- published: 25 Jan 2022
- views: 427984
Cochlear cupula
The cochlear cupula is a structure in the cochlea. It is the apex of the cochlea. The bony canal of the cochlea takes two and three-quarter turns around the modiolus. The modiolus is about 30 mm. in length, and diminishes gradually in diameter from the base to the summit, where it terminates in the cupula.
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Cochlear_cupula
Podcasts:
-
The Vestibular System, Animation
Anatomy and physiology (A&P;) of the vestibular system - the organ of equilibrium or balance. The 3 semicircular canals that sense rotational (angular) accelerations, and 2 otolith organs - saccule and utricle - that sense head positions and linear motions. Purchase a license to download a non-watermarked version of this video on AlilaMedicalMedia(dot)com Check out our new Alila Academy - AlilaAcademy(dot)com - complete video courses with quizzes, PDFs, and downloadable images. ©Alila Medical Media. All rights reserved. Voice by : Marty Henne All images/videos by Alila Medical Media are for information purposes ONLY and are NOT intended to replace professional medical advice, diagnosis or treatment. Always seek the advice of a qualified healthcare provider with any questions you may h...
published: 25 Jan 2022 -
How the Inner Ear Balance System Works - Labyrinth Semicircular Canals
Video describes how the inner ear balance system works. The semicircular canals are shown along with corresponding head movements. PLEASE NOTE that this video is a simplification of what actually happens as well as angles used. For example, the video implies that the posterior semicircular canal is oriented perfectly between the ears and that head tilting ONLY stimulates the posterior canal. That is not technically true. The posterior (and superior) canals are actually angled 45 degrees from that shown in the video. Also the head tilt and nod actually stimulates BOTH these canals. But for the purposes of lay audience education, these complicating details were ignored. Dix-Hallpike maneuver is also shown at the end. For more information about BPPV: https://www.FauquierENT.net/bppv.htm Pe...
published: 15 Sep 2014 -
Inner ear Anatomy Animation : Cochlear component, Vestibular component, Semi-circular component
📌 𝐅𝐨𝐥𝐥𝐨𝐰 𝐨𝐧 𝐈𝐧𝐬𝐭𝐚𝐠𝐫𝐚𝐦:- https://www.instagram.com/drgbhanuprakash 📌𝗝𝗼𝗶𝗻 𝗢𝘂𝗿 𝗧𝗲𝗹𝗲𝗴𝗿𝗮𝗺 𝗖𝗵𝗮𝗻𝗻𝗲𝗹 𝗛𝗲𝗿𝗲:- https://t.me/bhanuprakashdr 📌𝗦𝘂𝗯𝘀𝗰𝗿𝗶𝗯𝗲 𝗧𝗼 𝗠𝘆 𝗠𝗮𝗶𝗹𝗶𝗻𝗴 𝗟𝗶𝘀𝘁:- https://linktr.ee/DrGBhanuprakash Inner ear Anatomy: Cochlear component, Vestibular component, Semi-circular component - Animation The structures of the inner ear are designed to convert the mechanical energy transmitted in the form of waves generated by surrounding objects into neuronal impulses (transduction) that can be interpreted as sound. Likewise, the inner ear also plays pivotal roles in maintaining postural balance and visual focus on a single object (gaze fixation). As a result, the inner ear (which consists of a series of interlinked cavities termed labyrinths) can be divided into three general parts: Cochlear componen...
published: 01 Feb 2020 -
Labyrinth: Structure and inner ear function (preview) - Human Anatomy | Kenhub
This is a sneak peek at our video about the bony and membranous structures of the labyrinth of the ear. Learn about the cochlear and vestibular system in the full version of our video tutorial: https://khub.me/lub0x Oh, are you struggling with learning anatomy? We created the ★ Ultimate Anatomy Study Guide ★ to help you kick some gluteus maximus in any topic. Completely free. Download yours today: https://khub.me/1lw5q To master this topic, click on the link and carry on watching the full video (available to Premium members): https://khub.me/lub0x ! Want to test your knowledge on the labyrinth? Take this quiz: https://khub.me/xalz7 Read more on anatomy, structure and function of the inner ear with our free article in order to learn and understand this essential part of the auditory and...
published: 15 Apr 2020 -
1.7 Step 7. Ampulla and features of the cochlea
These videos have been excerpted from Netter’s Video Dissection Modules on Student Consult. http://bit.ly/2oEt9CO Step 7 In this right temporal bone preparation, the anterior semicircular canal and the lateral semicircular canal can be identified. At one end of the anterior semicircular canal is a dilated region called the ampulla. Within the ampulla lies the portion of the membranous labyrinth containing the receptors for the semicircular duct. The cochlea can best be located by trimming away the bone on the medial anterior slope of the petrous ridge near the apex of the ridge. The obvious structures will be the partitions between individual spirals and the osseous spiral lamina. Seen here at the tip of the pointer,. It contains the spiral ganglion. Also obvious are large spaces on eith...
published: 09 Nov 2017 -
Chapter 19 General and Special Senses Part4
Vestibular and Auditory Systems
published: 08 Jan 2016 -
2-Minute Neuroscience: Vestibular System
The vestibular system is a sensory system that is essential to normal movement and equilibrium. In this video, I discuss the vestibular labyrinth---the primary structure of the vestibular system, which consists of the semicircular canals, ampullae, and otolith organs. All of these are essential to the vestibular system's ability to provide the brain with information about things like motion, head position, and spatial orientation. For an article (on my website) that explains the vestibular system, click this link: https://neuroscientificallychallenged.com/posts/know-your-brain-vestibular-system TRANSCRIPT: Welcome to 2 minute neuroscience, where I simplistically explain neuroscience topics in 2 minutes or less. In this installment I will discuss the vestibular system. The vestibular sy...
published: 02 Sep 2016 -
Special Senses | Inner Ear Anatomy
Official Ninja Nerd Website: https://ninjanerd.org Ninja Nerds! During this lecture Professor Zach Murphy will be teaching you about the anatomy of the inner ear. We discuss the structures of the inner ear including the vestibule, cochlea, and semicircular canals. We hope you enjoy this lecture and be sure to support us below! Join this channel to get access to perks: https://www.youtube.com/channel/UC6QYFutt9cluQ3uSM963_KQ/join APPAREL | We are switching merchandise suppliers. DONATE PATREON | https://www.patreon.com/NinjaNerdScience PAYPAL | https://www.paypal.com/paypalme/ninjanerdscience SOCIAL MEDIA FACEBOOK | https://www.facebook.com/NinjaNerdlectures INSTAGRAM | https://www.instagram.com/ninjanerdlectures TWITTER | https://twitter.com/ninjanerdsci @NinjaNerdSci DISCORD | ht...
published: 31 Jul 2017 -
The Vestibular System Endolymph Motion Demonstration
A brief overview of endolymph motion. For functional examples of vestibular inputs and corresponding eye movements see https://itunes.apple.com/app/avor/id497245573?mt=8
published: 16 Jan 2014 -
Vestibular System: Neuroanatomy Video Lab - Brain Dissections
Diagrams, models and skull preparations are used to describe the vestibular apparatus. The semicircular canals, saccule and utricle are described as well as transduction by the hair cells in the ampullae and maculae. Gross material emphasizes the nerve, vestibular nuclei and connections through the MLF to the abducens and oculomotor nuclei in the brain stem for coordinating eye and head movements with body position. Nystagmus, INO, the vestibulocular reflex, and caloric testing are explained. Connections above the midbrain are not discussed. This is 19 of a series of 26 videos to be viewed in the suggested order or intermixed with other curricular materials. The entire series can be accessed here: https://neurologicexam.med.utah.edu/a... The videos may be downloaded in various formats...
published: 09 Sep 2015
developed with YouTube
4:06
The Vestibular System, Animation
- Order: Reorder
- Duration: 4:06
- Uploaded Date: 25 Jan 2022
- views: 427984
Anatomy and physiology (A&P;) of the vestibular system - the organ of equilibrium or balance. The 3 semicircular canals that sense rotational (angular) accelerat...
