DOCSLIB.ORG

Cochlear Anatomy, Function and Pathology I

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Cochlear Anatomy, Function and Pathology I Cochlear anatomy, function and pathology I Professor Dave Furness Keele University [email protected] Aims and objectives of these lectures • Introduction to gross anatomy of the cochlea • Focus (1) on the sensory epithelium: – Hair cells and the organ of Corti – The mechanism of mechanoelectrical transduction Aims and objectives of these lectures • Focus (2) on the biophysics of the cochlea, the dual roles of hair cells and their innervation: – Cochlear frequency selectivity – The cochlear amplifier – Neurotransmission and innervation of the hair cells – Spiral ganglion and the structure of the auditory nerve Aims and objectives of these lectures • Focus (3) on the cochlear lateral wall and Reissner’s membrane: – The spiral ligament – The stria vascularis – The endolymphatic potential and potassium recycling – Reissner’s membrane Aims and objectives of these lectures • Focus (4) on cochlear pathology: – Presbyacusis – Ototoxicity – Noise trauma – Genetic hearing loss – Molecular mechanisms of cell loss – Regeneration and repair Inner ear From Bear, Connors and Paradiso, Neuroscience: exploring the brain (Lippincott Williams and Wilkins) Cochlea • The main functions of the cochlea are to analyse and convert the vibrations caused by sound into a pattern of electrical signals that can be conveyed along the auditory nerve fibres to the brain • This process involves three main steps: – sensory transduction – processing of the signal – neurotransmission The bony and membraneous labyrinths From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 scala vestibuli scala media scala tympani Cross sections of the cochlear duct 3 week old mouse 8 week old guinea pig Left: Mahendrasingam et al., 2011, JARO; Right Hackney and Furness, Noise and its Pathophysiology (eds Luxon and Prasher, 2007, Wiley) Fluid segregation • The three chambers contain different fluids • Endolymph, high in potassium, in scala media • Perilymph, high in sodium, in scala vestibuli and scala tympani The cochlea is a frequency analyser Increasing mass Low frequencies Basilar membrane and organ of Corti High frequencies Increasing stiffness cochlear nerve Frequency mapping on the basilar membrane • Discovered by Georg von Békésy who was awarded the Nobel Prize for Physiology or Medicine, 1961 • Used human cadavers and played sounds to them, whilst observing the motion of the basilar membrane • Measured the travelling wave and noted peaks of tuning • However, the peaks were not sharp enough to account for human frequency selectivity • Active physiological mechanisms are also required Frequency analysis in the cochlea • Sound sets up a travelling wave along the basilar membrane • The peak of motion determines the frequency selectivity (tuning) of the cochlea at that point • The peak moves further along as frequency gets lower Basilar membrane animation YouTube video Copyright: Howard Hughes Institute (under license) Cross sections of the cochlear duct From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 Organ of Corti • Organ of Corti consists of a sensory epithelium with hair cells and supporting cells Stria vascularis tectorial membrane Nerve fibres From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 The reticular lamina by scanning electron microscopy OHC IHC The reticular lamina by scanning electron microscopy OHC IHC Supporting cells: inner pillar, outer pillar, Deiter’s cell 1, Deiter’s cell 2, Deiters cell 3. Supporting cells are rich in actin and tubulin (cytoskeletal proteins) to provide mechanical support to the organ of Corti From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 Supporting cells are rich in actin and tubulin (cytoskeletal proteins) to provide mechanical support to the organ of Corti From Furness and Hackney, Scott-Brown’s Otorhinolaryngology: Head and Neck Surgery 7 Immunogold shows sorting of different actin isoforms in different organ of Corti cell types From Furness et al Hear Res. 2005 Sep;207(1-2):22-34 Hair cells • Auditory stimuli are received in the form of mechanical energy • Hair cells are mechanosensory receptors of the inner ear and are found in the cochlear and vestibular epithelia • They share common characteristics which underlie their sensitivity to mechanical stimuli Hair cells in auditory epithelium Cochlea + Inner hair Outer hair organ of Corti cells cells Comparing the