Literature DB >> 32467881

Biocompatible PEGDA Resin for 3D Printing.

Chandler Warr1, Jonard Corpuz Valdoz2, Bryce P Bickham3, Connor J Knight2, Nicholas A Franks2, Nicholas Chartrand2, Pam M Van Ry2, Kenneth A Christensen2, Gregory P Nordin3, Alonzo D Cook1.   

Abstract

We report a non-cytotoxic resin compatible with and designed for use in custom high-resolution 3D printers that follow the design approach described in Gong et al., Lab Chip 17, 2899 (2017). The non-cytotoxic resin is based on a poly(ethylene glycol) diacrylate (PEGDA) monomer with avobenzone as the UV absorber instead of 2-nitrophenyl phenyl sulfide (NPS). Both NPS-PEGDA and avobenzone-PEGDA (A-PEGDA) resins were evaluated for cytotoxicity and cell adhesion. We show that NPS-PEGDA can be made effectively non-cytotoxic with a post-print 12-hour ethanol wash, and that A-PEGDA, as-printed, is effectively non-cytotoxic. 3D prints made with either resin do not support strong cell adhesion in their as-printed state; however, cell adhesion increases dramatically with a short plasma treatment. Using A-PEGDA, we demonstrate spheroid formation in ultra-low adhesion 3D printed wells, and cell migration from spheroids on plasma-treated adherent surfaces. Given that A-PEGDA can be 3D printed with high resolution, it has significant promise for a wide variety of cell-based applications using 3D printed microfluidic structures.

Entities:  

Keywords:  3D printing; biocompatibility; cytotoxicity; microfluidics; resin; spheroid

Year:  2020        PMID: 32467881      PMCID: PMC7255423          DOI: 10.1021/acsabm.0c00055

Source DB:  PubMed          Journal:  ACS Appl Bio Mater        ISSN: 2576-6422


  26 in total

1.  Moving from millifluidic to truly microfluidic sub-100-μm cross-section 3D printed devices.

Authors:  Michael J Beauchamp; Gregory P Nordin; Adam T Woolley
Journal:  Anal Bioanal Chem       Date:  2017-06-13       Impact factor: 4.142

2.  Cost-effective three-dimensional printing of visibly transparent microchips within minutes.

Authors:  Aliaa I Shallan; Petr Smejkal; Monika Corban; Rosanne M Guijt; Michael C Breadmore
Journal:  Anal Chem       Date:  2014-02-24       Impact factor: 6.986

Review 3.  Lab-on-a-chip technologies for stem cell analysis.

Authors:  Peter Ertl; Drago Sticker; Verena Charwat; Cornelia Kasper; Günter Lepperdinger
Journal:  Trends Biotechnol       Date:  2014-04-09       Impact factor: 19.536

4.  Fiji: an open-source platform for biological-image analysis.

Authors:  Johannes Schindelin; Ignacio Arganda-Carreras; Erwin Frise; Verena Kaynig; Mark Longair; Tobias Pietzsch; Stephan Preibisch; Curtis Rueden; Stephan Saalfeld; Benjamin Schmid; Jean-Yves Tinevez; Daniel James White; Volker Hartenstein; Kevin Eliceiri; Pavel Tomancak; Albert Cardona
Journal:  Nat Methods       Date:  2012-06-28       Impact factor: 28.547

Review 5.  3D printed microfluidic devices: enablers and barriers.

Authors:  Sidra Waheed; Joan M Cabot; Niall P Macdonald; Trevor Lewis; Rosanne M Guijt; Brett Paull; Michael C Breadmore
Journal:  Lab Chip       Date:  2016-05-24       Impact factor: 6.799

6.  Comparing Microfluidic Performance of Three-Dimensional (3D) Printing Platforms.

Authors:  Niall P Macdonald; Joan M Cabot; Petr Smejkal; Rosanne M Guijt; Brett Paull; Michael C Breadmore
Journal:  Anal Chem       Date:  2017-03-24       Impact factor: 6.986

7.  Custom 3D printer and resin for 18 μm × 20 μm microfluidic flow channels.

Authors:  Hua Gong; Bryce P Bickham; Adam T Woolley; Gregory P Nordin
Journal:  Lab Chip       Date:  2017-08-22       Impact factor: 6.799

8.  3D-printed Microfluidic Devices: Fabrication, Advantages and Limitations-a Mini Review.

