Microbubbles as biocompatible porogens for hydrogel scaffolds

Eric G. Lima; Krista M. Durney; Shashank R. Sirsi; Adam B. Nover; Gerard A. Ateshian; Mark A. Borden; Clark T. Hung

doi:10.1016/j.actbio.2012.07.007

Microbubbles as biocompatible porogens for hydrogel scaffolds

Eric G. Lima, Krista M. Durney, Shashank R. Sirsi, Adam B. Nover, Gerard A. Ateshian, Mark A. Borden, Clark T. Hung

Research output: Contribution to journal › Article › peer-review

31 Scopus citations

Abstract

In this study, we explored the application of lipid-shelled, gas-filled microbubbles as a method for creating on-demand microporous hydrogels for cartilage tissue engineering. The technique allowed for homogenous distribution of cells and micropores within the scaffold, increasing the absorption coefficient of large solutes (70 kDa dextran) over controls in a concentration-dependent manner. The stability of the gas phase of the microbubbles depended on several factors, including the initial size distribution of the microbubble suspension, as well as the temperature and pressure during culture. Application of pressure cycles provided controlled release of the gas phase to generate fluid-filled micropores with remnant lipid. The resulting microporous agarose scaffolds were biocompatible, leading to a twofold increase in engineered cartilage properties (E_Y = 492 ± 42 kPa for the bubble group vs. 249 ± 49 kPa for the bubble-free control group) over a 42-day culture period. Our results suggest that microbubbles offer a simple and robust method of modulating mass transfer in cell-seeded hydrogels through mild pressurization, and the methodology may be expanded in the future to include focused ultrasound for improved spatio-temporal control.

Original language	English (US)
Pages (from-to)	4334-4341
Number of pages	8
Journal	Acta Biomaterialia
Volume	8
Issue number	12
DOIs	https://doi.org/10.1016/j.actbio.2012.07.007
State	Published - Dec 2012

Keywords

Cartilage tissue engineering
Cell encapsulation
Mechanical properties
Microbubbles
Porosity

ASJC Scopus subject areas

Biotechnology
Biomaterials
Biochemistry
Biomedical Engineering
Molecular Biology

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10.1016/j.actbio.2012.07.007

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title = "Microbubbles as biocompatible porogens for hydrogel scaffolds",

abstract = "In this study, we explored the application of lipid-shelled, gas-filled microbubbles as a method for creating on-demand microporous hydrogels for cartilage tissue engineering. The technique allowed for homogenous distribution of cells and micropores within the scaffold, increasing the absorption coefficient of large solutes (70 kDa dextran) over controls in a concentration-dependent manner. The stability of the gas phase of the microbubbles depended on several factors, including the initial size distribution of the microbubble suspension, as well as the temperature and pressure during culture. Application of pressure cycles provided controlled release of the gas phase to generate fluid-filled micropores with remnant lipid. The resulting microporous agarose scaffolds were biocompatible, leading to a twofold increase in engineered cartilage properties (EY = 492 ± 42 kPa for the bubble group vs. 249 ± 49 kPa for the bubble-free control group) over a 42-day culture period. Our results suggest that microbubbles offer a simple and robust method of modulating mass transfer in cell-seeded hydrogels through mild pressurization, and the methodology may be expanded in the future to include focused ultrasound for improved spatio-temporal control.",

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AU - Lima, Eric G.

AU - Durney, Krista M.

AU - Sirsi, Shashank R.

AU - Nover, Adam B.

AU - Ateshian, Gerard A.

AU - Borden, Mark A.

AU - Hung, Clark T.

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Microbubbles as biocompatible porogens for hydrogel scaffolds

Abstract

Keywords

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