Your search keyword '"Rapid prototyping"' showing total 99 results

1. Three-Dimensionally Printed Microsystems to Facilitate Flow-Based Study of Cells from Neurovascular Barriers of the Retina.

Author

Leverant, Adam, Oprysk, Larissa, Dabrowski, Alexandra, Kyker-Snowman, Kelly, and Vazquez, Maribel

Subjects

RAPID prototyping, 3-D printers, THREE-dimensional printing, CELL morphology, BIOENGINEERING, FUSED deposition modeling, STEREOLITHOGRAPHY

Abstract

Rapid prototyping has produced accessible manufacturing methods that offer faster and more cost-effective ways to develop microscale systems for cellular testing. Commercial 3D printers are now increasingly adapted for soft lithography, where elastomers are used in tandem with 3D-printed substrates to produce in vitro cell assays. Newfound abilities to prototype cellular systems have begun to expand fundamental bioengineering research in the visual system to complement tissue engineering studies reliant upon complex microtechnology. This project used 3D printing to develop elastomeric devices that examined the responses of retinal cells to flow. Our experiments fabricated molds for elastomers using metal milling, resin stereolithography, and fused deposition modeling via plastic 3D printing. The systems were connected to flow pumps to simulate different flow conditions and examined phenotypic responses of endothelial and neural cells significant to neurovascular barriers of the retina. The results indicated that microdevices produced using 3D-printed methods demonstrated differences in cell survival and morphology in response to external flow that are significant to barrier tissue function. Modern 3D printing technology shows great potential for the rapid production and testing of retinal cell responses that will contribute to both our understanding of fundamental cell response and the development of new therapies. Future studies will incorporate varied flow stimuli as well as different extracellular matrices and expanded subsets of retinal cells. [ABSTRACT FROM AUTHOR]

Published

2024

2. Universal and Versatile Magnetic Connectors for Microfluidic Devices.

Author

Alvarez-Amador, Maria, Salimov, Amir, and Brouzes, Eric

Subjects

PRESSURE-sensitive adhesives, RAPID prototyping, TUBES, MICROFLUIDIC devices

Abstract

World-to-chip interfacing remains a critical issue for microfluidic devices. Current solutions to connect tubing to rigid microfluidic chips remain expensive, laborious, or require specialized skills and precision machining. Here, we report reusable, inexpensive, and easy-to-use connectors that enable monitoring of the connection ports. Our magnetic connectors benefit from a simple one-step fabrication process and low dead volume. They sustain pressures within the high range of microfluidic applications. They represent an essential tool for rapid thermoplastic (PMMA, PC, COC) prototyping and can also be used with glass, pressure-sensitive adhesive, or thin PDMS devices. [ABSTRACT FROM AUTHOR]

Published

2024

3. A Novel 3D-Printed and Miniaturized Periodic Counter Current Chromatography System for Continuous Purification of Monoclonal Antibodies.

Author

Kortmann, Carlotta, Habib, Taieb, Heuer, Christopher, Solle, Dörte, and Bahnemann, Janina

Subjects

ION exchange chromatography, COUNTERCURRENT chromatography, CHROMATOGRAPHIC analysis, AFFINITY chromatography, CELL culture, PROTEIN fractionation, MONOCLONAL antibodies, RAPID prototyping

Abstract

Continuous chromatography has emerged as one of the most attractive methods for protein purification. Establishing such systems involves installing several chromatographic units in series to enable continuous separation processes and reduce the cost of the production of expensive proteins and biopharmaceuticals (such as monoclonal antibodies). However, most of the established systems are bulky and plagued by high dead volume, which requires further optimization for improved separation procedures. In this article, we present a miniaturized periodic counter-current chromatography (PCCC) system, which is characterized by substantially reduced dead volume when compared to traditional chromatography setups. The PCCC device was fabricated by 3D printing, allowing for flexible design adjustments and rapid prototyping, and has great potential to be used for the screening of optimized chromatography conditions and protocols. The functionality of the 3D-printed device was demonstrated with respect to the capture and polishing steps during a monoclonal antibody purification process. Furthermore, this novel miniaturized system was successfully used for two different chromatography techniques (affinity and ion-exchange chromatography) and two different types of chromatographic units (columns and membrane adsorbers). This demonstrated versability underscores the flexibility of this kind of system and its potential for utilization in various chromatography applications, such as direct product capture from perfusion cell cultures. [ABSTRACT FROM AUTHOR]

Published

2024

4. Comparing the Performance of Rolled Steel and 3D-Printed 316L Stainless Steel.

Author

Lin, Yao-Tsung, Tsai, Ming-Yi, Yen, Shih-Yu, Lung, Guan-Hua, Yei, Jin-Ting, Hsu, Kuo-Jen, and Chen, Kai-Jung

Subjects

ROLLED steel, RAPID prototyping, STAINLESS steel, MANUFACTURING processes, SURFACE roughness, THREE-dimensional printing

Abstract

Three-dimensional printing is a non-conventional additive manufacturing process. It is different from the conventional subtractive manufacturing process. It offers exceptional rapid prototyping capabilities and results that conventional subtractive manufacturing methods cannot attain, especially in applications involving curved or intricately shaped components. Despite its advantages, metal 3D printing will face porosity, warpage, and surface roughness issues. These issues will affect the future practical application of the parts indirectly, for example, by affecting the structural strength and the parts' assembly capability. Therefore, this study compares the qualities of the warpage, weight, and surface roughness after milling and grinding processes for the same material (316L stainless steel) between rolled steel and 3D-printed steel. The experimental results show that 3D-printed parts are approximately 13% to 14% lighter than rolled steel. The surface roughness performance of 3D-printed steel is better than that of rolled steel for the same material after milling or grinding processing. The hardness of the 3D-printed steel is better than that of the rolled steel. This research verifies that 3D additive manufacturing can use surface processing to optimize surface performance and achieve the functions of lightness and hardness. [ABSTRACT FROM AUTHOR]

Published

2024

5. Pysanky to Microfluidics: An Innovative Wax-Based Approach to Low Cost, Rapid Prototyping of Microfluidic Devices.

Author

Schneider, Philip J., Christie, Liam B., Eadie, Nicholas M., Siskar, Tyler J., Sukhotskiy, Viktor, Koh, Domin, Wang, Anyang, and Oh, Kwang W.

Subjects

MICROFLUIDIC devices, RAPID prototyping, MICROFLUIDICS, PAINTING techniques, CONTACT angle, MATHEMATICAL optimization

Abstract

A wax-based contact printing method to create microfluidic devices is demonstrated. This printing technology demonstrates a new pathway to rapid, cost-effective device prototyping, eliminating the use of expensive micromachining equipment and chemicals. Derived from the traditional Ukrainian Easter egg painting technique called "pysanky" a series of microfluidic devices were created. Pysanky is the use of a heated wax stylus, known as a "kistka", to create micro-sized, intricate designs on the surface of an egg. The proposed technique involves the modification of an x-y-z actuation translation system with a wax extruder tip in junction with Polydimethysiloxane (PDMS) device fabrication techniques. Initial system optimization was performed considering design parameters such as extruder tip size, contact angle, write speed, substrate temperature, and wax temperature. Channels created ranged from 160 to 900 μm wide and 10 to 150 μm high based upon system operating parameters set by the user. To prove the capabilities of this technology, a series of microfluidic mixers were created via the wax technique as well as through traditional photolithography: a spiral mixer, a rainbow mixer, and a linear serial dilutor. A thermo-fluidic computational fluid dynamic (CFD) model was generated as a means of enabling rational tuning, critical to the optimization of systems in both normal and extreme conditions. A comparison between the computational and experimental models yielded a wax height of 57.98 μm and 57.30 μm, respectively, and cross-sectional areas of 11,568 μm2 and 12,951 μm2, respectively, resulting in an error of 1.18% between the heights and 10.76% between the cross-sectional areas. The device's performance was then compared using both qualitative and quantitative measures, considering factors such as device performance, channel uniformity, repeatability, and resolution. [ABSTRACT FROM AUTHOR]

Published

2024

6. Three-Dimensionally Printed Microsystems to Facilitate Flow-Based Study of Cells from Neurovascular Barriers of the Retina

Author

Adam Leverant, Larissa Oprysk, Alexandra Dabrowski, Kelly Kyker-Snowman, and Maribel Vazquez

Subjects

rapid prototyping, endothelial cells, retinal neural cells, morphology, survival, Mechanical engineering and machinery, TJ1-1570

Abstract

Rapid prototyping has produced accessible manufacturing methods that offer faster and more cost-effective ways to develop microscale systems for cellular testing. Commercial 3D printers are now increasingly adapted for soft lithography, where elastomers are used in tandem with 3D-printed substrates to produce in vitro cell assays. Newfound abilities to prototype cellular systems have begun to expand fundamental bioengineering research in the visual system to complement tissue engineering studies reliant upon complex microtechnology. This project used 3D printing to develop elastomeric devices that examined the responses of retinal cells to flow. Our experiments fabricated molds for elastomers using metal milling, resin stereolithography, and fused deposition modeling via plastic 3D printing. The systems were connected to flow pumps to simulate different flow conditions and examined phenotypic responses of endothelial and neural cells significant to neurovascular barriers of the retina. The results indicated that microdevices produced using 3D-printed methods demonstrated differences in cell survival and morphology in response to external flow that are significant to barrier tissue function. Modern 3D printing technology shows great potential for the rapid production and testing of retinal cell responses that will contribute to both our understanding of fundamental cell response and the development of new therapies. Future studies will incorporate varied flow stimuli as well as different extracellular matrices and expanded subsets of retinal cells.