Anatomy and physiology (A&P;) of the vestibular system - the organ of equilibrium or balance. The 3 semicircular canals that sense rotational (angular) accelerations, and 2 otolith organs - saccule and utricle - that sense head positions and linear motions.
Purchase a license to download a non-watermarked version of this video on AlilaMedicalMedia(dot)com
Check out our new Alila Academy - AlilaAcademy(dot)com - complete video courses with quizzes, PDFs, and downloadable images.
©Alila Medical Media. All rights reserved.
Voice by : Marty Henne
All images/videos by Alila Medical Media are for information purposes ONLY and are NOT intended to replace professional medical advice, diagnosis or treatment. Always seek the advice of a qualified healthcare provider with any questions you may have regarding a medical condition.
The vestibular system is responsible for the body’s equilibrium, it maintains balance and provides awareness of the body’s spatial orientation. Vestibular sensory organs detect changes in the head’s positions and movements, and transmit this information to various regions of the brain. Projections to the brainstem trigger reflex pathways that lead to compensatory actions to maintain stability or re-establish equilibrium, while projections to the cortex provide perception of gravity and movement.
Examples of vestibular reflex pathways include:
- the vestibulo-ocular reflex that controls eye muscles to keep visual objects in focus while the head is moving. It does so by moving the eyes in the opposite direction as the head.
- and the vestibulo-spinal reflex that senses a potential loss of balance and activates body muscles to keep the body from falling.
The sensory part of the vestibular system is located in the inner ear on each side of the body. It consists of 3 semicircular canals that sense rotational movements, such as when the head is turning, and 2 otolithic organs that sense head positions, as well as straight line motions, such as when riding in a car or an elevator.
The 3 semicircular canals, or ducts, are oriented approximately at a right angle to each other, each corresponding roughly to one of the 3 planes of motions: turning left and right, nodding up and down, and tilting to a side. They contain a fluid called endolymph. Each canal has an enlargement at one end called an ampulla. Within the ampulla, there are hair cells embedded in a gel-like structure named cupula that extends the entire height of the ampulla.
When the head turns, the ducts that are located on the same plane of motion rotate, but the fluid lags behind because of inertia. This causes the fluid to briefly move in the opposite direction as the head, and either push or pull on the cupula, bending the cilia on the hair cells, and thus activating them to send nerve impulses to the brain. The direction of the bend determines if the signals generated are excitatory or inhibitory. Because the 2 sides of the head are mirror images, a head turn generates excitatory signals on one side, and inhibitory signals on the other.
The 2 otolithic organs are 2 patches of hair cells oriented nearly perpendicular to each other: the saccule being vertical, and the utricle being horizontal. The cilia of these cells are embedded in a gel-like layer sprinkled with calcium carbonate crystals called otoconia, commonly known as “ear rocks”. The crystals add weight to the layer, pulling it down with gravity.
When the head is in upright position, the gelatinous layer bears down evenly on the cells of the utricle, the cilia remain straight and no signals are generated. On the vertical saccule, however, the heavy gel is pulled down by gravity at one end, bending the cilia, generating nerve impulses. The reverse is true when the head is horizontal. Other head positions are determined by a combination of signals coming from both organs.
Vestibular sensory organs detect not the motion itself, but changes in the rate of motion, specifically acceleration or deceleration. For example, when a person is sitting in a car that starts to move, the heavy gel-like layer of the utricle lags behind at first, bending the cilia back, activating the hair cells. The more sudden the car starts, the greater the stimulation. Once the car is in stable motion, the gel catches up with the rest of the tissue, and no activation results. Similar events occur in the saccule during an elevator ride up or down.
https://wn.com/The_Vestibular_System,_Animation
Anatomy and physiology (A&P;) of the vestibular system - the organ of equilibrium or balance. The 3 semicircular canals that sense rotational (angular) accelerations, and 2 otolith organs - saccule and utricle - that sense head positions and linear motions.
Purchase a license to download a non-watermarked version of this video on AlilaMedicalMedia(dot)com
Check out our new Alila Academy - AlilaAcademy(dot)com - complete video courses with quizzes, PDFs, and downloadable images.
©Alila Medical Media. All rights reserved.
Voice by : Marty Henne
All images/videos by Alila Medical Media are for information purposes ONLY and are NOT intended to replace professional medical advice, diagnosis or treatment. Always seek the advice of a qualified healthcare provider with any questions you may have regarding a medical condition.
The vestibular system is responsible for the body’s equilibrium, it maintains balance and provides awareness of the body’s spatial orientation. Vestibular sensory organs detect changes in the head’s positions and movements, and transmit this information to various regions of the brain. Projections to the brainstem trigger reflex pathways that lead to compensatory actions to maintain stability or re-establish equilibrium, while projections to the cortex provide perception of gravity and movement.
Examples of vestibular reflex pathways include:
- the vestibulo-ocular reflex that controls eye muscles to keep visual objects in focus while the head is moving. It does so by moving the eyes in the opposite direction as the head.
- and the vestibulo-spinal reflex that senses a potential loss of balance and activates body muscles to keep the body from falling.
The sensory part of the vestibular system is located in the inner ear on each side of the body. It consists of 3 semicircular canals that sense rotational movements, such as when the head is turning, and 2 otolithic organs that sense head positions, as well as straight line motions, such as when riding in a car or an elevator.
The 3 semicircular canals, or ducts, are oriented approximately at a right angle to each other, each corresponding roughly to one of the 3 planes of motions: turning left and right, nodding up and down, and tilting to a side. They contain a fluid called endolymph. Each canal has an enlargement at one end called an ampulla. Within the ampulla, there are hair cells embedded in a gel-like structure named cupula that extends the entire height of the ampulla.
When the head turns, the ducts that are located on the same plane of motion rotate, but the fluid lags behind because of inertia. This causes the fluid to briefly move in the opposite direction as the head, and either push or pull on the cupula, bending the cilia on the hair cells, and thus activating them to send nerve impulses to the brain. The direction of the bend determines if the signals generated are excitatory or inhibitory. Because the 2 sides of the head are mirror images, a head turn generates excitatory signals on one side, and inhibitory signals on the other.
The 2 otolithic organs are 2 patches of hair cells oriented nearly perpendicular to each other: the saccule being vertical, and the utricle being horizontal. The cilia of these cells are embedded in a gel-like layer sprinkled with calcium carbonate crystals called otoconia, commonly known as “ear rocks”. The crystals add weight to the layer, pulling it down with gravity.
When the head is in upright position, the gelatinous layer bears down evenly on the cells of the utricle, the cilia remain straight and no signals are generated. On the vertical saccule, however, the heavy gel is pulled down by gravity at one end, bending the cilia, generating nerve impulses. The reverse is true when the head is horizontal. Other head positions are determined by a combination of signals coming from both organs.
Vestibular sensory organs detect not the motion itself, but changes in the rate of motion, specifically acceleration or deceleration. For example, when a person is sitting in a car that starts to move, the heavy gel-like layer of the utricle lags behind at first, bending the cilia back, activating the hair cells. The more sudden the car starts, the greater the stimulation. Once the car is in stable motion, the gel catches up with the rest of the tissue, and no activation results. Similar events occur in the saccule during an elevator ride up or down.
2:10
How the Inner Ear Balance System Works - Labyrinth Semicircular Canals
- Order: Reorder
- Duration: 2:10
- Uploaded Date: 15 Sep 2014
- views: 1424470
Video describes how the inner ear balance system works. The semicircular canals are shown along with corresponding head movements. PLEASE NOTE that this video i...
