"Skin 3D Bioprinting. Applications in Cosmetology"
written by Cristina Velasquillo, Eduardo A. Galue, Lourdes Rodriquez, Clemente Ibarra, L. Guillermo Ibarra-Ibarra,
published by Journal of Cosmetics, Dermatological Sciences and Applications, Vol.3 No.1A, 2013
has been cited by the following article(s):
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[1] Emergence of Three Dimensional Printed Cardiac Tissue: Opportunities and Challenges in Cardiovascular Diseases
[2] Clinical Perspectives on 3D Bioprinting Paradigms for Regenerative Medicine
[3] Biomaterials Based on Marine Resources for 3D Bioprinting Applications
[4] Biocompatible Hybrid Molecular Brushes Composed of Chitosan, Polylactide, and Poly (N-vinyl pyrrolidone) as Scaffolds for Skin Wound Healing
[5] Bioprinting of human skin
[6] Hyperspectral Imaging with Burn Contour Extraction for Burn Wound Depth Assessment
[7] Simulating image-guided in situ bioprinting of a skin graft onto a phantom burn wound bed
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[8] Multiscale bioprinting of vascularized models
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[9] Emissions related to the operation of 3D printers
[10] 3D Printing of Biosamples: A Concise Review
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[11] Biomechanics of the Human Skin Barrier
ProQuest Dissertations Publishing, 2017
[12] Simulating image-guided in situ bioprinting of a skin graft onto a phantom burn
[13] Organ Printing With Life Cells: A Review
Materials Today: Proceedings, 2017
[14] Skin regeneration in three dimensions, current status, challenges and opportunities
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[15] Polymers for 3D Printing and Customized Additive Manufacturing
Chemical Reviews, 2017
[16] 三维打印皮肤组织研究进展
[17] Konzeption und Prototypenbau eines Zweikomponenten-Druckkopfs mit wechselbaren Dual-Extrudern für das 3D-Bioprinting im Bereich des Tissue Engineering
[18] Current Trends on Medical and Pharmaceutical Applications of Inkjet Printing Technology
Pharmaceutical Research, 2016
[19] Design of a Skin Grafting Methodology for Burn Wound Using an Additive Biomanufacturing System Guided by Hyperspectral Imaging
[20] Impressão 3D: persptivas de adoção na Indústria Portuguesa
[21] 3D printing of tissue-simulating phantoms as a traceable standard for biomedical optical measurement
Seventh International Symposium on Precision Mechanical Measurements, 2016
[22] Freeform fabrication of tissue-simulating phantoms by combining three-dimensional printing and casting
SPIE BiOS, 2016
[23] 3D printing‐assisted fabrication of double‐layered optical tissue phantoms for laser tattoo treatments
Lasers in surgery and medicine, 2016
[24] Evaluation of fibrin-gelatin hydrogel as biopaper for application in skin bioprinting: An in-vitro study
Bio-Medical Materials and Engineering, 2016
[25] Fabricating optical phantoms to simulate skin tissue properties and microvasculatures
SPIE BiOS, 2015
[26] Design of a Personalized Skin Grafting Methodology Using an Additive Biomanufacturing System Guided by 3D Photogrammetry
ASME 2015 International Mechanical Engineering Congress and Exposition, 2015
[27] Nanomedicine and Tissue Engineering
Nanotechnology Applications for Tissue Engineering, 2015
[28] 3D printing method for freeform fabrication of optical phantoms simulating heterogeneous biological tissue
SPIE BiOS. International Society for Optics and Photonics, 2014
[29] The impact of melanocytic cell destruction in pediatric facial burns and plastic surgery therapeutic management
Rom J Morphol Embryol, 2014
[30] Effect of Bioglass on Growth and Biomineralization of SaOS-2 Cells in Hydrogel after 3D Cell Bioprinting
PloS one, 2014
[31] Schrö der HC
Neufurth M, Feng Q, et al, 2014