Published

2024

7. A Rapid Prototyping Approach for Multi-Material, Reversibly Sealed Microfluidics.

Author

Halwes, Michael, Stamp, Melanie, and Collins, David J.

Subjects

MICROFLUIDIC devices, RAPID prototyping, MICROFLUIDICS, LASER beam cutting, THREE-dimensional printing, SEALS (Closures), LASER printing

Abstract

Microfluidic organ-on-chip models recapitulate increasingly complex physiological phenomena to study tissue development and disease mechanisms, where there is a growing interest in retrieving delicate biological structures from these devices for downstream analysis. Standard bonding techniques, however, often utilize irreversible sealing, making sample retrieval unfeasible or necessitating destructive methods for disassembly. To address this, several commercial devices employ reversible sealing techniques, though integrating these techniques into early-stage prototyping workflows is often ignored because of the variation and complexity of microfluidic designs. Here, we demonstrate the concerted use of rapid prototyping techniques, including 3D printing and laser cutting, to produce multi-material microfluidic devices that can be reversibly sealed. This is enhanced via the incorporation of acrylic components directly into polydimethylsiloxane channel layers to enhance stability, sealing, and handling. These acrylic components act as a rigid surface separating the multiple mechanical seals created between the bottom substrate, the microfluidic features in the device, and the fluidic interconnect to external tubing, allowing for greater design flexibility. We demonstrate that these devices can be produced reproducibly outside of a cleanroom environment and that they can withstand ~1 bar pressures that are appropriate for a wide range of biological applications. By presenting an accessible and low-cost method, we hope to enable microfluidic prototyping for a broad range of biomedical research applications. [ABSTRACT FROM AUTHOR]

Published

2023

8. Towards High Efficiency and Rapid Production of Room-Temperature Liquid Metal Wires Compatible with Electronic Prototyping Connectors.

Author

Morita, Luka, Jalali, Shima, Vaheb, Abolfazl, Elsersawy, Rawan, Golwala, Kunj, Asad, Asad, Dolez, Patricia I., Hogan, James D., Khondoker, Mohammad Abu Hasan, and Sameoto, Dan

Subjects

LIQUID metals, THERMOPLASTIC elastomers, SOFT robotics, RAPID prototyping, WEARABLE technology, GALLIUM

Abstract

We present in this work new methodologies to produce, refine, and interconnect room-temperature liquid-metal-core thermoplastic elastomer wires that have extreme extendibility (>500%), low production time and cost at scale, and may be integrated into commonly used electrical prototyping connectors like a Japan Solderless Terminal (JST) or Dupont connectors. Rather than focus on the development of a specific device, the aim of this work is to demonstrate strategies and processes necessary to achieve scalable production of liquid-metal-enabled electronics and address several key challenges that have been present in liquid metal systems, including leak-free operation, minimal gallium corrosion of other electrode materials, low liquid metal consumption, and high production rates. The ultimate goal is to create liquid-metal-enabled rapid prototyping technologies, similar to what can be achieved with Arduino projects, where modification and switching of components can be performed in seconds, which enables faster iterations of designs. Our process is focused primarily on fibre-based liquid metal wires contained within thermoplastic elastomers. These fibre form factors can easily be integrated with wearable sensors and actuators as they can be sewn or woven into fabrics, or cast within soft robotic components. [ABSTRACT FROM AUTHOR]

Published

2023

9. Rapid Micromolding of Sub-100 µm Microfluidic Channels Using an 8K Stereolithographic Resin 3D Printer.

Author

Vedhanayagam, Arpith, Golfetto, Michael, Ram, Jeffrey L., and Basu, Amar S.

Subjects

RAPID prototyping, SOFT lithography, TURNAROUND time, 3-D printers, MICROFLUIDIC devices, MICROFLUIDICS, THREE-dimensional printing

Abstract

Engineering microfluidic devices relies on the ability to manufacture sub-100 micrometer fluidic channels. Conventional lithographic methods provide high resolution but require costly exposure tools and outsourcing of masks, which extends the turnaround time to several days. The desire to accelerate design/test cycles has motivated the rapid prototyping of microfluidic channels; however, many of these methods (e.g., laser cutters, craft cutters, fused deposition modeling) have feature sizes of several hundred microns or more. In this paper, we describe a 1-day process for fabricating sub-100 µm channels, leveraging a low-cost (USD 600) 8K digital light projection (DLP) 3D resin printer. The soft lithography process includes mold printing, post-treatment, and casting polydimethylsiloxane (PDMS) elastomer. The process can produce microchannels with 44 µm lateral resolution and 25 µm height, posts as small as 400 µm, aspect ratio up to 7, structures with varying z-height, integrated reservoirs for fluidic connections, and a built-in tray for casting. We discuss strategies to obtain reliable structures, prevent mold warpage, facilitate curing and removal of PDMS during molding, and recycle the solvents used in the process. To our knowledge, this is the first low-cost 3D printer that prints extruded structures that can mold sub-100 µm channels, providing a balance between resolution, turnaround time, and cost (~USD 5 for a 2 × 5 × 0.5 cm3 chip) that will be attractive for many microfluidics labs. [ABSTRACT FROM AUTHOR]

Published

2023

10. Rapid Prototyping of Multi-Functional and Biocompatible Parafilm ® -Based Microfluidic Devices by Laser Ablation and Thermal Bonding.

Author

Wei, Yuanyuan, Wang, Tianle, Wang, Yuye, Zeng, Shuwen, Ho, Yi-Ping, and Ho, Ho-Pui

Subjects

LASER ablation, ESCHERICHIA coli, MICROFLUIDIC devices, SHEARING force, POINT-of-care testing, POLYMETHYLMETHACRYLATE, RAPID prototyping

Abstract

In this paper, we report a simple, rapid, low-cost, biocompatible, and detachable microfluidic chip fabrication method for customized designs based on Parafilm®. Here, Parafilm® works as both a bonding agent and a functional membrane. Its high ultimate tensile stress (3.94 MPa) allows the demonstration of high-performance actuators such as microvalves and micropumps. By laser ablation and the one-step bonding of multiple layers, 3D structured microfluidic chips were successfully fabricated within 2 h. The consumption time of this method (~2 h) was 12 times less than conventional photolithography (~24 h). Moreover, the shear stress of the PMMA–Parafilm®–PMMA specimens (0.24 MPa) was 2.13 times higher than that of the PDMS–PDMS specimens (0.08 MPa), and 0.56 times higher than that of the PDMS–Glass specimens (0.16 MPa), showing better stability and reliability. In this method, multiple easily accessible materials such as polymethylmethacrylate (PMMA), PVC, and glass slides were demonstrated and well-incorporated as our substrates. Practical actuation devices that required high bonding strength including microvalves and micropumps were fabricated by this method with high performance. Moreover, the biocompatibility of the Parafilm®-based microfluidic devices was validated through a seven-day E. coli cultivation. This reported fabrication scheme will provide a versatile platform for biochemical applications and point-of-care diagnostics. [ABSTRACT FROM AUTHOR]

Published

2023

11. Plotter Cut Stencil Masks for the Deposition of Organic and Inorganic Materials and a New Rapid, Cost Effective Technique for Antimicrobial Evaluations.

Author

Childs, Andre, Pereira, Jorge, Didier, Charles M., Baksh, Aliyah, Johnson, Isaac, Castro, Jorge Manrique, Davidson, Edwin, Santra, Swadeshmukul, and Rajaraman, Swaminathan

Subjects

STENCIL work, RAPID prototyping, MEDICAL masks, RAPID tooling, DRUG resistance in bacteria

Abstract

Plotter cutters in stencil mask prototyping are underutilized but have several advantages over traditional MEMS techniques. In this paper we investigate the use of a conventional plotter cutter as a highly effective benchtop tool for the rapid prototyping of stencil masks in the sub-250 μm range and characterize patterned layers of organic/inorganic materials. Furthermore, we show a new diagnostic monitoring application for use in healthcare, and a potential replacement of the Standard Kirby-Bauer Diffusion Antibiotic Resistance tests was developed and tested on both Escherichia coli and Xanthomonas alfalfae as pathogens with Oxytetracycline, Streptomycin and Kanamycin. We show that the reduction in area required for the minimum inhibitory concentration tests; allow for three times the number of tests to be performed within the same nutrient agar Petri dish, demonstrated both theoretically and experimentally resulting in correlations of R ≈ 0.96 and 0.985, respectively for both pathogens. [ABSTRACT FROM AUTHOR]

Published

2023

12. A Rapid Prototyping Approach for Multi-Material, Reversibly Sealed Microfluidics

Author

Michael Halwes, Melanie Stamp, and David J. Collins

Subjects

microfluidics, rapid prototyping, additive manufacturing, lab-on-a-chip, organ-on-chip, Mechanical engineering and machinery, TJ1-1570