inner and outer hair cells IHCs flask shaped; mitochondria dispersed; nucleus central OHCs cylindrical; mitochondria mostly lateral, nucleus basal Hair cells in the organ of Corti • Two types, structurally and functionally distinct • A number of similarities and differences • Bundle structure – similar rows of stereocilia but different shapes • Both can perform mechanoelectrical transduction • Innervation differs between the two Overview of bundle structure • Stereocilia form precise rows • They are coupled by various extracellular filaments From Hackney and Furness J Cell Sci 2013; 126(Pt 8):1721-1731 The hair bundle is the hair cell’s transducing element • Composed of stereocilia linked together by extracellular filaments • Contains many different proteins • The core of the stereocilium is actin • It also contains myosins and a variety of scaffolding and calcium modulating proteins • Extracellular filaments composed of other proteins Other important proteins required for transduction • Transducer elements • Structural and regulatory – TMC1 (transmembrane components channel 1) – Harmonin – TMC2 (transmembrane – Sans channel 2) – Whirlin – LHFPL5 (TMHS) – Usherin (tetraspan membrane – Stereocilin protein of hair cell stereocilia) – EPS8, EPS8L2 – Protocadherin 15 – PTPRQ – Cadherin 23 – VLGR1 – TMIE (transmembrane – Calmodulin inner ear protein) – PMCA2A (calcium ATPase) Links • The composition of links is becoming better understood • Their distributions tend to follow a particular pattern Hair bundles are the site of mechanoelectrical transduction • Hair cells are sensitive to deflections of the hair bundle plus (excitation) along the axis of sensitivity 0 0 minus (inhibition) Transduction occurs when the stereocilia are deflected positive negative + - - + Hair cell responses Moving stereocilia Cell electrical response The tip-links • Excitatory deflections of stereocilia open transduction channels by means of a gating spring • The spring is represented by the tip link A model of mechanosensitivity A single tip link Tip links and transduction channels TMHS From Hackney and Furness J Cell Sci 2013; 126(Pt 8):1721-1731 Immunolocalization of TMHS/LHFPL5 Actin (green), TMHS (red) Hair-cell transduction and neurotransmission +80 mV stimulus -70 mV response Glutamate transporters around IHCs but not OHCs confirm glutamatergic transmission OHC area Inner phalangeal Fibrocytes cells around IHCs Summary • In this lecture we have looked at the gross structural anatomy of the cochlea • We have examined the organisation and function of the organ of Corti • We have described and explained mechanoelectrical transduction – how the hair cells detect mechanical stimulation.
Load more

Recommended publications
  • The Standing Acoustic Wave Principle Within the Frequency Analysis Of
    inee Eng ring al & ic d M e e d Misun, J Biomed Eng Med Devic 2016, 1:3 m i o c i a B l D f o e v DOI: 10.4172/2475-7586.1000116 l i a c n e r s u o Journal of Biomedical Engineering and Medical Devices J ISSN: 2475-7586 Review Article Open Access The Standing Acoustic Wave Principle within the Frequency Analysis of Acoustic Signals in the Cochlea Vojtech Misun* Department of Solid Mechanics, Mechatronics and Biomechanics, Brno University of Technology, Brno, Czech Republic Abstract The organ of hearing is responsible for the correct frequency analysis of auditory perceptions coming from the outer environment. The article deals with the principles of the analysis of auditory perceptions in the cochlea only, i.e., from the overall signal leaving the oval window to its decomposition realized by the basilar membrane. The paper presents two different methods with the function of the cochlea considered as a frequency analyzer of perceived acoustic signals. First, there is an analysis of the principle that cochlear function involves acoustic waves travelling along the basilar membrane; this concept is one that prevails in the contemporary specialist literature. Then, a new principle with the working name “the principle of standing acoustic waves in the common cavity of the scala vestibuli and scala tympani” is presented and defined in depth. According to this principle, individual structural modes of the basilar membrane are excited by continuous standing waves of acoustic pressure in the scale tympani. Keywords: Cochlea function; Acoustic signals; Frequency analysis; The following is a description of the theories in question: Travelling wave principle; Standing wave principle 1.
