What question did this study set out to answer?

This research aims to explore the topological properties of microtubules and their implications in soft-matter physics.

March 18, 2026Open Access

Topological Edge States in Helical Soft-Matter Lattices: Microtubules as a Natural Platform

Key Points

This research aims to explore the topological properties of microtubules and their implications in soft-matter physics.
Analyzed microtubule structures as Jackiw-Rebbi domain walls in an SSH model
Investigated excitonic couplings related to α–β tubulin geometry
Examined effects of dipole contributions on binding states
Predicted a topological gap of ~20 meV in microtubules
Achieved substantial decoherence suppression with Γ_eff/Γ₀ ~ 10⁻³
Identified a dipole-active absorption feature near 160 cm⁻¹ that disappears upon depolymerization

Abstract

We show that the structural seam of the 13-protofilament microtubule acts as a Jackiw–Rebbi domain wall in an effective Su–Schrieffer–Heeger (SSH) model, binding a topologically protected mid-gap state. The tight binding parameters are treated as effective excitonic couplings (tryptophan-based Frenkel excitons) anchored to the α–β tubulin heterodimer geometry. Assuming beyond-dipole contributions invert the point-dipole ordering (t₂ > t₁, to be verified by DFT/DFTB), the model predicts a topological gap of ~20 meV, substantial decoherence suppression (Γₑff/Γ₀ ~ 10⁻³), and a dipole-active absorption feature near 160 cm⁻¹ (~5 THz) that disappears upon depolymerization. The accompanying code repository is available at https: //github. com/lucasgpinheiro-rgb/microtubule-topology.

Topological Edge States in Helical Soft-Matter Lattices: Microtubules as a Natural Platform

Key Points

Abstract

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