RM
+
Light micrograph of an unstained iris showing the localisation of pigment cells in the iris pupillary border The pigment melanin is located in the po
RM
+
Ciliary body pigment light micrograph Unstained ciliary body (pars plicata) showing the location of pigment in the folds or ciliary processes (inne
RM
+
Ciliary body epithelium light micrograph The ciliary body is lined by a double-layered epithelium This unstained ciliary body epithelium clearly sh
RM
+
Light micrograph of the rear surface of an unstained iris showing the localisation of pigment cells The melanin pigment is concentrated in the rear s
RM
+
Light micrograph of the eye of an embryo showing from top left to bottom fused eyelids anterior chamber cornea posterior chamber and lens lined b
RM
+
Light micrograph of the inner layers of the eyeball showing from bottom the choroid stroma with blood vessels and pigment cells the choriocapillari
RM
+
Human ciliary body light micrograph Two ciliary processes lined by a double epithelial layer the non-pigmented inner epithelium and the pigmented e
RM
+
Light micrograph of the posterior surface of the iris showing the strongly pigmented anterior and posterior epithelia This section is near the iris p
RM
+
Light micrograph of the anterior surface of the iris lined by stromal fibroblasts and melanocytes It is one of the few body surfaces not lined by an
ED
+
Citrobacter rodentium-infected mouse colon Coloured scanning electron micrograph (SEM) showing gut microbiota (blue) Citrobacter bacteria (red) and
RM
+
Light micrograph of the layers of the eyeball showing from bottom the sclera the choroid with blood vessels and many pigment cells the choriocapil
RM
+
Human Iris light micrograph
RM
+
Light micrograph of a human retina From top to bottom the retina layers are nerve fibre layer ganglion cell layer inner plexiform layer inner nuc
RM
+
Light micrograph of a human eye showing the limit between the neural or photosensitive multi-layered retina (right) and the bilayered ora serrata
RM
+
Eye lens light micrograph Equator of the lens in a developing eye showing the transition from lens epithelium (top right corner) to lens fibres by
RM
+
Light micrograph of the layers of the eyeball showing from bottom the sclera the choroid stroma with blood vessels and many pigment cells the chor
RM
+
Light micrograph of an embryonic eye showing from bottom to top developing lens with lens fibres and anterior columnar simple epithelium Above the
RM
+
Light micrograph of the inner layers of the eyeball showing from bottom the sclera the choroid stroma with blood vessels and pigment cells the cho
RM
+
Light micrograph of an iris showing from left anterior non-epithelia surface bordered by stromal fibroblasts and melanocytes iris stroma with str
ED
+
Epithelial gonorrhoea infection Coloured scanning electron micrograph (SEM) of INeisseria gonorrhoeaei bacteria (clusters of small round cells) and
RM
+
Light micrograph of the ciliary body of the eye which is lined by a double-layered epithelium This micrograph clearly shows this double layer an in
RM
+
Light micrograph of eyeball showing its three layers separated by a retraction during sample processing From left bottom are the sclera pigmented ch
RM
+
Light micrograph of an unstained ciliary body of the eye showing the melanin granules in the pigmented cells of the ciliary body stroma by JOSE CALV
RM
+
Light micrograph of the eye showing from top the choroid stroma with blood vessels and pigment cells the choriocapillaris (a single layer of blood
RM
+
Light micrograph of the eye of an early albino rat embryo showing from left to right the optic cup with an outer layer (pigment epithelium without p
RM
+
Light micrograph of the developing eye of a rat embryo showing from top to bottom fused eyelids anterior chamber cornea posterior chamber and len
RM
+
Light micrograph of the developing eye of a rat embryo showing from top to bottom fused eyelids anterior chamber cornea posterior chamber and len
RM
+
Human sublingual gland Light micrograph showing an interlobular connective tissue tract with two excretory ducts lined by stratified columnar epithel
RM
+
Human sublingual gland light micrograph The sublingual gland is a mixed mucous gland consisting mostly of mucous acini capped with serous demilunes
ED
+
Epithelial gonorrhoea infection Coloured scanning electron micrograph (SEM) of INeisseria gonorrhoeaei bacteria (round red) on and round an epithe
RM
+
Human sublingual gland light micrograph The sublingual gland is a mixed mucous gland consisting mostly of mucous acini capped with serous demilunes
RM
+
Light micrograph of a canal of Hering or intrahepatic bile ductule in a pig liver These ducts are part of the outflow system of exocrine bile produ
