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Olivocochlear system

April 13, 2024

The olivocochlear system is a component of the auditory system involved with the descending control of the cochlea. Its nerve fibres, the olivocochlear bundle (OCB), form part of the vestibulocochlear nerve (VIIIth cranial nerve, also known as the auditory-vestibular nerve), and project from the superior olivary complex in the brainstem (pons) to the cochlea.[1]

Anatomy of the olivocochlear system edit

Cell bodies of origin edit

 
The mammalian olivocochlear bundle, divided into medial (red) and lateral (green) systems. Both contain crossed and uncrossed fibres. The predominant fibres are represented by a thicker line. The insert (far left) shows the position of the cell bodies of the MOCS and LOCS relative to the MSOC and LSOC respectively, as observed in mammals.

The olivocochlear bundle (OCB) originates in the superior olivary complex in the brainstem. The vestibulocochlear anastomosis carries the efferent axons into the cochlea, where they innervate the organ of Corti (OC). The OCB contains fibres projecting to both the ipsilateral and contralateral cochleae, prompting an initial division into crossed (COCB) and uncrossed (UCOCB) systems.[1] More recently, however, the division of the OCB is based on the cell bodies' site of origin in the brainstem relative to the medial superior olive (MSO). The medioventral periolivary (MVPO) region, also known as the ventral nucleus of the trapezoid body, a diffuse region of neurons located medial to the MSO, gives rise to the medial olivocochlear system (MOCS). The lateral superior olive (LSO), a distinct nucleus of neurons located lateral to the MSO, gives rise to the lateral olivocochlear system (LOCS).[2][3] The MOCS neurons are large multipolar cells, while the LOCS are classically defined as composed of small spherical cells. This division is viewed as being more meaningful with respect to OCB physiology.[4] In addition to these classically defined olivocochlear neurons, advances in tract tracing methods helped reveal a third class of olivocochlear neurons, termed shell neurons, which surround the LSO.[5] Thus, LOCS class cell bodies within the LSO are referred to as intrinsic LOCS neurons, while those surrounding the LSO are referred to as shell, or extrinsic, LOCS neurons. Shell neurons are typically large, and morphologically are very similar to MOCS neurons.

Olivocochlear fibers edit

The LOCS (originating from both the intrinsic and shell neurons) contains unmyelinated fibres that synapse with the dendrites of the Type I spiral ganglion cells projecting to the inner hair cells. While the intrinsic LOCS neurons tend to be small (~10 to 15 µm in diameter), and the shell OC neurons are larger (~25 µm in diameter), it is the intrinsic OC neurons that possess the larger axons (0.77 µm compared to 0.37 µm diameter for shell neurons). In contrast, the MOCS contains myelinated nerve fibres which innervate the outer hair cells directly.[6] Although both the LOCS and MOCS contain crossed (contralateral) and uncrossed (ipsilateral) fibres, in most mammalian species the majority of LOCS fibres project to the ipsilateral cochlea, whilst the majority of the MOCS fibres project to the contralateral cochlea.[2][7] The proportion of fibres in the MOCS and LOCS also varies between species, but in most cases the fibres of the LOCS are more numerous.[8][9][10] In humans, there are an estimated (average) 1,000 LOCS fibres and 360 MOCS fibres,[11][12] however the numbers vary between individuals. The MOCS gives rise to a frequency-specific innervation of the cochlea, in that MOC fibres terminate on the outer hair cells at the place in the cochlea predicted from the fibres' characteristic frequency, and are thus tonotopically organised in the same fashion as the primary afferent neurons.[6][13] The fibres of the LOCS also appear to be arranged in a tonotopic fashion.[14] However, it is not known whether the characteristic frequencies of the LOCS fibres coincide with the characteristic frequencies of the primary afferent neurons, since attempts to selectively stimulate the fibres of the LOCS have been largely unsuccessful.[15] Intrinsic LOCS derived axons travel only approximately 1 µm within the organ of Corti, generally spiraling apically. They give off a small tuft of synaptic boutons that is compact in its extent, often involving less than 10 IHCs. In comparison, shell neurons spiral both apically and basally, and can cover large territories within the organ of Corti. The shell axons often cover 1-2 octaves of tonotopic length.[16] Their terminal arbor is quite sparse, however.

