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1. Sustainable synthesis of CO ₂ -derived polycarbonates from d -xylose

   https://doi.org/10.1039/D1PY00784J  

   Tran, David K.; Rashad, Ahmed Z.; Darensbourg, Donald J.; Wooley, Karen L. (September 2021, Polymer Chemistry)

   Synthetic transformation of d -xylose into a four-membered cyclic ether allows for reactions with carbon dioxide (CO 2 ) leading to linear polycarbonates by either a one-step ring-opening copolymerisation (ROCOP) directly, or by sequential isolation of a preformed six-membered cyclic carbonate followed by ring-opening polymerisation (ROP). 

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2. Bio-based polycarbonates derived from the neolignan honokiol

   https://doi.org/10.1039/C6RA19568G  

   Wacker, Kevin T.; Kristufek, Samantha L.; Lim, Soon-Mi; Kahn, Sarosh; Wooley, Karen L. (January 2016, RSC Advances)

   Honokiol, a highly functional phenolic- and alkenyl-containing neolignan natural product isolated from several Magnolia plant species, is an interesting bio-based resource, which is shown to be useful directly as a monomer for the rapid and scalable synthesis of poly(honokiol carbonate) (PHC). PHC was synthesized in one step from the natural product using condensation polymerization methods. Polymers of number average molecular weight ( M n ) ranging from 10–55 kDa were obtained on gram scales in yields up to 80%. Thermal analysis demonstrated high thermal stability, with degradation temperatures in excess of ca. 450 °C. Mechanical testing of several PHC polymers indicated a generally increasing storage modulus with increasing M n and a similar trend with T g . With an interest toward cardiovascular applications, initial cytotoxicity and fluorescence cell imaging studies were conducted and showed no cytotoxicity toward coronary venular endothelial cells (CVECs), which proliferated on PHC thin films up to a month. Bulk PHC is a robust material, as it underwent slow hydrolytic degradation under basic conditions ( ca. 0.1% per day under 1 M NaOH (aq) ), and no observable degradation under acidic and neutral conditions, each at 37 °C over 130 days. These polycarbonates serve as potential specialty engineering- or bio-materials derived from a commercially-available natural product monomer. 

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3. Functional sugar-based polymers and nanostructures comprised of degradable poly( d -glucose carbonate)s

   https://doi.org/10.1039/C6PY01978A  

   Su, Lu; Khan, Sarosh; Fan, Jingwei; Lin, Yen-Nan; Wang, Hai; Gustafson, Tiffany P.; Zhang, Fuwu; Wooley, Karen L. (January 2017, Polymer Chemistry)

   Fundamental synthetic methodology was advanced to allow for the preparation of a reactive glucose-based block copolycarbonate, which was conveniently transformed into a series of amphiphilic block copolymers that underwent aqueous assembly into functional nanoparticle morphologies having practical utility in biomedical and other applications. Two degradable d -glucose carbonate monomers, with one carrying alkyne functionality, were designed and synthesized to access well-defined block polycarbonates ( Đ < 1.1) via sequential organocatalytic ring opening polymerizations (ROPs). Kinetic studies of the organocatalyzed sequential ROPs showed a linear relationship between the monomer conversion and the polymer molecular weight, which indicated the controlled fashion during each polymerization. The pendant alkyne groups underwent two classic click reactions, copper-catalyzed azide–alkyne dipolar cycloaddition (CuAAC) and thiol–yne addition reactions, which were employed to render hydrophilicity for the alkyne-containing block and to provide a variety of amphiphilic diblock poly( d -glucose carbonate)s (PGCs). The resulting amphiphilic PGCs were further assembled into a family of nanostructures with different sizes, morphologies, surface charges and functionalities. These non-ionic and anionic nanoparticles showed low cytotoxicity in RAW 264.7 mouse macrophage cells and MC3T3 healthy mouse osteoblast precursor cells, while the cationic nanoparticles exhibited significantly higher IC 50 (162 μg mL −1 in RAW 264.7; 199 μg mL −1 in MC3T3) compared to the commercially available cationic lipid-based formulation, Lipofectamine (IC 50 = 31 μg mL −1 ), making these nanomaterials of interest for biomedical applications. 

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4. Ring-Opening Polymerization of Cyclic Esters and Carbonates with (Thio)urea/Cyclopropenimine Organocatalytic Systems

   https://doi.org/10.1021/acsmacrolett.3c00716  

   Morodo, Romain; Dumas, David M; Zhang, Jia; Lui, Kai H; Hurst, Paul J; Bosio, Riccardo; Campos, Luis M; Park, Nathaniel H; Waymouth, Robert M; Hedrick, James L (January 2024, ACS Macro Letters)

   Rowan, Stuart J (Ed.)

   Organocatalyzed ring-opening polymerization is a powerful tool for the synthesis of a variety of functional readily degradable polyesters and polycarbonates. We report the use of (thio)ureas in combination with cyclopropenimine bases as unique catalyst for the polymerization of cyclic esters and carbonates with a large span of reactivities. Methodologies of exceptionally effective and selective cocatalyst combinations were devised to produce polyesters and polycarbonates with narrow dispersity (Đ = 1.01 – 1.10). Correlations of the pKa of the various ureas and cyclopropenimine bases revealed the critical importance of matching the pKa of the two cocatalysts to achieve the most efficient polymerization conditions. It was found that promoting strong H-bonding interactions with a noncompetitive organic solvent, such as CH2Cl2, enabled greatly accelerated polymerization rates. The stereoselective polymerization of rac-lactide afforded stereoblock poly(lactides) that crystallize as stereocomplexes, as confirmed by wide-angle x-ray scattering. 

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5. Recent Advances in Sequence‐Controlled Ring‐Opening Copolymerizations of Monomer Mixtures

   https://doi.org/10.1002/asia.202201147  

   Wang, Xiaoqian; Huo, Ziyu; Xie, Xiaoyu; Shanaiah, Narasimhamurthy; Tong, Rong (January 2023, Chemistry – An Asian Journal)

   Abstract Transforming renewable resources into functional and degradable polymers is driven by the ever‐increasing demand to replace unsustainable polyolefins. However, the utility of many degradable homopolymers remains limited due to their inferior properties compared to commodity polyolefins. Therefore, the synthesis of sequence‐defined copolymers from one‐pot monomer mixtures is not only conceptually appealing in chemistry, but also economically attractive by maximizing materials usage and improving polymers’ performances. Among many polymerization strategies, ring‐opening (co)polymerization of cyclic monomers enables efficient access to degradable polymers with high control on molecular weights and molecular weight distributions. Herein, we highlight recent advances in achieving one‐pot, sequence‐controlled polymerizations of cyclic monomer mixtures using a single catalytic system that combines multiple catalytic cycles. The scopes of cyclic monomers, catalysts, and polymerization mechanisms are presented for this type of sequence‐controlled ring‐opening copolymerization. 

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