UK researchers from the University of Edinburgh have developed an affordable new device, outlined in ‘Low-cost FDM 3D-printed modular electrospray/electrospinning setup for biomedical applications.’
While one of the greatest benefits of 3D printing is being able to produce softball-sized objects and parts, digital fabrication often occurs on the nanoscale today too, with varying materials, techniques, and systems. In this study, the authors focus making machines that make nano-sized objects produced via electrospray ionization deposition and electrospinning.
Electrospray is known to be extremely efficient and affordable for preparation of nanoparticles which are most often used in the medical realm, to include pharmaceutical and biological uses. Nanoparticles can be used as drug delivery systems, and also loaded with elements to promote cell growth during tissue engineering processes. Electrospinning is used in the development of solutions and suspensions, creating long fibers.
Nanostructures are able to imitate the extracellular matrix, making them suitable for scaffolds and promoting successful cell growth:
“This makes electrospinning an attractive technique for tissue engineering applications, including vascular graft fabrication,” stated the researchers. “It is also widely used in medical diagnosis and drug delivery as they can immobilize the recognition element or active pharmaceutical ingredient due to the large surface area and porosity.
“Recently, electrospinning has been also used for replica molding and producing three-dimensional scaffolds.”
The electrospinning setup is usually comprised of:
- Syringe
- Metallic nozzle
- High-voltage power supply
- Collector
A conventionally manufactured setup may be basic, but the researchers note that commercially they cost around $17,000 – $300,000 USD; in fact, the price is so cost-prohibitive that many researchers may have created their own setups which are potentially unsafe due to high voltage. With FDM printing, setups can be printed affordably, offering good safety, reliability, and functionality.
For this study, the researchers used PLA with an Ultimaker 3. PVA was used for support material, with the total cost for filaments around $100.
“After a part with PVA support was printed, 30 °C water was used to dissolve the PVA in a water bath. It took approximately 24 h to fully dissolve the PVA at this temperature,” stated the researchers. All the larger parts were printed with a sheet of paper attached to the open front part of the Ultimaker 3 printer, in order to reduce the temperature fluctuations during the 3D printing process.”
As threads for modular parts required smoothing, the researchers used chloroform vapor as a treatment—meant to smooth and cause better tensile strength—improving quality overall (we would urge extreme caution with deploying this as a process and recommend mechanical smoothing instead).
“The chemical treatment showed a slight improvement in the surface roughness, which helped the part assembly at the threads,” concluded the researchers.
“Due to the modular nature of the setup, the parts can be exchanged easily, offering easy configuration for different applications. The cap part had several gas channels, allowing a uniform gas flowing against the direction of the nanoparticles/nanofibers, enhancing the evaporation rate. The setup was tested in both electrospray and electrospinning modes successfully. However, ABS, PEEK, or ceramic materials would be recommended for 3D printing the central chamber part in order to increase the chemical resistivity.”
Both the .sldprt and .stl files are provided for download.
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