Amorphous Linear Aliphatic Polyesters for the Facile Preparation of Tunable Rapidly Degrading Elastomeric Devices and Delivery Vectors

Olson, D. A.; Gratton, Stephanie E. A.; DeSimone, Joseph M.; Sheares, Valerie V.

doi:10.1021/ja063092m

Cited by 70 publications

(76 citation statements)

References 48 publications

(98 reference statements)

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“…As it was previously mentioned, suitable techniques in modification of mechanical features are synthesis of copolymers with other monomers or preparation of blends with polylactones, polyethers, poly(amino acids), polycarbonates, polyurethanes and other polymers of natural and synthetic origin [34][35][36][37].…”

Section: Application Of Biodegradable Polymers In Tissue Engineeringmentioning

confidence: 99%

Biodegradable polymers suitable for tissue engineering and drug delivery systems

Porjazoska-Kujundziski¹,

Chamovska²

2017

Zas Mat

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Section: Application Of Biodegradable Polymers In Tissue Engineeringmentioning

confidence: 99%

Biodegradable polymers suitable for tissue engineering and drug delivery systems

Porjazoska-Kujundziski¹,

Chamovska²

2017

Zas Mat

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“…Poly(ester ether)s are prepared by reacting oligomeric ethylene glycol and trans-β-hydromuconic acid via the polycondensation reaction. Low M w poly(ester ether)s were obtained as amorphous liquids at room temperature (157,158). The double bonds of this polymer participate in cross-linking.…”

Section: Biodegradable Combination Polymersmentioning

confidence: 99%

“…The double bonds of this polymer participate in cross-linking. Therefore, they are promising biomaterials for filling nonuniform defects (158). Also, they can be fabricated into complex architectures, which is not easy with solid polyesters (158).…”

Section: Biodegradable Combination Polymersmentioning

confidence: 99%

Biodegradable Polymers: Medical Applications

Kunduru

Basu

Domb

2016

Encyclopedia of Polymer Science and Technology

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Biodegradable polymers are the “green materials” of the future. They break down into smaller chemical fragments and are finally eliminated from the body. Biodegradable polymers have been used for more than 50 years with diverse applications such as surgical sutures, wound dressings, tissue regeneration, enzyme immobilization, controlled drug delivery and gene delivery, tissue engineering scaffold, cryopreservation, nanotechnology, medical implants and devices, prosthetics, augmentation, cosmetics, sanitation products, coatings, adhesives, and many more. This article reviews synthetic (esters, amides, ethers, urethanes) and natural (polysaccharides and proteins) biodegradable polymers, highlighting their biomedical applications.

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“…20, 23 In addition to its potential conversion to large-scale commodity chemicals, MA is also an intermediate to trans-3-hexenedioic acid (t3HDA), a promising monomer for the production of bioadvantaged nylons ( Figure 1) and poly(ester)ethers: the additional double bond compared to adipic acid enables the subsequent functionalization of the polyamide, thus creating nylons with tailored properties. 17,24,25 Figure 1. Potential commercial products derived from unsaturated polyamide 6,6 (UPA 6,6).…”

Section: Introductionmentioning

confidence: 99%

Electrochemical Conversion of Biologically Produced Muconic Acid: Key Considerations for Scale-Up and Corresponding Technoeconomic Analysis

Matthiesen

Suástegui

et al. 2016

ACS Sustainable Chem. Eng.

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We present muconic acid, an unsaturated diacid that can be produced from cellulosic sugars and lignin monomers by fermentation, emerges as a promising intermediate for the sustainable manufacture of commodity polyamides and polyesters including Nylon-6,6 and polyethylene terephthalate (PET). Current conversion schemes consist in the biological production of cis,cis-muconic acid using metabolically engineered yeasts and bacteria, and the subsequent diversification to adipic acid, terephthalic acid, and their derivatives using chemical catalysts. In some instances, conventional precious metal catalysts can be advantageously replaced by base metal electrocatalysts. Here, we show the economic relevance of utilizing a hybrid biological-electrochemical conversion scheme to convert glucose to trans-3-hexenedioic acid (t3HDA), a monomer used for the synthesis of bioadvantaged 6. Potential roadblocks to biological and electrochemical integration in a single reactor, including electrocatalyst deactivation due to biogenic impurities and low faradaic efficiency inherent to side reactions in complex media, have been studied and addressed. In this study, t3HDA was produced with 94% yield and 100% faradaic efficiency. With consideration of the high t3HDA yield and faradaic efficiency, a technoeconomic analysis was developed on the basis of the current yield and titer achieved for muconic acid, the figures of merit defined for industrial electrochemical processes, and the separation of the desired product from the medium. On the basis of this analysis, t3HDA could be produced for approximately $2.00 kg -1. The low cost for t3HDA is a primary factor of the electrochemical route being able to cascade biological catalysis and electrocatalysis in one pot without separation of the muconic acid intermediate from the fermentation broth. AbstractMuconic acid, an unsaturated diacid that can be produced from cellulosic sugars and lignin monomers by fermentation, emerges as a promising intermediate for the sustainable manufacture of commodity polyamides and polyesters including Nylon-6,6 and polyethylene terephthalate (PET). Current conversion schemes consist in the biological production of cis,cis-muconic acid using metabolically engineered yeasts and bacteria, and the subsequent diversification to adipic acid, terephthalic acid, and their derivatives using chemical catalysts.In some instances, conventional precious metal catalysts can be advantageously replaced by base metal electrocatalysts. Here, we show the economic relevance of utilizing a hybrid biological-electrochemical conversion scheme to convert glucose to trans-3-hexenedioic acid (t3HDA), a monomer used for the synthesis of bioadvantaged Nylon-6,6. Potential roadblocks to biological and electrochemical integration in a single reactor, including electrocatalyst deactivation due to biogenic impurities and low faradaic efficiency inherent to side reactions in complex media, have been studied and addressed. In this study, t3HDA was produced with 94% yield and 100% farad...

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Amorphous Linear Aliphatic Polyesters for the Facile Preparation of Tunable Rapidly Degrading Elastomeric Devices and Delivery Vectors

Cited by 70 publications

References 48 publications

Biodegradable polymers suitable for tissue engineering and drug delivery systems

Biodegradable polymers suitable for tissue engineering and drug delivery systems

Biodegradable Polymers: Medical Applications

Electrochemical Conversion of Biologically Produced Muconic Acid: Key Considerations for Scale-Up and Corresponding Technoeconomic Analysis

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