Video describes how the inner ear balance system works. The semicircular canals are shown along with corresponding head movements. PLEASE NOTE that this video is a simplification of what actually happens as well as angles used. For example, the video implies that the posterior semicircular canal is oriented perfectly between the ears and that head tilting ONLY stimulates the posterior canal. That is not technically true. The posterior (and superior) canals are actually angled 45 degrees from that shown in the video. Also the head tilt and nod actually stimulates BOTH these canals. But for the purposes of lay audience education, these complicating details were ignored.
Dix-Hallpike maneuver is also shown at the end.
For more information about BPPV:
https://www.FauquierENT.net/bppv.htm
Perform Dix-Hallpike to determine what type of BPPV here (the full length video):
https://www.youtube.com/watch?v=wgWOmuB1VFY
Check out our online store for other ear/balance related products:
https://www.FauquierENT.net/store_ear.htm
POSTERIOR canal BPPV treated by Epley maneuver here:
https://www.youtube.com/watch?v=9SLm76jQg3g
POSTERIOR canal BPPV treated by Foster Half-Somersault here:
https://www.youtube.com/watch?v=Wez9SZJ7ABs
LATERAL canal BPPV treated by Lempert maneuver here:
https://www.youtube.com/watch?v=mwTmM6uF5yA
SUPERIOR canal BPPV treated by Deep Head-Hanging here:
https://www.youtube.com/watch?v=qw1QciZWfP0
Flowchart for BPPV diagnosis and treatment can be found here:
https://www.fauquierent.net/bppv1.htm
Video on Meniere's Disease:
https://www.youtube.com/watch?v=qrk7OyAB_ss
Free, fast, simple, and accurate online hearing test:
http://www.homehearingtest.net
Video produced by Dr. Chris Chang:
https://www.FauquierENT.net
Still haven’t subscribed to Fauquier ENT on YouTube? ►► https://bit.ly/35SazwA
#innerearbalance #labyrinth #dizziness #vertigo #medicalanimation #ent #innerearbalance
https://wn.com/How_The_Inner_Ear_Balance_System_Works_Labyrinth_Semicircular_Canals
Video describes how the inner ear balance system works. The semicircular canals are shown along with corresponding head movements. PLEASE NOTE that this video is a simplification of what actually happens as well as angles used. For example, the video implies that the posterior semicircular canal is oriented perfectly between the ears and that head tilting ONLY stimulates the posterior canal. That is not technically true. The posterior (and superior) canals are actually angled 45 degrees from that shown in the video. Also the head tilt and nod actually stimulates BOTH these canals. But for the purposes of lay audience education, these complicating details were ignored.
Dix-Hallpike maneuver is also shown at the end.
For more information about BPPV:
https://www.FauquierENT.net/bppv.htm
Perform Dix-Hallpike to determine what type of BPPV here (the full length video):
https://www.youtube.com/watch?v=wgWOmuB1VFY
Check out our online store for other ear/balance related products:
https://www.FauquierENT.net/store_ear.htm
POSTERIOR canal BPPV treated by Epley maneuver here:
https://www.youtube.com/watch?v=9SLm76jQg3g
POSTERIOR canal BPPV treated by Foster Half-Somersault here:
https://www.youtube.com/watch?v=Wez9SZJ7ABs
LATERAL canal BPPV treated by Lempert maneuver here:
https://www.youtube.com/watch?v=mwTmM6uF5yA
SUPERIOR canal BPPV treated by Deep Head-Hanging here:
https://www.youtube.com/watch?v=qw1QciZWfP0
Flowchart for BPPV diagnosis and treatment can be found here:
https://www.fauquierent.net/bppv1.htm
Video on Meniere's Disease:
https://www.youtube.com/watch?v=qrk7OyAB_ss
Free, fast, simple, and accurate online hearing test:
http://www.homehearingtest.net
Video produced by Dr. Chris Chang:
https://www.FauquierENT.net
Still haven’t subscribed to Fauquier ENT on YouTube? ►► https://bit.ly/35SazwA
#innerearbalance #labyrinth #dizziness #vertigo #medicalanimation #ent #innerearbalance
- published: 15 Sep 2014
- views: 1424470
13:09
Inner ear Anatomy Animation : Cochlear component, Vestibular component, Semi-circular component
- Order: Reorder
- Duration: 13:09
- Uploaded Date: 01 Feb 2020
- views: 744614
📌 𝐅𝐨𝐥𝐥𝐨𝐰 𝐨𝐧 𝐈𝐧𝐬𝐭𝐚𝐠𝐫𝐚𝐦:- https://www.instagram.com/drgbhanuprakash
📌𝗝𝗼𝗶𝗻 𝗢𝘂𝗿 𝗧𝗲𝗹𝗲𝗴𝗿𝗮𝗺 𝗖𝗵𝗮𝗻𝗻𝗲𝗹 𝗛𝗲𝗿𝗲:- https://t.me/bhanuprakashdr
📌𝗦𝘂𝗯𝘀𝗰𝗿𝗶𝗯𝗲 𝗧𝗼 𝗠𝘆 𝗠𝗮𝗶𝗹𝗶𝗻𝗴 𝗟𝗶𝘀𝘁:- ...
📌 𝐅𝐨𝐥𝐥𝐨𝐰 𝐨𝐧 𝐈𝐧𝐬𝐭𝐚𝐠𝐫𝐚𝐦:- https://www.instagram.com/drgbhanuprakash
📌𝗝𝗼𝗶𝗻 𝗢𝘂𝗿 𝗧𝗲𝗹𝗲𝗴𝗿𝗮𝗺 𝗖𝗵𝗮𝗻𝗻𝗲𝗹 𝗛𝗲𝗿𝗲:- https://t.me/bhanuprakashdr
📌𝗦𝘂𝗯𝘀𝗰𝗿𝗶𝗯𝗲 𝗧𝗼 𝗠𝘆 𝗠𝗮𝗶𝗹𝗶𝗻𝗴 𝗟𝗶𝘀𝘁:- https://linktr.ee/DrGBhanuprakash
Inner ear Anatomy: Cochlear component, Vestibular component, Semi-circular component - Animation
The structures of the inner ear are designed to convert the mechanical energy transmitted in the form of waves generated by surrounding objects into neuronal impulses (transduction) that can be interpreted as sound. Likewise, the inner ear also plays pivotal roles in maintaining postural balance and visual focus on a single object (gaze fixation). As a result, the inner ear (which consists of a series of interlinked cavities termed labyrinths) can be divided into three general parts:
Cochlear component that is concerned with hearing.
Vestibular component (comprised of the utricle and saccule) that deals with balance while stationary.
A semi-circular component that regulates balance while in motion.
The former is located anterior to the latter. The gross anatomical structures, their spatial relations, innervation, and blood supply will be discussed in this article.
#innerear #innerearanatomy #internalear #earanatomy #ear #anatomy #usmle #uworld #usmleanatomy
https://wn.com/Inner_Ear_Anatomy_Animation_Cochlear_Component,_Vestibular_Component,_Semi_Circular_Component
📌 𝐅𝐨𝐥𝐥𝐨𝐰 𝐨𝐧 𝐈𝐧𝐬𝐭𝐚𝐠𝐫𝐚𝐦:- https://www.instagram.com/drgbhanuprakash
📌𝗝𝗼𝗶𝗻 𝗢𝘂𝗿 𝗧𝗲𝗹𝗲𝗴𝗿𝗮𝗺 𝗖𝗵𝗮𝗻𝗻𝗲𝗹 𝗛𝗲𝗿𝗲:- https://t.me/bhanuprakashdr
📌𝗦𝘂𝗯𝘀𝗰𝗿𝗶𝗯𝗲 𝗧𝗼 𝗠𝘆 𝗠𝗮𝗶𝗹𝗶𝗻𝗴 𝗟𝗶𝘀𝘁:- https://linktr.ee/DrGBhanuprakash
Inner ear Anatomy: Cochlear component, Vestibular component, Semi-circular component - Animation
The structures of the inner ear are designed to convert the mechanical energy transmitted in the form of waves generated by surrounding objects into neuronal impulses (transduction) that can be interpreted as sound. Likewise, the inner ear also plays pivotal roles in maintaining postural balance and visual focus on a single object (gaze fixation). As a result, the inner ear (which consists of a series of interlinked cavities termed labyrinths) can be divided into three general parts:
Cochlear component that is concerned with hearing.