Abstract

Microfluidic organ-on-chip models recapitulate increasingly complex physiological phenomena to study tissue development and disease mechanisms, where there is a growing interest in retrieving delicate biological structures from these devices for downstream analysis. Standard bonding techniques, however, often utilize irreversible sealing, making sample retrieval unfeasible or necessitating destructive methods for disassembly. To address this, several commercial devices employ reversible sealing techniques, though integrating these techniques into early-stage prototyping workflows is often ignored because of the variation and complexity of microfluidic designs. Here, we demonstrate the concerted use of rapid prototyping techniques, including 3D printing and laser cutting, to produce multi-material microfluidic devices that can be reversibly sealed. This is enhanced via the incorporation of acrylic components directly into polydimethylsiloxane channel layers to enhance stability, sealing, and handling. These acrylic components act as a rigid surface separating the multiple mechanical seals created between the bottom substrate, the microfluidic features in the device, and the fluidic interconnect to external tubing, allowing for greater design flexibility. We demonstrate that these devices can be produced reproducibly outside of a cleanroom environment and that they can withstand ~1 bar pressures that are appropriate for a wide range of biological applications. By presenting an accessible and low-cost method, we hope to enable microfluidic prototyping for a broad range of biomedical research applications.

Published

2023

13. Diode Laser and Polyimide Tape Enables Cheap and Fast Fabrication of Flexible Microfluidic Sensing Devices.

Author

Thaweeskulchai, Thana and Schulte, Albert

Subjects

MICROFLUIDIC devices, LASER machining, ELECTROCHEMICAL analysis, RAPID prototyping, LASER ablation, WEARABLE technology, SEMICONDUCTOR lasers

Abstract

Wearable devices are a new class of healthcare monitoring devices designed for use in close contact with the patient's body. Such devices must be flexible to follow the contours of human anatomy. With numerous potential applications, a wide variety of flexible wearable devices have been created, taking various forms and functions. Therefore, different fabrication techniques and materials are employed, resulting in fragmentation of the list of equipment and materials needed to make different devices. This study attempted to simplify and streamline the fabrication process of all key components, including microfluidic chip and flexible electrode units. A combination of diode laser CNC machine and polyimide tape is used to fabricate flexible microfluidic chip and laser-induced graphene (LIG) electrodes, to create flexible microfluidic sensing devices. Laser ablation on polyimide tape can directly create microfluidic features on either PDMS substrates or LIG electrodes. The two components can be assembled to form a flexible microfluidic sensing device that can perform basic electrochemical analysis and conform to curved surfaces while undergoing microfluidic flow. This study has shown that simple, commonly available equipment and materials can be used to fabricate flexible microfluidic sensing devices quickly and easily, which is highly suitable for rapid prototyping of wearable devices. [ABSTRACT FROM AUTHOR]

Published

2022

14. Picoliter Droplet Generation and Dense Bead-in-Droplet Encapsulation via Microfluidic Devices Fabricated via 3D Printed Molds.

Author

Anyaduba, Tochukwu D., Otoo, Jonas A., and Schlappi, Travis S.

Subjects

MICROFLUIDIC devices, DRUG discovery, RAPID prototyping, 3-D printers, THREE-dimensional printing, CELL analysis

Abstract

Picoliter-scale droplets have many applications in chemistry and biology, such as biomolecule synthesis, drug discovery, nucleic acid quantification, and single cell analysis. However, due to the complicated processes used to fabricate microfluidic channels, most picoliter (pL) droplet generation methods are limited to research in laboratories with cleanroom facilities and complex instrumentation. The purpose of this work is to investigate a method that uses 3D printing to fabricate microfluidic devices that can generate droplets with sizes <100 pL and encapsulate single dense beads mechanistically. Our device generated monodisperse droplets as small as ~48 pL and we demonstrated the usefulness of this droplet generation technique in biomolecule analysis by detecting Lactobacillus acidophillus 16s rRNA via digital loop-mediated isothermal amplification (dLAMP). We also designed a mixer that can be integrated into a syringe to overcome dense bead sedimentation and found that the bead-in-droplet (BiD) emulsions created from our device had <2% of the droplets populated with more than 1 bead. This study will enable researchers to create devices that generate pL-scale droplets and encapsulate dense beads with inexpensive and simple instrumentation (3D printer and syringe pump). The rapid prototyping and integration ability of this module with other components or processes can accelerate the development of point-of-care microfluidic devices that use droplet-bead emulsions to analyze biological or chemical samples with high throughput and precision. [ABSTRACT FROM AUTHOR]

Published

2022

15. PDMS Organ-On-Chip Design and Fabrication: Strategies for Improving Fluidic Integration and Chip Robustness of Rapidly Prototyped Microfluidic In Vitro Models.

Author

Cameron, Tiffany C., Randhawa, Avineet, Grist, Samantha M., Bennet, Tanya, Hua, Jessica, Alde, Luis G., Caffrey, Tara M., Wellington, Cheryl L., and Cheung, Karen C.

Subjects

CELL culture, FLUID flow, INJECTION molding, RAPID prototyping, FLUIDIC devices, UNIFORMITY

Abstract

The PDMS-based microfluidic organ-on-chip platform represents an exciting paradigm that has enjoyed a rapid rise in popularity and adoption. A particularly promising element of this platform is its amenability to rapid manufacturing strategies, which can enable quick adaptations through iterative prototyping. These strategies, however, come with challenges; fluid flow, for example, a core principle of organs-on-chip and the physiology they aim to model, necessitates robust, leak-free channels for potentially long (multi-week) culture durations. In this report, we describe microfluidic chip fabrication methods and strategies that are aimed at overcoming these difficulties; we employ a subset of these strategies to a blood–brain-barrier-on-chip, with others applied to a small-airway-on-chip. Design approaches are detailed with considerations presented for readers. Results pertaining to fabrication parameters we aimed to improve (e.g., the thickness uniformity of molded PDMS), as well as illustrative results pertaining to the establishment of cell cultures using these methods will also be presented. [ABSTRACT FROM AUTHOR]

Published

2022

16. Rapid Micromolding of Sub-100 µm Microfluidic Channels Using an 8K Stereolithographic Resin 3D Printer

Author

Arpith Vedhanayagam, Michael Golfetto, Jeffrey L. Ram, and Amar S. Basu

Subjects

3D resin printing, micromolding, rapid prototyping, PDMS soft lithography, Mechanical engineering and machinery, TJ1-1570

Abstract

Engineering microfluidic devices relies on the ability to manufacture sub-100 micrometer fluidic channels. Conventional lithographic methods provide high resolution but require costly exposure tools and outsourcing of masks, which extends the turnaround time to several days. The desire to accelerate design/test cycles has motivated the rapid prototyping of microfluidic channels; however, many of these methods (e.g., laser cutters, craft cutters, fused deposition modeling) have feature sizes of several hundred microns or more. In this paper, we describe a 1-day process for fabricating sub-100 µm channels, leveraging a low-cost (USD 600) 8K digital light projection (DLP) 3D resin printer. The soft lithography process includes mold printing, post-treatment, and casting polydimethylsiloxane (PDMS) elastomer. The process can produce microchannels with 44 µm lateral resolution and 25 µm height, posts as small as 400 µm, aspect ratio up to 7, structures with varying z-height, integrated reservoirs for fluidic connections, and a built-in tray for casting. We discuss strategies to obtain reliable structures, prevent mold warpage, facilitate curing and removal of PDMS during molding, and recycle the solvents used in the process. To our knowledge, this is the first low-cost 3D printer that prints extruded structures that can mold sub-100 µm channels, providing a balance between resolution, turnaround time, and cost (~USD 5 for a 2 × 5 × 0.5 cm3 chip) that will be attractive for many microfluidics labs.

Published

2023

17. Low Cost, Ease-of-Access Fabrication of Microfluidic Devices Using Wet Paper Molds.

Author

Thakur, Raviraj and Fridman, Gene Y.

