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CIP 및 SLA 방식의 3D 프린터로 제조한 45S5 Bioactive glass scaffold의 물성 평가 = Evaluation of physical property of 45S5 bioactive glass scaffold fabricated by CIP and SLA type 3D printer

강진호 2020년

논문상세정보
인용/피인용
' CIP 및 SLA 방식의 3D 프린터로 제조한 45S5 Bioactive glass scaffold의 물성 평가 = Evaluation of physical property of 45S5 bioactive glass scaffold fabricated by CIP and SLA type 3D printer' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 외과의 다방면
  • 3d printing
  • 45S5 bioactive glass
  • additive manufacturing
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
2,867 0

0.0%

' CIP 및 SLA 방식의 3D 프린터로 제조한 45S5 Bioactive glass scaffold의 물성 평가 = Evaluation of physical property of 45S5 bioactive glass scaffold fabricated by CIP and SLA type 3D printer' 의 참고문헌

  • Wilson J. Surface-active biomaterials
    226 ( 467 5 ) :630-6 . [1984]
  • Third-generation biomedical materials
  • Tailoring interfacial interaction through glass fusion in glass/zinc-hydr oxyapatite composite coatings on glass-infiltrated zirconia
    44 ( 14 ) :16181-90 . [2018]
  • Synthesis and ch aracterization of a phytic acid/mesoporous 45S5 bioglass composite co ating on a magnesium alloy and degradation behavior
    5 ( 33 ) :25708-16 . [2015]
  • Sung I-K. UV-and thermal-cur ing behaviors of dual-curable adhesives based on epoxy acrylate oligom ers
    29 ( 7 ) :710-7 . [2009]
  • Stereolithographic ceramic manufacturing of high strength bioactive glass
    12 ( 1 ) :38-45 [2015]
  • Sintering andCrystallisation of 45S5 Bioglass¢ç p owder .
    29 ( 16 ) :3299-30 6 . [2009]
  • Sautier J-M. P otential of biomimetic surfaces to promote in vitro osteoblast-likeCell differentiation
    26 ( 8 ) :839-48 . [2005]
  • S. ThermalConductivity and thermal diffusivity analyses of low-density polyethyle neComposites reinforced with sisal , glass and intimately mixed sisal/g lass fibres
    60 ( 16 ) :2967-7 7 . [2000]
  • Robocasting of 45S5 bioactive glass scaffolds for bone tissue engineer ing .
    34 ( 1 ) :107-18 . [2014]
  • ResorbableCalcium phosphate bone substitute
    43 ( 4 ) :399-409 . [1998]
  • Processing of 45S5 Bioglass¢ç by lithography-based additive manufacturing .
    74:81-4 [2012]
  • Processing andCharacterization of innovative scaffolds for bone tissue engineering
    23 ( 6 ) :1397-409 . [2012]
  • Processing and in vitro bioactivity of high-strengt h 45S5 glass-ceramic scaffolds for bone regeneration .
    43 ( 9 ) :6868-75 . [2017]
  • Process planning for rapid manufacturing of plastic in jection mold for short run production
    [2010]
  • Proangiogenic potential of aCollagen/bioactive glass substrate
    25 ( 5 ) :1222-9 . [2008]
  • Polak J. Bioactive glass scaffolds for bone reg eneration .
    3 ( 6 ) :393-9 . [2007]
  • Peng S. Characterization of mechanical and b iological properties of 3-D scaffolds reinforced with zinc oxide for bo ne tissue engineering
    9 ( 1 ) : e87755 . [2014]
  • Park S-W. Effect of the volume fraction of zirconia suspensions on the microstructure and physical prope -rties of products produced by additive manufacturing .
    35 ( 5 ) : e97-e106 . [2019]
  • Novel biomaterials used in medical 3D p rinting techniques
    9 ( 1 ) :17 . [2018]
  • Madras G. Optimi zation of rheological properties of photopolymerizable alumina suspens ions for ceramic microstereolithography
    40 ( 2 ) :3655-65 . [2014]
  • Luk K. Strengthening me chanisms of bone bonding to crystalline hydroxyapatite in vivo
    25 ( 18 ) :4243-54 . [2004]
  • Light scattering in absorbing ceramic suspen sions : effect on the width and depth of photopolymerized features
