So-called fragile topological states of matter challenge our conventional notion of topology by lacking the robustness typically associated with topological protection, thereby displaying elusive manifestations that are difficult to harness for wave control. In this Letter, we leverage the recent discovery of fragile topological states in special classes of structural kagome lattices to document the availability of domain wall elastic wave modes that are directly traceable to fragile topology and, yet, exhibit remarkably strong signatures that support omni-directionality. We design twisted kagome bi-domains comprising two topologically distinct sublattices - one trivial and the other fragile topological - sharing a common bandgap and meeting at a domain wall. The two phases are achieved via carefully engineered surface cut patterns that modify the band landscape of the underlying lattices in complementary fashions, leading to dichotomous irreps landscapes. Under these circumstances, a domain wall-bound mode emerges within the shared bandgap and displays remarkable stability against domain wall orientation and introduced defects. We corroborate these findings via $\mathbf{k}\cdot\mathbf{p}$ Hamiltonian and Jackiw-Rabbi analysis and validate them experimentally through laser vibrometry tests on a prototype endowed with water jet-induced perforation patterns.

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