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Literature DB >> 28367477

The NIH 3D Print Exchange: A Public Resource for Bioscientific and Biomedical 3D Prints.

Meghan F Coakley¹, Darrell E Hurt¹, Nick Weber¹, Makazi Mtingwa¹, Erin C Fincher², Vsevelod Alekseyev³, David T Chen⁴, Alvin Yun⁵, Metasebia Gizaw³, Jeremy Swan², Terry S Yoo⁴, Yentram Huyen¹.

Abstract

The National Institutes of Health (NIH) has launched the NIH 3D Print Exchange, an online portal for discovering and creating bioscientifically relevant 3D models suitable for 3D printing, to provide both researchers and educators with a trusted source to discover accurate and informative models. There are a number of online resources for 3D prints, but there is a paucity of scientific models, and the expertise required to generate and validate such models remains a barrier. The NIH 3D Print Exchange fills this gap by providing novel, web-based tools that empower users with the ability to create ready-to-print 3D files from molecular structure data, microscopy image stacks, and computed tomography scan data. The NIH 3D Print Exchange facilitates open data sharing in a community-driven environment, and also includes various interactive features, as well as information and tutorials on 3D modeling software. As the first government-sponsored website dedicated to 3D printing, the NIH 3D Print Exchange is an important step forward to bringing 3D printing to the mainstream for scientific research and education.

Entities: Disease Gene Species

Year: 2014 PMID： 28367477 PMCID： PMC4981148 DOI： 10.1089/3dp.2014.1503

Source DB: PubMed Journal: 3D Print Addit Manuf ISSN： 2329-7662 Impact factor: 5.449

10 in total

1. The Protein Data Bank.

Authors: H M Berman; J Westbrook; Z Feng; G Gilliland; T N Bhat; H Weissig; I N Shindyalov; P E Bourne
Journal: Nucleic Acids Res Date: 2000-01-01 Impact factor: 16.971

Review 2. Innovations in prosthetic interfaces for the upper extremity.

Authors: Theodore A Kung; Reuben A Bueno; Ghadah K Alkhalefah; Nicholas B Langhals; Melanie G Urbanchek; Paul S Cederna
Journal: Plast Reconstr Surg Date: 2013-12 Impact factor: 4.730

3. Utilizing Three-Dimensional Printing Technology to Assess the Feasibility of High-Fidelity Synthetic Ventricular Septal Defect Models for Simulation in Medical Education.

Authors: John P Costello; Laura J Olivieri; Axel Krieger; Omar Thabit; M Blair Marshall; Shi-Joon Yoo; Peter C Kim; Richard A Jonas; Dilip S Nath
Journal: World J Pediatr Congenit Heart Surg Date: 2014-07

4. The production of anatomical teaching resources using three-dimensional (3D) printing technology.

Authors: Paul G McMenamin; Michelle R Quayle; Colin R McHenry; Justin W Adams
Journal: Anat Sci Educ Date: 2014-06-27 Impact factor: 5.958

5. 3D bioprinting of tissues and organs.

Authors: Sean V Murphy; Anthony Atala
Journal: Nat Biotechnol Date: 2014-08 Impact factor: 54.908

6. Intermolecular recognition revealed by the complex structure of human CLOCK-BMAL1 basic helix-loop-helix domains with E-box DNA.

Authors: Zixi Wang; Yaling Wu; Lanfen Li; Xiao-Dong Su
Journal: Cell Res Date: 2012-12-11 Impact factor: 25.617

7. Characterization of virus-like particles in GARDASIL® by cryo transmission electron microscopy.

Authors: Qinjian Zhao; Clinton S Potter; Bridget Carragher; Gabriel Lander; Jaime Sworen; Victoria Towne; Dicky Abraham; Paul Duncan; Michael W Washabaugh; Robert D Sitrin
Journal: Hum Vaccin Immunother Date: 2013-12-03 Impact factor: 3.452

8. Human cartilage tissue fabrication using three-dimensional inkjet printing technology.

Authors: Xiaofeng Cui; Guifang Gao; Tomo Yonezawa; Guohao Dai
Journal: J Vis Exp Date: 2014-06-10 Impact factor: 1.355

9. EMDataBank.org: unified data resource for CryoEM.

Authors: Catherine L Lawson; Matthew L Baker; Christoph Best; Chunxiao Bi; Matthew Dougherty; Powei Feng; Glen van Ginkel; Batsal Devkota; Ingvar Lagerstedt; Steven J Ludtke; Richard H Newman; Tom J Oldfield; Ian Rees; Gaurav Sahni; Raul Sala; Sameer Velankar; Joe Warren; John D Westbrook; Kim Henrick; Gerard J Kleywegt; Helen M Berman; Wah Chiu
Journal: Nucleic Acids Res Date: 2010-10-08 Impact factor: 16.971

10. The billion cell construct: will three-dimensional printing get us there?

Authors: Jordan S Miller
Journal: PLoS Biol Date: 2014-06-17 Impact factor: 8.029

10 in total

13 in total

1. 3D Printing in the Laboratory: Maximize Time and Funds with Customized and Open-Source Labware.

Authors: Meghan Coakley; Darrell E Hurt
Journal: J Lab Autom Date: 2016-05-19

2. 3-D printing provides a novel approach for standardization and reproducibility of freezing devices.

Authors: E Hu; William Childress; Terrence R Tiersch
Journal: Cryobiology Date: 2017-04-29 Impact factor: 2.487

3. Impact of Three-Dimensional Printing on the Study and Treatment of Congenital Heart Disease.

Authors: Matthew Bramlet; Laura Olivieri; Kanwal Farooqi; Beth Ripley; Meghan Coakley
Journal: Circ Res Date: 2017-03-17 Impact factor: 17.367

Review 4. Perspectives on Structural Molecular Biology Visualization: From Past to Present.

Authors: Arthur J Olson
Journal: J Mol Biol Date: 2018-07-23 Impact factor: 5.469

Review 5. The Various Applications of 3D Printing in Cardiovascular Diseases.

Authors: Abdallah El Sabbagh; Mackram F Eleid; Mohammed Al-Hijji; Nandan S Anavekar; David R Holmes; Vuyisile T Nkomo; Gustavo S Oderich; Stephen D Cassivi; Sameh M Said; Charanjit S Rihal; Jane M Matsumoto; Thomas A Foley
Journal: Curr Cardiol Rep Date: 2018-05-10 Impact factor: 2.931