Researchers at the 天美影视传媒 have developed a method that uses smartphone-derived images to identify potentially harmful bacteria on skin and in oral cavities. Their approach, outlined in published in the May issue of Optics and Lasers in Engineering, can visually identify microbes on skin contributing to acne and slow wound healing, as well as bacteria in the oral cavity that can cause gingivitis and dental plaques.
The team 鈥 led by , a UW professor of bioengineering and of ophthalmology 鈥 combined a smartphone-case modification with image-processing methods to illuminate bacteria on images taken by a conventional smartphone camera. This approach yielded a relatively low-cost and quick method that could be used at home to assess whether potentially harmful bacteria are present on skin and in the oral cavity.
鈥淏acteria on skin and in our mouths can have wide impacts on our health 鈥 from causing tooth to decay to slowing down wound healing,鈥 said Wang. 鈥淪ince smartphones are so widely used, we wanted to develop a cost-effective, easy tool that people could use to learn about bacteria on skin and in the oral cavity.鈥
Bacteria aren鈥檛 easy to see using conventional smartphone images. Smartphone cameras are 鈥淩GB cameras,鈥 said Wang. They essentially funnel all the different wavelengths of light in the visual spectrum into three different colors 鈥 red, green and blue. Every pixel in a smartphone-generated image is a combination of those colors. But bacteria emit many colors beyond red, green and blue, which a typical smartphone camera misses.
Wang鈥檚 team augmented the smartphone camera鈥檚 capabilities by attaching a small 3D-printed ring containing 10 LED black lights around a smartphone case鈥檚 camera opening. The researchers used the LED-augmented smartphone to take images of the oral cavity and skin on the face of two research subjects.
鈥淭he LED lights 鈥榚xcite鈥 a class of bacteria-derived molecules called porphyrins, causing them to emit a red fluorescent signal that the smartphone camera can then pick up,鈥 said lead author Qinghua He, a UW doctoral student in bioengineering.
Other components in the image 鈥 such as proteins or oily molecules produced by our bodies, as well as skin, teeth and gums 鈥 won鈥檛 glow red under LED. They鈥檒l fluoresce in other colors, He added.
Many bacteria produce porphyrins as a byproduct of their growth and metabolism. The porphyrins can accumulate on skin and in our mouths where bacteria are present in high amounts, according to co-author Yuandong Li, a UW postdoctoral researcher in bioengineering.
鈥淕enerally, the more porphyrins you see on skin surface, for example, the greater difficulty you see with wound-healing and acne,鈥 said Li.
The LED illumination gave the team enough visual information to computationally 鈥渃onvert鈥 the RGB colors from the smartphone-derived images into other wavelengths in the visual spectrum. This generates a 鈥減seudo-multispectral鈥 image consisting of 15 different sections of the visual spectrum 鈥 rather than the three in the original RGB image. Obtaining this visual information up front would have required expensive and cumbersome lights, rather than using the relatively inexpensive LED black lights, Wang said.
With their greater degree of visual discrimination, the pseudo-multispectral images clearly resolved porphyrin clusters on the skin and within the oral cavity. In addition, though they tailored this method to show porphyrin, Researchers could modify the image-analysis pipeline to detect other bacterial signatures that also fluoresce under LED.
鈥淭hat is the beauty of this technique: We can look at different components simultaneously,鈥 said Wang. 鈥淚f you have bacteria producing a different byproduct that you want to detect, you can use the same image to look for it 鈥 something you can鈥檛 do today with conventional imaging systems.鈥
This initial study鈥檚 success could form the basis of new home-based methods to assess basic skin and oral health, the researchers said 鈥 providing users with information about whether they need to see a dentist, for example, or consult a doctor about certain types of skin conditions. Their visual system and image-analysis pipeline may also help identify potentially problematic bacteria in other medical contexts, such as wound healing on other parts of the body.
鈥淭here are a lot of directions we can go here,鈥 said Wang. 鈥淥ur bodies are complex environments, and this approach has great potential to look at many types of problems.鈥
Additional co-authors were UW visiting scholar Zhiyuan Sun and undergraduate researcher Wendy Wang. The study was funded by the Washington Research Foundation.
For more information, contact Wang at wangrk@uw.edu.