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3D프린팅 활용 생체의료분야 기술동향

박석희(Suk-Hee Park) 박진호(Jean Ho Park) 이혜진(Hye Jin Lee) 이낙규(Nak Kyu Lee) 2014년

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영향력

논문상세정보

- 저자 박석희(Suk-Hee Park) 박진호(Jean Ho Park) 이혜진(Hye Jin Lee) 이낙규(Nak Kyu Lee)
- 제어번호 100162775
- 학술지명 한국정밀공학회지
- 권호사항 Vol. 31 No. 12 [ 2014 ]
- 발행처 Korean Society for Precision Engineering
- 발행처 URL http://www.kspe.or.kr/
- 자료유형 학술저널
- 수록면 1067-1076 ( 10쪽)
- 언어 Korean
- 출판년도 2014
- KDC 555
- 등재정보 KCI등재
- 판매처 누리미디어
- 주제어 3D printing (3 차원 프린팅) Biomaterials(생체재료) Biomedicalapplication(생체의료활용) Scaffold(지지체) tissue engineering(조직 공학)
- 참고문헌( 35)
유사주제 논문( 322)

인용/피인용

' 3D프린팅 활용 생체의료분야 기술동향' 의 주제별 논문영향력

논문영향력 요약
동일주제 총논문수	논문피인용 총횟수	주제별 논문영향력의 평균
주제	정밀기계 3d printing (3 차원 프린팅) biomaterials(생체재료) biomedicalapplication(생체의료활용) scaffold(지지체) tissue engineering(조직 공학)
328	4	0.0%

논문영향력
주제		주제별 논문수	주제별 피인용횟수	주제별 논문영향력
주제분류(KDC/DDC)	정밀기계	299	0	0.0%
주제어	3d printing (3 차원 프린팅)	20	0	0.0%
	biomaterials(생체재료)	1	0	0.0%
	biomedicalapplication(생체의 ...	1	0	0.0%
	scaffold(지지체)	2	0	0.0%
	tissue engineering(조직 공학 ...	5	0	0.0%
계		328	0	0.0%
* 다른 주제어 보유 논문에서 피인용된 횟수			4

