147 related articles for article (PubMed ID: 28532063)
21. Biodegradable poly(ether-ester) multiblock copolymers for controlled release applications.
van Dijkhuizen-Radersma R; Roosma JR; Kaim P; Métairie S; Péters FL; de Wijn J; Zijlstra PG; de Groot K; Bezemer JM
J Biomed Mater Res A; 2003 Dec; 67(4):1294-304. PubMed ID: 14624516
[TBL] [Abstract][Full Text] [Related]
22. Controlled Release of Salicylic Acid from Biodegradable Cross-Linked Polyesters.
Dasgupta Q; Chatterjee K; Madras G
Mol Pharm; 2015 Sep; 12(9):3479-89. PubMed ID: 26284981
[TBL] [Abstract][Full Text] [Related]
23. Novel biodegradable star-shaped polylactide scaffolds for bone regeneration fabricated by two-photon polymerization.
Timashev P; Kuznetsova D; Koroleva A; Prodanets N; Deiwick A; Piskun Y; Bardakova K; Dzhoyashvili N; Kostjuk S; Zagaynova E; Rochev Y; Chichkov B; Bagratashvili V
Nanomedicine (Lond); 2016 May; 11(9):1041-53. PubMed ID: 27078220
[TBL] [Abstract][Full Text] [Related]
24. Synthesis and electrospinning of ε-polycaprolactone-bioactive glass hybrid biomaterials via a sol-gel process.
Allo BA; Rizkalla AS; Mequanint K
Langmuir; 2010 Dec; 26(23):18340-8. PubMed ID: 21050002
[TBL] [Abstract][Full Text] [Related]
25. Networks based on biodegradable polyesters: An overview of the chemical ways of crosslinking.
Mangeon C; Renard E; Thevenieau F; Langlois V
Mater Sci Eng C Mater Biol Appl; 2017 Nov; 80():760-770. PubMed ID: 28866226
[TBL] [Abstract][Full Text] [Related]
26. Controlled Release of Usnic Acid from Biodegradable Polyesters to Inhibit Biofilm Formation.
Dasgupta Q; Madras G; Chatterjee K
ACS Biomater Sci Eng; 2017 Mar; 3(3):291-303. PubMed ID: 33465928
[TBL] [Abstract][Full Text] [Related]
27. Chemical crosslinking of biopolymeric scaffolds: Current knowledge and future directions of crosslinked engineered bone scaffolds.
Oryan A; Kamali A; Moshiri A; Baharvand H; Daemi H
Int J Biol Macromol; 2018 Feb; 107(Pt A):678-688. PubMed ID: 28919526
[TBL] [Abstract][Full Text] [Related]
28. Four-Dimensional Printing Hierarchy Scaffolds with Highly Biocompatible Smart Polymers for Tissue Engineering Applications.
Miao S; Zhu W; Castro NJ; Leng J; Zhang LG
Tissue Eng Part C Methods; 2016 Oct; 22(10):952-963. PubMed ID: 28195832
[TBL] [Abstract][Full Text] [Related]
29. New generation poly(ε-caprolactone)/gel-derived bioactive glass composites for bone tissue engineering: Part I. Material properties.
Dziadek M; Menaszek E; Zagrajczuk B; Pawlik J; Cholewa-Kowalska K
Mater Sci Eng C Mater Biol Appl; 2015 Nov; 56():9-21. PubMed ID: 26249560
[TBL] [Abstract][Full Text] [Related]
30. Preparation and evaluation of biodegradable films containing the potent osteogenic compound BFB0261 for localized delivery.
Umeki N; Sato T; Harada M; Takeda J; Saito S; Iwao Y; Itai S
Int J Pharm; 2011 Feb; 404(1-2):10-8. PubMed ID: 21047548
[TBL] [Abstract][Full Text] [Related]
31. Human osteoprogenitor bone formation using encapsulated bone morphogenetic protein 2 in porous polymer scaffolds.
Yang XB; Whitaker MJ; Sebald W; Clarke N; Howdle SM; Shakesheff KM; Oreffo RO
Tissue Eng; 2004; 10(7-8):1037-45. PubMed ID: 15363161
[TBL] [Abstract][Full Text] [Related]
32. Surface modification of 3D-printed porous scaffolds via mussel-inspired polydopamine and effective immobilization of rhBMP-2 to promote osteogenic differentiation for bone tissue engineering.
Lee SJ; Lee D; Yoon TR; Kim HK; Jo HH; Park JS; Lee JH; Kim WD; Kwon IK; Park SA
Acta Biomater; 2016 Aug; 40():182-191. PubMed ID: 26868173
[TBL] [Abstract][Full Text] [Related]
33. Fabrication, characterization, and in vitro evaluation of poly(lactic acid glycolic acid)/nano-hydroxyapatite composite microsphere-based scaffolds for bone tissue engineering in rotating bioreactors.
Lv Q; Nair L; Laurencin CT
J Biomed Mater Res A; 2009 Dec; 91(3):679-91. PubMed ID: 19030184
[TBL] [Abstract][Full Text] [Related]
34. Reinforcement of poly-l-lactic acid electrospun membranes with strontium borosilicate bioactive glasses for bone tissue engineering.
Fernandes JS; Gentile P; Martins M; Neves NM; Miller C; Crawford A; Pires RA; Hatton P; Reis RL
Acta Biomater; 2016 Oct; 44():168-77. PubMed ID: 27554018
[TBL] [Abstract][Full Text] [Related]
35. Fabricating poly(1,8-octanediol citrate) elastomer based fibrous mats via electrospinning for soft tissue engineering scaffold.
Zhu L; Zhang Y; Ji Y
J Mater Sci Mater Med; 2017 Jun; 28(6):93. PubMed ID: 28510114
[TBL] [Abstract][Full Text] [Related]
36. PHBV/PLLA-based composite scaffolds fabricated using an emulsion freezing/freeze-drying technique for bone tissue engineering: surface modification and in vitro biological evaluation.
Sultana N; Wang M
Biofabrication; 2012 Mar; 4(1):015003. PubMed ID: 22258057
[TBL] [Abstract][Full Text] [Related]
37. Polycaprolactone diacrylate crosslinked biodegradable semi-interpenetrating networks of polyacrylamide and gelatin for controlled drug delivery.
Jaiswal M; Dinda AK; Gupta A; Koul V
Biomed Mater; 2010 Dec; 5(6):065014. PubMed ID: 21079283
[TBL] [Abstract][Full Text] [Related]
38. Recent developments in biodegradable synthetic polymers.
Gunatillake P; Mayadunne R; Adhikari R
Biotechnol Annu Rev; 2006; 12():301-47. PubMed ID: 17045198
[TBL] [Abstract][Full Text] [Related]
39. Preparation and characterization of (PCL-crosslinked-PEG)/hydroxyapatite as bone tissue engineering scaffolds.
Koupaei N; Karkhaneh A; Daliri Joupari M
J Biomed Mater Res A; 2015 Dec; 103(12):3919-26. PubMed ID: 26015080
[TBL] [Abstract][Full Text] [Related]
40. High strength bioresorbable bone plates: preparation, mechanical properties and in vitro analysis.
Hasirci V; Lewandrowski KU; Bondre SP; Gresser JD; Trantolo DJ; Wise DL
Biomed Mater Eng; 2000; 10(1):19-29. PubMed ID: 10950204
[TBL] [Abstract][Full Text] [Related]
[Previous] [Next] [New Search]
