Ear Tubes

Ear Tubes

Infections of the middle ear, the air-filled space behind the eardrum that contains the tiny vibrating bones of hearing, annually affect more than 700 million people worldwide. Children are especially prone to ear infections, with 40% of them developing recurrent or chronic infections that can lead to complications like impaired hearing, speech and language delays, perforations in their eardrums, and even life-threatening meningitis.

As a treatment, doctors may surgically insert ear tubes knowns as “tympanostomy tubes” (TTs) into the eardrum to create an opening between the ear canal and middle ear. Ideally, these conduits ventilate the middle ear, provide a route for fluid to drain out, and allow antibiotic drops to reach the infection-causing bacteria. But in reality, these small hollow cylindrical devices made of plastic or metal function far from perfectly. Bacteria can lay down biofilms and local tissue can grow on their surfaces, which blocks TTs’ lumen and causes them to extrude. Also, antibiotic ear drops applied in the ear canal may not effectively reach the site of infection behind the eardrum. These complications pose risks and result in the need for frequent replacement surgeries, producing sizeable economic costs to the health care system.

ear tube overview

Importantly, problems affecting TTs also plague other fluid-transporting “implantable medical conduits” (IMCs), such as catheters, shunts, and various small tubes with use in the brain, liver, eyes, and other organs where a high-pressure barrier prevents fluids from flowing through the conduit. In the quest for superior devices, the fundamental challenge faced by biomedical engineers is rooted in the conflict that reducing IMC devices’ size and invasiveness comes at the price of increasing their risk of becoming blocked and malfunctioning.

ear tube CT scan

Our approach enables IMCs with predictable and effective uni- and bi-directional fluid transport at the millimeter scale that resist various contaminations. With the example of TTs fabricated from a liquid-infused material (iTTs, short for “infused tympanostomy tubes”), they co-optimized difficult-to-reconcile functions, including fast drug delivery into and drainage of fluids out of the middle ear, resistance against water crossing from the outside into the middle ear, as well as the prevention of bacterial and cell adhesion to tubes, by introducing a novel curved lumen geometry of the tube. The findings are published in the recent cover article of Science Translational Medicine.