Physiology of the olivocochlear system edit

Neurophysiology edit

All currently known activity of the olivocochlear system is via a nicotinic class neurotransmitter receptor complex that is coupled with a calcium-activated potassium channel. Together, these systems generate an unusual synaptic response to stimulation from the brain. The olivocochlear synaptic terminals contain various neurotransmitters and neuroactive peptides. The major neurotransmitter employed by the olivocochlear system is acetylcholine (ACh), although gamma-aminobutyric acid (GABA) is also localized in the terminals. ACh release from the olivocochlear terminals activates an evolutionarily ancient cholinergic receptor complex composed of the nicotinic alpha9[17] and alpha10 subunits.[18] While these subunits create a ligand-gated ion channel that is especially permeable to calcium and monovalent cations[19] the cellular response of the outer hair cells to ACh activation is hyperpolarizing, rather than the expected depolarizing response. This comes about due to the rapid activation of an associated potassium channel. This channel, the apamin sensitive, small conductance SK2 potassium channel, is activated by calcium that is likely released into the cytoplasm via calcium-induced calcium release from calcium stores within the subsynaptic cisternae as a response to incoming calcium from the nicotinic complex.[20] However, it has not been ruled out that some incoming calcium through the nicotinic alpha9alpha10 channel may also directly activate the SK channel. Electrophysiological responses recorded from outer hair cells following ACh stimulation therefore show a small inward current (carried largely by incoming calcium via the acetylcholine receptor) that is immediately followed by a large outward current, the potassium current, that hyperpolarizes the outer hair cell.

When the olivocochlear bundle is surgically transected prior to the onset of hearing, auditory sensitivity is compromised.[21] However, upon genetic ablation of either the alpha9 or alpha10 genes, such effects are not observed. This may be due to the different nature of the lesions- the surgical lesion results in complete loss of all olivocochlear innervation to the hair cells, while the genetic manipulations result in much more selective functional loss- that of the targeted gene only. Any remaining neuroactive substances that can be released by the intact synaptic terminals can still activate the hair cells. Indeed, upon genetic ablation of one of the neuroactive peptides present in the LOCS terminals,[22] consequences similar to that following the surgical lesion were observed, demonstrating that the effects of the surgery were most likely due to loss of this peptide, and not the ACh present in the synaptic terminals.

Effects of electrical stimulation edit

In animals, the physiology of the MOCS has been studied far more extensively than the physiology of the LOCS. This is because the myelinated fibres of the MOCS are easier to electrically stimulate and record.[15] Consequently, relatively little is known about the physiology of the LOCS.[23]

Many studies performed on animals in vivo have stimulated the olivocochlear bundle (OCB) using shock stimuli delivered by electrodes placed on the nerve bundle. These studies have measured the output of the auditory nerve (AN), with and without OCB stimulation. In 1956, Galambos activated the efferent fibres of the cat by delivering shock stimuli to the floor of the fourth ventricle (at the decussation of the COCB). Galambos observed a suppression of the compound action potentials of the AN (referred to as the N1 potential) evoked by low-intensity click stimuli.[24] This basic finding was repeatedly confirmed (Desmedt and Monaco, 1961; Fex, 1962; Desmedt, 1962; Wiederhold, 1970). An efferent suppression of N1 was also observed by stimulating the MOCS cells bodies in the medial SOC,[25] confirming that the N1 suppression was the result of MOC (not LOC) stimulation. More recently, several researchers have observed a suppression of cochlear neural output during stimulation of the inferior colliculus (IC) in the midbrain, which projects to the superior olivary complex (SOC) (Rajan, 1990; Mulders and Robertson, 2000; Ota et al., 2004; Zhang and Dolan, 2006). Ota et al. (2004) also showed that the N1 suppression in the cochlea was greatest at the frequency corresponding to the frequency placement of the electrode in the IC, providing further evidence for tonotopic organisation of the efferent pathways.