Vestibular component (comprised of the utricle and saccule) that deals with balance while stationary.
A semi-circular component that regulates balance while in motion.
The former is located anterior to the latter. The gross anatomical structures, their spatial relations, innervation, and blood supply will be discussed in this article.
#innerear #innerearanatomy #internalear #earanatomy #ear #anatomy #usmle #uworld #usmleanatomy
- published: 01 Feb 2020
- views: 744614
3:22
Labyrinth: Structure and inner ear function (preview) - Human Anatomy | Kenhub
- Order: Reorder
- Duration: 3:22
- Uploaded Date: 15 Apr 2020
- views: 86376
This is a sneak peek at our video about the bony and membranous structures of the labyrinth of the ear. Learn about the cochlear and vestibular system in the fu...
This is a sneak peek at our video about the bony and membranous structures of the labyrinth of the ear. Learn about the cochlear and vestibular system in the full version of our video tutorial: https://khub.me/lub0x
Oh, are you struggling with learning anatomy? We created the ★ Ultimate Anatomy Study Guide ★ to help you kick some gluteus maximus in any topic. Completely free. Download yours today: https://khub.me/1lw5q
To master this topic, click on the link and carry on watching the full video (available to Premium members): https://khub.me/lub0x !
Want to test your knowledge on the labyrinth? Take this quiz: https://khub.me/xalz7
Read more on anatomy, structure and function of the inner ear with our free article in order to learn and understand this essential part of the auditory and vestibular system: https://khub.me/s4awt
For more engaging video tutorials, interactive quizzes, articles and an atlas of Human anatomy and histology, go to https://khub.me/m3dgz
https://wn.com/Labyrinth_Structure_And_Inner_Ear_Function_(Preview)_Human_Anatomy_|_Kenhub
This is a sneak peek at our video about the bony and membranous structures of the labyrinth of the ear. Learn about the cochlear and vestibular system in the full version of our video tutorial: https://khub.me/lub0x
Oh, are you struggling with learning anatomy? We created the ★ Ultimate Anatomy Study Guide ★ to help you kick some gluteus maximus in any topic. Completely free. Download yours today: https://khub.me/1lw5q
To master this topic, click on the link and carry on watching the full video (available to Premium members): https://khub.me/lub0x !
Want to test your knowledge on the labyrinth? Take this quiz: https://khub.me/xalz7
Read more on anatomy, structure and function of the inner ear with our free article in order to learn and understand this essential part of the auditory and vestibular system: https://khub.me/s4awt
For more engaging video tutorials, interactive quizzes, articles and an atlas of Human anatomy and histology, go to https://khub.me/m3dgz
- published: 15 Apr 2020
- views: 86376
1:56
1.7 Step 7. Ampulla and features of the cochlea
- Order: Reorder
- Duration: 1:56
- Uploaded Date: 09 Nov 2017
- views: 1142
These videos have been excerpted from Netter’s Video Dissection Modules on Student Consult.
http://bit.ly/2oEt9CO
Step 7
In this right temporal bone preparati...
These videos have been excerpted from Netter’s Video Dissection Modules on Student Consult.
http://bit.ly/2oEt9CO
Step 7
In this right temporal bone preparation, the anterior semicircular canal and the lateral semicircular canal can be identified. At one end of the anterior semicircular canal is a dilated region called the ampulla. Within the ampulla lies the portion of the membranous labyrinth containing the receptors for the semicircular duct.
The cochlea can best be located by trimming away the bone on the medial anterior slope of the petrous ridge near the apex of the ridge. The obvious structures will be the partitions between individual spirals and the osseous spiral lamina. Seen here at the tip of the pointer,. It contains the spiral ganglion. Also obvious are large spaces on either side of the osseous spiral lamina that contain perilymph. The one anteromedial to the osseous spiral lamina is the scala vestibuli and the one posterolateral is the scala tympani.
Key Terms
• Anterior semicircular canal: the most anterior and superior of the three semicircular canals N95. It is a hollow arch with a thin, dense wall of bone. The canal houses the anterior semicircular duct N95 and protrudes upward to form the arcuate eminence on the petrous ridge. It lies in the same plane as the contralateral posterior semicircular canal N97. Its anterior end is dilated to accommodate the ampulla, and its posterior end joins the posterior canal to form a common bony limb.
• Lateral semicircular canal: the bony canal that houses the lateral semicircular duct. It is also called the horizontal canal, which indicates its orientation. The outer surface of the canal protrudes into the middle ear cavity where it forms the prominence of the lateral semicircular canal; here it lies just dorsal to the bony prominence of the facial canal N94. In terms of the oval window (and footplate of the stapes) it is useful to remember that the ventral to dorsal sequence is: oval window facial canal lateral semicircular canal. It is the ampulla of the canal that lies above the oval window N95.
• Semicircular ducts: the three endolymphatic fluid-filled ducts that are components of the membranous labyrinth N95. They have the same anterior, posterior and lateral designations as the canals they occupy. One end of each duct has a dilated region (ampulla) where the receptor cells are located. These cells are normally stimulated by motion of the receptors relative to that of the more static endolymphatic fluid. The signals sent to the vestibular nerve are essential to balance and equilibrium. The ducts lie in three different planes and the plane of the anterior canal aligns with the posterior canal of the opposite side. The two lateral canals are in the same horizontal plane.
• Ampulla (bony): dilation at one end of each of the bony semicircular canals, which is approximately twice the diameter of the canal N95. They each open into the bony vestibule.
• Ampulla (membranous): dilatations at one end of each of the membranous semicircular ducts N95 N96. The ampulla of each of the three bony canals encloses the membranous ampulla. The ampulla contains the cupula, a cluster of sensitive hair cells embedded in a gelatinous tissue containing embedded calcareous granules called otoliths. As the head moves in the plane of a given canal, motions of the fluid deflect the cupula to produce nerve impulses.
• Bony (osseous) labyrinth: the network of passages with bony walls lined with periosteum that surrounds the membranous labyrinth N95. It includes the semicircular canals, the cochlea, and the centrally located vestibule which connects to the other parts. It is lined with periosteum and contains perilymph, which lies between the walls of the bony labyrinth and the membranous labyrinth. It is named by analogy with the mythical maze that imprisoned the Minotaur.
ABOUT:
The project was made possible by several very dedicated faculty and staff at University of North Carolina, Chapel Hill--especially O.W. Henson and Noelle A. Granger--and partner schools, and by a grant from the Fund for the Improvement of Post-Secondary Education of the US Department of Education. This channel includes over 400 short videos highlighting the steps in a full-body human dissection in the gross anatomy lab. Each step is narrated and key structures labeled.
https://wn.com/1.7_Step_7._Ampulla_And_Features_Of_The_Cochlea
These videos have been excerpted from Netter’s Video Dissection Modules on Student Consult.
http://bit.ly/2oEt9CO
Step 7
In this right temporal bone preparation, the anterior semicircular canal and the lateral semicircular canal can be identified. At one end of the anterior semicircular canal is a dilated region called the ampulla. Within the ampulla lies the portion of the membranous labyrinth containing the receptors for the semicircular duct.
The cochlea can best be located by trimming away the bone on the medial anterior slope of the petrous ridge near the apex of the ridge. The obvious structures will be the partitions between individual spirals and the osseous spiral lamina. Seen here at the tip of the pointer,. It contains the spiral ganglion. Also obvious are large spaces on either side of the osseous spiral lamina that contain perilymph. The one anteromedial to the osseous spiral lamina is the scala vestibuli and the one posterolateral is the scala tympani.
