Poly(ω-pentadecalactone-co-p-dioxanone) [poly(PDL-co-DO)] copolyesters are copolymers of an isodimorphic system, which remain semicrystalline over the whole range of compositions. Here, we evaluated enzymatically synthesized poly(PDL-co-DO) copolymers as new materials for biomedical applications. In vivo experiments using mice, showed that the copolyesters are well tolerated, with tissue responses that are comparable to poly(p-dioxanone). In addition, the copolymers were found to degrade hydrolytically at controlled rates over a period of several months under physiological conditions. The poly(PDL-co-DO) copolymers with up to 69 mol% DO units were successfully transformed to free-standing nanoparticles that are capable of encapsulating an anticancer drug, doxorubicin, or a polynucleotide, siRNA. Drug- or siRNA-loaded nanoparticles exhibited controlled and continuous release of agent over many weeks. In addition, siLUC-encapsulated poly(PDL-co-DO) nanoparticles were active in inhibiting luciferase gene expression in LUC-RKO cells. Because of substantial differences in structure and hydrophobicity between PDL and DO units, poly(PDL-co-DO) biodegradation rate and physical properties can be tuned over a wide range depending on the copolymer composition. Our results demonstrate that the semicrystalline and biodegradable poly(PDL-co-DO) copolyesters are promising biomaterials to serve as drug carriers, as well as potential raw materials for constructing bioabsorbable sutures and other medical devices.
Poly(ω-pentadecalactone-co-n>an class="Chemical">p-dioxanone) [poly(PDL-co-DO)] copolyesters are copolymers of an isodimorphic system, which remain semicrystalline over the whole range of compositions. Here, we evaluated enzymatically synthesized poly(PDL-co-DO) copolymers as new materials for biomedical applications. In vivo experiments using mice, showed that the copolyesters are well tolerated, with tissue responses that are comparable to poly(p-dioxanone). In addition, the copolymers were found to degrade hydrolytically at controlled rates over a period of several months under physiological conditions. The poly(PDL-co-DO) copolymers with up to 69 mol% DO units were successfully transformed to free-standing nanoparticles that are capable of encapsulating an anticancer drug, doxorubicin, or a polynucleotide, siRNA. Drug- or siRNA-loaded nanoparticles exhibited controlled and continuous release of agent over many weeks. In addition, siLUC-encapsulated poly(PDL-co-DO) nanoparticles were active in inhibiting luciferase gene expression in LUC-RKO cells. Because of substantial differences in structure and hydrophobicity between PDL and DO units, poly(PDL-co-DO) biodegradation rate and physical properties can be tuned over a wide range depending on the copolymer composition. Our results demonstrate that the semicrystalline and biodegradable poly(PDL-co-DO) copolyesters are promising biomaterials to serve as drug carriers, as well as potential raw materials for constructing bioabsorbable sutures and other medical devices.
Authors: F Tewes; E Munnier; B Antoon; L Ngaboni Okassa; S Cohen-Jonathan; H Marchais; L Douziech-Eyrolles; M Soucé; P Dubois; I Chourpa Journal: Eur J Pharm Biopharm Date: 2007-02-28 Impact factor: 5.571
Authors: R S Bezwada; D D Jamiolkowski; I Y Lee; V Agarwal; J Persivale; S Trenka-Benthin; M Erneta; J Suryadevara; A Yang; S Liu Journal: Biomaterials Date: 1995-10 Impact factor: 12.479
Authors: Evan M Chen; Amanda R Quijano; Young-Eun Seo; Christopher Jackson; Alexander D Josowitz; Seth Noorbakhsh; Andrea Merlettini; Ranjini K Sundaram; Maria Letizia Focarete; Zhaozhong Jiang; Ranjit S Bindra; W Mark Saltzman Journal: Biomaterials Date: 2018-06-18 Impact factor: 12.479
Authors: Jagadish Beloor; Shalley N Kudalkar; Gina Buzzelli; Fan Yang; Hanna K Mandl; Jyothi K Rajashekar; Krasimir A Spasov; William L Jorgensen; W Mark Saltzman; Karen S Anderson; Priti Kumar Journal: Bioeng Transl Med Date: 2021-06-26