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INNER EAR

INNER EAR. Two Halves: Vestibular--transduces motion and pull of gravity Cochlear--transduces sound energy (Both use Hair Cells). Subdivision into spaces containing endolymph (blue) , and spaces containing perilymph (red). The Endolymphatic Sac. Termination of vestibular aquaduct

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INNER EAR

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  1. INNER EAR Two Halves: • Vestibular--transduces motion and pull of gravity • Cochlear--transduces sound energy (Both use Hair Cells)

  2. Subdivision into spaces containing endolymph (blue), and spaces containing perilymph (red)

  3. The Endolymphatic Sac • Termination of vestibular aquaduct • Outside of temporal bone; next to dura mater lining of the brain • Thought to maintain endolymphatic volume/pressure

  4. Cochlea is Divided into 3 “Scala” • Scala Vestibuli • Reissner’s Membrane • Scala Media • Basilar Membrane • Scala Tympani • Helicotrema - the opening between 2 outer Scala

  5. Fluids filling the Inner Ear • Perilymph- in S. Vestibuli and S. Tympani • High Sodium / Low Potassium concentrations • Low Voltage (0 to +5 mV) • Endolymph- in S. Media • High Potassium / Low Sodium concentrations • High Positive Voltage (80 mV)

  6. Cross-Section of the Cochlea Third Turn Second Turn First Turn

  7. A Cross Section Shows the 3 Scala

  8. Within S. Media is the Organ of Corti

  9. I = Inner Hair Cells P = Pillar Cells O = Outer Hair Cells D = Deiter’s Cells

  10. IHCs, OHCs And Their Stereocilia • OHCs (at top) • 3, 4 or 5 rows • Approx 12,000 cells • 10 to 90 microns • V- or W-shaped ranks of stereocilia • 50 to 150 stereocilia per cell • IHC (at bottom) • 1 or 2 rows • Approx 3,500 cells • 35 microns • straight line ranks of stereocilia • 50 to 70 stereocilia per cell

  11. Cochlear Functions • Transduction- Converting acoustical-mechanical energy into electro-chemical energy. • Frequency Analysis-Breaking sound up into its component frequencies

  12. Transduction- • Inner Hair Cells are the true sensory transducers, converting motion of stereocilia into neurotransmitter release. Mechanical Electro-chemical • Outer Hair Cells have both forward and reverse transduction-- Mechanical  Electro-chemical Mechanical Electro-chemical

  13. Frequency Analysis - the Traveling Wave • Bekesy studied cochleae from cadavers, developed the Traveling Wave theory • 1. Response always begins at the base • 2. Amplitude grows as it travels apically • 3. Reaches a peak at a point determined by frequency of the sound • 4. Vibration then dies out rapidly

  14. Bekesy’s Theory describes Passive Mechanics • Based on work in “dead” cochleae • Highly damped -- not sharply tuned • Active Undamping occurs in live and healthy cochleae • Like pumping on a swing--adds amplitude

  15. The Active Component Adds to Bekesy’s Traveling Wave

  16. The Active Component • Improves Sensitivity for soft sounds • Improves frequency resolution

  17. Frequency Tuning Curves Show these Effects = plots of response threshold as a function of frequency They have a characteristic shape • sharp tip (shows best sensitivity at one freq) • steep high frequency tail • shallow low frequency tail

  18. Tuning Curves Passive Only Active + Passive

  19. More on Tuning & Tuning Curves: • Seen for basilar membrane, hair cells, nerve cells • Frequency of “tip” is called the CHARACTERISTIC FREQUENCY

  20. OHC Length and CF High Freqs Low Freqs

  21. Tectorial Membrane

  22. Hair Cell Activation • Involves Ion Flow into cell • Through channels in the stereocilia • Bending stereocilia causes # of open channels to change. • Toward Modiolus = Fewer channels open • Away from Modiolus = More open

  23. Ion Channels are opened by “TIP LINKS” • Tip Links connect tip of shorter stereocilia to the side of a stereocilium in the next taller row • Bending toward taller rows pulls tip links • Bending toward shorter rows relaxes tip links

  24. Tip Links

  25. Resting (or Membrane) Potentials • Inner Hair Cell = - 45 mV • Outer Hair Cell = - 70 mV

  26. Stereocilia bent toward tallest row • Potassium flows into cell • Calcium flows into cell • Voltage shifts to a less negative value • More neurotransmitter is released

  27. Synapse Basics • Pre-Synaptic cell contains vesicles • Gap between cells is Synaptic Cleft • Post synaptic cell may show darkened area adjacent to membrane

  28. Afferent & Efferent Neurons

  29. 4 Types of Cochlear Neurons • INNER HAIR CELLS • Multiple (10 to 20) Afferent synapses • (Efferents synapse on afferent dendrites) • OUTER HAIR CELLS: • Large Efferent synapses engulf base of cell • Small (& not very active) Afferent synapses

  30. IHC Innervation Pattern

  31. OHC Innervation Pattern

  32. Inner hair cells • Synapse at the base with up to 20 afferent neurons • “Divergence” • Efferents synapse on afferent dendrites under IHCs

  33. IHC activation alters firing rate

  34. Afferent neurons have their cell bodies in the Spiral Ganglion (4)

  35. An Action Potential (or Spike)

  36. IHC activation alters firing rate

  37. Spike Rate Increases Thru a 30 dB Range

  38. Cochlear Potentials: • Resting Potentials: voltages which exist without external stimulation e.g., Endolymphatic Potential, Cell Membrane Potential • Stimulus-Related Potentials: voltages occurring in response to sounds We’ll talk about 3 of these from the cochlea

  39. Cochlear Microphonic • Least valuable from a clinical standpoint. • Is an alternating current (AC) response that mirrors the waveform of low to moderately intense sound stimuli • Appears to arise from outer hair cells in the basal-most turn of the cochlea

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