Subjects

MICROFLUIDICS, MICROFLUIDIC devices, RAPID prototyping, THREE-dimensional printing, ELECTRIC impedance, MINERAL oils, MINERAL waters

Abstract

Rapid prototyping methods enable the widespread adoption of microfluidic technologies by empowering end-users from non-engineering disciplines to make devices using processes that are rapid, simple and inexpensive. In this work, we developed a liquid molding technique to create silicone/PDMS microfluidic devices by replica molding. To construct a liquid mold, we use inexpensive adhesive-backed paper, an acetate backing sheet, and an off-the-shelf digital cutter to create paper molds, which we then wet with predetermined amounts of water. Due to the immiscibility of water and PDMS, mold patterns can be effectively transferred onto PDMS similarly to solid molds. We demonstrate the feasibility of these wet paper molds for the fabrication of PDMS microfluidic devices and assess the influence of various process parameters on device yield and quality. This method possesses some distinct benefits compared to conventional techniques such as photolithography and 3D printing. First, we demonstrate that the shape of a channel's cross-section may be altered from rectangular to semicircular by merely modifying the wetting parameters. Second, we illustrate how electrical impedance can be utilized as a marker for inspecting mold quality and identifying defects in a non-invasive manner without using visual tools such as microscopes or cameras. As a proof-of-concept device, we created a microfluidic T-junction droplet generator to produce water droplets in mineral oil ranging in size from 1.2 µL to 75 µL. We feel that this technology is an excellent addition to the microfluidic rapid prototyping toolbox and will find several applications in biological research. [ABSTRACT FROM AUTHOR]

Published

2022

18. Modular Microfluidics: Current Status and Future Prospects.

Author

Lai, Xiaochen, Yang, Mingpeng, Wu, Hao, and Li, Dachao

Subjects

MICROFLUIDICS, MODULAR forms, RAPID prototyping

Abstract

This review mainly studies the development status, limitations, and future directions of modular microfluidic systems. Microfluidic technology is an important tool platform for scientific research and plays an important role in various fields. With the continuous development of microfluidic applications, conventional monolithic microfluidic chips show more and more limitations. A modular microfluidic system is a system composed of interconnected, independent modular microfluidic chips, which are easy to use, highly customizable, and on-site deployable. In this paper, the current forms of modular microfluidic systems are classified and studied. The popular fabrication techniques for modular blocks, the major application scenarios of modular microfluidics, and the limitations of modular techniques are also discussed. Lastly, this review provides prospects for the future direction of modular microfluidic technologies. [ABSTRACT FROM AUTHOR]

Published

2022

19. 3D Printed PCB Microfluidics.

Author

Gassmann, Stefan, Jegatheeswaran, Sathurja, Schleifer, Till, Arbabi, Hesam, and Schütte, Helmut

Subjects

MICROFLUIDICS, 3-D printers, PRINTED circuits, MANUFACTURING processes, RAPID prototyping, STEREOLITHOGRAPHY, THREE-dimensional printing

Abstract

The combination of printed circuit boards (PCB) and microfluidics has many advantages. The combination of electrodes, sensors and electronics is needed for almost all microfluidic systems. Using PCBs as a substrate, this integration is intrinsic. Additive manufacturing has become a widely used technique in industry, research and by hobbyists. One very promising rapid prototype technique is vat polymerization with an LCD as mask, also known as masked stereolithography (mSLA). These printers are available with resolutions down to 35 µm, and they are affordable. In this paper, a technology is described which creates microfluidics on a PCB substrate using an mSLA printer. All steps of the production process can be carried out with commercially available printers and resins: this includes the structuring of the copper layer of the PCB and the buildup of the channel layer on top of the PCB. Copper trace dimensions down to 100 µm and channel dimensions of 800 µm are feasible. The described technology is a low-cost solution for combining PCBs and microfluidics. [ABSTRACT FROM AUTHOR]

Published

2022

20. Reconfigurable Electronic Platforms: A Top-Down Approach to Learn about Design and Integration of Electronic Systems.

Author

Rivadeneyra, Almudena, Romero, Francisco J., Haider, Michael, Bhatt, Vijay D., Salmeron, Jose F., Rodriguez, Noel, Morales, Diego P., and Becherer, Markus

Subjects

ELECTRONIC systems, SYSTEM integration, ELECTRONICS engineers, ENGINEERING students, TEACHING methods

Abstract

This case report presents a real example of a study which introduces the use of reconfigurable platforms in the teaching of electronics engineering to establish a bridge between theory and practice. This gap is one of the major concerns of the electronics engineering students. Different strategies, such as simulation tools or breadboard implementations, have been followed so far to make it easier for students to practice what they study in lectures. However, many students still claim to have problems when they face real practical implementations. The use of reconfigurable platforms as a teaching tool is proposed to provide the students the possibility of fast experimentation, reducing both development time and the learning curve. In addition, reconfigurable platforms available on the market make this methodology suitable to be applied throughout the different courses of their curricula. The feasibility of this approach is demonstrated in a course at the M.Eng. level, where the objective is the study, design and development of electronic sensor nodes. We firmly consider, based on the students' results and reflections collected during the course, that this methodology helps students to address the theoretical framework from a practical viewpoint, as well as to acquire some of the fundamental skills for their professional careers, such as the usage of communication protocols and embedded systems programming, in a more intuitive way when compared to traditional teaching methodologies. [ABSTRACT FROM AUTHOR]

Published

2022

21. Picoliter Droplet Generation and Dense Bead-in-Droplet Encapsulation via Microfluidic Devices Fabricated via 3D Printed Molds

Author

Tochukwu D. Anyaduba, Jonas A. Otoo, and Travis S. Schlappi

Subjects

microfluidics, picoliter droplets, rapid prototyping, bead encapsulation, 3D printing, Mechanical engineering and machinery, TJ1-1570

Abstract

Picoliter-scale droplets have many applications in chemistry and biology, such as biomolecule synthesis, drug discovery, nucleic acid quantification, and single cell analysis. However, due to the complicated processes used to fabricate microfluidic channels, most picoliter (pL) droplet generation methods are limited to research in laboratories with cleanroom facilities and complex instrumentation. The purpose of this work is to investigate a method that uses 3D printing to fabricate microfluidic devices that can generate droplets with sizes

Published

2022

22. PDMS Organ-On-Chip Design and Fabrication: Strategies for Improving Fluidic Integration and Chip Robustness of Rapidly Prototyped Microfluidic In Vitro Models

Author

Tiffany C. Cameron, Avineet Randhawa, Samantha M. Grist, Tanya Bennet, Jessica Hua, Luis G. Alde, Tara M. Caffrey, Cheryl L. Wellington, and Karen C. Cheung

Subjects

microfluidic, organ-on-chip, rapid prototyping, cell culture, Mechanical engineering and machinery, TJ1-1570

Abstract

The PDMS-based microfluidic organ-on-chip platform represents an exciting paradigm that has enjoyed a rapid rise in popularity and adoption. A particularly promising element of this platform is its amenability to rapid manufacturing strategies, which can enable quick adaptations through iterative prototyping. These strategies, however, come with challenges; fluid flow, for example, a core principle of organs-on-chip and the physiology they aim to model, necessitates robust, leak-free channels for potentially long (multi-week) culture durations. In this report, we describe microfluidic chip fabrication methods and strategies that are aimed at overcoming these difficulties; we employ a subset of these strategies to a blood–brain-barrier-on-chip, with others applied to a small-airway-on-chip. Design approaches are detailed with considerations presented for readers. Results pertaining to fabrication parameters we aimed to improve (e.g., the thickness uniformity of molded PDMS), as well as illustrative results pertaining to the establishment of cell cultures using these methods will also be presented.

Published

2022

23. Low Cost, Ease-of-Access Fabrication of Microfluidic Devices Using Wet Paper Molds

Author

Raviraj Thakur and Gene Y. Fridman

Subjects

microfluidic devices, rapid prototyping, micromolding, polydimethylsiloxane (PDMS), microfluidics fabrication, microfabrication, Mechanical engineering and machinery, TJ1-1570

Abstract

Rapid prototyping methods enable the widespread adoption of microfluidic technologies by empowering end-users from non-engineering disciplines to make devices using processes that are rapid, simple and inexpensive. In this work, we developed a liquid molding technique to create silicone/PDMS microfluidic devices by replica molding. To construct a liquid mold, we use inexpensive adhesive-backed paper, an acetate backing sheet, and an off-the-shelf digital cutter to create paper molds, which we then wet with predetermined amounts of water. Due to the immiscibility of water and PDMS, mold patterns can be effectively transferred onto PDMS similarly to solid molds. We demonstrate the feasibility of these wet paper molds for the fabrication of PDMS microfluidic devices and assess the influence of various process parameters on device yield and quality. This method possesses some distinct benefits compared to conventional techniques such as photolithography and 3D printing. First, we demonstrate that the shape of a channel’s cross-section may be altered from rectangular to semicircular by merely modifying the wetting parameters. Second, we illustrate how electrical impedance can be utilized as a marker for inspecting mold quality and identifying defects in a non-invasive manner without using visual tools such as microscopes or cameras. As a proof-of-concept device, we created a microfluidic T-junction droplet generator to produce water droplets in mineral oil ranging in size from 1.2 µL to 75 µL. We feel that this technology is an excellent addition to the microfluidic rapid prototyping toolbox and will find several applications in biological research.

Published

2022

24. Modular Microfluidics: Current Status and Future Prospects

Author

Xiaochen Lai, Mingpeng Yang, Hao Wu, and Dachao Li

Subjects

modular microfluidics, reconfiguration, reusability, on-demand deployment, rapid prototyping, organs-on-a-chip, Mechanical engineering and machinery, TJ1-1570

Abstract

This review mainly studies the development status, limitations, and future directions of modular microfluidic systems. Microfluidic technology is an important tool platform for scientific research and plays an important role in various fields. With the continuous development of microfluidic applications, conventional monolithic microfluidic chips show more and more limitations. A modular microfluidic system is a system composed of interconnected, independent modular microfluidic chips, which are easy to use, highly customizable, and on-site deployable. In this paper, the current forms of modular microfluidic systems are classified and studied. The popular fabrication techniques for modular blocks, the major application scenarios of modular microfluidics, and the limitations of modular techniques are also discussed. Lastly, this review provides prospects for the future direction of modular microfluidic technologies.

