scholarly journals Microfluidic Neural Devices: 3D‐Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices (Adv. Sci. 16/2020)

2020 ◽  
Vol 7 (16) ◽  
pp. 2070088
Author(s):  
Janko Kajtez ◽  
Sebastian Buchmann ◽  
Shashank Vasudevan ◽  
Marcella Birtele ◽  
Stefano Rocchetti ◽  
...  
Keyword(s):  
Soft Lithography ◽  
3D Printed ◽  
Neural Devices

scholarly journals 3D‐Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices

2020 ◽  
Vol 7 (16) ◽  
pp. 2001150 ◽  
Author(s):  
Janko Kajtez ◽  
Sebastian Buchmann ◽  
Shashank Vasudevan ◽  
Marcella Birtele ◽  
Stefano Rocchetti ◽  
...  
Keyword(s):  
Soft Lithography ◽  
3D Printed ◽  
Neural Devices

scholarly journals 3D‐Printed Soft Lithography for Complex Compartmentalized Microfluidic Neural Devices

2021 ◽  
Vol 8 (12) ◽  
pp. 2101787
Author(s):  
Janko Kajtez ◽  
Sebastian Buchmann ◽  
Shashank Vasudevan ◽  
Marcella Birtele ◽  
Stefano Rocchetti ◽  
...  
Keyword(s):  
Soft Lithography ◽  
3D Printed ◽  
Neural Devices

Fabrication of Tunable Silk Materials Through Microfluidic Mixers

2016 ◽  
Author(s):  
Joseph R. Nalbach ◽  
Dave Jao ◽  
Douglas G. Petro ◽  
Kyle M. Raudenbush ◽  
Shibbir Ahmad ◽  
...  
Keyword(s):  
Soft Lithography ◽  
Mixing Processes ◽  
Microfluidic Mixing ◽  
Microfluidic Mixer ◽  
Continuous Mixing ◽  
Mixing Performance ◽  
3D Printed ◽  
Distribution Uniformity ◽  
Mixing Patterns ◽  
Microfluidic Mixers

A common method to precisely control the material properties is to evenly distribute functional nanomaterials within the substrate. For example, it is possible to mix a silk solution and nanomaterials together to form one tuned silk sample. However, the nanomaterials are likely to aggregate in the traditional manual mixing processes. Here we report a pilot study of utilizing specific microfluidic mixing designs to achieve a uniform nanomaterial distribution with minimal aggregation. Mixing patterns are created based on classic designs and then validated by experimental results. The devices are fabricated on polydimethylsiloxane (PDMS) using 3D printed molds and soft lithography for rapid replication. The initial mixing performance is validated through the mixing of two solutions with colored dyes. The microfluidic mixer designs are further analyzed by creating silk-based film samples. The cured film is inspected with scanning electron microscopy (SEM) to reveal the distribution uniformity of the dye particles within the silk material matrix. Our preliminary results show that the microfluidic mixing produces uniform distribution of dye particles. Because the microfluidic device can be used as a continuous mixing tool, we believe it will provide a powerful platform for better preparation of silk materials. By using different types of nanomaterials such as graphite (demonstrated in this study), graphene, carbon nanotubes, and magnetic nanoparticles, the resulting silk samples can be fine-tuned with desired electrical, mechanical, and magnetic properties.

Microfluidics 4: PDMS Chip Soft Lithography v2

2021 ◽  
Author(s):  
Serhat Sevli ◽  
not provided C. Yunus Sahan
Keyword(s):  
Soft Lithography ◽  
Cost Effective ◽  
Cnc Machining ◽  
3D Printed ◽  
Low Volume ◽  
Pdms Chip ◽  
Application Specific ◽  
Lithography Technique

Microfluidics materials are of various types and application-specific. PDMS is one of the most preferred and cost-effective solutions for research and low-volume manufacturing. After having the mold, PDMS replicas are generated by a technique called soft-lithography. This protocol describes the preparation of PDMS microchannels using SU8 molds, 3D Printed resin molds, and/or metal molds by the soft lithography technique, SLA printing, or CNC machining.

