AI Article Synopsis
- The paper presents a novel method using microfluidics to create tissue engineering scaffolds with consistent pore sizes for better biological compatibility.
- The microfluidic device features two tapered channels that generate bubbles encapsulated in an alginate solution, allowing for dynamic manipulation of bubble sizes based on gas pressure and liquid flow.
- These uniform bubbles can self-assemble into crystalline structures, which are then converted into solid foams to serve as scaffolds for culturing chondrocytes, highlighting their potential in tissue engineering applications.
Article Abstract
In this paper, we demonstrate for the first time the technique to using microfluidics to fabricate tissue engineering scaffolds with uniform pore sizes. We investigate both the bubble generation of the microfluidic device and the application of foam as a tissue engineering scaffold. Our microfluidic device consists of two concentric tapered channels, which are made by micropipettes. Nitrogen gas and aqueous alginate solution with Pluronic((R)) F127 surfactant are pumped through the inner and the outer channels, respectively. We observe rich dynamic patterns of bubbles encapsulated in the liquid droplets. The size of the bubble depends linearly on the gas pressure and inversely on the liquid flow rate. In addition, monodisperse bubbles self-assemble into crystalline structures. The liquid crystalline foams are further processed into open-cell solid foams. The novel foam gel was used as a scaffold to culture chondrocytes.
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Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2717582 | PMC |
| http://dx.doi.org/10.1063/1.3122665 | DOI Listing |
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