These findings led to the current understanding that MOC activity decreases the active process of OHCs, leading to a frequency-specific reduction of cochlear gain.

Acoustically evoked responses of the MOCS edit

 
The basic MOC acoustic reflex. The auditory nerve responds to sound, sending a signal to the cochlear nucleus. Afferent nerve fibres cross the midline from the cochlear nucleus to the cell bodies of the MOCS (located near the MSOC), whose efferent fibres project back to the cochlea (red). In most mammals, the majority of the reflex is ipsilateral (shown as a thicker line), effectuated by the crossed MOCS.

Electrical stimulation in the brainstem can result in (i) the entire MOCS being stimulated, (ii) a discharge rate (up to 400 s-1) much higher than is normally evoked by sound (up to 60 s-1), and (iii) electrical stimulation of neurons other than MOCS fibres. Therefore, electrical stimulation of the MOCS may not give an accurate indication of its biological function, nor the natural magnitude of its effect.

The MOCS' response to sound is mediated through the MOC acoustic reflex pathway (see inset), which had been previously investigated using anterograde and retrograde labelling techniques (Aschoff et al., 1988; Robertson and Winter, 1988). Acoustic stimulation of the inner hair cells sends a neural signal to the posteroventral cochlear nucleus (PVCN), and the axons of the neurons from the PVCN cross the brainstem to innervate the contralateral MOC neurons. In most mammals, the MOC neurons predominantly project to the contralateral side (forming the ipsilateral reflex), with the remainder projecting to the ipsilateral side (forming the contralateral reflex).

The strength of the reflex is weakest for pure tones, and becomes stronger as the bandwidth of the sound is increased (Berlin et al., 1993), hence the maximum MOCS response is observed for broadband noise (Guinan et al., 2003). Researchers have measured the effects of stimulating the MOCS with sound. In cats, Liberman (1989) showed that contralateral sound (resulting in MOCS stimulation) reduced the N1 potential, a suppression which was eliminated upon transection of the olivocochlear bundle (OCB). In humans, the largest amount of evidence for the action of efferents has come from the suppression of otoacoustic emissions (OAEs) following acoustic stimulation.

Using acoustic stimuli to activate the MOC reflex pathway, recordings have been made from single efferent fibres in guinea pigs[13] and cats.[6] Both studies confirmed that MOC neurons are sharply tuned to frequency, as previously suggested by Cody and Johnstone (1982), and Robertson (1984). They also showed that the firing rate of MOC neurons increased as the intensity of sound increased from 0 to 100 dB SPL, and have comparable thresholds (within ~15 dB) to afferent neurons. Furthermore, both studies showed that most MOC neurons responded to sound presented in the ipsilateral ear, consistent with the majority of mammalian MOC neurons being contralaterally located.[2][7] No recordings have been made from MOC fibres in humans. because invasive in vivo experiments are not possible. In other primate species however, it has been shown that about 50-60% of MOC fibres are crossed (Bodian and Gucer, 1980; Thompson and Thompson, 1986).

Proposed functions of the MOCS edit

The hypothesised functions of the MOCS fall into three general categories; (i) cochlear protection against loud sounds, (ii) development of cochlea function, and (iii) detection and discrimination of sounds in noise.

Cochlear protection against loud sounds edit

Cody and Johnstone (1982) and Rajan and Johnstone (1988a; 1988b) showed that constant acoustic stimulation that in (which evokes a strong MOCS response (Brown et al., 1998)) reduced the severity of acoustic trauma. This protection was negated in the presence of a chemical known to suppress the action of the olivocochlear bundle (OCB) (strychnine), implicating the action of the MOCS in protection of the cochlea from loud sounds. Further evidence for the auditory efferents having a protective role was provided by Rajan (1995a) and Kujawa and Liberman (1997). Both studies showed that the hearing loss sustained by animals due to binaural sound exposure was more severe if the OCB was severed. Rajan (1995b) also showed a frequency dependence of MOC protection roughly consistent with the distribution of MOC fibres in the cochlea. Other studies supporting this function of the MOCS have shown that MOC stimulation reduces the temporary threshold shift (TTS) and permanent threshold shift (PTS) associated with prolonged noise exposure (Handrock and Zeisberg, 1982; Rajan, 1988b; Reiter and Liberman, 1995), and that animals with the strongest MOC reflex sustain less hearing damage to loud sounds (Maison and Liberman, 2000). This proposed biological role of the MOCS, protection from loud sounds, was challenged by Kirk and Smith (2003), who argued that the intensity of sounds used in the experiments (≥105 dB SPL) would rarely or never occur in nature, and therefore a protective mechanism for sounds of such intensities could not have evolved. This claim (that MOC-mediated cochlear protection is an epiphenomenon) was recently challenged by Darrow et al. (2007), who suggested that the LOCS has an anti-excitotoxic effect, indirectly protecting the cochlea from damage.

