RM
+
Light micrograph showing a semicircular canal ampulla (top) with an ampullary crista leading into the utricle that shows the utricle macula The bo
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 an immature utricle macula On the surface the hair cells have a large rounded nucleus The supporting basal cells have darker el
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 a semicircular canal located in the bony labyrinth of the inner ear The canal is delimited by squamous cells surrounded by
RM
+
Light micrograph showing semicircular ducts located in the bony labyrinth of the inner ear The canals are delimited by squamous cells surrounded by
RM
+
Light micrograph of the junction between the utricle (top showing the macula) and an ampulla of a semicircular canal (bottom showing a crista ampull
RM
+
Light micrograph of a cross-section of the cochlea of the inner ear showing from top to bottom the vestibular cochlear and tympanic ducts or scala
RM
+
Vestibular system Light micrograph showing the saccule with macula sacculi On the bone are nerve fibre fascicles of vestibulo cochlear nerve by JO
ED
+
Oyster toadfish (Opsanus tau) This is a bottom- dwelling fish that inhabits the coastal waters of eastern North America from Cape Cod USA to the C
RM
+
Light micrograph showing from top the join between a semicircular canal ampulla (with crista ampullaris) and utricle (with macula utriculi) a cross
RM
+
Light micrograph of a cross-section of the cochlea of the inner ear showing from top to bottom the vestibular cochlear and tympanic ducts or scala
RM
+
Light micrograph of the spiral-shaped cochlea showing in each section of the coiled duct the vestibular cochlear and tympanic ducts or scala tympa
RM
+
Light micrograph of a cross-section of the cochlea of the inner ear showing from top to bottom the vestibular cochlear and tympanic ducts or scala
RM
+
Light micrograph of a cross-section of the cochlea of the inner ear showing from top to bottom the vestibular cochlear and tympanic ducts or scala
RF
+
Young child doing downward dog yoga on crowded beach Chesterton Indiana United States by Cavan Images Krista Taylor
RM
+
Helicotrema of the inner ear light micrograph
RM
+
Cochlea light micrograph
RM
+
Organ of Corti light micrograph
ED
+
Acoustic nerve tumour Coloured axial (horizontal) magnetic resonance imaging (MRI) scan of the head of a patient with a tumour (red) on the acoustic
RM
+
Cochlea light micrograph
RM
+
Cochlea light micrograph
RM
+
Opened vocal cords illustration Photo by medicalgraphicsF1online
RM
+
Opened vocal cords illustration Photo by medicalgraphicsF1online
RM
+
Illustration showing the anatomical structure of the human ear Sound waves are collected by the ear pinna (at left) and pass down the auditory canal
RM
+
Inner ear sensory cells SEM
RM
+
Inner ear balance sensing SEM
RM
+
LM of a section through the cochlea of inner ear
RM
+
Inner ear False-colour scanning electron micrograph of bundles of ciliated hair cells (pink) situated in the macula utriculi within the human inner e
ED
+
Inner ear sensory cells Coloured scanning electron micrograph (SEM) of bundles of cilia (hair cells blue) situated in the macula utriculi within the
RM
+
Neurons confocal light micrograph
RM
+
Neurons confocal light micrograph
RM
+
Neuron Confocal light micrograph of a neuron (nerve cell red) from the vestibular area of the brain Glial cells (support cells) Ă‚are green The neu
RM
+
Vomiting Illustration of the human vomiting mechanism An impulse from the brain (within triangle) stimulates the vomiting centre (red) in the brains
RM
+
Ear anatomy Historical anatomical artwork of a human ear The main diagram (centre) shows the outer ear (pinna left) and the internal structure of t
RM
+
Motion sickness band worn on the wrist of a patient suffering from nausea Motion sickness is due to the effect of repetitive movement on the system o
RM
+
Auditory brainstem response equipment
RM
+
Astronaut training device
RM
+
A cantilevered chair at the China Science and Technology Museum in Beijing China designed to mimic an astronaut training device It is used to give
ED
+
Inner ear sensory cells Coloured scanning electron micrograph (SEM) of bundles of cilia (hair cells blue) situated in the macula utriculi within the
RM
+
Cat ear anatomy illustration
RM
+
Dog ear anatomy illustration
RM
+
Zebrafish inner ear and otoliths Coloured 3D micro-computed tomography (CT) scan of part of the skull inner ears and three pairs of otoliths of an a
RM
+
Weberian apparatus 3D micro-CT scan
RM
+
Female genitals 1866 illustration showing the blood supply (blue lines) and anatomy of the external female genitals that make up the vulva Fig I l
RM
+
Virgin and non-virgin vulva anatomy
RM
+
Female genitals 1866 illustration showing the anatomy of the internal and external female genitals Fig 1 vagina (centre) clitoris (upper centre)
RM
+
Virgin and non-virgin vulva anatomy 1866 illustration comparing the vulva (external reproductive organs) of a virgin (left) and non-virgin (right) fe
RM
+
Female genitals 1866 illustration showing the anatomy of the external female genitals that make up the vulva The vulva includes the labia majora mo
ED
+
Inner ear Coloured scanning electron micrograph of part of the macula sacculi in the sacculus a component of the organ of balance It consists of su
RM
+
Anatomical model of the inner ear At centre are the semicircular canals (loops) of the vestibular system which are responsible for balance The cana
RM
+
Inner ear anatomy Cut-away computer illustration showing the vestibular system of the inner ear The vestibular system is important for maintaining b
RM
+
Inner ear anatomy Cut-away computer illustration showing the vestibular system of the inner ear The vestibular system is important for maintaining b
