Ring-opening copolymerization of L-lactide and ɛ-caprolactone in supercritical carbon dioxide using triblock oligomers of caprolactone and PEG as stabilizers

Abstract: In this study, the use of triblock (A-B-A) oligomers of e-caprolactone (e-CL) (A) and PEG400 (B) as stabilizers (SB) for the copolymerization of L-lactide (LLA) and e-CL in supercritical carbon dioxide (scCO 2 ) was investigated. To determine the effect of CO 2 -philic and polymer-philic segments on copolymerization, oligomers with three different average molecular weights (M w ¼2000-6000 Da) were synthesized by changing the PEG400/e-CL ratio. Copolymerizations were confirmed by 1 H-nuclear magnetic resonance … Show more

“…The cleaning process also removed all residuals within the matrix as previously reported. 19,20,[25][26][27][28] Here, we have observed a similar behavior, the materials look optically very clear after scCO 2 treatment. More importantly, almost all the NaCl particles were removed from the matrix after salt extraction (Figure 1(b)).…”

“…23,24 In this study and in the previous study, scCO 2 treatment was applied to both the synthesis of biodegradable polymers (lactide and ϵ-caprolactone homopolymer and copolymers) and the preparation of tissue engineering scaffolds. 19,20,25,26…”

“…23,24 In this study and in the previous study, scCO 2 treatment was applied to both the synthesis of biodegradable polymers (lactide and ε-caprolactone homopolymer and copolymers) and the preparation of tissue engineering scaffolds. 19,20,25,26 The porous silicone disks prepared using NaCl crystals in the size range of 250-355 µm with three different salt loadings 60%, 70%, and 80% (w/w) were treated in scCO 2 media. [21][22][23] The average pore sizes and porosities of the silicone scaffolds after scCO 2 treatment are listed in Table 2.…”

Macroporous silicone biomaterials with modified surface chemistry: Production and characterization

“…The cleaning process also removed all residuals within the matrix as previously reported. 19,20,[25][26][27][28] Here, we have observed a similar behavior, the materials look optically very clear after scCO 2 treatment. More importantly, almost all the NaCl particles were removed from the matrix after salt extraction (Figure 1(b)).…”

“…23,24 In this study and in the previous study, scCO 2 treatment was applied to both the synthesis of biodegradable polymers (lactide and ϵ-caprolactone homopolymer and copolymers) and the preparation of tissue engineering scaffolds. 19,20,25,26…”

“…23,24 In this study and in the previous study, scCO 2 treatment was applied to both the synthesis of biodegradable polymers (lactide and ε-caprolactone homopolymer and copolymers) and the preparation of tissue engineering scaffolds. 19,20,25,26 The porous silicone disks prepared using NaCl crystals in the size range of 250-355 µm with three different salt loadings 60%, 70%, and 80% (w/w) were treated in scCO 2 media. [21][22][23] The average pore sizes and porosities of the silicone scaffolds after scCO 2 treatment are listed in Table 2.…”

Macroporous silicone biomaterials with modified surface chemistry: Production and characterization

“…In order to serve their purpose, biodegradable polymers such as PCL can be used in combination with each other. Moreover, different techniques, such as blending of polymers [ 20 ], copolymerization [ 21 ], fabrication of biocomposite with biofillers [ 22 , 23 ], grafting [ 24 ], crosslinking [ 25 ], etc., can be used to tailor the properties of the PCL based final product. Fabrication of the composite with fillers via blending, in situ polymerization [ 26 ], and reinforcement [ 27 ], is a promising approach to tailor the final product’s properties, such as mechanical strength, toughness, stiffness, biodegradability, and behavior of shape memory.…”

Shape Memory Polyurethane Biocomposites Based on Toughened Polycaprolactone Promoted by Nano-Chitosan

“…50,51,45,52 For example, scCO 2 was previously employed as a solvent for the synthesis of linear PCL by ROP of ε-CL using Sn(Oct) 2 or Novozym 435 as a catalyst. 33,50,53,54 In this work, we studied several polyols, including 1,6-hexanediol, glycerol, pentaerythritol and triglycerol, as initiators for the synthesis of star polyol-PCL by ring opening polymerisation. Eventually, we investigated the synthesis of complex star PCL architectures using a renewable polyol core, D-sorbitol, as the initiator, aiming at establishing an environmentally benign process to make biodegradable star D-sorbitol-PCL under mild conditions.…”

Sustainable synthesis and precise characterisation of bio-based star polycaprolactone synthesised with a metal catalyst and with lipase