Published

2022

25. Latest Advancements in Micro Nano Molding Technologies—Process Developments and Optimization, Materials, Applications, Key Enabling Technologies.

Author

Tosello, Guido

Subjects

INJECTION molding, PROCESS optimization, PROCESS capability, RAPID prototyping, COMPLIANT mechanisms, MASS production

Abstract

Micro and nano molding technologies are continuously being developed due to enduring trends such as increasing miniaturization and the higher functional integration of products, devices and systems. Calaon et al. [[1]] analyzed and compared the process capability and design of conventional injection molding and of micro injection molding machines; Wöhner et al. [[2]] characterized the formation of blisters in film micro insert molding; Loaldi et al. [[3]] integrated direct ink writing with injection molding to generate micro conductive tracks in polymer devices. Weng et al. [[4]] modeled the demolding phase in nano scale molding by using molecular dynamic simulations; Loaldi et al. [[5]] simulated the micro injection molding process of both three-dimensional micro parts and micro structured components by applying multi-scale meshing and virtual design of experiment techniques. [Extracted from the article]

Published

2022

26. Reconfigurable Electronic Platforms: A Top-Down Approach to Learn about Design and Integration of Electronic Systems

Author

Almudena Rivadeneyra, Francisco J. Romero, Michael Haider, Vijay D. Bhatt, Jose F. Salmeron, Noel Rodriguez, Diego P. Morales, and Markus Becherer

Subjects

education, electronics engineering, programmable platforms, rapid prototyping, reconfigurable electronics, sensors, Mechanical engineering and machinery, TJ1-1570

Abstract

This case report presents a real example of a study which introduces the use of reconfigurable platforms in the teaching of electronics engineering to establish a bridge between theory and practice. This gap is one of the major concerns of the electronics engineering students. Different strategies, such as simulation tools or breadboard implementations, have been followed so far to make it easier for students to practice what they study in lectures. However, many students still claim to have problems when they face real practical implementations. The use of reconfigurable platforms as a teaching tool is proposed to provide the students the possibility of fast experimentation, reducing both development time and the learning curve. In addition, reconfigurable platforms available on the market make this methodology suitable to be applied throughout the different courses of their curricula. The feasibility of this approach is demonstrated in a course at the M.Eng. level, where the objective is the study, design and development of electronic sensor nodes. We firmly consider, based on the students’ results and reflections collected during the course, that this methodology helps students to address the theoretical framework from a practical viewpoint, as well as to acquire some of the fundamental skills for their professional careers, such as the usage of communication protocols and embedded systems programming, in a more intuitive way when compared to traditional teaching methodologies.

Published

2022

27. 3D Printed PCB Microfluidics

Author

Stefan Gassmann, Sathurja Jegatheeswaran, Till Schleifer, Hesam Arbabi, and Helmut Schütte

Subjects

microfluidics, PCB, rapid prototyping, 3D printing, PCB-MEMS, Mechanical engineering and machinery, TJ1-1570

Abstract

The combination of printed circuit boards (PCB) and microfluidics has many advantages. The combination of electrodes, sensors and electronics is needed for almost all microfluidic systems. Using PCBs as a substrate, this integration is intrinsic. Additive manufacturing has become a widely used technique in industry, research and by hobbyists. One very promising rapid prototype technique is vat polymerization with an LCD as mask, also known as masked stereolithography (mSLA). These printers are available with resolutions down to 35 µm, and they are affordable. In this paper, a technology is described which creates microfluidics on a PCB substrate using an mSLA printer. All steps of the production process can be carried out with commercially available printers and resins: this includes the structuring of the copper layer of the PCB and the buildup of the channel layer on top of the PCB. Copper trace dimensions down to 100 µm and channel dimensions of 800 µm are feasible. The described technology is a low-cost solution for combining PCBs and microfluidics.

Published

2022

28. Configurable 3D Printed Microfluidic Multiport Valves with Axial Compression

Author

Juliane Diehm, Verena Hackert, and Matthias Franzreb

Subjects

rotatory valve, rapid prototyping, polyjetting, digital light processing (DLP), sealing, Mechanical engineering and machinery, TJ1-1570

Abstract

In the last decade, the fabrication of microfluidic chips was revolutionized by 3D printing. It is not only used for rapid prototyping of molds, but also for manufacturing of complex chips and even integrated active parts like pumps and valves, which are essential for many microfluidic applications. The manufacturing of multiport injection valves is of special interest for analytical microfluidic systems, as they can reduce the injection to detection dead volume and thus enhance the resolution and decrease the detection limit. Designs reported so far use radial compression of rotor and stator. However, commercially available nonprinted valves usually feature axial compression, as this allows for adjustable compression and the possibility to integrate additional sealing elements. In this paper, we transfer the axial approach to 3D-printed valves and compare two different printing techniques, as well as six different sealing configurations. The tightness of the system is evaluated with optical examination, weighing, and flow measurements. The developed system shows similar performance to commercial or other 3D-printed valves with no measurable leakage for the static case and leakages below 0.5% in the dynamic case, can be turned automatically with a stepper motor, is easy to scale up, and is transferable to other printing methods and materials without design changes.

Published

2021

29. Fast Prototyping of Sensorized Cell Culture Chips and Microfluidic Systems with Ultrashort Laser Pulses

Author

Sebastian M. Bonk, Paul Oldorf, Rigo Peters, Werner Baumann, and Jan Gimsa

Subjects

rapid prototyping, micro sensor chip, ITO, oxygen, pH, picosecond laser, cell monitoring system, top-down approach, Mechanical engineering and machinery, TJ1-1570

Abstract

We developed a confined microfluidic cell culture system with a bottom plate made of a microscopic slide with planar platinum sensors for the measurement of acidification, oxygen consumption, and cell adhesion. The slides were commercial slides with indium tin oxide (ITO) plating or were prepared from platinum sputtering (100 nm) onto a 10-nm titanium adhesion layer. Direct processing of the sensor structures (approximately three minutes per chip) by an ultrashort pulse laser facilitated the production of the prototypes. pH-sensitive areas were produced by the sputtering of 60-nm Si3N4 through a simple mask made from a circuit board material. The system body and polydimethylsiloxane (PDMS) molding forms for the microfluidic structures were manufactured by micromilling using a printed circuit board (PCB) milling machine for circuit boards. The microfluidic structure was finally imprinted in PDMS. Our approach avoided the use of photolithographic techniques and enabled fast and cost-efficient prototyping of the systems. Alternatively, the direct production of metallic, ceramic or polymeric molding tools was tested. The use of ultrashort pulse lasers improved the precision of the structures and avoided any contact of the final structures with toxic chemicals and possible adverse effects for the cell culture in lab-on-a-chip systems.

Published

2015

30. Characterization of 3D-Printed Moulds for Soft Lithography of Millifluidic Devices.

Author

Mohd Fuad, Nurul, Carve, Megan, Kaslin, Jan, and Wlodkowic, Donald

Subjects

THREE-dimensional printing, RAPID prototyping, DIMETHYLPOLYSILOXANES

Abstract

Increased demand for inexpensive and rapid prototyping methods for micro- and millifluidic lab-on-a-chip (LOC) devices has stimulated considerable interest in alternative cost-effective fabrication techniques. Additive manufacturing (AM)--also called three-dimensional (3D) printing--provides an attractive alternative to conventional fabrication techniques. AM has been used to produce LOC master moulds from which positive replicas are made using soft-lithography and a biocompatible elastomer, poly(dimethylsiloxane) (PDMS). Here we characterize moulds made using twoAMmethods--stereolithography (SLA) and material-jetting (MJ)--and the positive replicas produced by soft lithography and PDMS moulding. The results showed that SLA, more than MJ, produced finer part resolution and finer tuning of feature geometry. Furthermore, as assessed by zebrafish (Danio rerio) biotoxicity tests, there was no toxicity observed in SLA and MJ moulded PDMS replicas. We conclude that SLA, utilizing commercially available printers and resins, combined with PDMS soft-lithography, is a simple and easily accessible technique that lends its self particularly well to the fabrication of biocompatible millifluidic devices, highly suited to the in-situ analysis of small model organisms. [ABSTRACT FROM AUTHOR]

Published

2018

31. Fiducial-Aided Robust Positioning of Optical Freeform Surfaces.

Author

Wang, Shixiang, Cheung, Chi Fai, Ren, Mingjun, and Liu, Mingyu

Subjects

RAPID prototyping, METROLOGY, MICROPOSITIONING systems

Abstract

Form characterization of a machined optical freeform surface demands accurate alignment of the sampled measured data points on the machined surface, and they are compared with the designed geometry of the surface through positioning. In this paper, a fiducial-aided robust positioning method (FAPM) is developed which attempts to evaluate freeform surfaces with high efficiency and precision. The FAPM method makes use of fiducials as reference datum to form a fiducial-aided computer-aided design (FA-CAD) of the freeform surface which not only establishes an inherent surface feature, but also links the different coordinate systems among design coordinate frame, machine tool, and measurement instrument. To verify the capability of the proposed method, a series of experiments were conducted. Compared with the traditional freeform measurement method (e.g., least squares method), the results indicate that the robustness and accuracy of the measurement is significantly enhanced by the FAPM. [ABSTRACT FROM AUTHOR]