RM
+
Brain tumour Coloured 3D computed tomography (CT) scan of a section through the head of a 37-year-old patient with a right vestibular schwannoma (aco
RM
+
Brain tumour Coloured 3D computed tomography (CT) scan of a section through the head of a 37-year-old patient with a right vestibular schwannoma (aco
RM
+
Ear and cochlear anatomy Illustration of the human ear (upper left) and successively expanded views of the anatomy of the cochlea the organ of heari
RM
+
Ear and cochlear anatomy Illustration of the human ear (upper left) and successively expanded views of the anatomy of the cochlea the organ of heari
RM
+
Damaged vestibular stereocilia artwork The vestibular system (part of the labyrinth of the inner ear) contributes to balance and provides the sense
RM
+
Vestibular stereocilia artwork The vestibular system (part of the labyrinth of the inner ear) contributes to balance and provides the sense of spati
RM
+
Coloured scanning electron micrograph (SEM) of Reissners membrane in the organ of Corti in the cochlear of the inner ear This membrane separates the
RM
+
Coloured scanning electron micrograph (SEM) of Reissners membrane in the organ of Corti in the cochlear of the inner ear This membrane separates the
RM
+
Oedema of larynx Artwork of sections through a larynx with and without swelling The bottom image shows a healthy larynx in transverse (axial) sectio
RM
+
Oedema of larynx Artwork of a transverse (axial) section through a larynx (seen from above) with and without swelling The bottom image shows a healt
RM
+
Oedema of larynx Artwork of a vertical (coronal) section through a larynx showing oedema (swelling caused by fluid accumulation) The swelling here
RM
+
Ampullary cupula Computer artwork showing how the ampullary cupula in the human vestibular system of the inner ear senses head rotation (top) and for
RM
+
Ampullary cupula Computer artwork of the ampullary cupula in the human vestibular system of the inner ear The vestibular system contributes to balan
RM
+
Ampullary cupula Computer artwork of the ampullary cupula in the human vestibular system of the inner ear The vestibular system contributes to balan
RM
+
Fish lateral line sense organ artwork In addition to the normal senses most fish also have a sensitive sense organ the lateral line system (red) I
RM
+
Vestibular ciliated cells Artwork of the anatomical structure and function of the vestibular ciliated cells found in the inner ear that help sense an
RM
+
Vestibular ciliated cells Diagram of the anatomical structure and function of the vestibular ciliated cells found in the inner ear that help sense an
RM
+
Ear artwork
RM
+
Squid sensory hair cells coloured scanning electron micrograph (SEM) These cells are from statocysts spherical structures found in squids and other
RM
+
Squid sensory hair cells coloured scanning electron micrograph (SEM) These cells are from statocysts spherical structures found in squids and other
RM
+
Squid sensory hair cells coloured scanning electron micrograph (SEM) These cells are from statocysts spherical structures found in squids and other
RF
+
Human ear anatomy computer artwork
RF
+
Female anatomy computer artwork
RM
+
Light micrograph of a rat embryo vestibule showing both maculae of utricule and saccule
RM
+
Light micrograph of sensory epithelium of the utricle macula showing two cell types basal supporting cells and large sensory hair cells Rat embryo i
RM
+
Light micrograph of the utricle macula of a rat embryo inner ear vestibule It appears as a thickening of the epithelium which shows two cell types b
RM
+
Cochlea light micrograph
RM
+
Cochlea light micrograph
RF
+
Inner ear sensory cells Coloured scanning electron micrograph (SEM) of bundles of cilia (hair cells pink) situated in the macula utriculi within the
RF
+
Inner ear sensory cells Coloured scanning electron micrograph (SEM) of bundles of cilia (hair cells pink) situated in the macula utriculi within the
RF
+
Inner ear sensory cells Coloured scanning electron micrograph (SEM) of bundles of cilia (hair cells purple) situated in the macula utriculi within t
RF
+
Neurologist performing the Romberg test on a female patient to test balance
RM
+
Axial section of the brain and inner ear Coloured T2-weighted magnetic resonance imaging (MRI) scan of an axial section of the brain The scan is cen
RM
+
Axial section of the brain and inner ear T2-weighted magnetic resonance imaging (MRI) scan of an axial section of the brain The scan is centred on t
RM
+
Vestibulo-ocular reflex (VOR) illustration This reflex shown here as neural pathways in the brain from the balance organs in the ear (the vestibula
RM
+
Labyrinthitis Illustration of the inner ear in a case of inflammation of the labyrinth that houses the vestibular system This condition is also know
RM
+
Inner ear anatomy Illustration of the anatomy of the sensory organs of the human inner ear The inner ear contains a maze of fluid-filled passages ca
RF
+
Cutaway diagram of human ear
RF
+
Microscopic view of the cochlea of the inner ear
RF
+
Anatomy of the organ of Corti part of the cochlea of the inner ear
RF
+
Medical illustration of endolymph in the membranous labyrinth of the inner ear
RF
+
Anatomy of the cochlear duct in the human ear
RM
+
Light micrograph showing a semicircular canal ampulla (top) with an ampullary crista leading into the utricle that shows the utricle macula The bo
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 an immature utricle macula On the surface the hair cells have a large rounded nucleus The supporting basal cells have darker el
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 a semicircular canal located in the bony labyrinth of the inner ear The canal is delimited by squamous cells surrounded by
105
0
https://www.afloimages.com/search/vestibular.html