applications.
poly(lactic acid) --- water emulsions --- water dispersions --- film formation --- waterborne coating --- microcapsule --- self-healing --- core material --- clad ratio --- poly(vinyl alcohol) --- glycerol --- microplastics --- biodegradation --- toxicity --- marine water --- thermoresponsive polymers --- hydrophobic transitions --- lower critical solution temperature --- functionalized materials --- contact angle --- drug delivery --- PBCA --- molecular weights --- biodegradable polymers --- NMR --- Advanced Polymer Chromatography™ --- chitosan --- sustainable development --- circular economy --- biopolymers --- n/a --- Research. --- Biology.
Choose an application
The use of polymers in biological applications is defined by the interactions promoted between living organisms and polymeric chains, which are generally associated with the polymers’ hydrophilic and hydrophobic behaviors. However, these water-friendly structures are also very useful for other applications, such as the adsorption of pollutants from sewage water. The modulation of the final properties of water-soluble and insoluble polymers tends to define the spectra of features associated with their final applications.
Research. --- Biology. --- poly(lactic acid) --- water emulsions --- water dispersions --- film formation --- waterborne coating --- microcapsule --- self-healing --- core material --- clad ratio --- poly(vinyl alcohol) --- glycerol --- microplastics --- biodegradation --- toxicity --- marine water --- thermoresponsive polymers --- hydrophobic transitions --- lower critical solution temperature --- functionalized materials --- contact angle --- drug delivery --- PBCA --- molecular weights --- biodegradable polymers --- NMR --- Advanced Polymer Chromatography™ --- chitosan --- sustainable development --- circular economy --- biopolymers --- poly(lactic acid) --- water emulsions --- water dispersions --- film formation --- waterborne coating --- microcapsule --- self-healing --- core material --- clad ratio --- poly(vinyl alcohol) --- glycerol --- microplastics --- biodegradation --- toxicity --- marine water --- thermoresponsive polymers --- hydrophobic transitions --- lower critical solution temperature --- functionalized materials --- contact angle --- drug delivery --- PBCA --- molecular weights --- biodegradable polymers --- NMR --- Advanced Polymer Chromatography™ --- chitosan --- sustainable development --- circular economy --- biopolymers
Choose an application
The use of polymers in biological applications is defined by the interactions promoted between living organisms and polymeric chains, which are generally associated with the polymers’ hydrophilic and hydrophobic behaviors. However, these water-friendly structures are also very useful for other applications, such as the adsorption of pollutants from sewage water. The modulation of the final properties of water-soluble and insoluble polymers tends to define the spectra of features associated with their final applications.
Research & information: general --- Biology, life sciences --- poly(lactic acid) --- water emulsions --- water dispersions --- film formation --- waterborne coating --- microcapsule --- self-healing --- core material --- clad ratio --- poly(vinyl alcohol) --- glycerol --- microplastics --- biodegradation --- toxicity --- marine water --- thermoresponsive polymers --- hydrophobic transitions --- lower critical solution temperature --- functionalized materials --- contact angle --- drug delivery --- PBCA --- molecular weights --- biodegradable polymers --- NMR --- Advanced Polymer Chromatography™ --- chitosan --- sustainable development --- circular economy --- biopolymers --- n/a --- Research. --- Biology.
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“Functional Polymer Solutions and Gels—Physics and Novel Applications” contains a broad range of articles in this vast field of polymer and soft matter science. It shows insight into the field by highlighting how sticky (non-covalent) chemical bonds can assemble a seemingly water-like liquid into a gel, how ionic liquids influence the gelation behavior of poly(N-Isopropylacrylamide) as well as how the molecular composition of functional copolymers is reflected in the temperature-responsiveness. These physics were augmented by theoretical works on drag-reduction. Also, drug-release – an improved control of how fast or dependent on an external factor – and antibacterial properties were the topic of several works. Biomedical applications on how cell growth can be influenced and how vessels in biological systems, e.g., blood vessels, can be improved by functional polymers were complemented with papers on tomography by using gels. On totally different lines, also the topic of how asphalt can be improved and how functional polymers can be used for the enrichment and removal of substances. These different papers are a good representation of the whole area of functional polymers.
