Here, we present a novel method for culturing kidneys in low volumes of medium that offers more organotypic development compared to conventional methods. Organ culture is a powerful technique for studying renal development. It recapitulates many aspects of early development very well, but the established techniques have some disadvantages: in particular, they require relatively large volumes (1–3 mls) of culture medium, which can make high-throughput screens expensive, they require porous (filter) substrates which are difficult to modify chemically, and the organs produced do not achieve good cortico-medullary zonation. Here, we present a technique of growing kidney rudiments in very low volumes of medium–around 85 microliters–using silicone chambers. In this system, kidneys grow directly on glass, grow larger than in conventional culture and develop a clear anatomical cortico-medullary zonation with extended loops of Henle.
Decellularization techniques have been used on a wide variety of tissues to create cell-seedable scaffolds for tissue engineering. Finding a suitable decellularization protocol for a certain type of tissue can be laborious, especially when organ perfusion devices are needed. In this study, we report a quick and simple method for comparing decellularization protocols combining the use of paraffin slices and two-dimensional cell cultures. We developed three decellularization protocols for adult murine kidney that yielded decellularized extracellular matrices (ECMs) with varying histological properties. The resulting paraffin-embedded ECM slices were deparaffinized and reseeded with murine embryonic stem cells (mESCs). We analyzed cell attachment four days post seeding via determination of cell numbers, and used quantitative Real-Time PCR 13 days post seeding to measure gene expression levels of two genes associated with renal development, Pax2 and Pou3f3. The three decellularization protocols produced kidney-matrices that showed clearly distinguishable results. We demonstrated that formerly paraffin-embedded decellularized ECMs can effectively influence differentiation of stem cells. This method can be used to identify optimal decellularization protocols for recellularization of three-dimensional tissue-scaffolds with embryonic stem cells and other tissue-specific cell types.
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