Published

2018

32. Micromachining Microchannels on Cyclic Olefin Copolymer (COC) Substrates with the Taguchi Method.

Author

Pin-Chuan Chen, Ren-Hao Zhang, Yingyot Aue-u-lan, and Guo-En Chang

Subjects

MICROFLUIDIC devices, COPOLYMERS, FACTOR analysis

Abstract

Micromilling is a straightforward approach to the manufacture of polymer microfluidic devices for applications in chemistry and biology. This fabrication process reduces costs, provides a relatively simple user interface, and enables the fabrication of complex structures, which makes it ideal for the development of prototypes. In this study, we investigated the influence of micromilling parameters on the surface roughness of a cyclic olefin copolymer (COC) substrate. We then employed factor analysis to determine the optimal cutting conditions. The parameters used in all experiments were the spindle speed, the feed rate, and the depth of cut. Roughness was measured using a stylus profilometer. The lowest roughness was 0.173 μm at a spindle speed of 20,000 rpm, feed rate of 300 mm/min, and cut depth of 20 μm. Factor analysis revealed that the feed rate has the greatest impact on surface quality, whereas the depth of cut has the least impact. [ABSTRACT FROM AUTHOR]

Published

2017

33. Rapid Prototyping of a Micromotor with an Optical Rotary Encoder.

Author

Da-Chen Pang and Yi-Wei Lai

Subjects

RAPID prototyping, PROTOTYPES, MICROMOTORS, ELECTROSTATIC motors, MANUFACTURING processes

Abstract

This study proposed a rapid prototyping fabrication method for micromotors that allowed us to develop both 1mmand 1.5mmdiameter permanent-magnet synchronous motors (PMSMs) with an optical rotary encoder. First, an integrated electroforming method was proposed for combining stator housing and flexible print circuit (FPC) coils to ease the manufacturing and assembly of micromotor components. This is particularly useful in the production of prototypes or small volumes of units. Second, an optical encoder was used to detect the rotational angle by means of a reflective code disk, an optical fiber, and a photo-detector. The micromotor was built with a code disk and an optical fiber. The code disk was designed to match the optical fiber and was made by photolithography and sputtering. Both the 1 mm and 1.5 mm diameter motors successfully achieved a rotational speed over 20,000 RPM and due to a 50 µm diameter optical fiber core, the encoders showed a resolution of 12 and 18 pulses per revolution (PPR), respectively. [ABSTRACT FROM AUTHOR]

Published

2017

34. Ultrasonic-Assisted Incremental Microforming of Thin Shell Pyramids of Metallic Foil.

Author

Toshiyuki Obikawa and Mamoru Hayashi

Subjects

METAL foils, RAPID prototyping, SHEET metal

Abstract

Single point incremental forming is used for rapid prototyping of sheet metal parts. This forming technology was applied to the fabrication of thin shell micropyramids of aluminum, stainless steel, and titanium foils. A single point tool used had a tip radius of 0.1 mm or 0.01 mm. An ultrasonic spindle with axial vibration was implemented for improving the shape accuracy of micropyramids formed on 5-12 micrometers-thick aluminum, stainless steel, and titanium foils. The formability was also investigated by comparing the forming limits of micropyramids of aluminum foil formed with and without ultrasonic vibration. The shapes of pyramids incrementally formed were truncated pyramids, twisted pyramids, stepwise pyramids, and star pyramids about 1 mm in size. A much smaller truncated pyramid was formed only for titanium foil for qualitative investigation of the size reduction on forming accuracy. It was found that the ultrasonic vibration improved the shape accuracy of the formed pyramids. In addition, laser heating increased the forming limit of aluminum foil and it is more effective when both the ultrasonic vibration and laser heating are applied. [ABSTRACT FROM AUTHOR]

Published

2017

35. Enhanced Liquid Metal Micro Droplet Generation by Pneumatic Actuation Based on the StarJet Method

Author

Peter Koltay, Roland Zengerle, Nils Lass, and Lutz Riegger

Subjects

StarJet, metal droplets, 3D-printing, rapid prototyping, droplet generator, microparticle, soldering, bumping, Mechanical engineering and machinery, TJ1-1570

Abstract

We present a novel pneumatic actuation system for generation of liquid metal droplets according to the so-called StarJet method. In contrast to our previous work, the performance of the device has been significantly improved: the maximum droplet generation frequency in continuous mode has been increased to fmax = 11 kHz (formerly fmax = 4 kHz). In addition, the droplet diameter has been reduced to 60 μm. Therefore, a new fabrication process for the silicon nozzle chips has been developed enabling the production of smaller nozzle chips with higher surface quality. The size of the metal reservoir has been increased to hold up to 22 mL liquid metal and the performance and durability of the actuator has been improved by using stainless steel and a second pneumatic connection to control the sheath flow. Experimental results are presented regarding the characterization of the droplet generation, as well as printed metal structures.

Published

2013

36. CO2 Laser-Based Rapid Prototyping of Micropumps

Author

Zachary Strike, Kamyar Ghofrani, and Chris Backhouse

Subjects

micropumps, microvalves, rapid prototyping, CO2 laser ablation, microdroplets, Mechanical engineering and machinery, TJ1-1570

Abstract

The fabrication of microdevices for fluidic control often requires the use of flexible diaphragms in a way that requires cleanroom equipment and compromises performance. We use a CO 2 laser to perform the standard ablative techniques of cutting and engraving materials, but we also apply a method that we call laser placement. This allows us to fabricate precisely-positioned and precisely-sized, isolated diaphragms. This in turn enables the rapid prototyping of integrated multilayer microfluidic devices to form complex structures without the need for manual positioning or cleanroom equipment. The fabrication process is also remarkably rapid and capable of being scaled to manufacturing levels of production. We explore the use of these devices to construct a compact system of peristaltic pumps that can form water in oil droplets without the use of the non-pulsatile pumping systems typically required. Many devices can be fabricated at a time on a sheet by sheet basis with a fabrication process that, to our knowledge, is the fastest reported to date for devices of this type (requiring only 3 h). Moreover, this system is unusually compact and self-contained.

Published

2018

37. Picoliter Droplet Generation and Dense Bead-in-Droplet Encapsulation via Microfluidic Devices Fabricated via 3D Printed Molds

Author

Travis Schlappi, Jonas Otoo, and Tochukwu Anyaduba

Subjects

microfluidics, picoliter droplets, rapid prototyping, bead encapsulation, 3D printing, Control and Systems Engineering, Mechanical Engineering, Electrical and Electronic Engineering

Abstract

Picoliter-scale droplets have many applications in chemistry and biology, such as biomolecule synthesis, drug discovery, nucleic acid quantification, and single cell analysis. However, due to the complicated processes used to fabricate microfluidic channels, most picoliter (pL) droplet generation methods are limited to research in laboratories with cleanroom facilities and complex instrumentation. The purpose of this work is to investigate a method that uses 3D printing to fabricate microfluidic devices that can generate droplets with sizes

Published

2022

38. A Rapid Prototyping Technique for Microfluidics with High Robustness and Flexibility.

Author

Zhenhua Liu, Wenchao Xu, Zining Hou, and Zhigang Wu

Subjects

RAPID prototyping, MICROFLUIDICS, ULTRAVIOLET lasers

Abstract

In microfluidic device prototyping, master fabrication by traditional photolithography is expensive and time-consuming, especially when the design requires being repeatedly modified to achieve a satisfactory performance. By introducing a high-performance/cost-ratio laser to the traditional soft lithography, this paper describes a flexible and rapid prototyping technique for microfluidics. An ultraviolet (UV) laser directly writes on the photoresist without a photomask, which is suitable for master fabrication. By eliminating the constraints of fixed patterns in the traditional photomask when the masters are made, this prototyping technique gives designers/researchers the convenience to revise or modify their designs iteratively. A device fabricated by this method is tested for particle separation and demonstrates good properties. This technique provides a flexible and rapid solution to fabricating microfluidic devices for non-professionals at relatively low cost. [ABSTRACT FROM AUTHOR]

Published

2016

39. Temperature Sensing in Modular Microfluidic Architectures.

Author

Bhargava, Krisna C., Thompson, Bryant, Tembhekar, Anoop, and Malmstadt, Noah

Subjects

MICROFLUIDICS, RAPID prototyping, STEREOLITHOGRAPHY

Abstract

A discrete microfluidic element with integrated thermal sensor was fabricated and demonstrated as an effective probe for process monitoring and prototyping. Elements were constructed using stereolithography and market-available glass-bodied thermistors within the modular, standardized framework of previous discrete microfluidic elements demonstrated in the literature. Flow rate-dependent response due to sensor self-heating and microchannel heating and cooling was characterized and shown to be linear in typical laboratory conditions. An acid-base neutralization reaction was performed in a continuous flow setting to demonstrate applicability in process management: the ratio of solution flow rates was varied to locate the equivalence point in a titration, closely matching expected results. This element potentially enables complex, three-dimensional microfluidic architectures with real-time temperature feedback and flow rate sensing, without application specificity or restriction to planar channel routing formats. [ABSTRACT FROM AUTHOR]

