Abstract
This paper describes the use of fused deposition modeling (FDM) printing to fabricate paper-based analytical devices (PAD) with three-dimensional (3D) features, which is termed as 3D-PAD. Material depositions followed by heat reflow is a standard approach for the fabrication of PAD. Such devices are primarily two-dimensional (2D) and can hold only a limited amount of liquid samples in the device. This constraint can pose problems when the sample consists of organic solvents that have low interfacial energies with the hydrophobic barriers. To overcome this limitation, we developed a method to fabricate PAD integrated with 3D features (vertical walls as an example) by FDM 3D printing. 3D-PADs were fabricated using two types of thermoplastics. One thermoplastic had a low melting point that formed hydrophobic barriers upon penetration, and another thermoplastic had a high melting point that maintained 3D features on the filter paper without reflowing. We used polycaprolactone (PCL) for the former, and polylactic acid (PLA) for the latter. Both PCL and PLA were printed with FDM without gaps at the interface, and the resulting paper-based devices possessed hydrophobic barriers consisting of PCL seamlessly integrated with vertical features consisting of PLA. We validated the capability of 3D-PAD to hold 30 μL of solvents (ethanol, isopropyl alcohol, and acetone), all of which would not be retained on conventional PADs fabricated with solid wax printers. To highlight the importance of containing an increased amount of liquid samples, a colorimetric assay for the formation of dimethylglyoxime (DMG)-Ni (II) was demonstrated using two volumes (10 μL and 30 μL) of solvent-based dimethylglyoxime (DMG). FDM printing of 3D-PAD enabled the facile construction of 3D structures integrated with PAD, which would find applications in paper-based chemical and biological assays requiring organic solvents.
Highlights
This paper describes the use of fused deposition modeling (FDM) printing to fabricate paper-based analytical devices (PAD) integrated with three-dimensional (3D) features
We fabricated PADs integrated with 3D features by FDM 3D printing, which we termed 3D-PAD. 3D-PADs have improved the containment of organic solvents (e.g., 30 μL of ethanol, isopropyl alcohol (IPA), and acetone), which should find applications in handling solvent-based samples for paper-based chemical and biological assays
We demonstrated the fabrication of 3D wells in paper analytical devices (PAD), which we termed 3D-PAD
Summary
This paper describes the use of fused deposition modeling (FDM) printing to fabricate paper-based analytical devices (PAD) integrated with three-dimensional (3D) features. Direct material printing (such as solid wax printing and inkjet printing) followed by heating is a standard approach for the fabrication of PAD Devices fabricated by such methods are inherently two-dimensional (2D); such conventional PADs are not able to hold organic solvents that have low interfacial energies with hydrophobic materials. Materials with high interfacial energy with solvents have been demonstrated to enhance the containment of liquid samples To this end, barriers based on fluoropolymers were patterned using chemical vapor deposition [45,46]. We patterned two different materials (with different melting points) by multi-material FDM printing: PCL and polylactic acid (PLA) Both PCL and PLA are hydrophobic thermoplastics exhibiting low solubility to selected organic solvents [54,55]. Our method enabled embedding 3D structures on filter paper and should provide opportunities to enhance the analytical capability and functionality of paper-based devices
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