Luo et al., 2023 - Google Patents
Digital light processing 3D printing for microfluidic chips with enhanced resolution via dosing-and zoning-controlled vat photopolymerizationLuo et al., 2023
View HTML- Document ID
- 9385452747258683077
- Author
- Luo Z
- Zhang H
- Chen R
- Li H
- Cheng F
- Zhang L
- Liu J
- Kong T
- Zhang Y
- Wang H
- Publication year
- Publication venue
- Microsystems & Nanoengineering
External Links
Snippet
Conventional manufacturing techniques to fabricate microfluidic chips, such as soft lithography and hot embossing process, have limitations that include difficulty in preparing multiple-layered structures, cost-and labor-consuming fabrication process, and low …
- 238000012545 processing 0 title abstract description 15
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Gross et al. | Recent advances in analytical chemistry by 3D printing | |
| Luo et al. | Digital light processing 3D printing for microfluidic chips with enhanced resolution via dosing-and zoning-controlled vat photopolymerization | |
| Warr et al. | Biocompatible PEGDA resin for 3D printing | |
| Hwang et al. | 3D‐Printing of functional biomedical microdevices via light‐and extrusion‐based approaches | |
| Shin et al. | Monolithic digital patterning of polydimethylsiloxane with successive laser pyrolysis | |
| Männel et al. | Optimizing Process Parameters in Commercial Micro‐Stereolithography for Forming Emulsions and Polymer Microparticles in Nonplanar Microfluidic Devices | |
| Behroodi et al. | A combined 3D printing/CNC micro-milling method to fabricate a large-scale microfluidic device with the small size 3D architectures: An application for tumor spheroid production | |
| Bhattacharjee et al. | The upcoming 3D-printing revolution in microfluidics | |
| Ji et al. | A modular microfluidic device via multimaterial 3D printing for emulsion generation | |
| Faraji Rad et al. | High-fidelity replication of thermoplastic microneedles with open microfluidic channels | |
| Tony et al. | The additive manufacturing approach to polydimethylsiloxane (PDMS) microfluidic devices: review and future directions | |
| He et al. | Research on the printability of hydrogels in 3D bioprinting | |
| Bragheri et al. | Microfluidics | |
| Ho et al. | 3D printed microfluidics for biological applications | |
| Choi et al. | Rapid patterning of PDMS microfluidic device wettability using syringe-vacuum-induced segmented flow in nonplanar geometry | |
| Baah et al. | Microfluidics for particle synthesis from photocrosslinkable materials | |
| Carugo et al. | Facile and cost-effective production of microscale PDMS architectures using a combined micromilling-replica moulding (μ Mi-REM) technique | |
| Accardo et al. | Direct laser fabrication of meso-scale 2D and 3D architectures with micrometric feature resolution | |
| Friedrich et al. | Suppression of filament defects in embedded 3D printing | |
| Weigel et al. | Flexible materials for high-resolution 3D printing of microfluidic devices with integrated droplet size regulation | |
| Kronenfeld et al. | Roll-to-roll, high-resolution 3D printing of shape-specific particles | |
| Hua et al. | Embedded 3D printing of PDMS-based microfluidic chips for biomedical applications | |
| Zips et al. | Biocompatible, flexible, and oxygen-permeable silicone-hydrogel material for stereolithographic printing of microfluidic lab-on-a-chip and cell-culture devices | |
| Dogan et al. | Customized 3D-printed stackable cell culture inserts tailored with bioactive membranes | |
| Simmons et al. | Hydrogel-assisted double molding enables rapid replication of stereolithographic 3D prints for engineered tissue design |