67 results filtered with: Clusters
- Digital Images
- Online
Prostate cancer cell spheroid, LM
Dr Khuloud T. Al-Jamal- Digital Images
- Online
Highly invasive human paediatric brain tumour derived cells
Valeria Molinari, Louise Howell, Maria Vinci, Katy Taylor and Chris Jones, Institute of Cancer Research- Digital Images
- Online
Neurone development, embryoid body
John Grady, Doug Turnbull, Claudia Racca, Newcastle University- Digital Images
- Online
Neurone development, embryoid body
John Grady, Doug Turnbull, Claudia Racca, Newcastle University- Digital Images
- Online
Early mouse embryo preimplantation, LM
Rajeev Samarage, Melanie White, Andreas Fouras and Nicolas Plachta, Monash University- Digital Images
- Online
Prostate cancer cells treated with nano sized drug carriers
Khuloud T. Al-Jamal & Izzat Suffian- Digital Images
- Online
Breast cancer cell, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
Mouse embryonic stem cells
Jenny Nichols- Digital Images
- Online
Cellular architecture of normal human skin imaged by whole mount tissue microscopy. Human skin has a rich network of white blood cells (specifically dendritic cells, T cells and macrophages) which form sheaths around blood vessels. This image was taken less than 20 micrometres beneath the junction that joins the dermal and epidermal layers of the skin (dermo-epidermal junction). At this level, dendritic cells (stained for CD11c; green) form clusters around and between blood capillary loops (stained for CD31; red). The blind-ended tips of initial lymphatic vessels are just visible (stained for LYVE-1; blue) at this level. This normal cellular architecture is grossly disrupted in diseased skin (see related images). Scale bar (white) represents 200 micrometres.
Dr. Xiao-nong Wang, Human Dendritic Cell Laboratory, Newcastle University- Digital Images
- Online
HeLa cell, immortal human epithelial cancer cell line, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
Cellular architecture of normal human skin imaged by whole mount tissue microscopy. Human skin has a rich network of white blood cells (specifically dendritic cells, T cells and macrophages) which form sheaths around blood vessels. In this image, T cells (stained for CD3; red) dendritic cells (stained for MHC class II; green) and macrophages (stained for LYVE-1; blue with some cells showing a tinge of green) can be seen. Cell nuclei have been stained with DAPI (grey). This normal cellular architecture is grossly disrupted in diseased skin (see related images). X10 magnification. Scale bar (white) represents 200 micrometres.
Dr. Xiao-nong Wang, Human Dendritic Cell Laboratory, Newcastle University- Digital Images
- Online
HeLa cell, immortal human epithelial cancer cell line, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
HeLa cell, immortal human epithelial cancer cell line, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
Prostate cancer cells treated with nano sized drug carriers
Khuloud T. Al-Jamal & Houmam Kafa- Digital Images
- Online
Cellular architecture of normal human skin imaged by whole mount tissue microscopy. Human skin has a rich network of white blood cells (specifically dendritic cells, T cells and macrophages) which form sheaths around blood vessels. In this image, T cells (stained for CD3; red) dendritic cells (stained for MHC class II; green) and macrophages (stained for LYVE-1; blue with some cells showing a tinge of green) can be seen. Cell nuclei have been stained with DAPI (grey). This normal cellular architecture is grossly disrupted in diseased skin (see related images). X20 magnification. Scale bar (white) represents 100 micrometres.
Dr. Xiao-nong Wang, Human Dendritic Cell Laboratory, Newcastle University- Digital Images
- Online
3D depth-coloured transparent mouse mammary gland
Felicity Davis, Bethan Lloyd-Lewis and Christine Watson; University of Cambridge- Digital Images
- Online
Breast cancer cell, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
Cellular architecture of normal human skin imaged by whole mount tissue microscopy. Human skin has a rich network of white blood cells (specifically dendritic cells, T cells and macrophages) which form sheaths around blood vessels. This image was taken directly beneath the junction that joins the dermal and epidermal layers of the skin (dermo-epidermal junction). At this level, the capillary network (stained for CD31; red) is visualised against a lawn of autofluorescent dermal papillae (finger-like projections of the dermis; green) scattered with dendritic cells (stained for CD11c; green) and macrophages (stained for LYVE-1; blue). This normal cellular architecture is grossly disrupted in diseased skin (see related images). Scale bar (white) represents 200 micrometres.
Dr. Xiao-nong Wang, Human Dendritic Cell Laboratory, Newcastle University- Digital Images
- Online
Pancreatic cancer cells grown in culture, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
Cellular architecture of normal human skin imaged by whole mount tissue microscopy. Human skin has a rich network of white blood cells (specifically dendritic cells, T cells and macrophages) which form sheaths around blood vessels. In this image, blood vessels (string-like structures stained for CD31; green), lymphatic vessels (ribbon-like structures stained for LYVE-1; blue) and T cells (stained for CD3; red) can be seen. T cells are only found around dermal blood vessels. Macrophages (stained for LYVE-1; blue) are also present. This normal cellular architecture is grossly disrupted in diseased skin (see related images). X10 magnification. Scale bar (white) represents 200 micrometres.
Dr. Xiao-nong Wang, Human Dendritic Cell Laboratory, Newcastle University- Digital Images
- Online
Mouse embryonic stem cells
Jenny Nichols- Digital Images
- Online
Pancreatic cancer cells grown in culture, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
HeLa cell, immortal human epithelial cancer cell line, SEM
Anne Weston, Francis Crick Institute- Digital Images
- Online
Highly invasive human paediatric brain tumour derived cells
Valeria Molinari, Louise Howell, Maria Vinci, Katy Taylor and Chris Jones, Institute of Cancer Research- Digital Images
- Online
HeLa cell, immortal human epithelial cancer cell line, SEM
Anne Weston, Francis Crick Institute