    [Show full text]
  • Activity-Dependent Regulation of Prestin Expression in Mouse Outer Hair Cells
    J Neurophysiol 113: 3531–3542, 2015. First published March 25, 2015; doi:10.1152/jn.00869.2014. Activity-dependent regulation of prestin expression in mouse outer hair cells Yohan Song, Anping Xia, Hee Yoon Lee, Rosalie Wang, Anthony J. Ricci, and John S. Oghalai Department of Otolaryngology-Head and Neck Surgery, Stanford University, Stanford, California Submitted 4 November 2014; accepted in final form 19 March 2015 Song Y, Xia A, Lee HY, Wang R, Ricci AJ, Oghalai JS. patch-clamp recording conditions (Kakehata and Santos-Sac- Activity-dependent regulation of prestin expression in mouse outer chi, 1995 and 1996; Santos-Sacchi 1991; Santos-Sacchi et al. hair cells. J Neurophysiol 113: 3531–3542, 2015. First published 1998a). Thus, measuring the NLC is a common way of assess- March 25, 2015; doi:10.1152/jn.00869.2014.—Prestin is a membrane protein necessary for outer hair cell (OHC) electromotility and normal ing the amount of functional prestin within an OHC (Abe et al. 2007; Oliver and Fakler 1999;). hearing. Its regulatory mechanisms are unknown. Several mouse Downloaded from models of hearing loss demonstrate increased prestin, inspiring us to There are many ways to modulate the voltage dependence of investigate how hearing loss might feedback onto OHCs. To test force production by prestin protein within the plasma mem- whether centrally mediated feedback regulates prestin, we developed brane, such as changing the surrounding lipid environment, a novel model of inner hair cell loss. Injection of diphtheria toxin (DT) intracellular Ca2ϩ level, membrane tension, membrane poten- into adult CBA mice produced significant loss of inner hair cells tial, and ionic composition of the intracellular and extracellular without affecting OHCs.
    [Show full text]
  • Morphological and Functional Changes in a New Animal Model Of
    Laboratory Investigation (2013) 93, 1001–1011 & 2013 USCAP, Inc All rights reserved 0023-6837/13 Morphological and functional changes in a new animal model of Me´nie`re’s disease Naoya Egami1, Akinobu Kakigi1, Takashi Sakamoto1, Taizo Takeda2, Masamitsu Hyodo2 and Tatsuya Yamasoba1 The purpose of this study was to clarify the underlying mechanism of vertiginous attacks in Me´nie`re’s disease (MD) while obtaining insight into water homeostasis in the inner ear using a new animal model. We conducted both histopatho- logical and functional assessment of the vestibular system in the guinea-pig. In the first experiment, all animals were maintained 1 or 4 weeks after electrocauterization of the endolymphatic sac of the left ear and were given either saline or desmopressin (vasopressin type 2 receptor agonist). The temporal bones from both ears were harvested and the extent of endolymphatic hydrops was quantitatively assessed. In the second experiment, either 1 or 4 weeks after surgery, animals were assessed for balance disorders and nystagmus after the administration of saline or desmopressin. In the first experiment, the proportion of endolymphatic space in the cochlea and the saccule was significantly greater in ears that survived for 4 weeks after surgery and were given desmopressin compared with other groups. In the second experiment, all animals that underwent surgery and were given desmopressin showed spontaneous nystagmus and balance disorder, whereas all animals that had surgery but without desmopressin administration were asymptomatic. Our animal model induced severe endolymphatic hydrops in the cochlea and the saccule, and showed episodes of balance disorder along with spontaneous nystagmus.
    [Show full text]
  • Chapter 1. Epithelium (Epithelia)
    Chapter 1. Epithelium (Epithelia) ▶ Epithelia separate the internal environment from the external environment by forming tightly cohesive sheets of polarized cells held together by specialized junctional complexes and cell adhesion molecules ▶ Epithelial cells participate in embryo morphogenesis and organ development This chapter address the structural characteristics of epithelial cells General Characteristics of epithelia 1) tightly cohesive sheet of cells that covers or lines body surface (skin, intestine, secretory ducts) and forms functional units of secretory gland (salivary gland, liver) 2) basic function; protection (skin) ; absorption (small and large intestine) ; transport of material at the surface (mediated by cilia) ; secretion (gland) ; excretion (tubules of kidney) ; gas exchange (lung alveolus) ; gliding between surface (mesothelium, 중피세포) 3) Most epithelial cells renew continuously by mitosis (regeneration) 4) Epithelia lack direct blood and lymphatic supply (avascular; no blood supply). Nutrients are delivered by diffusion 5) Epithelial cells have no free intercellular substance (in contrast to connective tissues) (Control of permeability) 6) The cohesive nature of an epithelium is maintained by cell adhesion molecules and junctional complexes (attachment). 7) Epithelia are anchored to a basal lamina (바닥판). The basal lamina and connective tissues components cooperate to form basement membrane (기저막) 8) Epithelia have structural and functional polarity Epithelial Tissue - Characteristics & Functions https://www.youtube.com/watch?v=xI2hsH-ZHR4
    [Show full text]
  • Introduction to Sound and Hearing
