Literature DB >> 27250897

3D-printed bioanalytical devices.

Gregory W Bishop1, Jennifer E Satterwhite-Warden, Karteek Kadimisetty, James F Rusling.   

Abstract

While 3D printing technologies first appeared in the 1980s, prohibitive costs, limited materials, and the relatively small number of commercially available printers confined applications mainly to prototyping for manufacturing purposes. As technologies, printer cost, materials, and accessibility continue to improve, 3D printing has found widespread implementation in research and development in many disciplines due to ease-of-use and relatively fast design-to-object workflow. Several 3D printing techniques have been used to prepare devices such as milli- and microfluidic flow cells for analyses of cells and biomolecules as well as interfaces that enable bioanalytical measurements using cellphones. This review focuses on preparation and applications of 3D-printed bioanalytical devices.

Entities:  

Mesh:

Year:  2016        PMID: 27250897      PMCID: PMC5010856          DOI: 10.1088/0957-4484/27/28/284002

Source DB:  PubMed          Journal:  Nanotechnology        ISSN: 0957-4484            Impact factor:   3.874


  42 in total

1.  Prototyping of microfluidic devices in poly(dimethylsiloxane) using solid-object printing.

Authors:  J Cooper McDonald; Michael L Chabinyc; Steven J Metallo; Janelle R Anderson; Abraham D Stroock; George M Whitesides
Journal:  Anal Chem       Date:  2002-04-01       Impact factor: 6.986

2.  Chaotic mixing in three-dimensional microvascular networks fabricated by direct-write assembly.

Authors:  Daniel Therriault; Scott R White; Jennifer A Lewis
Journal:  Nat Mater       Date:  2003-04       Impact factor: 43.841

3.  Omnidirectional printing of flexible, stretchable, and spanning silver microelectrodes.

Authors:  Bok Y Ahn; Eric B Duoss; Michael J Motala; Xiaoying Guo; Sang-Il Park; Yujie Xiong; Jongseung Yoon; Ralph G Nuzzo; John A Rogers; Jennifer A Lewis
Journal:  Science       Date:  2009-02-12       Impact factor: 47.728

4.  3D printing of interdigitated Li-ion microbattery architectures.

Authors:  Ke Sun; Teng-Sing Wei; Bok Yeop Ahn; Jung Yoon Seo; Shen J Dillon; Jennifer A Lewis
Journal:  Adv Mater       Date:  2013-06-18       Impact factor: 30.849

5.  Omnidirectional printing of 3D microvascular networks.

Authors:  Willie Wu; Adam DeConinck; Jennifer A Lewis
Journal:  Adv Mater       Date:  2011-03-23       Impact factor: 30.849

6.  Configurable 3D-Printed millifluidic and microfluidic 'lab on a chip' reactionware devices.

Authors:  Philip J Kitson; Mali H Rosnes; Victor Sans; Vincenza Dragone; Leroy Cronin
Journal:  Lab Chip       Date:  2012-08-09       Impact factor: 6.799

Review 7.  Advances in microfluidic materials, functions, integration, and applications.

Authors:  Pamela N Nge; Chad I Rogers; Adam T Woolley
Journal:  Chem Rev       Date:  2013-02-14       Impact factor: 60.622

8.  A 3D printed fluidic device that enables integrated features.

Authors:  Kari B Anderson; Sarah Y Lockwood; R Scott Martin; Dana M Spence
Journal:  Anal Chem       Date:  2013-05-29       Impact factor: 6.986

9.  A personalized food allergen testing platform on a cellphone.

Authors:  Ahmet F Coskun; Justin Wong; Delaram Khodadadi; Richie Nagi; Andrew Tey; Aydogan Ozcan
Journal:  Lab Chip       Date:  2013-02-21       Impact factor: 6.799

10.  Fabrication of versatile channel flow cells for quantitative electroanalysis using prototyping.

Authors:  Michael E Snowden; Philip H King; James A Covington; Julie V Macpherson; Patrick R Unwin
Journal:  Anal Chem       Date:  2010-04-15       Impact factor: 6.986
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  14 in total

1.  Automated 3D-printed unibody immunoarray for chemiluminescence detection of cancer biomarker proteins.

Authors:  C K Tang; A Vaze; J F Rusling
Journal:  Lab Chip       Date:  2017-01-31       Impact factor: 6.799

2.  3D-Printing of Functional Biomedical Microdevices via Light- and Extrusion-Based Approaches.

Authors:  Henry H Hwang; Wei Zhu; Grace Victorine; Natalie Lawrence; Shaochen Chen
Journal:  Small Methods       Date:  2017-12-19

3.  Developing Microfluidic Sensing Devices Using 3D Printing.

Authors:  James F Rusling
Journal:  ACS Sens       Date:  2018-03-05       Impact factor: 7.711

Review 4.  Applied tutorial for the design and fabrication of biomicrofluidic devices by resin 3D printing.

Authors:  Hannah B Musgrove; Megan A Catterton; Rebecca R Pompano
Journal:  Anal Chim Acta       Date:  2022-04-30       Impact factor: 6.911

5.  Automated 3-D Printed Arrays to Evaluate Genotoxic Chemistry: E-Cigarettes and Water Samples.

Authors:  Karteek Kadimisetty; Spundana Malla; James F Rusling
Journal:  ACS Sens       Date:  2017-05-02       Impact factor: 7.711

6.  Fully 3D printed integrated reactor array for point-of-care molecular diagnostics.

Authors:  Karteek Kadimisetty; Jinzhao Song; Aoife M Doto; Young Hwang; Jing Peng; Michael G Mauk; Frederic D Bushman; Robert Gross; Joseph N Jarvis; Changchun Liu
Journal:  Biosens Bioelectron       Date:  2018-03-10       Impact factor: 10.618

7.  High Performance, Low Cost Carbon Nanotube Yarn based 3D Printed Electrodes Compatible with a Conventional Screen Printed Electrode System.

Authors:  Cheng Yang; B Jill Venton
Journal:  IEEE Int Symp Med Meas Appl       Date:  2017-07-20

8.  Automated 3D-Printed Microfluidic Array for Rapid Nanomaterial-Enhanced Detection of Multiple Proteins.

Authors:  Karteek Kadimisetty; Spundana Malla; Ketki S Bhalerao; Islam M Mosa; Snehasis Bhakta; Norman H Lee; James F Rusling
Journal:  Anal Chem       Date:  2018-05-31       Impact factor: 6.986

9.  Facile assembly of an affordable miniature multicolor fluorescence microscope made of 3D-printed parts enables detection of single cells.

Authors:  Samuel B Tristan-Landin; Alan M Gonzalez-Suarez; Rocio J Jimenez-Valdes; Jose L Garcia-Cordero
Journal:  PLoS One       Date:  2019-10-10       Impact factor: 3.240

10.  Fabrication routes via projection stereolithography for 3D-printing of microfluidic geometries for nucleic acid amplification.

Authors:  Charalampos Tzivelekis; Pavlos Sgardelis; Kevin Waldron; Richard Whalley; Dehong Huo; Kenny Dalgarno
Journal:  PLoS One       Date:  2020-10-28       Impact factor: 3.240
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