    35 ( 6 ) :1895-904 . [2015]
  • Kokubo T. Properties of bioactive glasses and glass-cerami cs
  • Kim H-E. Coextrusion-based 3D plotting of ceramic pastes for porous calcium phosphate scaffolds comprised of hollow fil aments
    11 ( 6 ) :911 . [2018]
  • Jones JR. C ompressive strength of bioactive sol ? gel glass foam scaffolds
    7 ( 2 ) :229-37 . [2016]
  • Hofmann S. Controlled positioning of cells in biomaterials approaches towards 3D tissue printing
    2 ( 3 ) :119-54 . [2011]
  • Highly porous 45S5 bioglass-derived glass ? ceramic scaffo lds by gelcasting of foams
    53 ( 15 ) :1 0718-31 . [2018]
  • Highly bioactive P2O5 ? Na2O ? CaO ? SiO 2 glass-ceramics .
    292 ( 1-3 ) :11 5-26 . [2001]
  • Hench L. Crystallization kinetics of tape cast bioactive gla ss 45S5
    318 ( 1-2 ) :43-8 . [2003]
  • Guiberteau F. Improving the compressive strength of bioceramic robocast scaffolds b y polymer infiltration
    6 ( 11 ) :4361-8 . [2010]
  • Greenspan D. Sintering temperature effects on the in vitro bioactive response of tape cast and sintered bioactiv e glass ? ceramic in Tris buffer
    57 ( 4 ) :532-40
  • Greenlee T. Bonding mechanisms at th e interface of ceramic prosthetic materials
    5 ( 6 ) :117-41 . [1971]
  • Gene ? expression profiling of human osteoblasts following treatment with the ionic product s of Bioglass¢ç 45S5 dissolution
    55 ( 2 ) :151-7 . [2001]
  • Evaluation of borate bioactive gl ass scaffolds with different pore sizes in a rat subcutaneous implantati on model
    28 ( 5 ) :643-53 . [2014]
  • Effect of crystallization on apatite ? l ayer formation of bioactive glass 45S5
    30 ( 4 ) :509-14 . [1996]
  • Ducheyne P. Differential alkaline phospha tase responses of rat and human bone marrow derived mesenchymal st em cells to 45S5 bioactive glass
    28 ( 28 ) :4091-7 . [2007]
  • Di Silvio L. A porous scaffold for bone tissue engineering/45S5 Bioglass¢ç derived porous scaffolds for co-culturing o steoblasts and endothelial cells
    21 ( 3 ) :893-905 . [2010]
  • Chartier T. Stereolithography for the fabricati on of ceramic three-dimensional parts
    199 8 ; 4 ( 3 ) :104-11
  • Chartier T. Ceramic suspensions suitable for stereolithography .
    18 ( 6 ) :583-90 . [1998]
  • Biosilicate¢ç ? gelatine bone scaffolds by the foam replica t echnique : development and characterization .
    14 ( 4 ) :045008 . [2013]
  • Biomaterials science : an introduction to materials in medicine
    [2004]
  • Biocompatibility of hydroxyapatite scaffol ds processed by lithography-based additive manufacturing .
    26 ( 1-2 ) :31-8 . [2015]
  • Bioactivity of tape cast and sintered bioactive glass-ceramic in simulated body fl uid
    23 ( 12 ) :2599-606 . [2002]
  • Bioactive materials
    2 2 ( 6 ) :493-507 . [1996]
  • Bioactive glass scaffolds for bone tissue engineering : state of the art and future perspectives
    31 ( 7 ) :1245-56 . [2011]
  • Bioactive glass and glass-ceramic scaffolds for bone tissue engineering
    3 ( 7 ) :3867-910 . [2010]
  • Bi omedical production of implants by additive electro-chemical and phys ical processes
    61 ( 2 ) :635-55 . [2012]
  • Bi oactive glass in tissue engineering
    7 ( 6 ) :2355 -73 . [2011]
  • Bernardo E. Bi oactive glass-ceramic scaffolds by additive manufacturing and sinter-c rystallization of fine glass powders
    20 18 ; 33 ( 14 ) :1960-71 .
  • Ansari M. A review on bone scaffold fabrication methods
    2 : 1232-6 . [2015]
  • Additive manufacturing of ceramic ? based materials
    16 ( 6 ) :729-54 . [2014]
  • 31. Jones JR. Review of bioactive glass: from Hench to hybrids. Acta bio materialia. 2013;9(1):4457-86.