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Quantum Light Source Advances Bioimaging Clarity

Texas A&M researchers team up to create device to enhance spectroscopy results

Vladislav Yakovlev, Ph.D., and Girish Agarwal, Ph.D., created a novel light source to improve the clarity of Brillouin microscopy, a critical imaging technique for cell and tissue research. (Photo courtesy of Texas A&M Engineering)

Texas A&M University researchers accomplished what was once considered impossible — they created a device capable of squeezing the quantum fluctuations of light down to a directed path and used it to enhance contrast imaging.

This one-of-a-kind “flashlight” was built to increase the signal-to-noise ratio present in Brillouin microscopy spectroscopic measurements that visually record the mechanical properties of structures inside living cells and tissues. Test results reveal the new source significantly increases image clarity and accuracy.

“This is a new avenue in research,” said Vladislav Yakovlev, Ph.D., University Professor in the Texas A&M Department of Biomedical Engineering in the College of Engineering. “We are specially designing light in such a way that it can improve contrast.”

“It’s a new milestone in the capabilities of Brillouin microscopy and imaging extensively used for biosystems,” said Girish Agarwal, Ph.D., University Distinguished Professor in the Department of Biological and Agricultural Engineering in the College of Agriculture and Life Sciences. “And it becomes part of an international effort to develop quantum sensors for diverse applications like brain imaging, biomolecule structure mapping and exploring underground oil and water sources by devising supersensitive gravimeters.”

A paper detailing the work was published in Optica.

The ever-present problem of noisy images
All instruments capable of capturing a picture or image also capture signal distortion, or noise, in the process. The distortion can stem from too much or too little light and even brightness or color issues from the environment around the subject. Most noise is unnoticed until the image is enlarged enough for the naked eye to see the unwanted pixels clearly.

Brillouin microscopy is the fundamental limit of reduced-scale measurement imaging currently possible. The process aims lasers at solid objects and measures the waves or signals of vibration made by the moving atoms and structures within the visibly unmoving material. Distortion produced at this scale can severely obscure the signals received, creating muddied images that are hard to interpret. Currently, all laser spectroscopy systems like Brillouin microscopy suffer from the natural and technical noise distortions associated with laser light, which is why newer light sources are needed.

Improving the signal-to-noise ratio in Brillouin imaging
Six years ago, Yakovlev attempted to improve the signal-to-noise ratio in Brillouin microscopy by using intense light sources. Unfortunately, overexposure to light damaged the cells he was imaging.

Yakovlev searched the scientific literature for answers and found a theory from the 1980s postulating quantum light could solve the problem, though it didn’t mention how. Agarwal, an expert in quantum physics, came up with a possible way. Tian Li, Ph.D., then a postdoctoral researcher from the University of Maryland, was hired to create the first quantum light laboratory at Texas A&M. The laboratory space was provided by Marlan Scully, Ph.D., director of the Institute for Quantum Science and Engineering.

The team faced two significant challenges: finding funding for such a wild idea and finding graduate students and postdoctoral researchers to help them — ones who were willing to straddle the fields of biology and quantum physics.

After nearly two years of vigorous explorations, the device grew to a table-top-sized contraption of complex optical configurations and measuring instruments that allowed the researchers to adjust, direct, and efficiently manipulate and detect light. During that time, Li gained a better understanding of biology, and Yakovlev and Agarwal developed a mechanism to create the proper state and matter of light needed for noise reduction without damaging live cells.

Small gray inset area in the left image shows the tiny clear-glass triangle researchers put in water and used as a test shape. The left image is scattered spectroscopy using a traditional light source on the glass and water, where the faint outline of the triangle shape is the only clear signal captured. The right image was captured using the new light source, which allowed the scattered spectroscopy to differentiate the contrast between the glass signals and the water signals. (Image courtesy of Vladislav Yakovlev and Girish Agarwal)

Though the light-squeezing device can be adopted for other spectroscopic measurements, such as Raman scattering, Yakovlev and Agarwal are enhancing the capabilities of Brillouin microscopy to identify the viscous or elastic materials in biological systems. These systems control the physical properties of cells and cell structures and define everything from cell development to cancer progression.

Big impacts from seeing small details
Seeing details clearly makes all the difference in biomedical breakthroughs.
“Each time you get a new telescope or something like gravitational-wave astronomy, you discover new things you can’t possibly see without it,” said Yakovlev. “The same thing works in biology. Before the invention of the microscope, we didn’t know that we consist of individual cells.”

So far, only the contrast of spectroscopy images has been improved, but Yakovlev and Agarwal are already working on Agarwal’s theory to enhance spatial resolution or the smallest details possible. And if the task leads to creating another complex device that pushes the limits of current technology, the researchers are ready and willing to make that happen.

“I love those types of projects where people tell you something will never work, and it works,” said Yakovlev. “I love challenges.”

The project was primarily supported by funding awarded to the Texas A&M Engineering Experiment Station from the Air Force Office of Scientific Research, with Yakovlev, Agarwal and Scully listed as principal investigators.

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