Key Terms
• Anterior semicircular canal: the most anterior and superior of the three semicircular canals N95. It is a hollow arch with a thin, dense wall of bone. The canal houses the anterior semicircular duct N95 and protrudes upward to form the arcuate eminence on the petrous ridge. It lies in the same plane as the contralateral posterior semicircular canal N97. Its anterior end is dilated to accommodate the ampulla, and its posterior end joins the posterior canal to form a common bony limb.
• Lateral semicircular canal: the bony canal that houses the lateral semicircular duct. It is also called the horizontal canal, which indicates its orientation. The outer surface of the canal protrudes into the middle ear cavity where it forms the prominence of the lateral semicircular canal; here it lies just dorsal to the bony prominence of the facial canal N94. In terms of the oval window (and footplate of the stapes) it is useful to remember that the ventral to dorsal sequence is: oval window facial canal lateral semicircular canal. It is the ampulla of the canal that lies above the oval window N95.
• Semicircular ducts: the three endolymphatic fluid-filled ducts that are components of the membranous labyrinth N95. They have the same anterior, posterior and lateral designations as the canals they occupy. One end of each duct has a dilated region (ampulla) where the receptor cells are located. These cells are normally stimulated by motion of the receptors relative to that of the more static endolymphatic fluid. The signals sent to the vestibular nerve are essential to balance and equilibrium. The ducts lie in three different planes and the plane of the anterior canal aligns with the posterior canal of the opposite side. The two lateral canals are in the same horizontal plane.
• Ampulla (bony): dilation at one end of each of the bony semicircular canals, which is approximately twice the diameter of the canal N95. They each open into the bony vestibule.
• Ampulla (membranous): dilatations at one end of each of the membranous semicircular ducts N95 N96. The ampulla of each of the three bony canals encloses the membranous ampulla. The ampulla contains the cupula, a cluster of sensitive hair cells embedded in a gelatinous tissue containing embedded calcareous granules called otoliths. As the head moves in the plane of a given canal, motions of the fluid deflect the cupula to produce nerve impulses.
• Bony (osseous) labyrinth: the network of passages with bony walls lined with periosteum that surrounds the membranous labyrinth N95. It includes the semicircular canals, the cochlea, and the centrally located vestibule which connects to the other parts. It is lined with periosteum and contains perilymph, which lies between the walls of the bony labyrinth and the membranous labyrinth. It is named by analogy with the mythical maze that imprisoned the Minotaur.
ABOUT:
The project was made possible by several very dedicated faculty and staff at University of North Carolina, Chapel Hill--especially O.W. Henson and Noelle A. Granger--and partner schools, and by a grant from the Fund for the Improvement of Post-Secondary Education of the US Department of Education. This channel includes over 400 short videos highlighting the steps in a full-body human dissection in the gross anatomy lab. Each step is narrated and key structures labeled.
- published: 09 Nov 2017
- views: 1142
25:21
Chapter 19 General and Special Senses Part4
- Order: Reorder
- Duration: 25:21
- Uploaded Date: 08 Jan 2016
- views: 3117
Vestibular and Auditory Systems
Vestibular and Auditory Systems
https://wn.com/Chapter_19_General_And_Special_Senses_Part4
Vestibular and Auditory Systems
- published: 08 Jan 2016
- views: 3117
1:55
2-Minute Neuroscience: Vestibular System
- Order: Reorder
- Duration: 1:55
- Uploaded Date: 02 Sep 2016
- views: 720832
The vestibular system is a sensory system that is essential to normal movement and equilibrium. In this video, I discuss the vestibular labyrinth---the primary ...
The vestibular system is a sensory system that is essential to normal movement and equilibrium. In this video, I discuss the vestibular labyrinth---the primary structure of the vestibular system, which consists of the semicircular canals, ampullae, and otolith organs. All of these are essential to the vestibular system's ability to provide the brain with information about things like motion, head position, and spatial orientation.
For an article (on my website) that explains the vestibular system, click this link: https://neuroscientificallychallenged.com/posts/know-your-brain-vestibular-system
TRANSCRIPT:
Welcome to 2 minute neuroscience, where I simplistically explain neuroscience topics in 2 minutes or less. In this installment I will discuss the vestibular system.
The vestibular system is a sensory system responsible for providing our brain with information about motion, head position, and spatial orientation; it also is involved with motor functions that allow us to keep our balance, stabilize our head and body during movement, and maintain posture.
The main components of the vestibular system are found in the inner ear in a system of compartments called the vestibular labyrinth, which is continuous with the cochlea. The vestibular labyrinth contains the semicircular canals which are three tubes that are each situated in a plane in which the head can rotate. Each of the canals can detect one of the following head movements: nodding up and down, shaking side to side, or tilting left and right. The semicircular canals are filled with a fluid called endolymph. When the head is rotated, it causes the movement of endolymph through the canal that corresponds to the plane of the movement.
The endolymph flows into an expansion of the canal called the ampulla, within which there are hair cells, the sensory receptors of the vestibular system. At the top of each hair cell is a collection of small "hairs" called stereocilia. The movement of the endolymph causes movement of these stereocilia, which leads to the the release of neurotransmitters to send information about the plane of movement to the brain.
The vestibular system uses two other organs, known as the otolith organs, to detect forward and backward movements and gravitational forces. There are two otolith organs in the vestibular labyrinth: the utricle, which detects movement in the horizontal plane, and the saccule, which detects movement in the vertical plane. Within the utricle and saccule, hair cells detect movement when crystals of calcium carbonate called otoconia shift in response to it, leading to movement in the layers below the otoconia and displacement of hair cells.
REFERENCE:
Nolte J. The Human Brain: An Introduction to its Functional Anatomy. 6th ed. Philadelphia, PA. Elsevier; 2009.
https://wn.com/2_Minute_Neuroscience_Vestibular_System
The vestibular system is a sensory system that is essential to normal movement and equilibrium. In this video, I discuss the vestibular labyrinth---the primary structure of the vestibular system, which consists of the semicircular canals, ampullae, and otolith organs. All of these are essential to the vestibular system's ability to provide the brain with information about things like motion, head position, and spatial orientation.
For an article (on my website) that explains the vestibular system, click this link: https://neuroscientificallychallenged.com/posts/know-your-brain-vestibular-system
TRANSCRIPT:
Welcome to 2 minute neuroscience, where I simplistically explain neuroscience topics in 2 minutes or less. In this installment I will discuss the vestibular system.
The vestibular system is a sensory system responsible for providing our brain with information about motion, head position, and spatial orientation; it also is involved with motor functions that allow us to keep our balance, stabilize our head and body during movement, and maintain posture.
The main components of the vestibular system are found in the inner ear in a system of compartments called the vestibular labyrinth, which is continuous with the cochlea. The vestibular labyrinth contains the semicircular canals which are three tubes that are each situated in a plane in which the head can rotate. Each of the canals can detect one of the following head movements: nodding up and down, shaking side to side, or tilting left and right. The semicircular canals are filled with a fluid called endolymph. When the head is rotated, it causes the movement of endolymph through the canal that corresponds to the plane of the movement.
The endolymph flows into an expansion of the canal called the ampulla, within which there are hair cells, the sensory receptors of the vestibular system. At the top of each hair cell is a collection of small "hairs" called stereocilia. The movement of the endolymph causes movement of these stereocilia, which leads to the the release of neurotransmitters to send information about the plane of movement to the brain.
The vestibular system uses two other organs, known as the otolith organs, to detect forward and backward movements and gravitational forces. There are two otolith organs in the vestibular labyrinth: the utricle, which detects movement in the horizontal plane, and the saccule, which detects movement in the vertical plane. Within the utricle and saccule, hair cells detect movement when crystals of calcium carbonate called otoconia shift in response to it, leading to movement in the layers below the otoconia and displacement of hair cells.