    Salamanca Study Abroad Program: Neurobiology of Hearing Cochlear mechanics R. Keith Duncan University of Michigan [email protected] Outline Passive and active cochlear mechanics Prestin and outer hair cell motility Tonotopicity A place code is a general principle of many sensory systems (somatotopic, retinotopic, others?) Damage (hair cell loss) at particular locations along the cochlea is correlated with hearing loss at a particular frequency. The place code in the cochlea is “tonotopic”, each sound frequency stimulating a particular location best. Cochlear place is “tuned” to particular frequencies. But how is this frequency “tuning” established? Era of the “traveling wave” begins 1 kHz Georg von Békésy (1899-1972) Awarded a Nobel prize in 1961 for studies on cochlear mechanics. See “Experiments in hearing” compiled by Glen Weaver. “in situ” measurements • Improve visualization with silver grains and strobe illumination • Measure amp. of motion for constant input pressure at various frequencies. Tonotopic Distribution of Frequency The cochlea is a frequency analyzer, breaking complex waves into frequency components. Tonos = tone; Topia = place Tonotopic = frequency place code 4 kHz 1 kHz 250 Hz Passive mechanics largely due to gradual changes in the stiffness of the basilar membrane. Base: thick and narrow Apex: thin and wide A (Nonlinear) Amplifier in the Ear Gain = Amplitude of basilar membrane Amplitude of stapes motion Use laser to measure membrane at one tonotopic position. Compare with stapes motion to get gain. Vary frequency of sound stimulus while keeping input (stapes motion) constant. Passive mechanics gives the “dead or high level shape” (like with Békésy). Something else happens at low sound levels in an alive animal (like with psychoacoustics).
    [Show full text]
  • Ear, Page 1 Lecture Outline
    Ear - Hearing perspective Dr. Darren Hoffmann Lecture Objectives: After this lecture, you should be able to: -Describe the surface anatomy of the external ear in anatomical language -Recognize key anatomy in an otoscopic view of the tympanic membrane -Describe the anatomy and function of the ossicles and their associated muscles -Relate the anatomical structures of the middle ear to the anterior, posterior, lateral or medial walls -Explain the anatomy of middle ear infection and which regions have potential to spread to ear -Describe the anatomical structures of the inner ear -Discriminate between endolymph and perilymph in terms of their origin, composition and reabsorption mechanisms -Identify the structures of the Cochlea and Vestibular system histologically -Explain how hair cells function to transform fluid movement into electrical activity -Discriminate the location of cochlear activation for different frequencies of sound -Relate the hair cells of the cochlea to the hair cells of the vestibular system -Contrast the vestibular structures of macula and crista terminalis Let’s look at the following regions: Hoffmann – Ear, Page 1 Lecture Outline: C1. External Ear Function: Amplification of Sound waves Parts Auricle Visible part of external ear (pinna) Helix – large outer rim Tragus – tab anterior to external auditory meatus External auditory meatus Auditory Canal/External Auditory Meatus Leads from Auricle to Tympanic membrane Starts cartilaginous, becomes bony as it enters petrous part of temporal bone Earwax (Cerumen) Complex mixture
    [Show full text]
  • Stereocilia Rootlets: Actin-Based Structures That Are Essential for Structural Stability of the Hair Bundle
    International Journal of Molecular Sciences Review Stereocilia Rootlets: Actin-Based Structures That Are Essential for Structural Stability of the Hair Bundle Itallia Pacentine, Paroma Chatterjee and Peter G. Barr-Gillespie * Oregon Hearing Research Center & Vollum Institute, Oregon Health & Science University, Portland, OR 97239, USA; [email protected] (I.P.); [email protected] (P.C.) * Correspondence: [email protected]; Tel.: +1-503-494-2936 Received: 12 December 2019; Accepted: 1 January 2020; Published: 3 January 2020 Abstract: Sensory hair cells of the inner ear rely on the hair bundle, a cluster of actin-filled stereocilia, to transduce auditory and vestibular stimuli into electrical impulses. Because they are long and thin projections, stereocilia are most prone to damage at the point where they insert into the hair cell’s soma. Moreover, this is the site of stereocilia pivoting, the mechanical movement that induces transduction, which additionally weakens this area mechanically. To bolster this fragile area, hair cells construct a dense core called the rootlet at the base of each stereocilium, which extends down into the actin meshwork of the cuticular plate and firmly anchors the stereocilium. Rootlets are constructed with tightly packed actin filaments that extend from stereocilia actin filaments which are wrapped with TRIOBP; in addition, many other proteins contribute to the rootlet and its associated structures. Rootlets allow stereocilia to sustain innumerable deflections over their lifetimes and exemplify the unique manner in which sensory hair cells exploit actin and its associated proteins to carry out the function of mechanotransduction. Keywords: rootlet; actin; stereocilia; hair cell 1. Introduction Eukaryotic cells use actin as a basic building block of the cytoskeleton.
