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Journal Abstract Search

475 related items for PubMed ID: 32092713

  • 21. 3D printed high-resolution scaffold with hydrogel microfibers for providing excellent biocompatibility.
    Ye W, Xie C, Liu Y, He Y, Gao Q, Ouyang A.
    J Biomater Appl; 2021 Jan; 35(6):633-642. PubMed ID: 32996360
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  • 22. 3D printing of hybrid biomaterials for bone tissue engineering: Calcium-polyphosphate microparticles encapsulated by polycaprolactone.
    Neufurth M, Wang X, Wang S, Steffen R, Ackermann M, Haep ND, Schröder HC, Müller WEG.
    Acta Biomater; 2017 Dec; 64():377-388. PubMed ID: 28966095
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  • 23. Glucosamine-grafted methacrylated gelatin hydrogels as potential biomaterials for cartilage repair.
    Suo H, Li L, Zhang C, Yin J, Xu K, Liu J, Fu J.
    J Biomed Mater Res B Appl Biomater; 2020 Apr; 108(3):990-999. PubMed ID: 31369700
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  • 24. Mechanical properties and in vitro behavior of nanofiber-hydrogel composites for tissue engineering applications.
    Kai D, Prabhakaran MP, Stahl B, Eblenkamp M, Wintermantel E, Ramakrishna S.
    Nanotechnology; 2012 Mar 09; 23(9):095705. PubMed ID: 22322583
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  • 25. Hydrogels of agarose, and methacrylated gelatin and hyaluronic acid are more supportive for in vitro meniscus regeneration than three dimensional printed polycaprolactone scaffolds.
    Bahcecioglu G, Hasirci N, Bilgen B, Hasirci V.
    Int J Biol Macromol; 2019 Feb 01; 122():1152-1162. PubMed ID: 30218727
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  • 26. 3D bioprinting of a stem cell-laden, multi-material tubular composite: An approach for spinal cord repair.
    Hamid OA, Eltaher HM, Sottile V, Yang J.
    Mater Sci Eng C Mater Biol Appl; 2021 Jan 01; 120():111707. PubMed ID: 33545866
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  • 27. 3D Printing GelMA/PVA Interpenetrating Polymer Networks Scaffolds Mediated with CuO Nanoparticles for Angiogenesis.
    Hu Q, Lu R, Liu S, Liu Y, Gu Y, Zhang H.
    Macromol Biosci; 2022 Oct 01; 22(10):e2200208. PubMed ID: 35904133
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  • 28. Multiscale porosity in a 3D printed gellan-gelatin composite for bone tissue engineering.
    Gupta D, Vashisth P, Bellare J.
    Biomed Mater; 2021 Apr 16; 16(3):. PubMed ID: 33761468
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  • 29. Preparation and characterization of the collagen/cellulose nanocrystals/USPIO scaffolds loaded kartogenin for cartilage regeneration.
    Yang W, Zheng Y, Chen J, Zhu Q, Feng L, Lan Y, Zhu P, Tang S, Guo R.
    Mater Sci Eng C Mater Biol Appl; 2019 Jun 16; 99():1362-1373. PubMed ID: 30889670
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  • 30. Mechanical properties of polycaprolactone (PCL) scaffolds for hybrid 3D-bioprinting with alginate-gelatin hydrogel.
    Koch F, Thaden O, Conrad S, Tröndle K, Finkenzeller G, Zengerle R, Kartmann S, Zimmermann S, Koltay P.
    J Mech Behav Biomed Mater; 2022 Jun 16; 130():105219. PubMed ID: 35413680
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  • 31. Fabrication and In Vitro Evaluation of 3D Printed Porous Polyetherimide Scaffolds for Bone Tissue Engineering.
    Tang X, Qin Y, Xu X, Guo D, Ye W, Wu W, Li R.
    Biomed Res Int; 2019 Jun 16; 2019():2076138. PubMed ID: 31815125
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  • 32. Biomimetic composite coating on rapid prototyped scaffolds for bone tissue engineering.
    Arafat MT, Lam CX, Ekaputra AK, Wong SY, Li X, Gibson I.
    Acta Biomater; 2011 Feb 16; 7(2):809-20. PubMed ID: 20849985
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  • 33. Magnetic resonance imaging tracking of human adipose derived stromal cells within three-dimensional scaffolds for bone tissue engineering.
    Lalande C, Miraux S, Derkaoui SM, Mornet S, Bareille R, Fricain JC, Franconi JM, Le Visage C, Letourneur D, Amédée J, Bouzier-Sore AK.
    Eur Cell Mater; 2011 Apr 11; 21():341-54. PubMed ID: 21484704
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  • 34. A 3D-printed PRP-GelMA hydrogel promotes osteochondral regeneration through M2 macrophage polarization in a rabbit model.
    Jiang G, Li S, Yu K, He B, Hong J, Xu T, Meng J, Ye C, Chen Y, Shi Z, Feng G, Chen W, Yan S, He Y, Yan R.
    Acta Biomater; 2021 Jul 01; 128():150-162. PubMed ID: 33894346
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  • 35. 3D bioprinting of urethra with PCL/PLCL blend and dual autologous cells in fibrin hydrogel: An in vitro evaluation of biomimetic mechanical property and cell growth environment.
    Zhang K, Fu Q, Yoo J, Chen X, Chandra P, Mo X, Song L, Atala A, Zhao W.
    Acta Biomater; 2017 Mar 01; 50():154-164. PubMed ID: 27940192
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  • 36. Gelatin Methacryloyl (GelMA) - 45S5 Bioactive Glass (BG) Composites for Bone Tissue Engineering: 3D Extrusion Printability and Cytocompatibility Assessment Using Human Osteoblasts.
    Akhtar M, Peng P, Bernhardt A, Gelinsky M, Ur Rehman MA, Boccaccini AR, Basu B.
    ACS Biomater Sci Eng; 2024 Aug 12; 10(8):5122-5135. PubMed ID: 39038164
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  • 37. 3D printing of complicated GelMA-coated Alginate/Tri-calcium silicate scaffold for accelerated bone regeneration.
    Beheshtizadeh N, Farzin A, Rezvantalab S, Pazhouhnia Z, Lotfibakhshaiesh N, Ai J, Noori A, Azami M.
    Int J Biol Macromol; 2023 Feb 28; 229():636-653. PubMed ID: 36586652
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  • 38. Three-dimensionally printed polycaprolactone and β-tricalcium phosphate scaffolds for bone tissue engineering: an in vitro study.
    Sharaf B, Faris CB, Abukawa H, Susarla SM, Vacanti JP, Kaban LB, Troulis MJ.
    J Oral Maxillofac Surg; 2012 Mar 28; 70(3):647-56. PubMed ID: 22079064
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  • 39. 3D Bioprinting-Based Dopamine-Coupled Flexible Material for Nasal Cartilage Repair.
    Jia W, Liu Z, Ma Z, Hou P, Cao Y, Shen Z, Li M, Zhang H, Guo X, Sang S.
    Aesthetic Plast Surg; 2024 Aug 28; 48(15):2951-2964. PubMed ID: 38528127
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  • 40. Effect of sterilization treatment on mechanical properties, biodegradation, bioactivity and printability of GelMA hydrogels.
    Rizwan M, Chan SW, Comeau PA, Willett TL, Yim EKF.
    Biomed Mater; 2020 Oct 03; 15(6):065017. PubMed ID: 32640427
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