As human nature, imbued with both infinite curiosity and motivation, continues to march forward, we are amassing many intricate layers of new knowledge that keeps building and building, offering ever greater progress. With the advent of the internet we were closer to finding every bit of information we sought out. With 3D printing, we are now that much closer to ‘making’ every idea that comes to mind tangible, and putting those tangible concepts to very good use.
Just last week you probably had no idea that you might be able to use your phone as a microscope for finding and analyzing DNA. Taking affordable, portable diagnostics to a new level as well, might you be responsible for the next great cure?
Scientists hope to take their work to the field, maybe not for the next great cure, but at least for the next great wave of improving healthcare in developing countries and areas that are off the normal medical grid.
New on the scene is the one-of-a-kind 3D printed smartphone attachment from researchers at the University of California, Los Angeles (UCLA) that allows you to use your smartphone to perform functions only a very costly and unwieldy lab microscope would have done previously. Created by Professor Aydogan Ozca and his team at UCLA, this new innovation works with the magic—and pure science—of fluorescence.
“A single DNA molecule, once stretched, is about two nanometers in width,” said Dr. Ozcan, HHMI Chancellor Professor, UCLA. “For perspective, that makes DNA about 50,000 times thinner than a human hair. Currently, imaging single DNA molecules requires bulky, expensive optical microscopy tools, which are mostly confined to advanced laboratory settings. In comparison, the components for my device are significantly less expensive.”
Samples of DNA, single strands just two nanometers (imagine something 2,000 times smaller than a raindrop) wide, are labeled with fluorescence and then engaged with a laser. The 3D printed case encompasses:
- External lens
- Thin-film filter
- Miniature dovetail stage mount
- Laser diode
DNA is scanned and then the data is sent to the team’s lab where data can be measured and relayed to the user in just seconds. Being able to perform exercises of this kind allow traditional microscopes, planted in laboratories around the world, to help scientists diagnose diseases like Alzheimer’s and cancer.
Testing of the device is set for the field, where the team will apply the 3D printed microscope attachment to diagnosing malaria. The field is exactly where the team sees the future of this device–as well as the future of providing better healthcare in remote locations.
For more details on the device, you can check out an article published in ACS Nano.
Is a 3D printed microscope attachment something that you would find useful? How do you see this equipment helping developing countries in the long run for healthcare? Discuss in the 3D Printed Smartphone Microscope Attachment forum thread over at 3DPB.com.