Development of cochlea function edit

Evidence also exists for the role of the olivocochlear bundle (OCB) in the development of cochlear function. Liberman (1990) measured the responses from single AN fibres of adult cats for 6 months after the OCB was severed. Liberman did not find any change in AN fibres' thresholds, tuning curves and I/O functions. Walsh et al. (1998) performed a similar experiment, however the researchers severed the OCB of neonatal cats, and recorded from AN fibres one year later. In the cats without efferent input to the cochlea, elevated thresholds of the AN, a decreased sharpness of the tuning curves, and decreased SRs were recorded. Walsh et al. (1998) proposed that neonatal de-efferentation interferes with normal OHC development and function, hence implicating the OCB in the development of the active processes in the cochlea.

Detection and discrimination of sounds in noise edit

The MOC-induced effects discussed thus far have all been observed in experiments conducted in silence (generally in sound-attenuated booths or rooms). However, measuring the cochlea's response to sounds in these conditions may not reveal the true biological function of the MOCS, since evolving mammals are rarely in silent situations, and the MOCS is particularly responsive to noise (Guinan et al., 2003). The first experiments investigating the effects of MOC stimulation in the presence of noise were conducted on guinea pigs by Nieder and Nieder (1970a, 1970b, 1970c), who measured cochlear output evoked by click stimuli presented in constant background noise (BGN). In this condition, they found that the N1 potential evoked by click stimuli was enhanced during a period of MOC stimulation. This finding has been confirmed using both electrical stimulation (Dolan and Nuttall, 1988; Winslow and Sachs, 1987) and acoustic activation (Kawase et al., 1993, Kawase and Liberman, 1993) of the mammalian MOCS. Winslow and Sachs (1987) found that stimulating the OCB:

"...enables auditory nerve fibres to signal changes in tone level with changes in discharge rate at lower signal-to-noise ratios than would be possible otherwise." (Page 2002)

One interpretation of these findings is that MOC stimulation selectively reduces the auditory nerve's response to constant background noise, allowing a greater response to a transient sound.[15] In this way, MOC stimulation would reduce the effect of both suppressive and adaptive masking, and for this reason, the process has been referred to as "unmasking" or "antimasking" (Kawase et al., 1993, Kawase and Liberman, 1993). Antimasking has been suggested to occur in a similar fashion in humans (Kawase and Takasaka, 1995), and has implications for selective listening since the rapid unmasking of a sound resulting from MOC activation would increase the overall signal-to-noise ratio (SNR), thus facilitating better detection of a target sound.

 
Attentional filter depths from 12 subjects who underwent a vestibular neurectomy, for the same ear (triangles) or different ears (crosses). Combined mean (----) and 95% confidence intervals are shown. An average ~15% decline in attentional filter depth can be seen following olivocochlear bundle (OCB) lesion. Data taken from Scharf et al. (1997).[26]