    [Show full text]
  • Vestibular Neuritis, Labyrinthitis, and a Few Comments Regarding Sudden Sensorineural Hearing Loss Marcello Cherchi
    Vestibular neuritis, labyrinthitis, and a few comments regarding sudden sensorineural hearing loss Marcello Cherchi §1: What are these diseases, how are they related, and what is their cause? §1.1: What is vestibular neuritis? Vestibular neuritis, also called vestibular neuronitis, was originally described by Margaret Ruth Dix and Charles Skinner Hallpike in 1952 (Dix and Hallpike 1952). It is currently suspected to be an inflammatory-mediated insult (damage) to the balance-related nerve (vestibular nerve) between the ear and the brain that manifests with abrupt-onset, severe dizziness that lasts days to weeks, and occasionally recurs. Although vestibular neuritis is usually regarded as a process affecting the vestibular nerve itself, damage restricted to the vestibule (balance components of the inner ear) would manifest clinically in a similar way, and might be termed “vestibulitis,” although that term is seldom applied (Izraeli, Rachmel et al. 1989). Thus, distinguishing between “vestibular neuritis” (inflammation of the vestibular nerve) and “vestibulitis” (inflammation of the balance-related components of the inner ear) would be difficult. §1.2: What is labyrinthitis? Labyrinthitis is currently suspected to be due to an inflammatory-mediated insult (damage) to both the “hearing component” (the cochlea) and the “balance component” (the semicircular canals and otolith organs) of the inner ear (labyrinth) itself. Labyrinthitis is sometimes also termed “vertigo with sudden hearing loss” (Pogson, Taylor et al. 2016, Kim, Choi et al. 2018) – and we will discuss sudden hearing loss further in a moment. Labyrinthitis usually manifests with severe dizziness (similar to vestibular neuritis) accompanied by ear symptoms on one side (typically hearing loss and tinnitus).
    [Show full text]
  • Inner Ear Infection (Otitis Interna) in Dogs
    Hurricane Harvey Client Education Kit Inner Ear Infection (Otitis Interna) in Dogs My dog has just been diagnosed with an inner ear infection. What is this? Inflammation of the inner ear is called otitis interna, and it is most often caused by an infection. The infectious agent is most commonly bacterial, although yeast and fungus can also be implicated in an inner ear infection. If your dog has ear mites in the external ear canal, this can ultimately cause a problem in the inner ear and pose a greater risk for a bacterial infection. Similarly, inner ear infections may develop if disease exists in one ear canal or when a benign polyp is growing from the middle ear. A foreign object, such as grass seed, may also set the stage for bacterial infection in the inner ear. Are some dogs more susceptible to inner ear infection? Dogs with long, heavy ears seem to be predisposed to chronic ear infections that ultimately lead to otitis interna. Spaniel breeds, such as the Cocker spaniel, and hound breeds, such as the bloodhound and basset hound, are the most commonly affected breeds. Regardless of breed, any dog with a chronic ear infection that is difficult to control may develop otitis interna if the eardrum (tympanic membrane) is damaged as it allows bacteria to migrate down into the inner ear. "Dogs with long, heavy ears seem to bepredisposed to chronic ear infections that ultimately lead to otitis interna." Excessively vigorous cleaning of an infected external ear canal can sometimes cause otitis interna. Some ear cleansers are irritating to the middle and inner ear and can cause signs of otitis interna if the eardrum is damaged and allows some of the solution to penetrate too deeply.
