In a paper put into advance of printing in the Feb online. 13 problem of the journal Cell Reviews, the UO team implies that two molecular pathways function in concert to permit adult zebra seafood to properly replace bones dropped upon fin amputation. One pathway resets existing bone cells to a developmental stem cell-like state and supports their development to displace lost cells. The next directs the shaped cells to turn back to functional newly, arranged bone. Using genetic, molecular and cellular techniques, the authors detailed the way the opposing pathways cross-connect to keep carefully the regenerative procedure in balance. Unlike human beings, some vertebrates, including zebra seafood, have amazing innate capabilities to regenerate dropped appendages and organs, said co-writer Kryn Stankunas, a professor of biology and person in the UO Institute of Molecular Biology.Register using the e-mail form in the proper column now, and you’ll be emailed show details. Register Today! Cytation3 was among three winning items announced at the exhibition on September 25, 2013. Cytation3 combines automated digital microscopy and standard microplate multi-mode recognition to provide both wealthy phenotypic and well-centered quantitative analyses in a streamlined workflow. This original, patent pending design is fantastic for both biochemical and cell-based assays, and its own modular architecture enables users to choose the modes they want now, and easily update as their requirements evolve. Related StoriesJumping genes: a marker for early cancer medical diagnosis? An interview with Dr KazazianLinkam levels used in the Wolfson Bioimaging Service at the University of Bristol within the endocytic sorting analysis of Dr Paul VerkadeScalable creation of gene therapy vectors: an interview with Frank UbagsThe imaging setting includes multi-channel wide-field fluorescence and brightfield forms, using high-strength LED light onboard and sources filter cubes.