Poly(N-isopropylacrylamide) --- tacticity --- ionic liquid --- rheology --- hydrogel --- vascular graft --- braided fiber strut --- swellability --- mechanical property --- N-isopropylacrylamide --- lower critical solution temperature --- thermoresponsive polymers --- hydrophobic interactions --- statistical modeling --- SBS-modified asphalt binder --- UV aging --- rheological properties --- functional group --- cracking --- osteoporosis --- strontium --- polyphenol tannic acid --- titanium --- osteoblasts --- osteoclasts --- hydrophilic molecularly imprinted chitosan --- deep eutectic solvents --- solid phase microextraction --- gallic acid --- response surface methodology --- coating --- drug delivery --- surface roughness --- polymers --- mesoporous silica --- polypropylene --- nonwoven fibers --- plasma --- imprinted polymer --- chromium --- carbon-fibers --- multifunctional composites --- nanocomposites --- fracture toughness --- associative polymer colloids --- micellar assemblies --- Reynolds stress model --- polymer --- turbulent model --- drag reduction --- DNS --- responsive gels in biomedical and diagnostic applications --- gel --- precision --- radiation therapy --- dosimetry --- 3D --- flattening filter free --- FFF --- oxygen scavenger --- dose rate --- magnetic resonance --- fluorescent gels --- radio-fluorogenic (RFG) gel --- tomographic fluorescence imaging --- polymer-gel radiation dosimetry --- 3D radiation dosimetry --- microscopic characteristic --- poly (styrene-butadiene-styrene)-modified asphalt --- modified clamps --- adhesion --- n/a
Choose an application
“Functional Polymer Solutions and Gels—Physics and Novel Applications” contains a broad range of articles in this vast field of polymer and soft matter science. It shows insight into the field by highlighting how sticky (non-covalent) chemical bonds can assemble a seemingly water-like liquid into a gel, how ionic liquids influence the gelation behavior of poly(N-Isopropylacrylamide) as well as how the molecular composition of functional copolymers is reflected in the temperature-responsiveness. These physics were augmented by theoretical works on drag-reduction. Also, drug-release – an improved control of how fast or dependent on an external factor – and antibacterial properties were the topic of several works. Biomedical applications on how cell growth can be influenced and how vessels in biological systems, e.g., blood vessels, can be improved by functional polymers were complemented with papers on tomography by using gels. On totally different lines, also the topic of how asphalt can be improved and how functional polymers can be used for the enrichment and removal of substances. These different papers are a good representation of the whole area of functional polymers.
Research & information: general --- Poly(N-isopropylacrylamide) --- tacticity --- ionic liquid --- rheology --- hydrogel --- vascular graft --- braided fiber strut --- swellability --- mechanical property --- N-isopropylacrylamide --- lower critical solution temperature --- thermoresponsive polymers --- hydrophobic interactions --- statistical modeling --- SBS-modified asphalt binder --- UV aging --- rheological properties --- functional group --- cracking --- osteoporosis --- strontium --- polyphenol tannic acid --- titanium --- osteoblasts --- osteoclasts --- hydrophilic molecularly imprinted chitosan --- deep eutectic solvents --- solid phase microextraction --- gallic acid --- response surface methodology --- coating --- drug delivery --- surface roughness --- polymers --- mesoporous silica --- polypropylene --- nonwoven fibers --- plasma --- imprinted polymer --- chromium --- carbon-fibers --- multifunctional composites --- nanocomposites --- fracture toughness --- associative polymer colloids --- micellar assemblies --- Reynolds stress model --- polymer --- turbulent model --- drag reduction --- DNS --- responsive gels in biomedical and diagnostic applications --- gel --- precision --- radiation therapy --- dosimetry --- 3D --- flattening filter free --- FFF --- oxygen scavenger --- dose rate --- magnetic resonance --- fluorescent gels --- radio-fluorogenic (RFG) gel --- tomographic fluorescence imaging --- polymer-gel radiation dosimetry --- 3D radiation dosimetry --- microscopic characteristic --- poly (styrene-butadiene-styrene)-modified asphalt --- modified clamps --- adhesion --- Poly(N-isopropylacrylamide) --- tacticity --- ionic liquid --- rheology --- hydrogel --- vascular graft --- braided fiber strut --- swellability --- mechanical property --- N-isopropylacrylamide --- lower critical solution temperature --- thermoresponsive polymers --- hydrophobic interactions --- statistical modeling --- SBS-modified asphalt binder --- UV aging --- rheological properties --- functional group --- cracking --- osteoporosis --- strontium --- polyphenol tannic acid --- titanium --- osteoblasts --- osteoclasts --- hydrophilic molecularly imprinted chitosan --- deep eutectic solvents --- solid phase microextraction --- gallic acid --- response surface methodology --- coating --- drug delivery --- surface roughness --- polymers --- mesoporous silica --- polypropylene --- nonwoven fibers --- plasma --- imprinted polymer --- chromium --- carbon-fibers --- multifunctional composites --- nanocomposites --- fracture toughness --- associative polymer colloids --- micellar assemblies --- Reynolds stress model --- polymer --- turbulent model --- drag reduction --- DNS --- responsive gels in biomedical and diagnostic applications --- gel --- precision --- radiation therapy --- dosimetry --- 3D --- flattening filter free --- FFF --- oxygen scavenger --- dose rate --- magnetic resonance --- fluorescent gels --- radio-fluorogenic (RFG) gel --- tomographic fluorescence imaging --- polymer-gel radiation dosimetry --- 3D radiation dosimetry --- microscopic characteristic --- poly (styrene-butadiene-styrene)-modified asphalt --- modified clamps --- adhesion
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