All devices were designed using a 3D CAD software (SolidWorks 2015). The manufacturing of microfluidic devices was performed with a 3D-printer (ProJet MJP 2500 Plus, 3D Systems Inc., U.S.) using a transparent resin (VisiJet M2R-CL, 3D Systems Inc., U.S.) via multi-jet printing (MJP) which is an inject printing process using piezo printhead technology to deposit either photocurable plastic resin or casting wax material layer by layer. After fabrication, the removal of wax was performed with MJP EasyClean System (3D Systems Inc., U.S.) followed by pressurized steam with a steam gun to eliminate all the casting wax inside the microchannels.
Visijet m2r cl
Manufactured by 3D Systems
Sourced in United States
The VisiJet M2R-CL is a professional-grade 3D printer designed for high-precision and high-quality additive manufacturing. It utilizes stereolithography (SLA) technology to create detailed, accurate parts from a variety of materials. The VisiJet M2R-CL is capable of producing intricate features and smooth surface finishes, making it suitable for a wide range of applications.
Automatically generated - may contain errors
Lab products found in correlation
2 protocols using visijet m2r cl
1
3D-Printed Microfluidic Device Fabrication
2
3D-Printed Microfluidic Device Fabrication
Check if the same lab product or an alternative is used in the 5 most similar protocols
+ Expand
All 3D models were designed using the 3D-CAD-program SOLIDWORKS (Dassault Systèmes SOLIDWORKS Corporation). The multijet printer ProJet® MJP 2500 Plus (3D Systems, Rock Hill, SC, USA) was then used to produce the microfluidic devices. The polyacrylate photocurable resin VisiJet® M2R-CL (3D Systems, Rock Hill, SC, USA) was used to print the actually device, and hydroxylated wax (VisiJet® M2 SUP, 3D Systems, Rock Hill, SC, USA) acted as support material. 19 The printer was operated in HD mode, with a nominal resolution of 800 × 900 × 790 dpi and a layer resolution of 32 μm.
After printing, the device underwent several postprocessing steps according to Siller et al.: first, the printed parts are cooled at -18 °C for 5 minutes, followed by incubation in a hot water vapor bath, a hot ultrasonic oil bath and lastly in a hot ultrasonic water bath with detergent. 20
After printing, the device underwent several postprocessing steps according to Siller et al.: first, the printed parts are cooled at -18 °C for 5 minutes, followed by incubation in a hot water vapor bath, a hot ultrasonic oil bath and lastly in a hot ultrasonic water bath with detergent. 20
About PubCompare
Our mission is to provide scientists with the largest repository of trustworthy protocols and intelligent analytical tools, thereby offering them extensive information to design robust protocols aimed at minimizing the risk of failures.
We believe that the most crucial aspect is to grant scientists access to a wide range of reliable sources and new useful tools that surpass human capabilities.
However, we trust in allowing scientists to determine how to construct their own protocols based on this information, as they are the experts in their field.
Ready to get started?
Sign up for free.
Registration takes 20 seconds.
Available from any computer
No download required
Revolutionizing how scientists
search and build protocols!