    [Show full text]
  • CONGENITAL MALFORMATIONS of the INNER EAR Malformaciones Congénitas Del Oído Interno
    topic review CONGENITAL MALFORMATIONS OF THE INNER EAR Malformaciones congénitas del oído interno. Revisión de tema Laura Vanessa Ramírez Pedroza1 Hernán Darío Cano Riaño2 Federico Guillermo Lubinus Badillo2 Summary Key words (MeSH) There are a great variety of congenital malformations that can affect the inner ear, Ear with a diversity of physiopathologies, involved altered structures and age of symptom Ear, inner onset. Therefore, it is important to know and identify these alterations opportunely Hearing loss Vestibule, labyrinth to lower the risks of all the complications, being of great importance, among others, Cochlea the alterations in language development and social interactions. Magnetic resonance imaging Resumen Existe una gran variedad de malformaciones congénitas que pueden afectar al Palabras clave (DeCS) oído interno, con distintas fisiopatologías, diferentes estructuras alteradas y edad Oído de aparición de los síntomas. Por lo anterior, es necesario conocer e identificar Oído interno dichas alteraciones, con el fin de actuar oportunamente y reducir el riesgo de las Pérdida auditiva Vestíbulo del laberinto complicaciones, entre otras —de gran importancia— las alteraciones en el área del Cóclea lenguaje y en el ámbito social. Imagen por resonancia magnética 1. Epidemiology • Hyperbilirubinemia Ear malformations occur in 1 in 10,000 or 20,000 • Respiratory distress from meconium aspiration cases (1). One in every 1,000 children has some degree • Craniofacial alterations (3) of sensorineural hearing impairment, with an average • Mechanical ventilation for more than five days age at diagnosis of 4.9 years. The prevalence of hearing • TORCH Syndrome (4) impairment in newborns with risk factors has been determined to be 9.52% (2).
    [Show full text]
  • Measuring Cochlear Duct Length – a Historical Analysis of Methods and Results Robert W
    Koch et al. Journal of Otolaryngology - Head and Neck Surgery (2017) 46:19 DOI 10.1186/s40463-017-0194-2 REVIEW Open Access Measuring Cochlear Duct Length – a historical analysis of methods and results Robert W. Koch1*, Hanif M. Ladak1,2,3,4†, Mai Elfarnawany2† and Sumit K. Agrawal1,2,4,5† Abstract Background: Cochlear Duct Length (CDL) has been an important measure for the development and advancement of cochlear implants. Emerging literature has shown CDL can be used in preoperative settings to select the proper sized electrode and develop customized frequency maps. In order to improve post-operative outcomes, and develop new electrode technologies, methods of measuring CDL must be validated to allow usage in the clinic. Purpose: The purpose of this review is to assess the various techniques used to calculate CDL and provide the reader with enough information to make an informed decision on how to conduct future studies measuring the CDL. Results: The methods to measure CDL, the modality used to capture images, and the location of the measurement have all changed as technology evolved. With recent popularity and advancement in computed tomography (CT) imaging in place of histologic sections, measurements of CDL have been focused at the lateral wall (LW) instead of the organ of Corti (OC), due to the inability of CT to view intracochlear structures. After analyzing results from methods such as directly measuring CDL from histology, indirectly reconstructing the shape of the cochlea, and determining CDL based on spiral coefficients, it was determined the three dimensional (3D) reconstruction method is the most reliable method to measure CDL.
    [Show full text]
  • ANATOMY of EAR Basic Ear Anatomy
    ANATOMY OF EAR Basic Ear Anatomy • Expected outcomes • To understand the hearing mechanism • To be able to identify the structures of the ear Development of Ear 1. Pinna develops from 1st & 2nd Branchial arch (Hillocks of His). Starts at 6 Weeks & is complete by 20 weeks. 2. E.A.M. develops from dorsal end of 1st branchial arch starting at 6-8 weeks and is complete by 28 weeks. 3. Middle Ear development —Malleus & Incus develop between 6-8 weeks from 1st & 2nd branchial arch. Branchial arches & Development of Ear Dev. contd---- • T.M at 28 weeks from all 3 germinal layers . • Foot plate of stapes develops from otic capsule b/w 6- 8 weeks. • Inner ear develops from otic capsule starting at 5 weeks & is complete by 25 weeks. • Development of external/middle/inner ear is independent of each other. Development of ear External Ear • It consists of - Pinna and External auditory meatus. Pinna • It is made up of fibro elastic cartilage covered by skin and connected to the surrounding parts by ligaments and muscles. • Various landmarks on the pinna are helix, antihelix, lobule, tragus, concha, scaphoid fossa and triangular fossa • Pinna has two surfaces i.e. medial or cranial surface and a lateral surface . • Cymba concha lies between crus helix and crus antihelix. It is an important landmark for mastoid antrum. Anatomy of external ear • Landmarks of pinna Anatomy of external ear • Bat-Ear is the most common congenital anomaly of pinna in which antihelix has not developed and excessive conchal cartilage is present. • Corrections of Pinna defects are done at 6 years of age.
    [Show full text]