REFERENCE:
Nolte J. The Human Brain: An Introduction to its Functional Anatomy. 6th ed. Philadelphia, PA. Elsevier; 2009.
- published: 02 Sep 2016
- views: 720832
21:50
Special Senses | Inner Ear Anatomy
- Order: Reorder
- Duration: 21:50
- Uploaded Date: 31 Jul 2017
- views: 594811
Official Ninja Nerd Website: https://ninjanerd.org
Ninja Nerds!
During this lecture Professor Zach Murphy will be teaching you about the anatomy of the inner e...
Official Ninja Nerd Website: https://ninjanerd.org
Ninja Nerds!
During this lecture Professor Zach Murphy will be teaching you about the anatomy of the inner ear. We discuss the structures of the inner ear including the vestibule, cochlea, and semicircular canals. We hope you enjoy this lecture and be sure to support us below!
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https://wn.com/Special_Senses_|_Inner_Ear_Anatomy
Official Ninja Nerd Website: https://ninjanerd.org
Ninja Nerds!
During this lecture Professor Zach Murphy will be teaching you about the anatomy of the inner ear. We discuss the structures of the inner ear including the vestibule, cochlea, and semicircular canals. We hope you enjoy this lecture and be sure to support us below!
Join this channel to get access to perks:
https://www.youtube.com/channel/UC6QYFutt9cluQ3uSM963_KQ/join
APPAREL |
We are switching merchandise suppliers.
DONATE
PATREON | https://www.patreon.com/NinjaNerdScience
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#ninjanerd #InnerEarAnatomy #EENT
- published: 31 Jul 2017
- views: 594811
3:13
The Vestibular System Endolymph Motion Demonstration
- Order: Reorder
- Duration: 3:13
- Uploaded Date: 16 Jan 2014
- views: 440637
A brief overview of endolymph motion. For functional examples of vestibular inputs and corresponding eye movements see https://itunes.apple.com/app/avor/id4972...
A brief overview of endolymph motion. For functional examples of vestibular inputs and corresponding eye movements see https://itunes.apple.com/app/avor/id497245573?mt=8
https://wn.com/The_Vestibular_System_Endolymph_Motion_Demonstration
A brief overview of endolymph motion. For functional examples of vestibular inputs and corresponding eye movements see https://itunes.apple.com/app/avor/id497245573?mt=8
- published: 16 Jan 2014
- views: 440637
32:13
Vestibular System: Neuroanatomy Video Lab - Brain Dissections
- Order: Reorder
- Duration: 32:13
- Uploaded Date: 09 Sep 2015
- views: 60684
Diagrams, models and skull preparations are used to describe the vestibular apparatus. The semicircular canals, saccule and utricle are described as well as tr...
Diagrams, models and skull preparations are used to describe the vestibular apparatus. The semicircular canals, saccule and utricle are described as well as transduction by the hair cells in the ampullae and maculae. Gross material emphasizes the nerve, vestibular nuclei and connections through the MLF to the abducens and oculomotor nuclei in the brain stem for coordinating eye and head movements with body position. Nystagmus, INO, the vestibulocular reflex, and caloric testing are explained. Connections above the midbrain are not discussed.
This is 19 of a series of 26 videos to be viewed in the suggested order or intermixed with other curricular materials. The entire series can be accessed here:
https://neurologicexam.med.utah.edu/a...
The videos may be downloaded in various formats by going here:
https://neurologicexam.med.utah.edu/a...
Password Request form for downloadable Neuroanatomy Brain Dissection videos here: https://library.med.utah.edu/neuro-exam/
https://wn.com/Vestibular_System_Neuroanatomy_Video_Lab_Brain_Dissections
Diagrams, models and skull preparations are used to describe the vestibular apparatus. The semicircular canals, saccule and utricle are described as well as transduction by the hair cells in the ampullae and maculae. Gross material emphasizes the nerve, vestibular nuclei and connections through the MLF to the abducens and oculomotor nuclei in the brain stem for coordinating eye and head movements with body position. Nystagmus, INO, the vestibulocular reflex, and caloric testing are explained. Connections above the midbrain are not discussed.
This is 19 of a series of 26 videos to be viewed in the suggested order or intermixed with other curricular materials. The entire series can be accessed here:
https://neurologicexam.med.utah.edu/a...
The videos may be downloaded in various formats by going here:
https://neurologicexam.med.utah.edu/a...
Password Request form for downloadable Neuroanatomy Brain Dissection videos here: https://library.med.utah.edu/neuro-exam/
- published: 09 Sep 2015
- views: 60684
4:06
The Vestibular System, Animation
Anatomy and physiology (A&P;) of the vestibular system - the organ of equilibrium or balanc...
published: 25 Jan 2022
The Vestibular System, Animation
The Vestibular System, Animation
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- published: 25 Jan 2022
- views: 427984
Anatomy and physiology (A&P;) of the vestibular system - the organ of equilibrium or balance. The 3 semicircular canals that sense rotational (angular) accelerations, and 2 otolith organs - saccule and utricle - that sense head positions and linear motions.
Purchase a license to download a non-watermarked version of this video on AlilaMedicalMedia(dot)com
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Voice by : Marty Henne
All images/videos by Alila Medical Media are for information purposes ONLY and are NOT intended to replace professional medical advice, diagnosis or treatment. Always seek the advice of a qualified healthcare provider with any questions you may have regarding a medical condition.
The vestibular system is responsible for the body’s equilibrium, it maintains balance and provides awareness of the body’s spatial orientation. Vestibular sensory organs detect changes in the head’s positions and movements, and transmit this information to various regions of the brain. Projections to the brainstem trigger reflex pathways that lead to compensatory actions to maintain stability or re-establish equilibrium, while projections to the cortex provide perception of gravity and movement.
Examples of vestibular reflex pathways include:
- the vestibulo-ocular reflex that controls eye muscles to keep visual objects in focus while the head is moving. It does so by moving the eyes in the opposite direction as the head.
- and the vestibulo-spinal reflex that senses a potential loss of balance and activates body muscles to keep the body from falling.
The sensory part of the vestibular system is located in the inner ear on each side of the body. It consists of 3 semicircular canals that sense rotational movements, such as when the head is turning, and 2 otolithic organs that sense head positions, as well as straight line motions, such as when riding in a car or an elevator.
The 3 semicircular canals, or ducts, are oriented approximately at a right angle to each other, each corresponding roughly to one of the 3 planes of motions: turning left and right, nodding up and down, and tilting to a side. They contain a fluid called endolymph. Each canal has an enlargement at one end called an ampulla. Within the ampulla, there are hair cells embedded in a gel-like structure named cupula that extends the entire height of the ampulla.
When the head turns, the ducts that are located on the same plane of motion rotate, but the fluid lags behind because of inertia. This causes the fluid to briefly move in the opposite direction as the head, and either push or pull on the cupula, bending the cilia on the hair cells, and thus activating them to send nerve impulses to the brain. The direction of the bend determines if the signals generated are excitatory or inhibitory. Because the 2 sides of the head are mirror images, a head turn generates excitatory signals on one side, and inhibitory signals on the other.
The 2 otolithic organs are 2 patches of hair cells oriented nearly perpendicular to each other: the saccule being vertical, and the utricle being horizontal. The cilia of these cells are embedded in a gel-like layer sprinkled with calcium carbonate crystals called otoconia, commonly known as “ear rocks”. The crystals add weight to the layer, pulling it down with gravity.
When the head is in upright position, the gelatinous layer bears down evenly on the cells of the utricle, the cilia remain straight and no signals are generated. On the vertical saccule, however, the heavy gel is pulled down by gravity at one end, bending the cilia, generating nerve impulses. The reverse is true when the head is horizontal. Other head positions are determined by a combination of signals coming from both organs.