Authors:  Chengpeng Chen; Benjamin T Mehl; Akash S Munshi; Alexandra D Townsend; Dana M Spence; R Scott Martin
Journal:  Anal Methods       Date:  2016-07-27       Impact factor: 2.896

9.  3D-printing of transparent bio-microfluidic devices in PEG-DA.

Authors:  Arturo Urrios; Cesar Parra-Cabrera; Nirveek Bhattacharjee; Alan M Gonzalez-Suarez; Luis G Rigat-Brugarolas; Umashree Nallapatti; Josep Samitier; Cole A DeForest; Francesc Posas; José L Garcia-Cordero; Albert Folch
Journal:  Lab Chip       Date:  2016-05-24       Impact factor: 6.799

10.  3D Printed Microfluidic Features Using Dose Control in X, Y, and Z Dimensions.

Authors:  Michael J Beauchamp; Hua Gong; Adam T Woolley; Gregory P Nordin
Journal:  Micromachines (Basel)       Date:  2018-06-28       Impact factor: 2.891
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  13 in total

Review 1.  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

2.  High-Resolution 3D Printing Fabrication of a Microfluidic Platform for Blood Plasma Separation.

Authors:  Sandra Garcia-Rey; Jacob B Nielsen; Gregory P Nordin; Adam T Woolley; Lourdes Basabe-Desmonts; Fernando Benito-Lopez
Journal:  Polymers (Basel)       Date:  2022-06-22       Impact factor: 4.967

3.  Shape-Tunable UV-Printed Solid Drugs for Personalized Medicine.

Authors:  Bobby Aditya Darmawan; Sang Bong Lee; Minghui Nan; Van Du Nguyen; Jong-Oh Park; Eunpyo Choi
Journal:  Polymers (Basel)       Date:  2022-07-02       Impact factor: 4.967

4.  Emerging Technologies and Materials for High-Resolution 3D Printing of Microfluidic Chips.

Authors:  Frederik Kotz; Dorothea Helmer; Bastian E Rapp
Journal:  Adv Biochem Eng Biotechnol       Date:  2022       Impact factor: 2.768

5.  Soluble ECM promotes organotypic formation in lung alveolar model.

Authors:  Jonard C Valdoz; Nicholas A Franks; Collin G Cribbs; Dallin J Jacobs; Ethan L Dodson; Connor J Knight; P Daniel Poulson; Seth R Garfield; Benjamin C Johnson; Brandon M Hemeyer; Miranda T Sudo; Jordan A Saunooke; Braden C Kartchner; Aubrianna Saxton; Mary L Vallecillo-Zuniga; Matheus Santos; Brandon Chamberlain; Kenneth A Christensen; Greg P Nordin; A Sampath Narayanan; Ganesh Raghu; Pam M Van Ry
Journal:  Biomaterials       Date:  2022-03-16       Impact factor: 15.304

6.  Evaluation and optimization of PolyJet 3D-printed materials for cell culture studies.

Authors:  Emily R Currens; Michael R Armbruster; Andre D Castiaux; James L Edwards; R Scott Martin
Journal:  Anal Bioanal Chem       Date:  2022-03-11       Impact factor: 4.478

7.  3D-Printed Microfluidic Droplet Generator with Hydrophilic and Hydrophobic Polymers.

Authors:  Chandler A Warr; Hunter S Hinnen; Saroya Avery; Rebecca J Cate; Gregory P Nordin; William G Pitt
Journal:  Micromachines (Basel)       Date:  2021-01-16       Impact factor: 3.523

Review 8.  Can 3D Printing Bring Droplet Microfluidics to Every Lab?-A Systematic Review.

Authors:  Nafisat Gyimah; Ott Scheler; Toomas Rang; Tamas Pardy
Journal:  Micromachines (Basel)       Date:  2021-03-22       Impact factor: 2.891

9.  Investigation on photopolymerization of PEGDA to fabricate high-aspect-ratio microneedles.

Authors:  Sohyun Kim; Hyemin Lee; Hyewon Choi; Kee-Youn Yoo; Hyunsik Yoon
Journal:  RSC Adv       Date:  2022-03-28       Impact factor: 3.361

Review 10.  Fabrication of Microfluidic Devices for Emulsion Formation by Microstereolithography.

Authors:  Max J Männel; Elif Baysak; Julian Thiele
Journal:  Molecules       Date:  2021-05-10       Impact factor: 4.411
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