New microscope technique reveals internal structure of live embryos
Beckman Institute for Advanced Science and Technology Aug 22, 2017
University of Illinois researchers have developed a way to produce 3–D images of live embryos in cattle that could help determine embryo viability before in vitro fertilization in humans.
The new method, published in the journal Nature Communications, brought together electrical and computer engineering professor Gabriel Popescu and animal sciences professor Matthew Wheeler in a collaborative project through the Beckman Institute for Advanced Science and Technology at the U. of I.
Called gradient light interference microscopy, the method solves a challenge that other methods have struggled with  imaging thick, multicellular samples.
In many forms of traditional biomedical microscopy, light is shined through very thin slices of tissue to produce an image. Other methods use chemical or physical markers that allow the operator to find the specific object they are looking for within a thick sample, but those markers can be toxic to living tissue, Popescu said.
ÂWhen looking at thick samples with other methods, your image becomes washed out due to the light bouncing off of all surfaces in the sample, said graduate student Mikhail Kandel, the co–lead author of the study. ÂIt is like looking into a cloud.Â
GLIM can probe deep into thick samples by controlling the path length over which light travels through the specimen. The technique allows the researchers to produce images from multiple depths that are then composited into a single 3–D image.
To demonstrate the new method, PopescuÂs group joined forces with Wheeler and his team to examine cow embryos.
ÂOne of the holy grails of embryology is finding a way to determine which embryos are most viable, Wheeler said. ÂHaving a noninvasive way to correlate to embryo viability is key; before GLIM, we were taking more of an educated guess.Â
Those educated guesses are made by examining factors like the color of fluids inside the embryonic cells and the timing of development, among others, but there is no universal marker for determining embryo health, Wheeler said.
ÂThis method lets us see the whole picture, like a three–dimensional model of the entire embryo at one time, said Tan Nguyen, the other co–lead author of the study.
Choosing the healthiest embryo is not the end of the story, though. ÂThe ultimate test will be to prove that we have picked a healthy embryo and that it has gone on to develop a live calf, said Marcello Rubessa, a postdoctoral researcher and co–author of the study.
ÂIllinois has been performing in vitro studies with cows since the 1950s, Wheeler said. ÂHaving the resources made available through GabrielÂs research and the other resources at Beckman Institute have worked out to be a perfect–storm scenario.Â
The team hopes to apply GLIM technology to human fertility research and treatment, as well as a range of different types of tissue research. Popescu plans to continue collaborating with other biomedical researchers and already has had success looking at thick samples of brain tissue in marine life for neuroscience studies.
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The new method, published in the journal Nature Communications, brought together electrical and computer engineering professor Gabriel Popescu and animal sciences professor Matthew Wheeler in a collaborative project through the Beckman Institute for Advanced Science and Technology at the U. of I.
Called gradient light interference microscopy, the method solves a challenge that other methods have struggled with  imaging thick, multicellular samples.
In many forms of traditional biomedical microscopy, light is shined through very thin slices of tissue to produce an image. Other methods use chemical or physical markers that allow the operator to find the specific object they are looking for within a thick sample, but those markers can be toxic to living tissue, Popescu said.
ÂWhen looking at thick samples with other methods, your image becomes washed out due to the light bouncing off of all surfaces in the sample, said graduate student Mikhail Kandel, the co–lead author of the study. ÂIt is like looking into a cloud.Â
GLIM can probe deep into thick samples by controlling the path length over which light travels through the specimen. The technique allows the researchers to produce images from multiple depths that are then composited into a single 3–D image.
To demonstrate the new method, PopescuÂs group joined forces with Wheeler and his team to examine cow embryos.
ÂOne of the holy grails of embryology is finding a way to determine which embryos are most viable, Wheeler said. ÂHaving a noninvasive way to correlate to embryo viability is key; before GLIM, we were taking more of an educated guess.Â
Those educated guesses are made by examining factors like the color of fluids inside the embryonic cells and the timing of development, among others, but there is no universal marker for determining embryo health, Wheeler said.
ÂThis method lets us see the whole picture, like a three–dimensional model of the entire embryo at one time, said Tan Nguyen, the other co–lead author of the study.
Choosing the healthiest embryo is not the end of the story, though. ÂThe ultimate test will be to prove that we have picked a healthy embryo and that it has gone on to develop a live calf, said Marcello Rubessa, a postdoctoral researcher and co–author of the study.
ÂIllinois has been performing in vitro studies with cows since the 1950s, Wheeler said. ÂHaving the resources made available through GabrielÂs research and the other resources at Beckman Institute have worked out to be a perfect–storm scenario.Â
The team hopes to apply GLIM technology to human fertility research and treatment, as well as a range of different types of tissue research. Popescu plans to continue collaborating with other biomedical researchers and already has had success looking at thick samples of brain tissue in marine life for neuroscience studies.
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