Microfluidics 4: PDMS Chip Soft Lithography v2

2021 ◽  
Author(s):  
Serhat Sevli ◽  
not provided C. Yunus Sahan
Keyword(s):  
Soft Lithography ◽  
Cost Effective ◽  
Cnc Machining ◽  
3D Printed ◽  
Low Volume ◽  
Pdms Chip ◽  
Application Specific ◽  
Lithography Technique

Microfluidics materials are of various types and application-specific. PDMS is one of the most preferred and cost-effective solutions for research and low-volume manufacturing. After having the mold, PDMS replicas are generated by a technique called soft-lithography. This protocol describes the preparation of PDMS microchannels using SU8 molds, 3D Printed resin molds, and/or metal molds by the soft lithography technique, SLA printing, or CNC machining.

A Thermally Actuated Microvalve for Smart Irrigation in Precision Agriculture Applications

2021 ◽  
Author(s):  
Alaba Bamido ◽  
Debjyoti Banerjee
Keyword(s):  
Precision Agriculture ◽  
Soft Lithography ◽  
Large Field ◽  
Cfd Simulations ◽  
Manufacturing Costs ◽  
Pneumatic Actuation ◽  
3D Printed ◽  
Thermally Actuated ◽  
Control Layer

Abstract A normally-open thermally-actuated microvalve was designed (using microfabrication/soft-lithography techniques involving 3D Printed molds), assembled and tested. The motivation of the research work is to develop an array of microvalves for precise delivery of water to individual plants in a field (with the goal of developing smart irrigation systems for high value cash-crops in the agricultural sector). It is currently impossible to control application of irrigation-water at the level of a single plant. If such a capability were practically available on farms, the result would be a step change in precision agriculture, such that the output of every plant in a farm field could be optimized (i.e., food-water-energy nexus in sustainability applications). The aim of this study is to develop and test a microfluidic system (consisting of a microvalve array) that could be controlled, capillary by capillary, to deliver the needed amount of water to individual plants in a large field. Two types of test fluids were leveraged for thermo-hydraulic actuation of the microvalves developed in this study: (a) Design-I: using air, and (b) Design-II: using Phase Change Material (PCM). The PCM used in this study is PureTemp29. The proposed approach enabled a simple and cheap design for microvalves that can be manufactured easily and are robust to weather conditions (e.g., when exposed to the elements in orchards and open fields). Other advantages include: safe and reliable operation; low power consumption; can tolerate anomalous pressure loads/fluctuations; simple actuation; affords easy control schemes; is amenable for remote control; provides long-term reliability (life-cycle duration estimated to be 3∼5 years); can be mass produced and is low maintenance (possibly requiring no maintenance over the life time of operation). The microvalve consists of two layers: a flow layer and a control layer. The control layer is heated from below and contains a microfluidic chamber with a flexible polymeric thin-membrane (200 microns in thickness) on top. The device is microfabricated from Poly-Di-Methyl-Siloxane (PDMS) using soft lithography techniques (using a 3D Printed mold). The control chamber contains either air (thermo-pneumatic actuation) or PCM (thermo-hydraulic actuation involving repeated melting/freezing of PCM). The flow layer contains the flow channel (inlet and outlet ports, horizontal section and valve seat). The experimental results from testing the efficacy of the two types of micro-valves show a 60% reduction (for thermo-pneumatic actuation using air) and 40% reduction (for thermo-hydraulic actuation using PCM) in water flow rates for similar actuation conditions (i.e., heater temperature values). PCM design is expected to consume less power (lower OPEX) for long-term actuation but may have slower actuation speed and have higher manufacturing costs (CAPEX). Air actuation design is expected to consume more power (higher OPEX) for longer-term operation but may have faster actuation speeds and lower manufacturing costs (CAPEX). Computational Fluid Dynamics (CFD) simulations were performed to investigate the effect of flowing water (in the microfluidic channel) on the average absolute pressure and temperature of air in the actuation chamber. The CFD simulations were performed using a commercial tool (Ansys™ 2019R1®). The results from the CFD simulations are presented in this study.

scholarly journals Thermopneumatic Soft Micro Bellows Actuator for Standalone Operation

