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04/15/2026 12:23

IPF Researchers Create Olympic Gels, a Long-Theorized Class of DNA-Based Soft Materials

Emily Schöner Öffentlichkeitsarbeit
Leibniz-Institut für Polymerforschung Dresden e. V.

    An interdisciplinary research team led by Dr. Elisha Krieg at the Leibniz Institute of Polymer Research Dresden (IPF) has successfully synthesized and characterized Olympic gels, a long-theorized class of soft materials. Unlike conventional gels, which are held together by chemical crosslinks, Olympic gels derive their structural stability from the mechanical interlocking of ring-shaped molecules, similar to chain mail.

    First proposed in 1979, the realization of Olympic gels has remained challenging due to the complexity of their topology. Elisha Krieg’s team addressed this challenge by combining methods from synthetic biology, DNA nanotechnology, and polymer physics, supported by computer simulations carried out by the IPF group of Dr. Michael Lang.

    The key innovation was the creation of a library of more than 16,000 distinct DNA rings, each equipped with unique molecular “lock-and-key” sequences. Upon enzymatic activation, the rings preferentially close onto themselves rather than linking with neighboring molecules—a critical requirement for forming the interlocked network characteristic of Olympic gels. The resulting material exhibits mechanical properties and swelling behavior that differ markedly from those of conventional polymer networks, confirming long-standing predictions in polymer theory.

    Beyond its significance as a model system for fundamental materials research, Olympic gels hold promise for a range of applications. These include artificial microreactors for targeted drug delivery, advanced model systems for studying DNA organization in microorganisms such as Kinetoplastea, and the development of highly stretchable filtration membranes. More broadly, the work demonstrates how extreme compositional complexity, a hallmark of biological systems, can serve as a design principle for creating materials with novel and emergent properties.

    Contact for scientific information:

    Carsten Werner
    Wissenschaftlicher Direktor
    werner@ipfdd.de
    +49 351 4658 531

    Original publication:

    Speed, Peng, Atabay, Gupta, et al. Assembling a True “Olympic Gel” From over 16 000 Combinatorial DNA Rings. Advanced Materials (2026).
    https://advanced.onlinelibrary.wiley.com/doi/10.1002/adma.202520549

    Images

    Schematic illustration of the formation of interlocked DNA rings (“Olympic Gels”)
    Schematic illustration of the formation of interlocked DNA rings (“Olympic Gels”)
    Source: IPF/partly AI-generated

    Criteria of this press release:
    Journalists, Scientists and scholars, Students
    Biology, Chemistry, Materials sciences, Medicine
    transregional, national
    Research results, Scientific Publications
    English

     

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