Researchers have developed a 3D printable 'clip-on' that allows anyone – from scientists to the scientifically curious – to turn their smartphone into a fully functional microscope. The smartphone microscope is powerful enough to visualise specimens as small as 1/200th of a millimetre, including microscopic organisms, animal and plant cells, blood cells, cell nuclei and more.
And the researchers are making the technology freely available, sharing the 3D printing files publicly so anyone with access to a 3D printer can turn their own smartphone into a microscope.
Developed at the RMIT University node of the ARC Centre of Excellence for Nanoscale BioPhotonics (CNBP), the clip-on technology does not rely on external power or light source to work, yet offers high-powered microscopic performance in a robust and mobile handheld package.
Lead developer and CNBP Research Fellow at RMIT, Dr Antony Orth, believes the technology has immense potential as a scientific tool, one that is ideal for use in remote areas and for field-work where larger standalone microscopes are unavailable or impractical.
“We’ve designed a simple mobile phone microscope that takes advantage of the integrated illumination available with nearly all smartphone cameras,” Orth says.
The clip-on has been engineered with internal illumination tunnels that guide light from the camera flash to illuminate the sample from behind. This overcomes issues seen with other microscopy-enabled mobile phone devices, he says.
“Almost all other phone-based microscopes use externally powered light sources, while there’s a perfectly good flash on the phone itself,” Orth explains. “External LEDs and power sources can make these other systems surprisingly complex, bulky and difficult to assemble.
“The beauty of our design is that the microscope is useable after one simple assembly step and requires no additional illumination optics, significantly reducing the cost and complexity of assembly.
“The clip-on is also able to be 3D printed making the device accessible to anyone with basic 3D printing capabilities.” A further advantage noted by Orth is that the clip-on enables both bright-field and dark-field microscopy techniques to be undertaken.
Bright-field microscopy is where a specimen is observed on a bright background. Conversely, dark-field shows the specimen illuminated on a dark background. “The added dark-field functionality lets us observe samples that are nearly invisible under conventional bright-field operation such as cells in media,” he says.
“Having both capabilities in such a small device is extremely beneficial and increases the range of activity that the microscope can be successfully used for.”
Orth believes the potential applications for the smartphone microscope are enormous. “Our mobile microscope can be used as an inexpensive and portable tool for all types of on-site or remote area monitoring,” he says.
“Water quality, blood samples, environmental observation, early disease detection and diagnosis—these are all areas where our technology can be easily used to good effect.” Orth also sees significant benefit in developing countries for the device. “Powerful microscopes can be few and far between in some regions,” he says.
“They’re often only found in larger population centres and not in remote or smaller communities. Yet their use in these areas can be essential - for determining water quality for drinking, through to analysing blood samples for parasites, or for disease diagnosis including malaria.”
To ensure that the technology can be used the world over, the files for the 3D printing of the microscope clip-on are being made freely available for download.
“Ideally, a phone microscope should take advantage of the integrated flash found in nearly every modern mobile, avoiding the need for external lighting and power,” Orth says. “It should also be as compact and easy to assemble as possible. It is this design philosophy that inspired us in the development of this add-on clip.”
The new phone microscope has already been tested by Orth and his CNBP colleagues in a number of areas, successfully visualising samples ranging from cell culture, to zooplankton to live cattle semen in support of livestock fertility testing.
Discover more here.
Image credit: RMIT.