"A method to fabricate small features on scaffolds for tissue engineering via selective laser sintering"
written by S. Lohfeld, M. A. Tyndyk, S. Cahill, N. Flaherty, V. Barron, P. E. McHugh,
published by Journal of Biomedical Science and Engineering, Vol.3 No.2, 2010
has been cited by the following article(s):
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[3] Akermanite reinforced PHBV scaffolds manufactured using selective laser sintering
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[6] Biomechanical analysis of implantation of polyamide/hydroxyapatite shifted architecture porous scaffold in an injured femur bone
[7] ATINER's Conference Paper Series MEC2017-2378
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[9] Implementation of Industrial Additive Manufacturing: Intelligent Implants and Drug Delivery Systems
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[12] Morphological Characterization of Hydrogels
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[13] 3D Printing—Additive Manufacturing of Dental Biomaterials
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[16] Designing patient-specific melt-electrospun scaffolds for bone regeneration
[17] Open-Source Selective Laser Sintering (OpenSLS) of Nylon and Biocompatible Polycaprolactone
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[18] Tissue Engineering Scaffolds for Repairing Soft Tissues
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[19] Tissue Engineering Scaffolds for 3D Cell Culture
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[20] Biofabrication: The Future of Regenerative Medicine
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[21] Adaptive modeling method for 3-D printing with various polymer materials
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[22] Tissue Engineering Scaffolds for Bone Repair: General Aspects
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[23] Design, analysis and fabrication of polyamide/hydroxyapatite porous structured scaffold using selective laser sintering method for bio-medical applications
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[24] Assessment of biocompatibility of 3D printed photopolymers using zebrafish embryo toxicity assays
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[25] Composite scaffolds for osteochondral repair obtained by combination of additive manufacturing, leaching processes and hMSC-CM functionalization
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[26] A New File Format to Describe Fiber-reinforced Composite Workpiece Structure for Additive Technology Machines
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[27] The Fabrication of Integrated Strain Sensors for “Smart” Implants using a Direct Write Additive Manufacturing Approach
[28] Evaluating the effect of increasing ceramic content on the mechanical properties, material microstructure and degradation of selective laser sintered polycaprolactone/β-tricalcium phosphate materials
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[29] Evaluating the effect of increasing ceramic content on the mechanical properties, material microstructure and degradation of selective laser sintered polycaprolactone …
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[30] Improving the finite element model accuracy of tissue engineering scaffolds produced by selective laser sintering
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[31] Optimisation of process parameters for lattice structures
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[32] Recent advances in 3D printing of biomaterials
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[33] Free-Form Rapid Prototyped Porous PDMS Scaffolds Incorporating Growth Factors Promote Chondrogenesis
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[34] Controlling the porosity of collagen, gelatin and elastin biomaterials by ultrashort laser pulses
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[35] Predicting the Elastic Properties of Selective Laser Sintered PCL/β-TCP Bone Scaffold Materials Using Computational Modelling
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[36] Evaluation of a Multiscale Modelling Methodology to Predict the Mechanical Properties of PCL/β-TCP Sintered Scaffold Materials
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[37] Fabrication of dual-pore scaffolds using SLUP (salt leaching using powder) and WNM (wire-network molding) techniques
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[38] Review of rapid prototyping techniques for tissue engineering scaffolds fabrication
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[40] Processing and characterization of laser sintered hydroxyapatite scaffold for tissue engineering
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[41] Additive manufacturing of lab-on-a-chip devices: promises and challenges
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[42] A Process Engineering Perspective of Scaffold Fabrication Methods in Regenerative Medicine: A Review
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[43] Rapid prototyping for biomedical engineering: current capabilities and challenges
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[44] Fabrication, mechanical and in vivo performance of polycaprolactone/tricalcium phosphate composite scaffolds
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[45] Tissue Engineering Using Novel Rapid Prototyped Diamond‐Like Carbon Coated Scaffolds
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[46] Fabrication of Tissue Engineering Scaffolds Using Rapid Prototyping Techniques
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[47] Selective Laser Melting of Porous Structures
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[48] Fabrication of Tissue Eng Using Rapid Prototyp
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