Fraud Blocker Skip to main content

Hair Cell Collection

"Hair Cells: The Sensory Powerhouses of the Inner Ear" Ampullary cupula, artwork: Delicate structures that detect motion and help maintain balance in our inner ear

Background imageHair Cell Collection: Ampullary cupula, artwork

Ampullary cupula, artwork
Ampullary cupula. Computer artwork showing how the ampullary cupula in the human vestibular system of the inner ear senses head rotation (top) and forward motion (bottom)

Background imageHair Cell Collection: Structure of the cochlea, artwork

Structure of the cochlea, artwork
Structure of the cochlea. Computer artwork of a section through the organ of Corti, the auditory sense organ that lines the spiral of the cochlea in the inner ear

Background imageHair Cell Collection: False-colour SEM of hair cells in the inner ear

False-colour SEM of hair cells in the inner ear
Inner ear. False-colour scanning electron micrograph of hair cells (yellow) which are part of the Organ of Corti in the inner ear

Background imageHair Cell Collection: Organ of Corti, SEM

Organ of Corti, SEM
Organ of Corti. Coloured scanning electron micrograph (SEM) view of the top surface of the organ of Corti in the cochlea of the inner ear

Background imageHair Cell Collection: Fish lateral line sense organ, artwork

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)

Background imageHair Cell Collection: Sensory hair cell in the ear, artwork

Sensory hair cell in the ear, artwork
Sensory hair cell in the ear. Artwork showing a section through part of the cochlea, the inner ears auditory sense organ. The hair-like cells (grey) at upper centre are stereocilia

Background imageHair Cell Collection: Sensory hair cells in ear, SEM

Sensory hair cells in ear, SEM

Background imageHair Cell Collection: Vestibular ciliated cells, diagram

Vestibular ciliated cells, diagram
Vestibular ciliated cells. Diagram of the anatomical structure and function of the vestibular ciliated cells found in the inner ear that help sense and control of balance

Background imageHair Cell Collection: Vestibular ciliated cells, artwork

Vestibular ciliated cells, artwork
Vestibular ciliated cells. Artwork of the anatomical structure and function of the vestibular ciliated cells found in the inner ear that help sense and control of balance

Background imageHair Cell Collection: Herb oil glands, SEM

Herb oil glands, SEM
Herb oil glands. Coloured scanning electron micrograph (SEM) of the underside of a thyme (Thymus vulgaris) leaf, showing the modified trichomes (hair cells, round)

Background imageHair Cell Collection: Squid sensory hair cells, SEM

Squid sensory hair cells, SEM
Squid sensory hair cells, coloured scanning electron micrograph (SEM)

Background imageHair Cell Collection: Human ear anatomy, artwork

Human ear anatomy, artwork
Human ear anatomy. Computer artwork of the structure of the human ear, showing the outer ear, middle ear and inner ear

Background imageHair Cell Collection: Ivy stem, SEM

Ivy stem, SEM
Ivy stem. Coloured scanning electron micrograph (SEM) of the surface of an ivy plant stem


All products are expertly crafted, using premium materials, tailored to your specifications and promptly shipped

"Hair Cells: The Sensory Powerhouses of the Inner Ear" Ampullary cupula, artwork: Delicate structures that detect motion and help maintain balance in our inner ear. Structure of the cochlea, artwork: A spiral-shaped organ responsible for converting sound vibrations into electrical signals through its hair cells. Ampullary cupula, artwork: These specialized hair cells play a crucial role in detecting changes in head position and movement. Inner ear hair cells, SEM: Magnified view reveals the intricate structure of these sensory receptors that enable us to hear and perceive sound waves. Sensory hair cells in ear, SEM: Close-up image showcasing the remarkable sensitivity and complexity of these tiny hairs responsible for our auditory perception. False-color SEM of hair cells in the inner ear: Vibrant colors enhance our understanding of how different types of hair cells contribute to hearing and balance functions. Organ of Corti, SEM: This microscopic marvel within the cochlea contains rows upon rows of sensory hair cells that transform sound vibrations into electrical impulses for interpretation by our brain. Fish lateral line sense organ, artwork: Hair cell clusters found along fish's bodies allow them to sense water movements and navigate their aquatic environment effectively. Sensory hair cell in the ear, artwork: An artistic representation highlighting one single sensory receptor responsible for transmitting auditory information to our brain with astonishing precision. 10-12. Sensory hair cells in ear, SEM (repeated): Scanning electron microscopy captures stunning details as we explore further into this intricate world where countless sensory hairs work together harmoniously to provide us with an extraordinary sense - hearing.

© Copyright Media Storehouse, All Rights Reserved 2003 - 2024
Facebook     Pinterest     100% Payment Secure     Reviews IO