' 3D프린팅 활용 생체의료분야 기술동향' 의 참고문헌

Wohlers Report 2013 : 23 ~ 52
Wohler, T. [2013]
Tissue Engineering: Current Challenges and Expanding Opportunities
Griffith, L. G. Science 295 (8) : 1009 ~ 1016 [2002]
Solid Freeform Fabrication Technique in Tissue Engineering
Lee, S. J. J. Korean Soc. Precis. Eng. 23 (12) : 7 ~ 15 [2006]
Scaffold-free Vascular Tissue Engineering using Bioprinting
Norotte, C. Biomaterials 30 (30) : 5910 ~ 5917 [2009]
SLM in Action
Realizer
Regenerative Medicine
Yoo, J. J. Koonja Publishing Inc. : 293 ~ 508 [2010]
Regeneration of a Goat Femoral Head Using a Tissue-specific, Biphasic Scaffold Fabricated with CAD/CAM Technology
Ding, C. Biomaterials 34 (28) : 6706 ~ 6716 [2013]
Rapid Prototyping Helps Separate Conjoined Twins
Turkcadcam
Rapid Casting of Patterned Vascular Networks for Perfusable Engineered Three-dimensional Tissues
Miller, J. S. Nat. Mater 11 (9) : 768 ~ 774 [2012]
Rapid 3D Printing of Anatomically Accurate and Mechanically Heterogeneous Aortic Valve Hydrogel Scaffolds
Hockaday, L. A. Biofabrication 4 (3) [2012]
Principle of Rapid Prototyping and its Trends
Ahn, D. G. J. Korean Soc. Precis. Eng. 22 (10) : 7 ~ 16 [2005]
Porous Scaffold Design for Tissue Engineering
Hollister S. J. Nat. Mater. 4 (7) : 518 ~ 524 [2005]
Photo-polymerized Microarchitectural Constructs Prepared by Microstereolithography (μSL) using Liquid Acrylate-end-capped Trimethylene Carbonate-based Prepolymers
Kwon, I. K. Biomaterials 26 (14) : 1675 ~ 1684 [2005]
Patterning Methods for Polymers in Cell and Tissue Engineering
Kim, H. N. Ann. Biomed. Eng 40 (6) : 1339 ~ 1355 [2012]
Orthopaedic Technology
EOS
Microstructured Scaffold Coated with Hydroxyapatite/Collagen Nanocomposite Multilayer for Enhanced Osteogenic Induction of Human Mesenchymal Stem Cells
Kim, T. G. J. Mater. Chem 20 (40) : 8927 ~ 8933 [2010]
Microdrop Printing of Hydrogel Bioinks into 3D Tissue-Like Geometries
Pataky, K. Adv. Mater 24 (3) : 391 ~ 396 [2012]
Medical Devices
EOS
Medical Case Studies
Stratasys
Laser-assisted Printing of Alginate Long Tubes and Annular Constructs
Yan, J. Biofabrication 5 (1) [2013]
Ivan Owen: Life Enhancing 3D printed Prosthetics
3ders
Integrated Two-step Gene Synthesis in a Microfluidic Device
Huang, M. C. Lab on a Chip 9 (2) : 276 ~ 285 [2009]
In vivo Biocompatibility and Biodegradation of 3D-Printed Porous Scaffolds Based on a Hydroxyl-functionalized Poly(ε-caprolactone)
Seyednejad, H. Biomaterials 33 (17) : 4309 ~ 4318 [2012]
Implants and Medical Instruments with LaserCUSING
Conept Laser
Hierarchical Multilayer Assembly of an Ordered Nanofibrous Scaffold via Theramal Fusion Bonding
Park, S. H. Biofabrication 6 (2) [2014]
Fused Deposition Modeling of Novel Scaffold Architectures for Tissue Engineering Applications
Zein, I. Biomaterials 23 (4) : 1169 ~ 1185 [2002]
Formation of Highly Porous Biodegradable Scaffolds for Tissue Engineering
Mikos, A. G. Electron. J. Biotechnol. 3 (2) : 114 ~ 119 [2000]
Development of Nano-and Microscale Composite 3D Scaffolds using PPF/DEF-HA and Micro-stereolithography
Lee, J. W. Microelectron. Eng. 86 (4) : 1465 ~ 1467 [2009]
Development of Dual Scale Scaffolds via Direct Polymer Melt Deposition and Electrospinning for Applications in Tissue Regeneration
Park, S. H. Acta Biomater 4 (5) : 1198 ~ 1207 [2008]
Customized Biomimetic Scaffolds Created by Indirect Three-dimensional Printing for Tissue Engineering
Lee, J. Y. Biofabrication 5 (4) [2013]
Configurable 3D-Printed Millifluidic and Microfluidic ‘Lab on a Chip’ Reactionware Devices
Kitson, P. J. Lab on a Chip 12 (18) : 3199 ~ 3522 [2012]
Cells(MC3T3-E1)-laden Alginate Scaffolds Fabricated by a Modified Solid-Freeform Fabrication Process Supplemented with an Aerosol Spraying
Ahn, S. Biomacromolecules 13 (9) : 2997 ~ 3003 [2012]
3D-printed ‘Magic Arms’ Give Little Girl New Reach
Cnet
3D Printed Bionic Ears
Mannoor, M. S. Nano Lett 13 (6) : 2634 ~ 2639 [2013]
3D Insert : Proven & Superior 3D Architecture for in vivo-like 3D Culture
3D Biotek

3D프린팅 활용 생체의료분야 기술동향

유사주제 논문( 322)

' 3D프린팅 활용 생체의료분야 기술동향' 의 주제별 논문영향력

주제별 논문영향력

' 3D프린팅 활용 생체의료분야 기술동향' 의 참고문헌

' 3D프린팅 활용 생체의료분야 기술동향' 의 유사주제( ) 논문