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Rapid prototyping of 3d printed micropillars using fused filament fabrication technique for biomedical applications

Shamima Khatoon (Department of Electrical Engineering, Faculty of Engineering, Dayalbagh Educational Institute (Deemed-to-be-University), Agra, India)
Gufran Ahmad (Department of Electrical Engineering, Faculty of Engineering, Dayalbagh Educational Institute (Deemed-to-be-University), Agra, India)

Rapid Prototyping Journal

ISSN: 1355-2546

Article publication date: 20 September 2023

Issue publication date: 27 November 2023

119

Abstract

Purpose

The hygroscopic properties of 3D-printed filaments and moisture absorption itself during the process result in dimensional inaccuracy, particularly for nozzle movement along the x-axis and for micro-scale features. In view of that, this study aims to analyze in depth the dimensional errors and deviations of the fused filament fabrication (FFF)/fused deposition modeling (FDM) 3D-printed micropillars (MPs) from the reference values. A detailed analysis into the variability in printed dimensions below 1 mm in width without any deformations in the printed shape of the designed features, for challenging filaments like polymethyl methacrylate (PMMA) has been done. The study also explores whether the printed shape retains the designed structure.

Design/methodology/approach

A reference model for MPs of width 800 µm and height 2,000 µm is selected to generate a g-code model after pre-processing of slicing and meshing parameters for 3D printing of micro-scale structure with defined boundaries. Three SETs, SET-A, SET-B and SET-C, for nozzle diameter of 0.2 mm, 0.25 mm and 0.3 mm, respectively, have been prepared. The SETs containing the MPs were fabricated with the spacing (S) of 2,000 µm, 3,200 µm and 4,000 µm along the print head x-axis. The MPs were measured by taking three consecutive measurements (top, bottom and middle) for the width and one for the height.

Findings

The prominent highlight of this study is the successful FFF/FDM 3D printing of thin features (<1mm) without any deformation. The mathematical analysis of the variance of the optical microscopy measurements concluded that printed dimensions for micropillar widths did not vary significantly, retaining more than 65% of the recording within the first standard deviation (SD) (±1 s). The minimum value of SD is obtained from the samples of SET-B, that is, 31.96 µm and 35.865 µm, for height and width, respectively. The %RE for SET-B samples is 5.09% for S = 2,000µm, 3.86% for S = 3,200µm and 1.09% for S = 4,000µm. The error percentage is so small that it could be easily compensated by redesigning.

Research limitations/implications

The study does not cover other 3D printing techniques of additive manufacturing like stereolithography, digital light processing and material jetting.

Practical implications

The presented study can be potentially implemented for the rapid prototyping of microfluidics mixer, bioseparator and lab-on-chip devices, both for membrane-free bioseparation based on microfiltration, plasma extraction from whole blood, size-selection trapping of unwanted blood cells, and also for membrane-based plasma extraction that requires supporting microstructures. Our developed process may prove to be far more economical than the other existing techniques for such applications.

Originality/value

For the first time, this work presents a comprehensive analysis of the fabrication of micropillars using FDM/FFF 3D printing and PMMA in filament form. The primary focus of the study is to minimize the dimensional inaccuracies in the 3D printed devices containing thin features, especially in the area of biomedical engineering, by delivering benefits from the choice of the parameters. Thus, on the basis of errors and deviations, a thorough comparison of the three SETs of the fabricated micropillars has been done.

Keywords

Acknowledgements

Author contributions: Shamima Khatoon, Conceptualization, Investigations, Original draft preparation, SupervisionGufran Ahmad – Corresponding Author, Review, Editing. All authors have read and agreed to the published version of the manuscript.Funding: This funding does not cover the APC for this research article.Informed consent statement: Not applicable for studies not involving humans or animals.Conflicts of interest: The authors declare no conflict of interest.SK is the recipient of the Women Scientist-B, Postgraduate fellowship. GA is the project mentor. SK acknowledges the fund provided and research performed within the Women Scientist-B DST-WISE KIRAN Project (Grant No. DST/WOS-B/HN- 17/2021_Shamima) by the Ministry of Science & Technology. The authors also thank Prof. Sahabdas, Head, Department of Chemistry, Dayalbagh Educational Institute, for providing the characterization facilities. The authors also acknowledge Ms. Runjhun Dutta for assisting during optical microscopy. The authors also thank Prof. R.S. Sharma, Dept. of Mech. Engg., for providing the lab facilities.

Citation

Khatoon, S. and Ahmad, G. (2023), "Rapid prototyping of 3d printed micropillars using fused filament fabrication technique for biomedical applications", Rapid Prototyping Journal, Vol. 29 No. 10, pp. 2272-2284. https://doi.org/10.1108/RPJ-03-2023-0096

Publisher

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Emerald Publishing Limited

Copyright © 2023, Emerald Publishing Limited

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