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Main Authors: Echeverría-Alar, Sebastian, Narasimhan, Badri Narayanan, Fraley, Stephanie I, Rappel, Wouter-Jan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.01649
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author Echeverría-Alar, Sebastian
Narasimhan, Badri Narayanan
Fraley, Stephanie I
Rappel, Wouter-Jan
author_facet Echeverría-Alar, Sebastian
Narasimhan, Badri Narayanan
Fraley, Stephanie I
Rappel, Wouter-Jan
contents Lumens are cavities enclosed by polarized cells that are essential for organ function, from nutrient transport in the gut to gas exchange in the lungs. Defects in lumen formation are associated with severe diseases, including polycystic kidney disease and respiratory malformations. The emergence, growth, and maintenance of lumens involve a rich set of phenomena that can be framed within out-of-equilibrium physics and biological active matter, including osmotically driven hydraulic flows, coarsening-like dynamics, morphological instabilities, and mechanochemical feedbacks linking luminal pressure to tissue response. Yet experimental and theoretical efforts to study these phenomena have largely developed within specific biological systems, complicating the identification of shared physical principles across them. In this review, we bring these efforts together and present lumenogenesis within a biological physics framework in which lumens are viewed as active balloons: pressurized cavities that are inflated, sculpted, and maintained through tightly coupled active processes.
format Preprint
id arxiv_https___arxiv_org_abs_2605_01649
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Lumens as active balloons: a biological physics review
Echeverría-Alar, Sebastian
Narasimhan, Badri Narayanan
Fraley, Stephanie I
Rappel, Wouter-Jan
Biological Physics
Lumens are cavities enclosed by polarized cells that are essential for organ function, from nutrient transport in the gut to gas exchange in the lungs. Defects in lumen formation are associated with severe diseases, including polycystic kidney disease and respiratory malformations. The emergence, growth, and maintenance of lumens involve a rich set of phenomena that can be framed within out-of-equilibrium physics and biological active matter, including osmotically driven hydraulic flows, coarsening-like dynamics, morphological instabilities, and mechanochemical feedbacks linking luminal pressure to tissue response. Yet experimental and theoretical efforts to study these phenomena have largely developed within specific biological systems, complicating the identification of shared physical principles across them. In this review, we bring these efforts together and present lumenogenesis within a biological physics framework in which lumens are viewed as active balloons: pressurized cavities that are inflated, sculpted, and maintained through tightly coupled active processes.
title Lumens as active balloons: a biological physics review
topic Biological Physics
url https://arxiv.org/abs/2605.01649