In humans, psychophysical experiments conducted in constant BGN have also implicated the olivocochlear bundle (OCB) in selective listening. The research perhaps most relevant to this thesis has been performed by Scharf and his colleagues. In 1993, Scharf et al. presented data from eight patients who had undergone unilateral vestibular neurectomy to treat Ménière's disease, a procedure which severs the OCB (presumably both the MOCS and the LOCS). Scharf et al. (1993) did not find any clear differences in subjects' thresholds to tones in noise before and after surgery. Shortly after this finding, Scharf et al. (1994, 1997) performed a comprehensive set of psychophysical experiments from a total of sixteen patients who had undergone unilateral vestibular neurectomy (including the original eight subjects).[26][27] They measured performance in the psychophysical listening tasks before and after surgery, and found no significant difference in performance for (i) detection of tones, (ii) intensity discrimination of tones, (iii) frequency discrimination of tones, (iv) loudness adaptation, and (v) detection of tones in notched-noise.[26][27] Their only positive finding was that most patients detected unexpected sounds in the operated ear better than in the healthy ear, or the same ear before surgery. This result was obtained using a truncated probe-signal procedure which led the patient to expect a certain frequency on each trial. Twelve subjects completed this experiment.[26][27] Their procedure was similar to that of Greenberg and Larkin (1968), except only 50% of trials (not 77%) contained a target whose frequency matched that of the auditory cue. The other 50% of trials containing a probe whose frequency differed from that of the cue. Also, only two probe frequencies were used, one whose frequency was higher than the target, and one whose frequency was lower than the target. All trials contained an auditory cue (at the target frequency) prior to the first observation interval. The results were used to construct a basic attentional filter, which displayed detection level of the expected (and cued) target frequency and the two unexpected probe frequencies.[26][27] From the two published reports (Scharf et al., 1994, 1997), ears for which the OCB has been lesioned showed an attentional filter with an average depth of about 15%-correct less than those ears for which the OCB was intact.[26][27] Although there is no way to empirically convert this value to dB, a rough estimate based on psychometric functions presented by Green and Swets (1966) yields a value of 2-3 dB. Their results have been summarised in the inset figure.[26]

Scharf and his colleagues argued that sectioning the OCB in these patients released suppression of unexpected frequencies. This effect was not present in all subjects, and large variation between subjects was observed. Nevertheless, no other psychophysical characteristics of hearing were affected following sectioning of the OCB. Scharf et al. (1997) concluded that OCB-mediated suppression of sounds in the cochlea was responsible for the suppression of unexpected sounds, and thus plays a role in selective attention in normal hearing.[26] In contrast to Scharf's theory, Tan et al. (2008) argued that the OCB's role in selective listening pertains to the enhancement of a cued, or expected tone. This enhancement may be caused by the activity of the MOCS on the outer hair cells resulting in antimasking.[28]

Although Scharf et al.'s (1993, 1994, 1997) experiments failed to produce any clear differences in the basic psychophysical characteristics of hearing (other than the detection of unexpected sounds), many other studies using both animals and humans have implicated the OCB in listening-in-noise tasks using more complex stimuli. In constant BGN, rhesus monkeys with intact OCBs have been observed to perform better in vowel discrimination tasks than those without (Dewson, 1968). In cats, an intact OCB is associated with better vowel identification (Heinz et al., 1998), sound localisation (May et al., 2004), and intensity discrimination (May and McQuone, 1995). All of these studies were performed in constant BGN. In humans, speech-in-noise discrimination measurements have been performed on individuals who had undergone unilateral vestibular neurectomy (resulting in OCB sectioning). Giraud et al. (1997) observed a small advantage in the healthy ear over the operated ear for phoneme recognition and speech intelligibility in BGN. Scharf et al. (1988) had previously investigated the role of auditory attention during speech perception, and suggested that speech-in-noise discrimination is assisted by attentional focus on frequency regions. In 2000, Zeng et al., reported that vestibular neurectomy did not directly affect pure-tone thresholds or intensity discrimination,[29] confirming earlier findings of Scharf et al. 1994; 1997.[26][27] For the listening-in-noise tasks, they observed a number of discrepancies between the healthy and operated ear. Consistent with the earlier findings of May and McQuone (1995), intensity discrimination in noise was observed to be slightly worse in the ear without olivocochlear bundle (OCB) input. However, Zeng et al.'s main finding related to the "overshoot" effect, which was found to be significantly reduced (~50%) in the operated ears.[29] This effect was first observed by Zwicker (1965), and was characterised as an increased detection threshold of a tone when it is presented at the onset of the noise compared to when it is presented in constant, steady-state noise.[30] Zeng et al. proposed that this finding is consistent with MOCS-evoked antimasking; that is, MOCS-evoked antimasking being absent at the onset of noise however becoming active during steady-state noise. This theory was supported by the time course of MOC activation;[6][31] being similar to the time course of the overshoot effect (Zwicker, 1965),[30] as well as the overshoot effect being disrupted in subjects with sensorineural hearing loss, for whom the MOCS would be most likely ineffectual (Bacon and Takahashi, 1992).

