Mobile Microscopes

Turning cell phones into basic research tools can improve health care in the developing world.

By | June 1, 2013

SCOPE APP: Developed in the University of California, Berkeley, lab of Daniel Fletcher, the CellScope, here trained on an algae sample, turns the camera of a standard cell phone into a diagnostic-quality microscope with a magnification of 5x–60x.CINDY MANLY-FIELDS/BIOENGINEERING DEPARTMENT, UC BERKELEYIn some of the least-developed regions of Africa, Southeast Asia, and the Middle East, cell phones are the main mode of connecting to the wider world. Even in areas beyond government electrical grids, many people have cell phones, which they charge using solar cells or car batteries.

“You don’t have to put in these copper wires [for phone lines] anymore; you have the [cell] towers. It’s big business,” says bioengineer Daniel Fletcher of the University of California, Berkeley, who has seen cellular technology flourish in countries like Thailand and India. “It’s leaping over the need for infrastructure.”

It’s also big opportunity. Fletcher and others are developing technologies that take advantage of the 6 billion or so cell phones in use around the world to help improve health care in the most remote locations. In 2009, Fletcher and his colleagues added a set of lenses to a smart phone and used the device to image cells with both bright-field and fluorescence techniques. The resolution was high enough to diagnose malaria from blood samples and tuberculosis from sputum samples; image-analysis software on the phone even automatically counted the number of Mycobacterium tuberculosis bacilli (PLOS ONE, 4:e6320, 2009). “Our study really was aimed at emphasizing [that] this is possible,” says Fletcher—that diagnosing disease didn’t require bulky and expensive bench microscopes.

Now he’s seeking to demonstrate that it can work in the field. “Technology alone doesn’t create effective health care,” says Fletcher, who is involved in ongoing studies in Vietnam, India, Cameroon, and Thailand. “It’s got to be part of a context in which the information is captured and validated and is analyzed in the right way, and treatments are then available in response to information.”

This March, a group led by infectious disease specialist Isaac Bogoch of Toronto General Hospital heeded that call, diagnosing parasitic worm infections in children living on Pemba Island off the coast of Tanzania, Africa (Am J Trop Med Hyg, 12-0742, 2013). About a year earlier, while Bogoch was attending a tropical medicine course in Peru, his friend and colleague Jason Andrews of Massachusetts General Hospital had shared with Bogoch a report that described a very simple device—an iPhone with an attached 1-mm ball lens. Researchers led by Sebastian Wachsmann-Hogiu’s group at the University of California, Davis, had constructed it from just a few inexpensive parts, and used it to take pictures of blood smears at a 350x magnification and 1.5 micron resolution (PLOS ONE, 6:e17150, 2011).

“We thought that this was a great idea,” says Bogoch, who is part of a large, international team already working in remote locations around the world. “We thought . . . we could take it to the field and see if it accurately works in a more real-world setting.”

Bogoch and his colleagues recreated the device—simply by taping a 3-mm ball lens to an iPhone’s camera—and went to Tanzania to see if the homemade microscope could identify the presence of soil-transmitted helminth eggs in stool samples. They examined samples from 199 children participating in an ongoing clinical trial for these infections and were able to accurately identify helminth infections about 70 percent of the time. The microscope did exceptionally well spotting the eggs of certain parasites, flagging more than 80 percent of Ascaris lumbricoides infections, for example. For other parasites, however, the microscope was less effective, detecting just over half of whipworm cases and only 14 percent of hookworm infections. “Obviously the results aren’t perfect and there’s definitely room for improvement,” Bogoch says.

But it’s clear to Bogoch and others that such simple, low-cost cell-phone microscopes could revolutionize health care in the areas that need it most. Not only are the microscopes portable and affordable, they won’t need to be operated by a trained physician, says David Walker, president of the American Society of Tropical Medicine and Hygiene. Because the microscopes are connected to a cell phone, you can take an image with the phone’s digital camera and simply “send it to someone else who could interpret it.” And it’s not limited to microscopy either; Wachsmann-Hogiu and others are developing cell phone–based spectroscopy and diagnostic test software that can analyze samples on the spot.

Additionally, some argue that the field of mobile microscopes could change the way health care and research works in the developed world. Electrical and bioengineer Aydogan Ozcan of the University of California, Los Angeles, likens the budding technology to the evolution of the personal computer. “If you look at the early computers, they were bulky, they were extremely expensive,” says Ozcan, who is developing lens-free cell-phone microscopes based on computational software. Now, “[computers] are portable . . . and almost anyone can afford them. The same thing is going on today [with microscopy]. We are miniaturizing our micro- and nano-analysis tools. We’re making them more affordable; we’re making them more powerful.”

Add a Comment

Avatar of: You



Sign In with your LabX Media Group Passport to leave a comment

Not a member? Register Now!

LabX Media Group Passport Logo


Avatar of: eskay


Posts: 1

June 20, 2013

Am v interested. Am a Indian & US trained pathologist also US-trained in public health, presently working in India. Pls send me the articles cited by email. would like to also see the phone with this app to see how it works. 

Avatar of: vm123456


Posts: 61

June 21, 2013

    By placing the middle of a small rod of soda lime glass in a hot flame, Leeuwenhoek could pull the hot section apart to create two long whiskers of glass. Then, by reinserting the end of one whisker into the flame, he could create a very small, high-quality glass sphere. These spheres became the lenses of his microscopes, with the smallest spheres providing the highest magnifications.

- wiki article on Antonie van Leeuwenhoek

Avatar of: lazar3345


Posts: 3

June 23, 2013


Just letting you all know  that similar microscopes are already being sold (relativey cheap)  on Amazon, Nothing new, so what is the big deal, and why it deserves a report on The Scientist?

Avatar of: Christopher R. Lee

Christopher R. Lee

Posts: 15

June 27, 2013

Perhaps it isn't ready for industrial development, but there should be world-wide market (amateurs, schools, etc), so people in rich countries can help make the price as low as possible.

I'm playing with the lens from a dead CD drive, but havn't been able to get it lined up yet. They (at least the ancient ones) come with adjusting coils and magnets.

Avatar of: Sias


Posts: 7

August 19, 2014

An even cheaper solution - no need for a smartphone!


Popular Now

  1. A Newly Identified Species Represents Its Own Eukaryotic Lineage
  2. Telomere Length and Childhood Stress Don’t Always Correlate
  3. Optogenetic Therapies Move Closer to Clinical Use
  4. Research Links Gut Health to Neurodegeneration
    The Nutshell Research Links Gut Health to Neurodegeneration

    Rodent studies presented at the Society for Neuroscience meeting this week tie pathologies in the gastrointestinal tract or microbiome composition with Parkinson’s and Alzheimer’s diseases.