Project description:Influence of three-dimensional culture in an interwoven hollow fiber bioreactor on the gene expression profile of hepatic HepG2 cells

Project description:HCV proliferation is closely related to three-dimentional cellular condition. In case of blood-borne (bb) HCV culture in HuS-E2 cells, bbHCV was reproduced only from 3D-cultured cells in hollow fibers. Thus, in order to identify novel factors which support HCV proliferation under three-dimentional condition, we compared gene expression profile between 2D- and 3D-cultured HuS-E/2 cells with 3D-gene Human oligo chip 25k (Toray, Tokyo, Japan).

Project description:The development of more complex but reliable systems for compound testing in a pharmaceutical context is a challenging task to date. Three-dimensional (3D), organ mimetic cell culture is aiming to become an alternative to common two-dimensional (2D) cell culture or animal testing in that field. We developed a biocompatible 3D cell culture environment for a hepatocellular carcinoma (HCC) model that enables cellular maintenance in a polycarbonate scaffold structure. Albumin, regarded as a differentiation marker, was elevated in statically 3D cultivated HepG2 cells. Expression of HCC tumor marker alpha-fetoprotein (AFP) was reduced compared to immunofluorescence stainings of 2D cultivated cells. Remarkably, expression of cytokeratin and pathophysiologically relevant beta-1 integrin (ITGB1) was found enhanced in nonperfused 3D cell culture. Changes in gene expression induced by the 3D cultivation environment were investigated using Ingenuity Pathway Analysis (IPA). Our findings revealed involvement of the insulin growth factor (IGF) signaling pathway in upregulation of matrix metalloproteinases (MMP) and ITGB1. The experimental data indicate a more differentiated state in 3D cultivated HepG2 cells than in the respective 2D experiments. Hence, scaffold-supported 3D cultivation of HepG2 cells may lead to a gain of information valuable for both drug testing and cancer research. HepG2 cells were cultivated for five days under 2D and 3D statical and perfused conditions. Cultivation was started with 0.25x10^6 cells in 2D and with 1x10^6 vital cells for the 3D experiments. The day of seeding was defined as d0. The groups were classified as follows: 2D, i.e., monolayer cultures, 3D, i.e., statical 3D cultures and BR, which denotes perfused 3D culture of HepG2 cells. The perfusable bioreactor system was operated using a peristaltic pump. It houses the MatriGrid, a polycarbonate-based microporous cellular support. For 3D static cultivation, cell-inoculated MatriGrids were placed in wells of a 24-well plate. Microarray experiments of three 2D (i.e., control), three 3D statically and three actively perfused 3D cultivations were performed at SIRS-Lab GmbH (SIRS-Lab GmbH, Jena, Germany) according to the manufacturer's instructions (Illumina, San Diego, CA). Altogether, 9 RNA samples of hepatocyte cultures and an internal control RNA were hybridized on two HumanHT-12 v4 Expression BeadChips.

Project description:In order to gain insight into epithelial morphogenesis and the influence of culture geometry on gene expression patterns, Madin Darby Canine Kidney (MDCK) epithelial cells where grown in 2-dimensional (2D) culture or 3-dimensional (3D) culture . MDCK cells cultured in 2D were plated atop a pre-solidified type I collagen gel. Cells cultured under these conditions grew as flat monolayer sheets. In 3D culture, cells are embedded within type I collagen gel. Cells grown under these conditions form large spherical cysts with hollow central lumens. We anticipate, therefore, that these results provide insight into the mechanisms that regulate epithelial cystogenesis. Cells grown in the 2D or 3D geometries were collected from digested type I collagen gels on day 8. The 2D MDCK cells were treated as the control condition and there gene expression patterns were compared to those of 3D grown cells, which served as the experimental condition.

Project description:In order to gain insight into epithelial morphogenesis and the influence of culture geometry on gene expression patterns, Madin Darby Canine Kidney (MDCK) epithelial cells where grown in 2-dimensional (2D) culture or 3-dimensional (3D) culture . MDCK cells cultured in 2D were plated atop a pre-solidified type I collagen gel. Cells cultured under these conditions grew as flat monolayer sheets. In 3D culture, cells are embedded within type I collagen gel. Cells grown under these conditions form large spherical cysts with hollow central lumens. We anticipate, therefore, that these results provide insight into the mechanisms that regulate epithelial cystogenesis.

Project description:Full title: Three-dimensional culture of AIDS-NHL cells influences gene expression related to B-cell development, proliferation and survival The AIDS-NHL-derived cell line, UMCL01-101, representing diffuse large B-cell lymphoma of immunoblastic morphology (AIDS-IBL), was grown in conventional, static suspension culture or three-dimensionally (3D) in the Rotating Wall Vessel (RWV) bioreactor. The objective was to assess the impact on gene expression of growth as a three-dimensional tissue assembly. Global gene expression analysis was performed on UMCL01-101 cells grown under either condition using Affymetrix microarray. UMCL01-101 cells were cultured in the Rotating Wall Vessel bioreactor to form 3D assemblies, or in conventional suspension culture, for 15 days. RNA was prepared from triplicate samples under each growth condition and submitted for microarray analysis.