Contact: Haritosh Patel

Publications

2025

Grinham J, Alvarenga J, Richter-Lunn K, Lazovskis P, Ejarque S, Bilbao A, Bechthold M, Aizenberg J. Effective Indirect Evaporative Cooling Using Superhydrophobic Nano-Architectured Porous Ceramics. Applied Energy. 2025;397.
Grinham J, Alvarenga J, Richter-Lunn K, Lazovskis P, Ejarque S, Bilbao A, Bechthold M, Aizenberg J. Effective Indirect Evaporative Cooling Using Superhydrophobic Nano-Architectured Porous Ceramics. Applied Energy. 2025;397.
Lim KRG, Owen CJ, Kaiser SK, Routh PK, Mendoza M, Park K-CK, Kim T-S, Garg S, Gardener JA, Russotto L, et al. Nanoscale wetting controls reactive Pd ensembles in synthesis of dilute PdAu alloy catalysts. Nature Communications. 2025;16:6293.
Lim KRG, Owen CJ, Kaiser SK, Routh PK, Mendoza M, Park K-CK, Kim T-S, Garg S, Gardener JA, Russotto L, et al. Nanoscale wetting controls reactive Pd ensembles in synthesis of dilute PdAu alloy catalysts. Nature Communications. 2025;16:6293.
Lazovskis P, Alvarenga J, Teitelbaum E, Cabrera P, Merchant C, Rucewicz S, Rebbagondla JM, Norford L, Aizenberg J, Grinham J, et al. Sorption vs. Separation – Prototype Comparison of Two Approaches to Façade-Integrated Dehumidification. Building and Environment. 2025:113486+.
Lazovskis P, Alvarenga J, Teitelbaum E, Cabrera P, Merchant C, Rucewicz S, Rebbagondla JM, Norford L, Aizenberg J, Grinham J, et al. Sorption vs. Separation – Prototype Comparison of Two Approaches to Façade-Integrated Dehumidification. Building and Environment. 2025:113486+.
Li Y, Cheng D, Son G, Shneidman AV, Lim KRG, Aizenberg J, Sautet P. Modeling electron storage at the interface between Au and anatase-TiO2 under ambient conditions. Chem Catalysis. 2025:101430.
Li Y, Cheng D, Son G, Shneidman AV, Lim KRG, Aizenberg J, Sautet P. Modeling electron storage at the interface between Au and anatase-TiO2 under ambient conditions. Chem Catalysis. 2025:101430.
Lim KRG ", Azizli T, Kaiser SK, Aizenberg M, Montemore MM, Aizenberg J. Effects of Pd ensemble size in dilute and single atom alloy PdAu catalysts for one-pot selective hydrogenation and reductive amination. Catal. Sci. Technol. 2025.
Lim KRG ", Azizli T, Kaiser SK, Aizenberg M, Montemore MM, Aizenberg J. Effects of Pd ensemble size in dilute and single atom alloy PdAu catalysts for one-pot selective hydrogenation and reductive amination. Catal. Sci. Technol. 2025.
Volkov VV, Aizenberg J, Perry CC. Red blood cell Raman microscopy: modelling sub-cellular biochemistry. 2025;27(22):11955–11973,.
Volkov VV, Aizenberg J, Perry CC. Red blood cell Raman microscopy: modelling sub-cellular biochemistry. 2025;27(22):11955–11973,.
Karimi Z, Flores I, Kolle S, Kundu S, Walton E, Badder L, Levy N, Berry DB, Schar D, Levy J, et al. Mitigating Algal Competition with Fouling-Prevention Coatings for Coral Restoration and Reef Engineering. ACS Sustainable Chemistry & Engineering. 2025;13:5808–5817.
Karimi Z, Flores I, Kolle S, Kundu S, Walton E, Badder L, Levy N, Berry DB, Schar D, Levy J, et al. Mitigating Algal Competition with Fouling-Prevention Coatings for Coral Restoration and Reef Engineering. ACS Sustainable Chemistry & Engineering. 2025;13:5808–5817.
Xiong X, Zhou X, Zhang H, Aizenberg M, Yao Y, Hu Y, Aizenberg J, Cui J. Controlled macroscopic shape evolution of self-growing polymeric materials. 2025;16. doi:https://doi.org/10.1038/s41467-025-57030-2
Xiong X, Zhou X, Zhang H, Aizenberg M, Yao Y, Hu Y, Aizenberg J, Cui J. Controlled macroscopic shape evolution of self-growing polymeric materials. 2025;16. doi:https://doi.org/10.1038/s41467-025-57030-2
Lim KRG, Shirman T, Toops T, Alvarenga J, Aizenberg M, Aizenberg J. Active and Stable PtPd Diesel Oxidation Catalysts under Industry-Defined Test Protocols. ChemSusChem. 2025;(e202500295+).
Lim KRG, Shirman T, Toops T, Alvarenga J, Aizenberg M, Aizenberg J. Active and Stable PtPd Diesel Oxidation Catalysts under Industry-Defined Test Protocols. ChemSusChem. 2025;(e202500295+).
Lim KRG, Kaiser SK, Herring CJ, Kim T-S, Perich MP, Garg S, O’Connor C, Aizenberg M, van der Hoeven J, Reece C, et al. Partial PdAu nanoparticle embedding into TiO2 support accentuates catalytic contributions from the Au/TiO2 interface. Proceedings of the National Academy of Sciences. 2025;122(2).
Lim KRG, Kaiser SK, Herring CJ, Kim T-S, Perich MP, Garg S, O’Connor C, Aizenberg M, van der Hoeven J, Reece C, et al. Partial PdAu nanoparticle embedding into TiO2 support accentuates catalytic contributions from the Au/TiO2 interface. Proceedings of the National Academy of Sciences. 2025;122(2).
Lazovskis P, Alvarenga J, Teitelbaum E, Merchant C, Rucewicz S, Cabrera P, Rebbagondla JM, Norford L, Aizenberg J, Grinham J, et al. Sorption vs. Separation – Prototype Comparison of Two Approaches to Façade-Integrated Dehumidification. Multiphysics and Multiscale Building Physics. 2025:130–139,.
Lazovskis P, Alvarenga J, Teitelbaum E, Merchant C, Rucewicz S, Cabrera P, Rebbagondla JM, Norford L, Aizenberg J, Grinham J, et al. Sorption vs. Separation – Prototype Comparison of Two Approaches to Façade-Integrated Dehumidification. Multiphysics and Multiscale Building Physics. 2025:130–139,.
Patel H, Potilla VG, Shneidman AV, Movilli J, Alvarenga J, Dupre C, Aizenberg M, Murthy VN, Tropsha A, Aizenberg J. Design Principles From Natural Olfaction for Electronic Noses. Advanced Science. 2025;(2412669+).
Patel H, Potilla VG, Shneidman AV, Movilli J, Alvarenga J, Dupre C, Aizenberg M, Murthy VN, Tropsha A, Aizenberg J. Design Principles From Natural Olfaction for Electronic Noses. Advanced Science. 2025;(2412669+).
Patel H, Huang YX, Dengiz D, Pravdivtseva M, Jansen O, Quandt E, Aizenberg J. Fluid dynamics model of the cerebral ventricular system. Proceedings of the National Academy of Sciences. 2025;122:e2426067122. doi:10.1073/pnas.2426067122
Patel H, Huang YX, Dengiz D, Pravdivtseva M, Jansen O, Quandt E, Aizenberg J. Fluid dynamics model of the cerebral ventricular system. Proceedings of the National Academy of Sciences. 2025;122:e2426067122. doi:10.1073/pnas.2426067122
Routh PK, Liu X, Redekop E, Lim JS, Prodinger S, van der Hoeven JES, Aizenberg J, Nachtegaal M, Clark AH, Sautet P, et al. Unraveling the Kinetics of Hydride Formation and Decomposition at Pd–Au Bimetallic Interfaces: A Combined Spectroscopic and Computational Study. Journal of the American Chemical Society. 2025;147:11378–11389. doi:10.1021/jacs.5c00842
Routh PK, Liu X, Redekop E, Lim JS, Prodinger S, van der Hoeven JES, Aizenberg J, Nachtegaal M, Clark AH, Sautet P, et al. Unraveling the Kinetics of Hydride Formation and Decomposition at Pd–Au Bimetallic Interfaces: A Combined Spectroscopic and Computational Study. Journal of the American Chemical Society. 2025;147:11378–11389. doi:10.1021/jacs.5c00842

2024

Mader AV, Williams RM, Aizenberg J, Noorduin WL. Directing Sequential Self-Organization with Self-Assembled Nanocrystals. Crystal Growth & Design. 2024.
Mader AV, Williams RM, Aizenberg J, Noorduin WL. Directing Sequential Self-Organization with Self-Assembled Nanocrystals. Crystal Growth & Design. 2024.