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Journal Abstract Search

874 related items for PubMed ID: 26479454

  • 21. Fabrication and mechanical characterization of 3D printed vertical uniform and gradient scaffolds for bone and osteochondral tissue engineering.
    Bittner SM, Smith BT, Diaz-Gomez L, Hudgins CD, Melchiorri AJ, Scott DW, Fisher JP, Mikos AG.
    Acta Biomater; 2019 May; 90():37-48. PubMed ID: 30905862
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  • 22. Three-Dimensional Printing of Scaffolds with Synergistic Effects of Micro-Nano Surfaces and Hollow Channels for Bone Regeneration.
    Feng C, Ma B, Xu M, Zhai D, Liu Y, Xue J, Chang J, Wu C.
    ACS Biomater Sci Eng; 2021 Mar 08; 7(3):872-880. PubMed ID: 33715371
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  • 23. Biological response of 3D-printedβ-tricalcium phosphate bioceramic scaffolds with the hollow tube structure.
    Tian Y, Ma H, Yu X, Feng B, Yang Z, Zhang W, Wu C.
    Biomed Mater; 2023 Mar 24; 18(3):. PubMed ID: 36898162
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  • 24. [CYTOCOMPATIBILITY AND PREPARATION OF BONE TISSUE ENGINEERING SCAFFOLD BY COMBINING LOW TEMPERATURE THREE DIMENSIONAL PRINTING AND VACUUM FREEZE-DRYING TECHNIQUES].
    Li D, Zhang Z, Zheng C, Zhao B, Sun K, Nian Z, Zhang X, Li R, Li H.
    Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi; 2016 Mar 24; 30(3):292-7. PubMed ID: 27281872
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  • 25. Bioactive glass-reinforced bioceramic ink writing scaffolds: sintering, microstructure and mechanical behavior.
    Shao H, Yang X, He Y, Fu J, Liu L, Ma L, Zhang L, Yang G, Gao C, Gou Z.
    Biofabrication; 2015 Sep 10; 7(3):035010. PubMed ID: 26355654
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  • 26. Three-dimensional printing akermanite porous scaffolds for load-bearing bone defect repair: An investigation of osteogenic capability and mechanical evolution.
    Liu A, Sun M, Yang X, Ma C, Liu Y, Yang X, Yan S, Gou Z.
    J Biomater Appl; 2016 Nov 10; 31(5):650-660. PubMed ID: 27585972
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  • 27. Spiral-structured, nanofibrous, 3D scaffolds for bone tissue engineering.
    Wang J, Valmikinathan CM, Liu W, Laurencin CT, Yu X.
    J Biomed Mater Res A; 2010 May 10; 93(2):753-62. PubMed ID: 19642211
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  • 28. Three-Dimensional Printing of Large-Scale, High-Resolution Bioceramics with Micronano Inner Porosity and Customized Surface Characterization Design for Bone Regeneration.
    Zhang B, Gui X, Song P, Xu X, Guo L, Han Y, Wang L, Zhou C, Fan Y, Zhang X.
    ACS Appl Mater Interfaces; 2022 Feb 23; 14(7):8804-8815. PubMed ID: 35156367
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  • 29. 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 Feb 23; 2019():2076138. PubMed ID: 31815125
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  • 30. Fabrication of β-tricalcium phosphate composite ceramic sphere-based scaffolds with hierarchical pore structure for bone regeneration.
    He F, Qian G, Ren W, Li J, Fan P, Shi H, Shi X, Deng X, Wu S, Ye J.
    Biofabrication; 2017 Apr 24; 9(2):025005. PubMed ID: 28361794
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  • 31. 3D-printed scaffolds of mesoporous bioglass/gliadin/polycaprolactone ternary composite for enhancement of compressive strength, degradability, cell responses and new bone tissue ingrowth.
    Zhang Y, Yu W, Ba Z, Cui S, Wei J, Li H.
    Int J Nanomedicine; 2018 Apr 24; 13():5433-5447. PubMed ID: 30271139
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  • 32. Fracture behaviors of ceramic tissue scaffolds for load bearing applications.
    Entezari A, Roohani-Esfahani SI, Zhang Z, Zreiqat H, Dunstan CR, Li Q.
    Sci Rep; 2016 Jul 12; 6():28816. PubMed ID: 27403936
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  • 33. Effect of self-assembled nanofibrous silk/polycaprolactone layer on the osteoconductivity and mechanical properties of biphasic calcium phosphate scaffolds.
    Roohani-Esfahani SI, Lu ZF, Li JJ, Ellis-Behnke R, Kaplan DL, Zreiqat H.
    Acta Biomater; 2012 Jan 12; 8(1):302-12. PubMed ID: 22023750
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  • 34. Design and Structure-Function Characterization of 3D Printed Synthetic Porous Biomaterials for Tissue Engineering.
    Kelly CN, Miller AT, Hollister SJ, Guldberg RE, Gall K.
    Adv Healthc Mater; 2018 Apr 12; 7(7):e1701095. PubMed ID: 29280325
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  • 35. 3D printing of strontium-doped hydroxyapatite based composite scaffolds for repairing critical-sized rabbit calvarial defects.
    Luo Y, Chen S, Shi Y, Ma J.
    Biomed Mater; 2018 Aug 24; 13(6):065004. PubMed ID: 30091422
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  • 36. Biocompatibility and osteogenesis of biomimetic Bioglass-Collagen-Phosphatidylserine composite scaffolds for bone tissue engineering.
    Xu C, Su P, Chen X, Meng Y, Yu W, Xiang AP, Wang Y.
    Biomaterials; 2011 Feb 24; 32(4):1051-8. PubMed ID: 20980051
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  • 37. Development of bioinks for 3D printing microporous, sintered calcium phosphate scaffolds.
    Montelongo SA, Chiou G, Ong JL, Bizios R, Guda T.
    J Mater Sci Mater Med; 2021 Aug 14; 32(8):94. PubMed ID: 34390404
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  • 38. 3D printing of porous hydroxyapatite scaffolds intended for use in bone tissue engineering applications.
    Cox SC, Thornby JA, Gibbons GJ, Williams MA, Mallick KK.
    Mater Sci Eng C Mater Biol Appl; 2015 Feb 14; 47():237-47. PubMed ID: 25492194
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  • 39. Novel Extrusion-Microdrilling Approach to Fabricate Calcium Phosphate-Based Bioceramic Scaffolds Enabling Fast Bone Regeneration.
    He F, Lu T, Fang X, Feng S, Feng S, Tian Y, Li Y, Zuo F, Deng X, Ye J.
    ACS Appl Mater Interfaces; 2020 Jul 22; 12(29):32340-32351. PubMed ID: 32597161
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  • 40. 3D-printed silicate porous bioceramics using a non-sacrificial preceramic polymer binder.
    Zocca A, Elsayed H, Bernardo E, Gomes CM, Lopez-Heredia MA, Knabe C, Colombo P, Günster J.
    Biofabrication; 2015 May 22; 7(2):025008. PubMed ID: 26000907
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