Micromachines ◽  
2021 ◽  
Vol 12 (1) ◽  
pp. 46
Author(s):  
Seongbeom Ahn ◽  
Woojun Jung ◽  
Kyungho Ko ◽  
Yeongchan Lee ◽  
Chanju Lee ◽  
...  
Keyword(s):  
Heat Transfer ◽  
Soft Lithography ◽  
Copper Wire ◽  
The Body ◽  
Control Circuit ◽  
Power Supplies ◽  
Free Movement ◽  
Alkaline Batteries ◽  
3D Printed ◽  
Micro Actuators

Typical pneumatic soft micro actuators can be manufactured without using heavy driving components such as pumps and power supplies by adopting an independent battery-powered mechanism. In this study, a thermopneumatically operated soft micro bellows actuator was manufactured, and the standalone operation of the actuator was experimentally validated. Thermopneumatic actuation is based on heating a sealed cavity inside the elastomer of the actuator to raise the pressure, leading to deflection of the elastomer. The bellows actuator was fabricated by casting polydimethylsiloxane (PDMS) using the 3D-printed soluble mold technique to prevent leakage, which is inherent in conventional soft lithography due to the bonding of individual layers. The heater, manufactured separately using winding copper wire, was inserted into the cavity of the bellows actuator, which together formed the thermopneumatic actuator. The 3D coil heater and bellows allowed immediate heat transfer and free movement in the intended direction, which is unachievable for conventional microfabrication. The fabricated actuator produced a stroke of 2184 μm, equivalent to 62% of the body, and exerted a force of 90.2 mN at a voltage of 0.55 V. A system in which the thermopneumatic actuator was driven by alkaline batteries and a control circuit also demonstrated a repetitive standalone operation.

scholarly journals Characterization of 3D-Printed Moulds for Soft Lithography of Millifluidic Devices

Micromachines ◽  
2018 ◽  
Vol 9 (3) ◽  
pp. 116 ◽  
Author(s):  
Nurul Mohd Fuad ◽  
Megan Carve ◽  
Jan Kaslin ◽  
Donald Wlodkowic
Keyword(s):  
Soft Lithography ◽  
3D Printed

scholarly journals 3D printed self-supporting elastomeric structures for multifunctional microfluidics

2020 ◽  
Vol 6 (41) ◽  
pp. eabc9846 ◽  
Author(s):  
Ruitao Su ◽  
Jiaxuan Wen ◽  
Qun Su ◽  
Michael S. Wiederoder ◽  
Steven J. Koester ◽  
...  
Keyword(s):  
Soft Lithography ◽  
Dna Microarrays ◽  
Microfluidic Devices ◽  
The Self ◽  
Jet Printing ◽  
3D Printed ◽  
Manufacturing Methods ◽  
Sacrificial Materials ◽  
Electronic Sensors ◽  
Supporting Materials

Microfluidic devices fabricated via soft lithography have demonstrated compelling applications such as lab-on-a-chip diagnostics, DNA microarrays, and cell-based assays. These technologies could be further developed by directly integrating microfluidics with electronic sensors and curvilinear substrates as well as improved automation for higher throughput. Current additive manufacturing methods, such as stereolithography and multi-jet printing, tend to contaminate substrates with uncured resins or supporting materials during printing. Here, we present a printing methodology based on precisely extruding viscoelastic inks into self-supporting microchannels and chambers without requiring sacrificial materials. We demonstrate that, in the submillimeter regime, the yield strength of the as-extruded silicone ink is sufficient to prevent creep within a certain angular range. Printing toolpaths are specifically designed to realize leakage-free connections between channels and chambers, T-shaped intersections, and overlapping channels. The self-supporting microfluidic structures enable the automatable fabrication of multifunctional devices, including multimaterial mixers, microfluidic-integrated sensors, automation components, and 3D microfluidics.

scholarly journals Increasing the functionalities of 3D printed microchemical devices by single material, multimaterial, and print-pause-print 3D printing

Lab on a Chip ◽  
2019 ◽  
Vol 19 (1) ◽  
pp. 35-49 ◽  
Author(s):  
Feng Li ◽  
Niall P. Macdonald ◽  
Rosanne M. Guijt ◽  
Michael C. Breadmore
Keyword(s):  
3D Printing ◽  
Rapid Prototyping ◽  
Soft Lithography ◽  
Fluidic Devices ◽  
3D Printed ◽  
Single Material

3D printing has emerged as a valuable approach for the fabrication of fluidic devices and may replace soft-lithography as the method of choice for rapid prototyping.

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