References edit

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April 13, 2024
olivocochlear, system, olivocochlear, system, component, auditory, system, involved, with, descending, control, cochlea, nerve, fibres, olivocochlear, bundle, form, part, vestibulocochlear, nerve, viiith, cranial, nerve, also, known, auditory, vestibular, nerv. The olivocochlear system is a component of the auditory system involved with the descending control of the cochlea Its nerve fibres the olivocochlear bundle OCB form part of the vestibulocochlear nerve VIIIth cranial nerve also known as the auditory vestibular nerve and project from the superior olivary complex in the brainstem pons to the cochlea 1 Contents 1 Anatomy of the olivocochlear system 1 1 Cell bodies of origin 1 2 Olivocochlear fibers 2 Physiology of the olivocochlear system 2 1 Neurophysiology 2 2 Effects of electrical stimulation 2 3 Acoustically evoked responses of the MOCS 2 4 Proposed functions of the MOCS 2 4 1 Cochlear protection against loud sounds 2 4 2 Development of cochlea function 2 4 3 Detection and discrimination of sounds in noise 3 References 4 External linksAnatomy of the olivocochlear system editCell bodies of origin edit nbsp The mammalian olivocochlear bundle divided into medial red and lateral green systems Both contain crossed and uncrossed fibres The predominant fibres are represented by a thicker line The insert far left shows the position of the cell bodies of the MOCS and LOCS relative to the MSOC and LSOC respectively as observed in mammals The olivocochlear bundle OCB originates in the superior olivary complex in the brainstem The vestibulocochlear anastomosis carries the efferent axons into the cochlea where they innervate the organ of Corti OC The OCB contains fibres projecting to both the ipsilateral and contralateral cochleae prompting an initial division into crossed COCB and uncrossed UCOCB systems 1 More recently however the division of the OCB is based on the cell bodies site of origin in the brainstem relative to the medial superior olive MSO The medioventral periolivary MVPO region also known as the ventral nucleus of the trapezoid body a diffuse region of neurons located medial to the MSO gives rise to the medial olivocochlear system MOCS The lateral superior olive LSO a distinct nucleus of neurons located lateral to the MSO gives rise to the lateral olivocochlear system LOCS 2 3 The MOCS neurons are large multipolar cells while the LOCS are classically defined as composed of small spherical cells This division is viewed as being more meaningful with respect to OCB physiology 4 In addition to these classically defined olivocochlear neurons advances in tract tracing methods helped reveal a third class of olivocochlear neurons termed shell neurons which surround the LSO 5 Thus LOCS class cell bodies within the LSO are referred to as intrinsic LOCS neurons while those surrounding the LSO are referred to as shell or extrinsic LOCS neurons Shell neurons are typically large and morphologically are very similar to MOCS neurons Olivocochlear fibers edit The LOCS originating from both the intrinsic and shell neurons contains unmyelinated fibres that synapse with the dendrites of the Type I spiral ganglion cells projecting to the inner hair cells While the intrinsic LOCS neurons tend to be small 10 to 15 µm in diameter and the shell OC neurons are larger 25 µm in diameter it is the intrinsic OC neurons that possess the larger axons 0 77 µm compared to 0 37 µm diameter for shell neurons In contrast the MOCS contains myelinated nerve fibres which innervate the outer hair cells directly 6 Although both the LOCS and MOCS contain crossed contralateral and uncrossed ipsilateral fibres in most mammalian species the majority of LOCS fibres project to the ipsilateral cochlea whilst the majority of the MOCS fibres project to the contralateral cochlea 2 7 The proportion of fibres in the MOCS and LOCS also varies between species but in most cases the fibres of the LOCS are more numerous 8 9 10 In humans there are an estimated average 1 000 LOCS fibres and 360 MOCS fibres 11 12 however the numbers vary between individuals The MOCS gives rise to a frequency specific innervation of the cochlea in that MOC fibres terminate on the outer hair cells at the place in the cochlea predicted from the fibres characteristic frequency and are thus