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Bibliographic Details
Main Author: Tozzi, Arturo
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.07863
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author Tozzi, Arturo
author_facet Tozzi, Arturo
contents Biofilms in human tonsillar crypts show long term persistence with episodic dispersal that current biochemical and microbiological descriptions do not fully explain, particularly with respect to spatial localization. We introduce a biophysical framework in which tonsillar biofilm dynamics arise from the interaction between two mechanical phenomena: a Kosterlitz Thouless type defect nucleation process and a Kelvin Helmholtz type shear driven interfacial instability. Crypt geometry is modeled as a confined, heterogeneous environment that promotes mechanically persistent surface defects generated by growth induced compression. Tangential shear associated with breathing and swallowing selectively amplifies these defects, producing organized surface deformations. Numerical simulations show that only the coexistence of both mechanisms yields localized, propagating, and persistent interface structures, whereas their absence leads to diffuse, unstructured dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2601_07863
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle From local defects to shear-organized biofilms in tonsillar crypts via computational simulations
Tozzi, Arturo
Quantitative Methods
Biofilms in human tonsillar crypts show long term persistence with episodic dispersal that current biochemical and microbiological descriptions do not fully explain, particularly with respect to spatial localization. We introduce a biophysical framework in which tonsillar biofilm dynamics arise from the interaction between two mechanical phenomena: a Kosterlitz Thouless type defect nucleation process and a Kelvin Helmholtz type shear driven interfacial instability. Crypt geometry is modeled as a confined, heterogeneous environment that promotes mechanically persistent surface defects generated by growth induced compression. Tangential shear associated with breathing and swallowing selectively amplifies these defects, producing organized surface deformations. Numerical simulations show that only the coexistence of both mechanisms yields localized, propagating, and persistent interface structures, whereas their absence leads to diffuse, unstructured dynamics.
title From local defects to shear-organized biofilms in tonsillar crypts via computational simulations
topic Quantitative Methods
url https://arxiv.org/abs/2601.07863