Published

2016

40. A Low-Cost 3-in-1 3D Printer as a Tool for the Fabrication of Flow-Through Channels of Microfluidic Systems

Author

Albert Schulte and Thana Thaweskulchai

Subjects

Rapid prototyping, laser engraving, Fabrication, Computer science, Microfluidics, microfluidics, 3D printing, Nanotechnology, Article, law.invention, law, TJ1-1570, 3-in-1 3D printer, Mechanical engineering and machinery, Electrical and Electronic Engineering, Microchannel, Laser engraving, business.industry, Mechanical Engineering, CNC milling, Surface micromachining, microchannels, Control and Systems Engineering, Photolithography, business

Abstract

Recently published studies have shown that microfluidic devices fabricated by in-house three-dimensional (3D) printing, computer numerical control (CNC) milling and laser engraving have a good quality of performance. The 3-in-1 3D printers, desktop machines that integrate the three primary functions in a single user-friendly set-up are now available for computer-controlled adaptable surface processing, for less than USD 1000. Here, we demonstrate that 3-in-1 3D printer-based micromachining is an effective strategy for creating microfluidic devices and an easier and more economical alternative to, for instance, conventional photolithography. Our aim was to produce plastic microfluidic chips with engraved microchannel structures or micro-structured plastic molds for casting polydimethylsiloxane (PDMS) chips with microchannel imprints. The reproducability and accuracy of fabrication of microfluidic chips with straight, crossed line and Y-shaped microchannel designs were assessed and their microfluidic performance checked by liquid stream tests. All three fabrication methods of the 3-in-1 3D printer produced functional microchannel devices with adequate solution flow. Accordingly, 3-in-1 3D printers are recommended as cheap, accessible and user-friendly tools that can be operated with minimal training and little starting knowledge to successfully fabricate basic microfluidic devices that are suitable for educational work or rapid prototyping.

Published

2021

41. 3D Printing and Bioprinting in MEMS Technology

Author

Chee Kai Chua, Wai Yee Yeong, and Jia An

Subjects

MEMS, 3D printing, bioprinting, additive manufacturing, rapid prototyping, Mechanical engineering and machinery, TJ1-1570

Abstract

3D printing and bioprinting have advanced significantly in printing resolution in recent years, which presents a great potential for fabricating small and complex features suitable for microelectromechanical systems (MEMS) with new functionalities. This special issue aims to give a glimpse into the future of this research field.

Published

2017

42. Fast Prototyping of Sensorized Cell Culture Chips and Microfluidic Systems with Ultrashort Laser Pulses.

Author

Bonk, Sebastian M., Oldorf, Paul, Peters, Rigo, Baumann, Werner, and Gimsa, Jan

Subjects

INTEGRATED circuits, INDIUM tin oxide, LASER ultrasonics, PULSED lasers, CYTOLOGICAL techniques

Abstract

We developed a confined microfluidic cell culture system with a bottom plate made of a microscopic slide with planar platinum sensors for the measurement of acidification, oxygen consumption, and cell adhesion. The slides were commercial slides with indium tin oxide (ITO) plating or were prepared from platinum sputtering (100 nm) onto a 10-nm titanium adhesion layer. Direct processing of the sensor structures (approximately three minutes per chip) by an ultrashort pulse laser facilitated the production of the prototypes. pH-sensitive areas were produced by the sputtering of 60-nm Si3N4 through a simple mask made from a circuit board material. The system body and polydimethylsiloxane (PDMS) molding forms for the microfluidic structures were manufactured by micromilling using a printed circuit board (PCB) milling machine for circuit boards. The microfluidic structure was finally imprinted in PDMS. Our approach avoided the use of photolithographic techniques and enabled fast and cost-efficient prototyping of the systems. Alternatively, the direct production of metallic, ceramic or polymeric molding tools was tested. The use of ultrashort pulse lasers improved the precision of the structures and avoided any contact of the final structures with toxic chemicals and possible adverse effects for the cell culture in lab-on-a-chip systems. [ABSTRACT FROM AUTHOR]

Published

2015

43. Fused Deposition Modeling of Microfluidic Chips in Polymethylmethacrylate

Author

Nils Dellen, Markus Mader, Andrea Kick, Bastian E. Rapp, Patrick Risch, Frederik Kotz, and Dorothea Helmer

Subjects

Rapid prototyping, Materials science, lcsh:Mechanical engineering and machinery, Microfluidics, microfluidics, 3D printing, Nanotechnology, 02 engineering and technology, Molding (process), 01 natural sciences, Article, law.invention, law, lcsh:TJ1-1570, Electrical and Electronic Engineering, Fused deposition modeling, business.industry, fused deposition modeling, Mechanical Engineering, 010401 analytical chemistry, Replication (microscopy), 021001 nanoscience & nanotechnology, Chip, Microstructure, polymethylmethacrylate, 0104 chemical sciences, Control and Systems Engineering, 0210 nano-technology, business, additive manufacturing

Abstract

Polymethylmethacrylate (PMMA) is one of the most important thermoplastic materials and is a widely used material in microfluidics. However, PMMA is usually structured using industrial scale replication processes, such as hot embossing or injection molding, not compatible with rapid prototyping. In this work, we demonstrate that microfluidic chips made from PMMA can be 3D printed using fused deposition modeling (FDM). We demonstrate that using FDM microfluidic chips with a minimum channel cross-section of ~300 µm can be printed and a variety of different channel geometries and mixer structures are shown. The optical transparency of the chips is shown to be significantly enhanced by printing onto commercial PMMA substrates. The use of such commercial PMMA substrates also enables the integration of PMMA microstructures into the printed chips, by first generating a microstructure on the PMMA substrates, and subsequently printing the PMMA chip around the microstructure. We further demonstrate that protein patterns can be generated within previously printed microfluidic chips by employing a method of photobleaching. The FDM printing of microfluidic chips in PMMA allows the use of one of microfluidics’ most used industrial materials on the laboratory scale and thus significantly simplifies the transfer from results gained in the lab to an industrial product.

Published

2020

44. Toward Vasculature in Skeletal Muscle-on-a-Chip through Thermo-Responsive Sacrificial Templates

Author

Li Wan, Philip R. LeDuc, Burak Ozdoganlar, and James Flegle

Subjects

Rapid prototyping, 0303 health sciences, Scaffold, Materials science, muscle-on-a-chip, Mechanical Engineering, lcsh:Mechanical engineering and machinery, Microfluidics, microfluidics, Nanotechnology, 02 engineering and technology, 021001 nanoscience & nanotechnology, Chip, Soft lithography, Article, 03 medical and health sciences, Template, Tissue engineering, Control and Systems Engineering, Paraffin wax, sacrificial template, lcsh:TJ1-1570, Electrical and Electronic Engineering, 0210 nano-technology, 030304 developmental biology

Abstract

Developing new approaches for vascularizing synthetic tissue systems will have a tremendous impact in diverse areas. One area where this is particularly important is developing new skeletal muscle tissue systems, which could be utilized in physiological model studies and tissue regeneration. To develop vascularized approaches a microfluidic on-chip design for creating channels in polymer systems can be pursued. Current microfluidic tissue engineering methods include soft lithography, rapid prototyping, and cell printing, however, these have limitations such as having their scaffolding being inorganic, less desirable planar vasculature geometry, low fabrication efficiency, and limited resolution. Here we successfully developed a circular microfluidic channel embedded in a 3D extracellular matrix scaffolding with 3D myogenesis. We used a thermo-responsive polymer approach with micromilling-molding and designed a mixture of polyester wax and paraffin wax to fabricate the sacrificial template for microfluidic channel generation in the scaffolding. These findings will impact a number of fields including biomaterials, biomimetic structures, and personalized medicine in the future.

Published

2020

45. Freeform Fabrication of Magnetophotonic Crystals with Diamond Lattices of Oxide and Metallic Glasses for Terahertz Wave Control by Micro Patterning Stereolithography and Low Temperature Sintering.

