Pupa Gilbert (née Gelsomina De Stasio)
Research Group

Data from ref. 1.

(Click to enlarge)


The teeth of sea urchins are among the most complicated structures in the natural world. The image here shows the cross section of one tooth which looks a bit like a mushroom. In the higher magnification image, you can appreciate the details of imbricated minerals: the elongated structures are plates (the rounded ones are fibers) and these both are entirely made of calcite. The space between fibers and plates is completely filled by high-Mg calcite nanoparticles ten nanometers in size.



  1. C. E. Killian, R. A. Metzler, Y. T. Gong, T. H. Churchill, I. C. Olson, V. Trubetskoy, M. B. Christensen, J. H. Fournelle, F. De Carlo, S. Cohen, J. Mahamid, A. Scholl, A. Young, A. Doran, F. H. Wilt, S. N. Coppersmith, and P.U.P.A. Gilbert.
    Self-sharpening mechanism of the sea urchin tooth.
    Adv. Funct. Mater. 21, 682-690 (2011). PDF




  2. C. E. Killian, R. A. Metzler, Y. U. T. Gong, I. C. Olson, J. Aizenberg, Y. Politi, F. H. Wilt, A. Scholl, A. Young, A. Doran, M. Kunz, N. Tamura, S. N. Coppersmith, and P.U.P.A. Gilbert.
    Mechanism of calcite co-orientation in the sea urchin tooth.
    J. Am. Chem. Soc., 131, 18404-18409 (2009). PDF


  3. Y. Ma, B. Aichmayer, O. Paris, P. Fratzl, A. Meibom, R. A. Metzler, Y. Politi, L. Addadi, P.U.P.A. Gilbert and S. Weiner.
    The grinding tip of the sea urchin tooth: exquisite control over calcite crystal orientation and Mg distribution.
    Procs. Natl. Acad. Sci. USA 106, 6048-6053 (2009). PDF SI New York Times article on this work




  4. L. Yang, C. E. Killian, M. Kunz, N. Tamura, and P.U.P.A. Gilbert.
    Biomineral nanoparticles are space-filling.
    R. Soc. Chem. - Nanoscale, in press. PDF