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Rochester to advance research in biological imaging through new grant

Tuesday, February 23, 2021

A new multidisciplinary collaboration between the University of Rochester's departments of biology, biomedical engineering, and optics and the Goergen Institute for Data Science will establish an innovative microscopy resource on campus, allowing for cutting-edge scientific research in biological imaging.

Michael Welte, professor and chair of the Department of Biology, is the lead principal investigator of the project, which was awarded a $1.2 million grant from the Arnold and Mabel Beckman Foundation.

"The grant supports an endeavor at the intersection of optics, data science, and biomedical research, and the University of Rochester is very strong in these areas," Welte says. "The University has a highly collaborative culture, and the close proximity of our college and medical center makes Rochester ideally suited to lead advances in biological imaging."

The project will include developing and building a novel light-sheet microscope that employs freeform optical designs devised at Rochester. The microscope, which will be housed in a shared imaging facility in Goergen Hall and is expected to be online in 2022, enables three-dimensional imaging of complex cellular structures in living samples. Researchers and engineers will continually improve the microscope, and it will eventually become a resource for the entire campus research community.

In addition to funding the construction of the microscope and development of the data science component, the grant from the Arnold and Mabel Beckman Foundation supports three biological research projects:

  • Anne Meyer, an associate professor of biology, will study how communities of bacteria interact and change inside lab-grown biofilms—three-dimensional structures that mimic how bacteria (including bacteria that cause disease) live in nature. Most microscopy is so slow that the bacteria may have already divided by the time the microscope is back at the same spot. The speed of light-sheet microscopy is expected to enable Meyer to see the bacteria in the 3-D space in real time.
  • Dan Bergstralh, an assistant professor of biology, will study how the behavior of single cells generates the 3-D structure of animal organs. Using normal microscopy, researchers can either study single cells and their properties or the properties of tissues and organs. Light-sheet microscopy will allow Bergstralh to image both cells and organs at enough detail to understand how they influence each other.
  • Jim McGrath, a professor of biomedical engineering, and Richard Waugh, professor of biomedical engineering and vice provost for research, will study how molecules and cells travel from the bloodstream into surrounding tissue. Traditional microscopy is insufficient to visualize critical aspects of this transport, but the new microscope will allow the researchers to look across a whole plane of many cells at the same time. It will also allow them to add drugs during imaging and immediately see how the sample reacts.
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