Author

Soshu Kirihara and Maasa Nakano

Subjects

RAPID prototyping, PHOTONIC crystals, LATTICE theory, OXIDES, METALLIC glasses

Abstract

Micrometer order magnetophotonic crystals with periodic arranged metallic glass and oxide glass composite materials were fabricated by stereolithographic method to reflect electromagnetic waves in terahertz frequency ranges through Bragg diffraction. In the fabrication process, the photo sensitive acrylic resin paste mixed with micrometer sized metallic glass of Fe72B14.4Si9.6Nb4 and oxide glass of B2O3⋅Bi2O3 particles was spread on a metal substrate, and cross sectional images of ultra violet ray were exposed. Through the layer by layer stacking, micro lattice structures with a diamond type periodic arrangement were successfully formed. The composite structures could be obtained through the dewaxing and sintering process with the lower temperature under the transition point of metallic glass. Transmission spectra of the terahertz waves through the magnetophotonic crystals were measured by using a terahertz time domain spectroscopy. [ABSTRACT FROM AUTHOR]

Published

2013

46. Enhanced Liquid Metal Micro Droplet Generation by Pneumatic Actuation Based on the StarJet Method.

Author

Lass, Nils, Riegger, Lutz, Zengerle, Roland, and Koltay, Peter

Subjects

LIQUID metals, STAINLESS steel, STEEL alloys, PNEUMATICS, LIQUIDS

Abstract

We present a novel pneumatic actuation system for generation of liquid metal droplets according to the so-called StarJet method. In contrast to our previous work, the performance of the device has been significantly improved: the maximum droplet generation frequency in continuous mode has been increased to fmax = 11 kHz (formerly fmax = 4 kHz). In addition, the droplet diameter has been reduced to 60 µm. Therefore, a new fabrication process for the silicon nozzle chips has been developed enabling the production of smaller nozzle chips with higher surface quality. The size of the metal reservoir has been increased to hold up to 22 mL liquid metal and the performance and durability of the actuator has been improved by using stainless steel and a second pneumatic connection to control the sheath flow. Experimental results are presented regarding the characterization of the droplet generation, as well as printed metal structures. [ABSTRACT FROM AUTHOR]

Published

2013

47. Enabling Micro Injection Moulding Using a Soft Tooling Process Chain with Inserts Made of Mortar Material

Author

Matteo Calaon, Hans Nørgaard Hansen, Guido Tosello, Yang Zhang, Kilian Krüger, David Bue Pedersen, and M. Kain

Subjects

Rapid prototyping, wear, 0209 industrial biotechnology, Fabrication, Materials science, Alumina, Tool steel, Micro injection moulding, 02 engineering and technology, engineering.material, Article, chemistry.chemical_compound, 020901 industrial engineering & automation, Wear, tool steel, TJ1-1570, hard tooling, thermal conductivity, Mechanical engineering and machinery, micro injection moulding, Electrical and Electronic Engineering, Composite material, Insert (composites), soft tooling, Acrylonitrile butadiene styrene, Mechanical Engineering, Process (computing), QR code, 021001 nanoscience & nanotechnology, alumina, Hard tooling, Mortar, chemistry, Thermal conductivity, Control and Systems Engineering, Soft tooling, mortar, engineering, concrete, 0210 nano-technology, Micro injection, Concrete

Abstract

The manufacturing of inserts for micro injection moulding made of mortar material is presented in this work. The fabrication of the mortar insert described in this publication relied on a versatile and relatively fast rapid prototyping process based on soft tooling. The mortar insert has a QR code with micro features on its surface, which was replicated in acrylonitrile butadiene styrene (ABS) polymer by the micro injection moulding process. With this approach, it is possible to fabricate hard inserts for micro injection moulding purposes that are able to compete with conventional-made inserts made of tool steel.

Published

2021

48. A Thermocycler Using a Chip Resistor Heater and a Glass Microchip for a Portable and Rapid Microchip-Based PCR Device.

Author

Yeom, Dongsun, Kim, Jeongtae, Kim, Sungil, Ahn, Sanghoon, Choi, Jiyeon, Kim, Youngwook, and Koo, Chiwan

Subjects

RAPID prototyping, DIAGNOSTIC use of polymerase chain reaction, INTEGRATED circuits, HEATING, THERMISTORS, DNA data banks

Abstract

This study proposes a rapid and inexpensive thermocycler that enables rapid heating of samples using a thin glass chip and a cheap chip resistor to overcome the on-site diagnostic limitations of polymerase chain reaction (PCR). Microchip PCR devices have emerged to miniaturize conventional PCR systems and reduce operation time and cost. In general, PCR microchips require a thin-film heater fabricated through a semiconductor process, which is a complicated process, resulting in high costs. Therefore, this investigation substituted a general chip resistor for a thin-film heater. The proposed thermocycler consists of a compact glass microchip of 12.5 mm × 12.5 mm × 2 mm that could hold a 2 μL PCR sample and a surface-mounted chip resistor of 6432 size (6.4 mm × 3.2 mm). Improving heat transfer from the chip resistor heater to the PCR reaction chamber in the microchip was accomplished via the design and fabrication of a three-dimensional chip structure using selective laser-induced etching, a rapid prototyping technique that allowed to be embedded. The fabricated PCR microchip was combined with a thermistor temperature sensor, a blower fan, and a microcontroller. The assembled thermocycler could heat the sample at a maximum rate of 28.8 °C/s per second. When compared with a commercially available PCR apparatus running the same PCR protocol, the total PCR operating time with a DNA sample was reduced by about 20%. [ABSTRACT FROM AUTHOR]

Published

2022

49. Rapid Prototyping of Organ-on-a-Chip Devices Using Maskless Photolithography.

Author

Kasi, Dhanesh G., de Graaf, Mees N. S., Motreuil-Ragot, Paul A., Frimat, Jean-Phillipe M. S., Ferrari, Michel D., Sarro, Pasqualina M., Mastrangeli, Massimo, van den Maagdenberg, Arn M. J. M., Mummery, Christine L., and Orlova, Valeria V.

Subjects

PHOTOLITHOGRAPHY, MICROFLUIDIC devices, SILICON wafers, PHOTORESISTS, RAPID prototyping, MICROFABRICATION

Abstract

Organ-on-a-chip (OoC) and microfluidic devices are conventionally produced using microfabrication procedures that require cleanrooms, silicon wafers, and photomasks. The prototyping stage often requires multiple iterations of design steps. A simplified prototyping process could therefore offer major advantages. Here, we describe a rapid and cleanroom-free microfabrication method using maskless photolithography. The approach utilizes a commercial digital micromirror device (DMD)-based setup using 375 nm UV light for backside exposure of an epoxy-based negative photoresist (SU-8) on glass coverslips. We show that microstructures of various geometries and dimensions, microgrooves, and microchannels of different heights can be fabricated. New SU-8 molds and soft lithography-based polydimethylsiloxane (PDMS) chips can thus be produced within hours. We further show that backside UV exposure and grayscale photolithography allow structures of different heights or structures with height gradients to be developed using a single-step fabrication process. Using this approach: (1) digital photomasks can be designed, projected, and quickly adjusted if needed; and (2) SU-8 molds can be fabricated without cleanroom availability, which in turn (3) reduces microfabrication time and costs and (4) expedites prototyping of new OoC devices. [ABSTRACT FROM AUTHOR]

Published

2022

50. 3D Printed Lab-on-a-Chip Platform for Chemical Stimulation and Parallel Analysis of Ion Channel Function

Author

Daniel Gilbert, Oliver Friedrich, and Daniel Aschenbrenner

Subjects

Rapid prototyping, Materials science, Fluo-4 AM, lcsh:Mechanical engineering and machinery, Microfluidics, microfluidic, 3D printing, 02 engineering and technology, ABS, capsaicin, Article, law.invention, 03 medical and health sciences, Ca2+ imaging, law, HEK293 cells, lcsh:TJ1-1570, Fluidics, Electrical and Electronic Engineering, Throughput (business), Ion channel, 030304 developmental biology, 0303 health sciences, business.industry, Mechanical Engineering, Lab-on-a-chip, 021001 nanoscience & nanotechnology, TRPV1, zigzag channel, Transmission (telecommunications), Control and Systems Engineering, Optoelectronics, 0210 nano-technology, business

Abstract

Functional imaging has been a widely established method for the assessment of ion channel function in vitro. Conventional infrastructure used for in vitro functional analysis of ion channels is typically proprietary, non-customizable, expensive, and requires a high level of skill to use and maintain. 3D desktop printing, which is employed in the rapid prototyping field, allows for quick engineering of alternatives to conventional imaging infrastructure that are customizable, low cost, and user friendly. Here, we describe an ultra-low-cost microfluidic lab-on-a-chip (LOC) device manufactured using acrylonitrile butadiene styrene (ABS) for in vitro functional imaging of ion channels that can quickly and easily be reconstructed using three-dimensional (3D) desktop printing. The device is light weight (&lt, 5 g), small (20 mm &times, 49 mm), and extremely low cost (&lt, EUR 1). We simulate fluidics within the printed channels and assess the suitability of the engineered chamber to generate homogeneous mixtures during solution exchange. We demonstrate the usability of the 3D printed microfluidic device in a case study using Fluo-4-loaded human embryonal kidney-derived (HEK293) cells, recombinantly expressing the capsaicin receptor, transient receptor potential vanilloid receptor type 1 (TRPV1), as a model system. In the case study, we confirm its applicability to solution exchange for chemical stimulation and parallel functional time-lapse fluorescence microscopy-based calcium imaging. We assess the suitability of ABS for culturing HEK293 cells inside the microfluidic LOC, based on qualitative analysis of microscopic transmission light images of ABS-exposed HEK293 cells and confirm the previously reported biocompatibility of ABS. To highlight the versatility of the 3D printed microfluidic device, we provide an example for multiplication of the shown concept within a 3D printed multichannel microfluidic LOC to be used, for example, in a higher throughput format for parallelized functional analysis of ion channels. While this work focusses on Ca2+ imaging with TRPV1 channels, the device may also be useful for application with other ion channel types and in vitro models.

Published

2019