Vestibular sensory organs detect not the motion itself, but changes in the rate of motion, specifically acceleration or deceleration. For example, when a person is sitting in a car that starts to move, the heavy gel-like layer of the utricle lags behind at first, bending the cilia back, activating the hair cells. The more sudden the car starts, the greater the stimulation. Once the car is in stable motion, the gel catches up with the rest of the tissue, and no activation results. Similar events occur in the saccule during an elevator ride up or down.
2:10
How the Inner Ear Balance System Works - Labyrinth Semicircular Canals
Video describes how the inner ear balance system works. The semicircular canals are shown ...
published: 15 Sep 2014
How the Inner Ear Balance System Works - Labyrinth Semicircular Canals
How the Inner Ear Balance System Works - Labyrinth Semicircular Canals
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- published: 15 Sep 2014
- views: 1424470
Video describes how the inner ear balance system works. The semicircular canals are shown along with corresponding head movements. PLEASE NOTE that this video is a simplification of what actually happens as well as angles used. For example, the video implies that the posterior semicircular canal is oriented perfectly between the ears and that head tilting ONLY stimulates the posterior canal. That is not technically true. The posterior (and superior) canals are actually angled 45 degrees from that shown in the video. Also the head tilt and nod actually stimulates BOTH these canals. But for the purposes of lay audience education, these complicating details were ignored.
Dix-Hallpike maneuver is also shown at the end.
For more information about BPPV:
https://www.FauquierENT.net/bppv.htm
Perform Dix-Hallpike to determine what type of BPPV here (the full length video):
https://www.youtube.com/watch?v=wgWOmuB1VFY
Check out our online store for other ear/balance related products:
https://www.FauquierENT.net/store_ear.htm
POSTERIOR canal BPPV treated by Epley maneuver here:
https://www.youtube.com/watch?v=9SLm76jQg3g
POSTERIOR canal BPPV treated by Foster Half-Somersault here:
https://www.youtube.com/watch?v=Wez9SZJ7ABs
LATERAL canal BPPV treated by Lempert maneuver here:
https://www.youtube.com/watch?v=mwTmM6uF5yA
SUPERIOR canal BPPV treated by Deep Head-Hanging here:
https://www.youtube.com/watch?v=qw1QciZWfP0
Flowchart for BPPV diagnosis and treatment can be found here:
https://www.fauquierent.net/bppv1.htm
Video on Meniere's Disease:
https://www.youtube.com/watch?v=qrk7OyAB_ss
Free, fast, simple, and accurate online hearing test:
http://www.homehearingtest.net
Video produced by Dr. Chris Chang:
https://www.FauquierENT.net
Still haven’t subscribed to Fauquier ENT on YouTube? ►► https://bit.ly/35SazwA
#innerearbalance #labyrinth #dizziness #vertigo #medicalanimation #ent #innerearbalance
13:09
Inner ear Anatomy Animation : Cochlear component, Vestibular component, Semi-circular component
📌 𝐅𝐨𝐥𝐥𝐨𝐰 𝐨𝐧 𝐈𝐧𝐬𝐭𝐚𝐠𝐫𝐚𝐦:- https://www.instagram.com/drgbhanuprakash
📌𝗝𝗼𝗶𝗻 𝗢𝘂𝗿 𝗧𝗲𝗹𝗲𝗴𝗿𝗮𝗺 𝗖𝗵𝗮𝗻𝗻...
published: 01 Feb 2020
Inner ear Anatomy Animation : Cochlear component, Vestibular component, Semi-circular component
Inner ear Anatomy Animation : Cochlear component, Vestibular component, Semi-circular component
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- published: 01 Feb 2020
- views: 744614
📌 𝐅𝐨𝐥𝐥𝐨𝐰 𝐨𝐧 𝐈𝐧𝐬𝐭𝐚𝐠𝐫𝐚𝐦:- https://www.instagram.com/drgbhanuprakash
📌𝗝𝗼𝗶𝗻 𝗢𝘂𝗿 𝗧𝗲𝗹𝗲𝗴𝗿𝗮𝗺 𝗖𝗵𝗮𝗻𝗻𝗲𝗹 𝗛𝗲𝗿𝗲:- https://t.me/bhanuprakashdr
📌𝗦𝘂𝗯𝘀𝗰𝗿𝗶𝗯𝗲 𝗧𝗼 𝗠𝘆 𝗠𝗮𝗶𝗹𝗶𝗻𝗴 𝗟𝗶𝘀𝘁:- https://linktr.ee/DrGBhanuprakash
Inner ear Anatomy: Cochlear component, Vestibular component, Semi-circular component - Animation
The structures of the inner ear are designed to convert the mechanical energy transmitted in the form of waves generated by surrounding objects into neuronal impulses (transduction) that can be interpreted as sound. Likewise, the inner ear also plays pivotal roles in maintaining postural balance and visual focus on a single object (gaze fixation). As a result, the inner ear (which consists of a series of interlinked cavities termed labyrinths) can be divided into three general parts:
Cochlear component that is concerned with hearing.
Vestibular component (comprised of the utricle and saccule) that deals with balance while stationary.
A semi-circular component that regulates balance while in motion.
The former is located anterior to the latter. The gross anatomical structures, their spatial relations, innervation, and blood supply will be discussed in this article.
#innerear #innerearanatomy #internalear #earanatomy #ear #anatomy #usmle #uworld #usmleanatomy
3:22
Labyrinth: Structure and inner ear function (preview) - Human Anatomy | Kenhub
This is a sneak peek at our video about the bony and membranous structures of the labyrint...
published: 15 Apr 2020
Labyrinth: Structure and inner ear function (preview) - Human Anatomy | Kenhub
Labyrinth: Structure and inner ear function (preview) - Human Anatomy | Kenhub
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- published: 15 Apr 2020
- views: 86376
This is a sneak peek at our video about the bony and membranous structures of the labyrinth of the ear. Learn about the cochlear and vestibular system in the full version of our video tutorial: https://khub.me/lub0x
Oh, are you struggling with learning anatomy? We created the ★ Ultimate Anatomy Study Guide ★ to help you kick some gluteus maximus in any topic. Completely free. Download yours today: https://khub.me/1lw5q
To master this topic, click on the link and carry on watching the full video (available to Premium members): https://khub.me/lub0x !
Want to test your knowledge on the labyrinth? Take this quiz: https://khub.me/xalz7
Read more on anatomy, structure and function of the inner ear with our free article in order to learn and understand this essential part of the auditory and vestibular system: https://khub.me/s4awt
For more engaging video tutorials, interactive quizzes, articles and an atlas of Human anatomy and histology, go to https://khub.me/m3dgz
1:56
1.7 Step 7. Ampulla and features of the cochlea
These videos have been excerpted from Netter’s Video Dissection Modules on Student Consult...
published: 09 Nov 2017
1.7 Step 7. Ampulla and features of the cochlea
1.7 Step 7. Ampulla and features of the cochlea
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- published: 09 Nov 2017
- views: 1142
These videos have been excerpted from Netter’s Video Dissection Modules on Student Consult.
http://bit.ly/2oEt9CO
Step 7
In this right temporal bone preparation, the anterior semicircular canal and the lateral semicircular canal can be identified. At one end of the anterior semicircular canal is a dilated region called the ampulla. Within the ampulla lies the portion of the membranous labyrinth containing the receptors for the semicircular duct.
The cochlea can best be located by trimming away the bone on the medial anterior slope of the petrous ridge near the apex of the ridge. The obvious structures will be the partitions between individual spirals and the osseous spiral lamina. Seen here at the tip of the pointer,. It contains the spiral ganglion. Also obvious are large spaces on either side of the osseous spiral lamina that contain perilymph. The one anteromedial to the osseous spiral lamina is the scala vestibuli and the one posterolateral is the scala tympani.