RM
+
Light micrograph of a canal of Hering or intrahepatic bile ductule in a pig liver These ducts are part of the outflow system of exocrine bile produ
RM
+
Gastric mucosa light micrograph
RM
+
Gastric mucosa light micrograph
RM
+
Gastric mucosa light micrograph
RM
+
Light micrograph of a human oesophagus showing from top mucosa lined by a stratified squamous epithelium lamina propria muscularis mucosae submuc
RM
+
Light micrograph of the muscular layer of the esophagus This layer is unique in having a mixture of smooth muscle fibres and striated muscle fibres i
RM
+
Light micrograph of the muscular layer of the esophagus This layer is unique in having a mixture of smooth muscle fibres and striated muscle fibres i
ED
+
Epithelial gonorrhoea infection Coloured scanning electron micrograph (SEM) of INeisseria gonorrhoeaei bacteria (clusters of small round cells) and
RM
+
Light micrograph of human oesophagus mucosa showing the lining of stratified squamous epithelium lamina propria with blood vessels and muscularis muc
RM
+
Light micrograph of a human oesophagus showing from top mucosa lined by a stratified squamous epithelium lamina propria muscularis mucosae submuc
RM
+
Light micrograph of epididymal ducts lined by pseudostratified epithelium with tall columnar principal cells showing stereocilia and basal cells The
RM
+
Light micrograph of epididymal ducts lined by pseudostratified epithelium with tall columnar principal cells showing stereocilia and basal cells The
RM
+
Light micrograph of epididymal ducts lined by pseudostratified epithelium with tall columnar principal cells showing stereocilia and basal cells The
RM
+
Light micrograph of the ciliated pseudostratified columnar epithelium of the trachea (respiratory epithelium) The apical border of the epithelium has
RM
+
Light micrograph of epididymal ducts lined by pseudostratified columnar epithelium with tall columnar principal cells showing stereocilia and basal ce
RM
+
Light micrograph of epididymal ducts lined by pseudostratified epithelium with tall columnar principal cells showing stereocilia and basal cells The
RM
+
Light micrograph of human gingiva (gums) It is lined by a non-keratinised stratified squamous epithelium with long and complex rete ridges The conne
ED
+
Cell structure False-colour transmission electron micrograph of a single epithelial cell The epithelium is the tissue covering the bodys external s
RM
+
Light micrograph of the ciliated pseudostratified columnar epithelium of the trachea (respiratory epithelium) The apical border of the epithelium has
RM
+
Light micrograph of human gingiva (gums) showing the long and complex rete ridges existing in the base of the non-keratinised stratified squamous epit
RM
+
Light micrograph of a developing tooth in the bell stage of odontogenesis The tooth germ still joined to the surface epithelium shows from bottom
RM
+
Light micrograph of a developing tooth in the bell stage of odontogenesis The tooth germ still joined to the surface epithelium shows from bottom
RM
+
Light micrograph of a frontal section of the head of an embryo showing from top to bottom; skin with developing hair bulbs nasal cavities with the L
RM
+
Light micrograph showing the small intestine of a rat foetus The intestinal villi are already visible lined by a columnar epithelium by JOSE CALVO
RM
+
Light micrograph showing a developing maxillary sinus of a rat embryo Under the respiratory type pseudostratified columnar epithelium are many develo
RM
+
Rat embryo head light micrograph
RM
+
Light micrograph of a frontal section of the nasal cavity of a rat embryo showing the medial septum the nasal conchae or turbinate and at the top
ED
+
Barretts adenocarcinoma Endoscope view of a cancerous tumour (neoplasm far right) in the lower part of the oesophagus (gullet) of a 75 year-old pat
RM
+
Light micrograph of a developing tooth in the bell stage of odontogenesis The tooth germ still joined to the surface epithelium shows from bottom
RM
+
Light micrograph of a developing tooth in the bell stage of odontogenesis The tooth germ still joined to the surface epithelium shows from bottom
RM
+
Light micrograph of a developing tooth in the bell stage of odontogenesis The tooth germ still joined to the surface epithelium shows from bottom
RM
+
Light micrograph of a developing tooth in the bell stage of odontogenesis The tooth germ still joined to the surface epithelium shows from bottom
RM
+
Eye lens light micrograph Equator of the lens in a developing eye showing the transition from lens epithelium (top) to lens fibres by JOSE CALVO
RF
+
Illustration of inhaled pollen grains in a lung Pollen grains are allergens and can cause hay fever (allergic rhinitis) when inhaled They can also t
