Litcius/Paper detail

Limits of economy and fidelity for programmable assembly of size-controlled triply periodic polyhedra

Carlos M. Duque, Douglas M. Hall, Botond Tyukodi, Michael F. Hagan, Christian D. Santangelo, Gregory M. Grason

2024Proceedings of the National Academy of Sciences15 citationsDOIOpen Access PDF

Abstract

We propose and investigate an extension of the Caspar-Klug symmetry principles for viral capsid assembly to the programmable assembly of size-controlled triply periodic polyhedra, discrete variants of the Primitive, Diamond, and Gyroid cubic minimal surfaces. Inspired by a recent class of programmable DNA origami colloids, we demonstrate that the economy of design in these crystalline assemblies-in terms of the growth of the number of distinct particle species required with the increased size-scale (e.g., periodicity)-is comparable to viral shells. We further test the role of geometric specificity in these assemblies via dynamical assembly simulations, which show that conditions for simultaneously efficient and high-fidelity assembly require an intermediate degree of flexibility of local angles and lengths in programmed assembly. Off-target misassembly occurs via incorporation of a variant of disclination defects, generalized to the case of hyperbolic crystals. The possibility of these topological defects is a direct consequence of the very same symmetry principles that underlie the economical design, exposing a basic tradeoff between design economy and fidelity of programmable, size controlled assembly.

Topics & Concepts

PolyhedronGyroidMesoscopic physicsSymmetry (geometry)Flexibility (engineering)Topology (electrical circuits)NanotechnologyComputer scienceMaterials scienceMathematicsGeometryPhysicsCombinatoricsCondensed matter physicsPolymerCopolymerComposite materialStatisticsAdvanced biosensing and bioanalysis techniquesSupramolecular Self-Assembly in MaterialsModular Robots and Swarm Intelligence