Key Terms
• Anterior semicircular canal: the most anterior and superior of the three semicircular canals N95. It is a hollow arch with a thin, dense wall of bone. The canal houses the anterior semicircular duct N95 and protrudes upward to form the arcuate eminence on the petrous ridge. It lies in the same plane as the contralateral posterior semicircular canal N97. Its anterior end is dilated to accommodate the ampulla, and its posterior end joins the posterior canal to form a common bony limb.
• Lateral semicircular canal: the bony canal that houses the lateral semicircular duct. It is also called the horizontal canal, which indicates its orientation. The outer surface of the canal protrudes into the middle ear cavity where it forms the prominence of the lateral semicircular canal; here it lies just dorsal to the bony prominence of the facial canal N94. In terms of the oval window (and footplate of the stapes) it is useful to remember that the ventral to dorsal sequence is: oval window facial canal lateral semicircular canal. It is the ampulla of the canal that lies above the oval window N95.
• Semicircular ducts: the three endolymphatic fluid-filled ducts that are components of the membranous labyrinth N95. They have the same anterior, posterior and lateral designations as the canals they occupy. One end of each duct has a dilated region (ampulla) where the receptor cells are located. These cells are normally stimulated by motion of the receptors relative to that of the more static endolymphatic fluid. The signals sent to the vestibular nerve are essential to balance and equilibrium. The ducts lie in three different planes and the plane of the anterior canal aligns with the posterior canal of the opposite side. The two lateral canals are in the same horizontal plane.
• Ampulla (bony): dilation at one end of each of the bony semicircular canals, which is approximately twice the diameter of the canal N95. They each open into the bony vestibule.
• Ampulla (membranous): dilatations at one end of each of the membranous semicircular ducts N95 N96. The ampulla of each of the three bony canals encloses the membranous ampulla. The ampulla contains the cupula, a cluster of sensitive hair cells embedded in a gelatinous tissue containing embedded calcareous granules called otoliths. As the head moves in the plane of a given canal, motions of the fluid deflect the cupula to produce nerve impulses.
• Bony (osseous) labyrinth: the network of passages with bony walls lined with periosteum that surrounds the membranous labyrinth N95. It includes the semicircular canals, the cochlea, and the centrally located vestibule which connects to the other parts. It is lined with periosteum and contains perilymph, which lies between the walls of the bony labyrinth and the membranous labyrinth. It is named by analogy with the mythical maze that imprisoned the Minotaur.
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The project was made possible by several very dedicated faculty and staff at University of North Carolina, Chapel Hill--especially O.W. Henson and Noelle A. Granger--and partner schools, and by a grant from the Fund for the Improvement of Post-Secondary Education of the US Department of Education. This channel includes over 400 short videos highlighting the steps in a full-body human dissection in the gross anatomy lab. Each step is narrated and key structures labeled.
25:21
Chapter 19 General and Special Senses Part4
Vestibular and Auditory Systems
published: 08 Jan 2016
Chapter 19 General and Special Senses Part4
Chapter 19 General and Special Senses Part4
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Vestibular and Auditory Systems
1:55
2-Minute Neuroscience: Vestibular System
The vestibular system is a sensory system that is essential to normal movement and equilib...
published: 02 Sep 2016
2-Minute Neuroscience: Vestibular System
2-Minute Neuroscience: Vestibular System
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The vestibular system is a sensory system that is essential to normal movement and equilibrium. In this video, I discuss the vestibular labyrinth---the primary structure of the vestibular system, which consists of the semicircular canals, ampullae, and otolith organs. All of these are essential to the vestibular system's ability to provide the brain with information about things like motion, head position, and spatial orientation.
For an article (on my website) that explains the vestibular system, click this link: https://neuroscientificallychallenged.com/posts/know-your-brain-vestibular-system
TRANSCRIPT:
Welcome to 2 minute neuroscience, where I simplistically explain neuroscience topics in 2 minutes or less. In this installment I will discuss the vestibular system.
The vestibular system is a sensory system responsible for providing our brain with information about motion, head position, and spatial orientation; it also is involved with motor functions that allow us to keep our balance, stabilize our head and body during movement, and maintain posture.
The main components of the vestibular system are found in the inner ear in a system of compartments called the vestibular labyrinth, which is continuous with the cochlea. The vestibular labyrinth contains the semicircular canals which are three tubes that are each situated in a plane in which the head can rotate. Each of the canals can detect one of the following head movements: nodding up and down, shaking side to side, or tilting left and right. The semicircular canals are filled with a fluid called endolymph. When the head is rotated, it causes the movement of endolymph through the canal that corresponds to the plane of the movement.
The endolymph flows into an expansion of the canal called the ampulla, within which there are hair cells, the sensory receptors of the vestibular system. At the top of each hair cell is a collection of small "hairs" called stereocilia. The movement of the endolymph causes movement of these stereocilia, which leads to the the release of neurotransmitters to send information about the plane of movement to the brain.
The vestibular system uses two other organs, known as the otolith organs, to detect forward and backward movements and gravitational forces. There are two otolith organs in the vestibular labyrinth: the utricle, which detects movement in the horizontal plane, and the saccule, which detects movement in the vertical plane. Within the utricle and saccule, hair cells detect movement when crystals of calcium carbonate called otoconia shift in response to it, leading to movement in the layers below the otoconia and displacement of hair cells.
REFERENCE:
Nolte J. The Human Brain: An Introduction to its Functional Anatomy. 6th ed. Philadelphia, PA. Elsevier; 2009.
21:50
Special Senses | Inner Ear Anatomy
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published: 31 Jul 2017
Special Senses | Inner Ear Anatomy
Special Senses | Inner Ear Anatomy
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Official Ninja Nerd Website: https://ninjanerd.org
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During this lecture Professor Zach Murphy will be teaching you about the anatomy of the inner ear. We discuss the structures of the inner ear including the vestibule, cochlea, and semicircular canals. We hope you enjoy this lecture and be sure to support us below!
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3:13
The Vestibular System Endolymph Motion Demonstration
A brief overview of endolymph motion. For functional examples of vestibular inputs and co...
published: 16 Jan 2014
The Vestibular System Endolymph Motion Demonstration
The Vestibular System Endolymph Motion Demonstration
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A brief overview of endolymph motion. For functional examples of vestibular inputs and corresponding eye movements see https://itunes.apple.com/app/avor/id497245573?mt=8
32:13
Vestibular System: Neuroanatomy Video Lab - Brain Dissections
Diagrams, models and skull preparations are used to describe the vestibular apparatus. Th...
published: 09 Sep 2015
Vestibular System: Neuroanatomy Video Lab - Brain Dissections
Vestibular System: Neuroanatomy Video Lab - Brain Dissections
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Diagrams, models and skull preparations are used to describe the vestibular apparatus. The semicircular canals, saccule and utricle are described as well as transduction by the hair cells in the ampullae and maculae. Gross material emphasizes the nerve, vestibular nuclei and connections through the MLF to the abducens and oculomotor nuclei in the brain stem for coordinating eye and head movements with body position. Nystagmus, INO, the vestibulocular reflex, and caloric testing are explained. Connections above the midbrain are not discussed.
This is 19 of a series of 26 videos to be viewed in the suggested order or intermixed with other curricular materials. The entire series can be accessed here:
https://neurologicexam.med.utah.edu/a...
The videos may be downloaded in various formats by going here:
https://neurologicexam.med.utah.edu/a...
Password Request form for downloadable Neuroanatomy Brain Dissection videos here: https://library.med.utah.edu/neuro-exam/
Cochlear cupula
The cochlear cupula is a structure in the cochlea. It is the apex of the cochlea. The bony canal of the cochlea takes two and three-quarter turns around the modiolus. The modiolus is about 30 mm. in length, and diminishes gradually in diameter from the base to the summit, where it terminates in the cupula.
This page contains text from Wikipedia, the Free Encyclopedia - https://wn.com/Cochlear_cupula
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