Rare Mineral From Rocks Found in Mollusk Teeth (Paleontology)

First time rare type of iron mineral has been discovered in a living organism

  • Rare iron mineral, called santabarbaraite, was previously only observed in geological specimens
  • Researchers found santabarbaraite in mollusk’s stylus, a long, hollow structure that connects its ultrahard tooth to a soft membrane
  • The studied mollusk, Cryptochiton stelleri, is affectionately called the ‘wandering meatloaf’ due to its shape, size and reddish-brown color
  • Researchers leveraged discovery to design bio-inspired inks for 3D printing 

Northwestern University researchers have, for the first time, discovered a rare mineral hidden inside the teeth of a chiton, a large mollusk found along rocky coastlines. Before this strange surprise, the iron mineral, called santabarbaraite, only had been documented in rocks.

The new finding helps understand how the whole chiton tooth — not just the ultrahard, durable cusp — is designed to endure chewing on rocks to feed. Based on minerals found in chiton teeth, the researchers developed a bio-inspired ink for 3D printing ultrahard, stiff and durable materials.

Scanning electron microscope image of the anterior end of the radula with mature teeth. Credit: Northwestern University

“This mineral has only been observed in geological specimens in very tiny amounts and has never before been seen in a biological context,” said Northwestern’s Derk Joester, the study’s senior author. “It has high water content, which makes it strong with low density. We think this might toughen the teeth without adding a lot of weight.”

The study will be published this week in the Proceedings of the National Academy of Sciences.

Joester is an associate professor of materials science and engineering in Northwestern’s McCormick School of EngineeringLinus Stegbauer, a former postdoctoral fellow in Joester’s laboratory, is the paper’s first author. At Northwestern during the research, Stegbauer is now a principal investigator at the Institute of Interfacial Process Engineering and Plasma Technology of the University of Stuttgart in Germany.

One of the hardest known materials in nature, chiton teeth are attached to a soft, flexible, tongue-like radula, which scrapes over rocks to collect algae and other food. Having long studied chiton teeth, Joester and his team most recently turned to Cryptochiton stelleri, a giant, reddish-brown chiton that is sometimes affectionately referred to as the “wandering meatloaf.” 

Rendering of a virtual section of a single tooth head and upper stylus, generated from a 3D reconstruction as determined by synchrotron microcomputer tomography. Credit: Northwestern University

To examine a tooth from Cryptochiton stelleri, Joester’s team collaborated with Ercan Alp, a senior scientist at Argonne National Laboratory’s Advanced Photon Source, to use the facility’s synchrotron Mössbauer spectroscopy as well as with Paul Smeets to use transmission electron microscopy at the Northwestern University Atomic and Nanoscale Characterization and Experiment (NUANCE) Center. They found santabarbaraite dispersed throughout the chiton’s upper stylus, a long, hollow structure that connects the head of the tooth to the flexible radula membrane. 

“The stylus is like the root of a human tooth, which connects the cusp of our tooth to our jaw,” Joester said. “It’s a tough material composed of extremely small nanoparticles in a fibrous matrix made of biomacromolecules, similar to bones in our body.”

Distribution of iron and phosphorous in the major lateral teeth of C. stelleri. Longitudinal section of the tooth and upper stylus. Credit: Northwestern University

Joester’s group challenged itself to recreate this material in an ink designed for 3D printing. Stegbauer developed a reactive ink comprising iron and phosphate ions mixed into a biopolymer derived from the chitin. Along with Shay Wallace, a Northwestern graduate student in Mark Hersam’s laboratory, Stegbauer found that the ink printed well when mixed immediately before printing. 

“As the nanoparticles form in the biopolymer, it gets stronger and more viscous. This mixture can then be easily used for printing. Subsequent drying in air leads to the hard and stiff final material,” Joester said. 

Joester believes we can continue to learn from and develop materials inspired by the chiton’s stylus, which connects ultra-hard teeth to a soft radula.

“We’ve been fascinated by the chiton for a long time,” he said. “Mechanical structures are only as good as their weakest link, so it’s interesting to learn how the chiton solves the engineering problem of how to connect its ultrahard tooth to a soft underlying structure. This remains a significant challenge in modern manufacturing, so we look to organisms like the chiton to understand how this is done in nature, which has had a couple hundred million years of lead time to develop.” 

The study, “Persistent polyamorphism in the chiton tooth: From a new biomaterial to inks for additive manufacturing,” was supported by the National Science Foundation (award numbers DMR-1508399 and DMR-1905982), National Institutes of Health (award number NIH-DE026952), Air Force Research Laboratory (award number FA8650-15-2-5518) and Deutsche Forschungsgemeinschaft (award number STE2689/1-1).

Featured image: Mosaic image of the entire radula showing all stages of development. Credit: Northwestern University


Provided by Northwestern University

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