6 results on '"Denk, Lucia"'
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2. A modular culture system for the generation of multiple specialized tissues
- Author
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Minuth, Will W., Denk, Lucia, and Glashauser, Anne
- Subjects
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BIOMEDICAL materials , *TISSUE culture , *PERFUSION , *CELL physiology , *CELL adhesion , *BIOLOGICAL transport , *DEVELOPMENTAL biology , *TISSUE differentiation - Abstract
Abstract: Numerous factors influence cell functions and tissue development in culture. A modular culture system has been developed to allow the control of many of these important environmental parameters. Optimal adhesion of cells is obtained by selecting an individual biomaterial. Selected specimens are mounted in a tissue carrier in order to protect it against damage during handling and after seeding cells, the carriers can be used in a series of compatible perfusion culture containers. This technique allows the simple bathing of growing tissue under continuous medium transport and the exposure of epithelia to a gradient with different fluids at the luminal and basal sides. A further container is made of transparent material to observe microscopically the developing tissue. In addition, a special model features a flexible silicone lid to apply force to mimic the mechanical load required for developing connective and muscular tissue. Perfusion culture of stem/progenitor cells at the interface of an artificial interstitium made by a polyester fleece results in the spatial development of tubules. During long term culture over weeks the growing tissue is continuously exposed to fresh nutrition and respiratory gas. The medium is transported in a constant flow or in pulses, preventing unstirred layers of fluid. A variety of applications of this modular system, described in this paper, demonstrates that the biological profile of cells and tissues can be strongly improved when perfusion culture with a permanent provision of fresh medium is applied. [Copyright &y& Elsevier]
- Published
- 2010
- Full Text
- View/download PDF
3. Potential of stem/progenitor cell cultures within polyester fleeces to regenerate renal tubules
- Author
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Roessger, Anne, Denk, Lucia, and Minuth, Will W.
- Subjects
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TISSUE engineering , *CELL culture , *STEM cells , *KIDNEY tubules , *CHRONIC kidney failure , *POLYESTERS , *PERFUSION , *LABORATORY rabbits - Abstract
Abstract: The cell biological mechanism controlling the regeneration of renal tubules in renal failure after application of stem/progenitor cells is subject of actual research. Unsolved issues are the integration of stem/progenitor cells in a diseased organ environment, the differentiation into epithelial tissue and the formation of tubules in a spatial environment. Following this therapeutic strategy new biomaterials have to be found promoting spatial development of tubules. To obtain new information about the growth of tubules renal stem/progenitor cells from neonatal rabbit kidney were isolated and mounted in a tissue carrier between a selection of commercially available polyester fleeces. This procedure replaces coating by extracellular matrix proteins and creates an artificial interstitium supporting development of tubules. Perfusion culture was performed with chemically defined IMDM containing aldosterone as tubulogenic factor. Polyester fleeces were investigated by scanning electron microscopy. The spatial development of tubules was registered on whole-mount specimens and on cryosections labeled with SBA and antibodies indicating tubule differentiation. It is found that some polyester fleeces promote the spatial development of tubules between the fibers, whereat each of them produces its individual growth pattern. [Copyright &y& Elsevier]
- Published
- 2009
- Full Text
- View/download PDF
4. The formation of pores in the basal lamina of regenerated renal tubules
- Author
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Blattmann, Annette, Denk, Lucia, Strehl, Raimund, Castrop, Hayo, and Minuth, Will W.
