Literature DB >> 15151972

Short communication: fused deposition models from CT scans.

J R Meakin1, D E T Shepherd, D W L Hukins.   

Abstract

Fused deposition modelling (FDM) is a new method for rapid prototyping, a technique that produces models of objects from computer files. The most commonly used rapid prototyping technique for medical applications is stereolithography, but FDM has several potential advantages. This paper is concerned with the accuracy of an FDM model of a sheep lumbar vertebra using data from a CT scan. The model and the original vertebra were compared by making measurements with vernier callipers and by laser scanning. Visually, the model reproduced the features of the original object; this conclusion was supported by a comparison of the laser scans. Discrepancies in measurements were comparable with those of models produced using other rapid prototyping techniques, demonstrating that FDM is a viable method for making models for clinical use.

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Year:  2004        PMID: 15151972     DOI: 10.1259/bjr/50012454

Source DB:  PubMed          Journal:  Br J Radiol        ISSN: 0007-1285            Impact factor:   3.039


  10 in total

1.  Four-Dimensional Printing Hierarchy Scaffolds with Highly Biocompatible Smart Polymers for Tissue Engineering Applications.

Authors:  Shida Miao; Wei Zhu; Nathan J Castro; Jinsong Leng; Lijie Grace Zhang
Journal:  Tissue Eng Part C Methods       Date:  2016-10       Impact factor: 3.056

Review 2.  Selective laser sintering in biomedical engineering.

Authors:  Alida Mazzoli
Journal:  Med Biol Eng Comput       Date:  2012-12-19       Impact factor: 2.602

3.  Application of two segmentation protocols during the processing of virtual images in rapid prototyping: ex vivo study with human dry mandibles.

Authors:  Eduardo Gomes Ferraz; Lucio Costa Safira Andrade; Aline Rode dos Santos; Vinicius Rabelo Torregrossa; Izabel Regina Fischer Rubira-Bullen; Viviane Almeida Sarmento
Journal:  Clin Oral Investig       Date:  2013-01-24       Impact factor: 3.573

4.  Solid Free-form Fabrication Technology and Its Application to Bone Tissue Engineering.

Authors:  Jin Woo Lee; Jong Young Kim; Dong-Woo Cho
Journal:  Int J Stem Cells       Date:  2010-05       Impact factor: 2.500

5.  Polymers for 3D Printing and Customized Additive Manufacturing.

Authors:  Samuel Clark Ligon; Robert Liska; Jürgen Stampfl; Matthias Gurr; Rolf Mülhaupt
Journal:  Chem Rev       Date:  2017-07-30       Impact factor: 60.622

6.  A review of the design process for implantable orthopedic medical devices.

Authors:  G A Aitchison; D W L Hukins; J J Parry; D E T Shepherd; S G Trotman
Journal:  Open Biomed Eng J       Date:  2009-07-02

7.  Dimensional Error in Rapid Prototyping with Open Source Software and Low-cost 3D-printer.

Authors:  Marco A Rendón-Medina; Laura Andrade-Delgado; Jose E Telich-Tarriba; Antonio Fuente-Del-Campo; Carlos A Altamirano-Arcos
Journal:  Plast Reconstr Surg Glob Open       Date:  2018-01-25

8.  Influence of processing parameters on mechanical properties of a 3D-printed trabecular bone microstructure.

Authors:  Morteza Amini; Andreas Reisinger; Dieter H Pahr
Journal:  J Biomed Mater Res B Appl Biomater       Date:  2019-03-20       Impact factor: 3.368

9.  Creating physical 3D stereolithograph models of brain and skull.

Authors:  Daniel J Kelley; Mohammed Farhoud; M Elizabeth Meyerand; David L Nelson; Lincoln F Ramirez; Robert J Dempsey; Alan J Wolf; Andrew L Alexander; Richard J Davidson
Journal:  PLoS One       Date:  2007-10-31       Impact factor: 3.240

10.  Validation of anatomical models to study aerosol deposition in human nasal cavities.

Authors:  Sandrine Le Guellec; Deborah Le Pennec; Stephane Gatier; Lara Leclerc; Maria Cabrera; Jeremie Pourchez; Patrice Diot; Gregory Reychler; Laurent Pitance; Marc Durand; François Jamar; Laurent Vecellio
Journal:  Pharm Res       Date:  2013-09-25       Impact factor: 4.200
  10 in total

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