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In this closeup view of a southern live oak leaf, shown at 60 times magnification, protective structures called trichomes are colored white, vessels are in cyan and stomata in purple.
Jason Kirk/Baylor College of Medicine, Nikon Small World
September 13, 2021 at 10:00 am
A closeup view of even the most common objects can make the mundane look spectacular.
A glimpse of the underside of a southern live oak tree leaf, which won first place in the 2021 Nikon Small World photomicroscopy competition, is just one example. Jason Kirk, director of Baylor College of Medicine’s Optical Imaging and Vital Microscopy Core in Houston and a self-described microscope enthusiast, snapped the prizewinning photo with a microscope that he finished building in the early days of the coronavirus pandemic. He tested his homemade device with a variety of objects from his yard, including tree leaves.
Tap this image and those below to enlarge
“A lot of times, you stick weird stuff under the microscope and see what it looks like,” Kirk says. “That’s what happened with this.”
His daughter remarked that the leaf’s trichomes — structures that help protect plants and other organisms from extreme weather and insects — looked like sea anemones. That comment inspired Kirk to craft a photo that made the leaf’s underside look like an underwater landscape.
The picture is a composite of around 200 images stacked together. The leaf’s trichomes are colored white and stick out of cyan-colored vessels, which carry water. Surrounding stomata, colored purple, regulate the flow of gases such as carbon dioxide.
The oak leaf was one of 100 stunning images recognized in this year’s competition, the results of which were announced September 13. Here are a few of our favorites.
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It took a month of work for Esmeralda Paric and Holly Stefen, both of Macquarie University in Sydney, to capture this striking scene. Though at first glance it might look like a peek at galaxies, those glowing “stars” are mouse brain cells — part of an experiment that could help researchers understand the mechanisms behind neurogenerative diseases such as dementia.
The image, which earned second place in the competition, shows around 300,000 nerve cells, or neurons, separated by inky black fluid. The researchers coaxed some of the cells to extend spindly structures called axons, which allow neurons to send electrical signals, across the fluid.
“I named [the image] ‘The Jedi and the Sith’ … because when I look at it, I am compelled to reflect on [the] balance and connections that exist between otherwise seemingly isolated or opposing sides,” Paric says.
Her friends, however, had another name for the image. They “lovingly dubbed it ‘The Neuroverse,’” she says.
Is it a scorpion’s tail? Or perhaps a crab’s claw?
No, this menacing, microscopic snapshot shows a side view of the rear leg and claw of a hog louse (Haematopinus suis). The hog louse lives primarily on swine, where the insect feeds on blood, and is one of the largest sucking lice. Severely infested pigs can go bald.
Retired biology professor Frank Reiser of Nassau Community College in Garden City, N.Y., captured this picture, which won third place, using dark-field microscopy to make the inner workings of the transparent louse clearly visible. The tubes running along the louse are respiratory tubes, called tracheae, carrying oxygen to tissues.
As part of a doctoral thesis project, Paula Díaz Cespedes of Pontificia Universidad Católica de Chile in Santiago, who studies injury-related nerve pain, snapped this stunning picture of nerve cells from a 16-day-old rat embryo. The photograph earned fourth place in the competition.
The colorful whirl is a dorsal root ganglion, a cluster of sensory nerve cells, including ones that detect pain. These clusters are found close to the spinal cord in many animals. The major structural component of the cells is colored green, with supporting cells that keep the neurons alive colored red. The nuclei of cells are blue.
Studying how the dorsal root ganglion changes after a painful injury can help researchers better understand chronic pain, Díaz Cespedes says.
This work of art isn’t a stained-glass window. It’s a zoomed-in view of a tiny piece of dinosaur bone.
Geologist Bernardo Cesare of the University of Padua in Italy stitched together 25 images to create the picture. The black blobs are fossil remnants of the bone tissue that hosted a single bone cell. The different colors come from polarized light passing through mineral-filled pores within the sliver of bone. As the light moves through the mineral — called chalcedony, a type of quartz — the thickness and orientation of the crystals in relation to the light emit a rainbow of colors.
The small bone fragment, which was unearthed in Utah, inspired many photos such as this one, Cesare says.
Caleb Dawson of the Walter and Eliza Hall Institute of Medical Researcher in Parkville, Australia wants to know how the intestine handles the myriad microbes living there. To do that, he plans to image immune cells in the gut. Those immune cells live among and inside tentacle-like structures called villi, shown in this striking picture of a mouse’s intestine.
Showing the villi in their three-dimensional glory was difficult, Dawson says. The task required compiling thousands of images taken in different positions while scanning intestinal tissue. Dawson added antibodies and dyes to the tissue to make parts of the villi fluoresce blue or green under certain types of light.
Questions or comments on this article? E-mail us at [email protected]
2021 Nikon Small World photomicrography competition. Published online September 13, 2021.
Erin I. Garcia de Jesus is a staff writer at Science News. She holds a Ph.D. in microbiology from the University of Washington and a master’s in science communication from the University of California, Santa Cruz.
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