- Subjects
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KIDNEY tubules , *BASAL lamina , *PORE size (Materials) , *TISSUE engineering , *REGENERATIVE medicine - Abstract
Abstract: Little information is available concerning the generation of renal tubules, but this information is urgently needed in regenerative medicine for the future treatment of acute and chronic renal failures. Of major interests are the integration of stem/progenitor cells, the cellular development and the tubular growth in a spatial environment. In this regard, we investigated the basal aspect of renal tubules generated at the interphase of an artificial interstitium. Stem/progenitor cells derived from neonatal rabbit kidney were mounted inside a specific tissue holder and covered by layers of polyester fleece. The tissue was then kept in a perfusion culture container for 13 days in chemically defined IMDM containing aldosterone (1×10−7 m) as a tubulogenic factor. The spatial development of tubules was registered on whole-mount specimens and on cryo-sections labeled with soybean agglutinin (SBA) and tissue-specific antibodies indicating that collecting duct tubules were developed. Scanning electron microscopy (SEM) revealed that the generated tubules were completely covered by a basal lamina. Most interestingly, the matrix was not consistently composed, but exhibited three categories of pores. The most frequently found pore type had an apparent diameter of 133±26nm followed by a medium-sized pore type of 317±35nm. Another category of pores with a diameter of 605±101nm was rather rarely found. All of the pores were evenly distributed and not restricted to particular sites. The newly detected pores are not related to culture artifacts, since they were also detected in collecting duct tubules of the neonatal rabbit kidney. It remains to be evaluated whether these pores support physiological transport functions or if they indicate the site where extracellular matrix proteins are inserted into newly synthesized basal lamina. [Copyright &y& Elsevier]
- Published
- 2008
- Full Text
- View/download PDF
5. The role of polyester interstitium and aldosterone during structural development of renal tubules in serum-free medium
- Author
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Minuth, Will W., Denk, Lucia, and Hu, Kanghong
- Subjects
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POLYESTERS , *ALDOSTERONE , *KIDNEY tubules , *SERUM-free culture media - Abstract
Abstract: Little knowledge is available regarding the development of renal stem/progenitor cells into functional parenchyme. To investigate the environmental mechanisms during this maturation process, we elaborated an advanced culture technique to follow renal tubule development. Embryonic stem/progenitor cells derived from neonatal rabbit kidney were placed in a perfusion culture container at the interphase of an artificial polyester interstitium. Tissue culture was carried out in IMDM without serum or protein supplementation and without coating with extracellular matrix proteins. Development of tubules was registered histochemically on cryosections labeled with soybean agglutinin (SBA) and tissue-specific antibodies. The experiments revealed that the development of renal tubules depends exclusively on the administration of aldosterone. The use of 1×10−7 m aldosterone for 13 days generated numerous SBA-labeled tubules, while no tubules developed in the absence of the steroid hormone. To obtain further information about the action of the hormone on the cognate receptor, molecular precursors of the aldosterone synthesis pathway were tested. Surprisingly, application of cholesterol, pregnenolone, progesterone, 11-deoxycorticosterone (DOCA) and corticosterone failed to form numerous tubules. Only 11-DOCA and progesterone induced a few tubules, which were barely SBA-labeled. Furthermore, application of aldosterone antagonists such as 1×10−4 m spironolactone and 1×10−4 m canrenoate completely inhibited the development of tubules. We conclude that specifically aldosterone promotes the development of tubules via the mineralocorticoid receptor whereas its precursors have no effect. [Copyright &y& Elsevier]
- Published
- 2007
- Full Text
- View/download PDF
6. Growth of embryonic renal parenchyme at the interphase of a polyester artificial interstitium
- Author
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Minuth, Will W., Denk, Lucia, and Heber, Sabine
- Subjects
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ARTIFICIAL implants , *EPIDERMAL growth factor , *STEM cells , *CYTOKINES , *BIOMEDICAL materials - Abstract
Abstract: The construction of an artificial kidney module by tissue engineering or the application of cell-based therapies for the treatment of renal failure requires exact information regarding the cellbiological mechanisms of parenchyme development in combination with different kinds of biomaterials. To learn more about these processes tissue cultures are frequently used experimental tools. However, apart from experiments with early kidney anlagen there is a lack of suitable in-vitro models regarding the generation and long-term maintenance of renal tubules. In the present paper we like to demonstrate an advanced culture technique, which allows to generate tubular elements derived from renal stem cells. For the growth of tubules it is essential to fine-tune the interface between the embryonic tissue and the dead fluid space within a perfusion culture container by offering a polyester artificial interstitium. Culture was performed in IMDM supplemented with hormones and growth factors but using serum-free conditions over 14 days. Formation of tissue was then analysed by immunohistochemistry and two-dimensional (2D) electrophoresis. Culture in pure IMDM leads to a complete loss of tissue formation. In contrast, application of aldosterone (A) induces the development of numerous polarised tubules. Surprisingly, addition of epidermal growth factor (EGF), a cocktail of insulin, transferrin and selenium (ITS), retinoic acid (RA), cholecalciferol (VitD3) or bovine pituitary extract (BPT) does not further improve development of tubules, but leads to intensive cell clustering and a decrease of tubule formation. 2D Western blots of developing tissue probed with soybean agglutinin (SBA) reveal a unique pattern of newly detected proteins. It is found that growth factors do not support but abolish protein spots upregulated by aldosterone. It remains to be investigated, which cellbiological effect stimulates the embryonic cells to develop tubules in competition to cell clusters at the interphase of an artificial interstitium. [Copyright &y& Elsevier]
- Published
- 2005
- Full Text
- View/download PDF
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