Project description:Development of systems allowing the maintenance of native properties of mesenchymal stromal cells (MSC) is a critical challenge for studying physiological functions of skeletal progenitors, as well as towards cellular therapy and regenerative medicine applications. Conventional stem cell culture in monolayer on plastic dishes (2D) is associated with progressive loss of functionality, likely due to the absence of a biomimetic microenvironment and the selection of adherent populations. Here we demonstrate that 2D MSC expansion can be entirely bypassed by culturing freshly isolated bone marrow cells within the pores of 3D scaffolds in a perfusion-based bioreactor system, followed by enzymatic digestion for cell retrieval. The 3D-perfusion system supported MSC growth while maintaining cells of the hematopoietic lineage, and thus generated a cellular environment mimicking some features of the bone marrow stroma. As compared to 2D-expansion, sorted CD45- cells derived from 3D-perfusion culture after the same time (3 weeks) or a similar extent of proliferation (7-8 doublings) maintained a 4.3-fold higher clonogenicity and exhibited a superior differentiation capacity towards all typical mesenchymal lineages, with similar immunomodulatory function in vitro. Transcriptomic analysis performed on MSC from 5 donors validated the robustness of the process and indicated a reduced inter-donor variability as well as a significant upregulation of multipotency-related gene clusters following 3D-perfusion as compared to 2D expansion. The described system offers a model to study how factors of a 3D engineered niche may regulate MSC function and, by streamlining conventional labor-intensive processes, is prone to automation and scalability within closed bioreactor systems. Nucleated cells were isolated from 5 fresh human bone marrow aspirates by means of red blood cells lyses buffer and then were seeded into a 3D perfusion bioreactor system using a pure hydroxyapatite 3D scaffold and in conventional Petri dishes (2D). After culture for 19 days, cells from both systems were enzymatically retrieved and sorted using anti-CD45-coated magnetic beads. Total RNA was extracted from CD45- cells, QCed and hybridized to Affymetrix microarrays.

Project description:Commonly used monolayer cell cultures lack the capacity to provide a physiologically relevant environment for cell culture in terms of cell-cell architecture, extracellular matrix composition, and spatiotemporal delivery of key growth factors and small molecules, such as oxygen. Here, we describe a three-dimensional (3D) approach to cell culture in vitro, utilizing a bioreactor system designed to control oxygenation of 3D cancer cell cultures, in order to better mimic tumor microenvironments observed in vivo. We found transcriptomic differences in breast and ovarian cancer cell cultures grown in traditional monolayer cultures as compared to cultures grown in a Matrigel three-dimensional matrix. We also investigated the transcriptomes of 3D cultures grown in 21% O2, 3% O2, and a gradient of 3% O2 to 0% O2 using our bioreactor system. By controlling oxygen delivery, we observed differences in cell growth morphology and transcriptome regulation under the three conditions.

Project description:Disorders influencing bone form a major burden worldwide, with osteoporosis being the most common fracture-inducing bone disease. Currently, animal models are being utilized to develop and screen novel treatments. However, due to interspecies variations, different microenvironments, and ethical considerations, there is a need for a complex 3D bone model. This research aimed to perform a pilot study on developing a standardized representative bone model using a perfusion-based bioreactor, and to characterize the overall 3D bone proteomic profile. An immortalized human fetal osteoblastic cell line (hFOB1.19) was seeded on collagen scaffolds and cultured for 21 days in a perfusion bioreactor system and in static cultures. Different analyses allowed the monitoring of cell viability and compared morphological and proteome differences between both conditions. Scanning electron microscopy images suggested an altered cellular morphology within the bioreactor culture compared to the static cultures. A proteomic analysis identified a total of 1897 proteins and a total of 93 unique regulated proteins. Enrichment analyses of these proteins revealed seven significant pathways including TNF-alpha signaling pathway via NF-kB. These pathways also included hypoxia and epithelial-mesenchymal transition, where the EMT pathway was the most significant and indicated a reduction in cell motility within the bioreactor system on day 21. This preliminary study suggests that the U-CUP perfusion bioreactor is promising for further exploration of facilitating osteogenic differentiation induction in 3D cultures.

Project description:In vitro models of human liver functions are used across a diverse range of applications in preclinical drug development and disease modeling, with particular increasing interest in models that capture facets of liver inflammatory status. This study investigates how the interplay between biophysical and biochemical microenvironment cues influence phenotypic responses, including inflammation signatures, of primary human hepatocytes (PHH) cultured in a commercially available perfused bioreactor. A 3D printing-based alginate microwell system was designed to form thousands of hepatic spheroids in a scalable manner as a comparator 3D culture modality to the bioreactor. Soft, synthetic extracellular matrix (ECM) hydrogel scaffolds with biophysical properties mimicking features of liver were engineered to replace polystyrene scaffolds, and the biochemical microenvironment was modulated with a defined set of growth factors and signaling modulators. The supplemented media significantly increased tissue density, albumin secretion, and CYP3A4 activity but also upregulated inflammatory markers. Basal inflammatory markers were lower for cells maintained in ECM hydrogel scaffolds or spheroid formats than polystyrene scaffolds, while hydrogel scaffolds exhibited the most sensitive response to inflammation as assessed by multiplexed cytokine and RNA-seq analyses. Together, these engineered 3D liver microenvironments provide insights for probing human liver functions and inflammatory response in vitro.