RF
+
Illustration of inhaled pollen grains in the windpipe (trachea) Pollen grains are allergens and can cause hay fever (allergic rhinitis) when inhaled
RF
+
Illustration of inhaled pollen grains in a lung Pollen grains are allergens and can cause hay fever (allergic rhinitis) when inhaled They can also t
RF
+
Illustration of inhaled pollen grains in the windpipe (trachea) Pollen grains are allergens and can cause hay fever (allergic rhinitis) when inhaled
ED
+
Macrophotograph of a 175 day old foetus of a rat still linked to the placenta (extreme right) The placenta is firmly attached to the uterine epithel
RF
+
Illustration of inhaled pollen grains on the nasal epithelium Pollen grains are allergens and can cause cause hay fever (allergic rhinitis) when inha
RF
+
Illustration of inhaled pollen grains on the nasal epithelium Pollen grains are allergens and can cause cause hay fever (allergic rhinitis) when inha
RM
+
Duodenum Light micrograph showing the Brunner glands located on the submucosa on a circular fold or Kerckring valve Brunners glands are compound t
RM
+
Duodenum Light micrograph showing the Brunner glands located on the submucosa on a circular fold or Kerckring valve Brunners glands are compound t
RM
+
Duodenum Light micrograph showing the Brunner glands located on the submucosa on a circular fold or Kerckring valve Brunners glands are compound t
RM
+
Bottom of a palatine tonsil crypt light micrograph The crypt is lined by stratified squamous epithelium showing lymphoid follicles with germinal cen
RM
+
Light micrograph of the opening to the mouth (right) of a palatine tonsil crypt The crypt is lined by stratified squamous epithelium showing lymphoid
RM
+
Light micrograph of a palatine tonsil crypt lined by stratified squamous epithelium showing lymphoid follicles with germinal centres in the lamina pr
RM
+
Transmission electron micrograph (TEM) of an epidermis spinous layer The keratinocytes show polygonal shapes a central nucleus with nucleolus cytop
ED
+
False-colour scanning electron micrograph (SEM) of the internal lining or epithelium of the bronchial passages in the human lung Clumps of fine hai
RF
+
Enterocyte illustration by ALI DAMOUHSCIENCE PHOTO LIBRARY
RF
+
Intestine epithelium illustration by ALI DAMOUHSCIENCE PHOTO LIBRARY
RF
+
Enterocyte illustration by ALI DAMOUHSCIENCE PHOTO LIBRARY
RM
+
Trachea lining SEM
RM
+
Developing inner ear of an embryo light micrograph The bony labyrinth is still in the cartilaginous phase Two components of the vestibular system (
RM
+
Light micrograph of a semicircular canal ampulla delimited by squamous cells and surrounded by perilymphatic space At bottom is an ampullary cristae
RM
+
Light micrograph showing from right the ear canal lined by squamous stratified epithelium the eardrum or tympanic membrane with the insertion of
RM
+
Eardrum light micrograph
RM
+
Light micrograph of oesophageal squamous cells The squamous cells have distinct and roughly polygonal borders (dark pink lines) between each other T
ED
+
Embryonic stem cells Confocal light micrograph of dividing stem cells from the ventricular zone of the retina of a developing embryo The ventricular
RM
+
Light micrograph of squamous cells Squamous cells line the skin and other mucosal surfaces in the body This image shows a layer of squamous cells cu
RM
+
Light micrograph of squamous cells The cells are polygonal in shape with centrally located nuclei (round dark purple dots) The cells are connected b
RM
+
Small bowel Paneth cells light micrograph
RM
+
Light micrograph of the epithelial cells lining the luminal spaces of a seminal vesicle The epithelium forms complex infoldings within the luminal sp
RM
+
Light micrograph of respiratory epithelium basal cells This immunohistochemical stain for p40 protein colours the basal cells brown showing them at
RM
+
Light micrograph of respiratory epithelium cut tangentially The cells of the epithelium (surface lining) are filled with mucinous substance (pale wh
RM
+
Light micrograph of an oesophagus papilla cross section The squamous cells of the oesophagus epithelium (lining layer) form projections called papill
RM
+
Light micrograph of a corpus amylaceous which is a kind of body found inside normal prostate glands The corpus amylaceous is seen within a prostate
RM
+
Light micrograph of a corpus amylaceous which is a kind of body found inside normal prostate glands The roughly round corpus amylaceous is seen abov
ED
+
False-colour scanning electron micrograph (SEM) of the internal lining or epithelium of the bronchial passages in the human lung Clumps of fine hai
4047
0
https://www.afloimages.com/search/epithelium.html