UNTHSC Microscopy Core Facility Images


E. coli biofilm captured using flourescence on the Nikon Microphot FXA. 3D reconstruction using Voxblast. (25,920 bytes) SEM micrograph of the inner surface of the fallopian tube. Researcher: Robert Wordinger (16,401 bytes) Freeze fracture micrograph of the tight juctional complex beteween two urinary epithelial cells. Researcher: Thomas Yorio (11,692 bytes) 3D images of E. coli biofilm. Selected are is rotated and tilted then layers removed to expose deeper views using Voxblast. Researcher: Tony Romeo (51,887 bytes) Another selection of 3D images of an E. coli biofilm. Selection was tilted, rotated, and eroded using Voxblast. Researcher: Tony Romeo (106,223 bytes)
High Resolution tungsten metal shadowed TEM micrographs of the transmembrane erythrocyte protein Glycophorin A. Upper image shows both the amino acid chain(arrows) and the glycosylated end (arrowheads) which are on the cell surface. Researcher: Gary Wise (73,860 bytes) Localization of Glycophorin A on a freeze-fracture freeze-etch replica. Cells were stained with gold-wheat germ aggluttinin which attaches to the sialic acid residues in Glycophorin A. Researcher: Gary Wise (6,968 bytes) Nomarski image of a tissue culture cell captured digitally on the Nikon Microphot. Researcher: Patrick Cammarata (4,702 bytes) Basal view of skin equivalent. Researcher: Dan Dimitijevich (14,628 bytes) Food vacuole inside the synsytium of Physarum polycephalum. Researcher: lawrence Oakford (18,986 bytes)
Nomarski image of neuronal tissue culture cells. Researcher: Harold Sheedlo (10,776 bytes) 3D reconstruction of an image stack collected from the Nikon Microphot microscope. Recontruction was done using Voxblast. False colored by color (white=low) (blue=high). Researcher: Tony Romeo (19,847 bytes) Top view of reconstructed volume of an E. coli biofilm. Researcher: Tony Romeo (25,552 bytes) Tilted 3D recontruction of an image stack through an E. coli biofilm. Recontructon done in Voxblast. Researcher: Tony Romeo (162,353 bytes)  

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