|A human kidney stones from Mayo Clinic.|
A geologist, a microscopist and a doctor walk into a lab and, with their colleagues from across the nation, make a discovery that overturns centuries of thought about the nature and composition of kidney stones. The team's key insight, reported in the journal Scientific Reports, is that kidney stones are built up in calcium-rich layers that resemble other mineralizations in nature, such as those forming coral reefs or arising in hot springs, Roman aqueducts or subsurface oil fields.
Most importantly for human health, the researchers found, kidney stones partially dissolve and regrow again and again as they form.
This contradicts the widely held notion that kidney stones are homogenous rocks that never dissolve and are different from all other rocks in nature, said University of Illinois geology and microbiology professor Bruce Fouke, who led the new research with Jessica Saw, an M.D. student at the Mayo Clinic School of Medicine and Ph.D. student at the U. of I.; and Mayandi Sivaguru, an associate director of the Carl Zeiss [email protected] at the Carl R. Woese Institute for Genomic Biology at the U. of I.
"Instead of being worthless crystalline lumps, kidney stones are a minute-by-minute record of the health and functioning of a person's kidney," he said.
The findings were the result of looking at kidney stones much more closely and with a broader array of light and electron microscopy techniques than others had employed before, said Sivaguru, the lead author of the study who led the microscopy work. The methods included bright-field, phase-contrast, polarization, confocal, fluorescence and electron microscopy, with newly invented combinations of these tools and X-ray spectroscopy.
Many of the techniques are commonly employed in geology and geobiology, but have not been used to study mineralizations in living organisms, like the kidney stones and gallstones that form in the human body, Fouke said. In particular, the use of ultraviolet light, which causes some minerals and proteins to fluoresce at different wavelengths, offered a vast new treasure trove of information.
A recently developed technology, Airyscan super-resolution microscopy, allowed the team to view the samples at 140-nanometer resolution, a much higher magnification than is normally possible with light microscopy.
In the earliest stages of kidney stone development, the researchers found, crystals of a hydrated form of calcium oxalate adhere to one another, forming a big, irregular clump. Layers of organic matter and crystals build up on top of this inner core, creating an outer shell. The stones continue to dissolve and grow. Being able to see the layers clearly for the first time made it possible to recreate this geological history, Fouke said.
"In geology, when you see layers, that means that something older is underneath something younger," he said. "One layer may be deposited over the course of very short to very long periods of time."
But many of the layers were disrupted, revealing that part of the stones -- usually the interior dihydrate crystals -- had dissolved. New crystals of a dehydrated form of calcium oxalate had begun to grow again within those voids.
"Therefore, just one rock represents a whole series of events over time that are critical to deciphering the history of kidney stone disease," Fouke said.
"Researchers and doctors who study and treat kidney disease will now need to rethink their basic assumptions," Saw said.
"Before this study, it was thought that a kidney stone is just a simple crystal that gets bigger over time," she said. "What we're seeing here is that it's dynamic. The stone is growing and dissolving, growing and dissolving. It's very rich with many components. It's very much alive."
The above story is based on Materials provided by University of Illinois at Urbana-Champaign. Original written by Diana Yates.