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process rates and genes that are differentially expressed in genome-sequenced marine model bacteria and natural marine bacterial assemblages. Analyses will involve state-of-the-art techniques in microbial
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, inflammation, and disease resolution, using the joint as a model system. To maximise the impact of tissue discoveries, our lab follows a bedside-to-bench-and-back scientific approach, in which human and mouse
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that are differentially expressed in genome-sequenced marine model bacteria and natural marine bacterial assemblages. Analyses will involve state-of-the-art techniques in microbial ecology and molecular biology (e.g. gene
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model of the Inspection Testbed. Use CS Ontology elements or add new elements if necessary. Include requirements, verifications and traceability. Include resilience KPIs in the model. Upload the model
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of academia and industry, driving projects that translate innovative science into novel cancer therapies. Key Responsibilities Conduct standard cell biology techniques, including 2D and 3D culture systems and
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) We are recruiting 2 Research Assistants (RA) to pursue highly collaborative and interdisciplinary projects of developing new cancer immunotherapy, using novel 3D tumor organoid models and 3D single
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with cell culture, 3D models and in vitro assays. Experience in phototherapy, programming and large data analysis is a plus. Excellent communication skills and fluency in English (written and oral). Our
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this, the TUNIC project aims to develop a 3D tumour-on-chip (ToC) model incorporating primary neutrophils, tumour cells, and CD8+ T cells. This model will investigate the direct and indirect killing capacities
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the experimental development of an approach to the 3D characterization of organic crystals. The approach is based on thermo-microscopy, combined with multidirectional observation, allowing for in situ, 3D
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characterize in-vitro vasculature-on-chip models. To create the vascular networks, we will use a proven concept of 3D printing and angiogenesis. With our previously developed sugar 3D printing technique, we can