tonotopically organised in the same fashion as the primary afferent neurons 6 13 The fibres of the LOCS also appear to be arranged in a tonotopic fashion 14 However it is not known whether the characteristic frequencies of the LOCS fibres coincide with the characteristic frequencies of the primary afferent neurons since attempts to selectively stimulate the fibres of the LOCS have been largely unsuccessful 15 Intrinsic LOCS derived axons travel only approximately 1 µm within the organ of Corti generally spiraling apically They give off a small tuft of synaptic boutons that is compact in its extent often involving less than 10 IHCs In comparison shell neurons spiral both apically and basally and can cover large territories within the organ of Corti The shell axons often cover 1 2 octaves of tonotopic length 16 Their terminal arbor is quite sparse however Physiology of the olivocochlear system editNeurophysiology edit All currently known activity of the olivocochlear system is via a nicotinic class neurotransmitter receptor complex that is coupled with a calcium activated potassium channel Together these systems generate an unusual synaptic response to stimulation from the brain The olivocochlear synaptic terminals contain various neurotransmitters and neuroactive peptides The major neurotransmitter employed by the olivocochlear system is acetylcholine ACh although gamma aminobutyric acid GABA is also localized in the terminals ACh release from the olivocochlear terminals activates an evolutionarily ancient cholinergic receptor complex composed of the nicotinic alpha9 17 and alpha10 subunits 18 While these subunits create a ligand gated ion channel that is especially permeable to calcium and monovalent cations 19 the cellular response of the outer hair cells to ACh activation is hyperpolarizing rather than the expected depolarizing response This comes about due to the rapid activation of an associated potassium channel This channel the apamin sensitive small conductance SK2 potassium channel is activated by calcium that is likely released into the cytoplasm via calcium induced calcium release from calcium stores within the subsynaptic cisternae as a response to incoming calcium from the nicotinic complex 20 However it has not been ruled out that some incoming calcium through the nicotinic alpha9alpha10 channel may also directly activate the SK channel Electrophysiological responses recorded from outer hair cells following ACh stimulation therefore show a small inward current carried largely by incoming calcium via the acetylcholine receptor that is immediately followed by a large outward current the potassium current that hyperpolarizes the outer hair cell When the olivocochlear bundle is surgically transected prior to the onset of hearing auditory sensitivity is compromised 21 However upon genetic ablation of either the alpha9 or alpha10 genes such effects are not observed This may be due to the different nature of the lesions the surgical lesion results in complete loss of all olivocochlear innervation to the hair cells while the genetic manipulations result in much more selective functional loss that of the targeted gene only Any remaining neuroactive substances that can be released by the intact synaptic terminals can still activate the hair cells Indeed upon genetic ablation of one of the neuroactive peptides present in the LOCS terminals 22 consequences similar to that following the surgical lesion were observed demonstrating that the effects of the surgery were most likely due to loss of this peptide and not the ACh present in the synaptic terminals Effects of electrical stimulation edit In animals the physiology of the MOCS has been studied far more extensively than the physiology of the LOCS This is because the myelinated fibres of the MOCS are easier to electrically stimulate and record 15 Consequently relatively little is known about the physiology of the LOCS 23 Many studies performed on animals in vivo have stimulated the olivocochlear bundle OCB using shock stimuli delivered by electrodes placed on the nerve bundle These studies have measured the output of the auditory nerve AN with and without OCB stimulation In 1956 Galambos activated the efferent fibres of the cat by delivering shock stimuli to the floor of the fourth ventricle at the decussation of the COCB Galambos observed a suppression of the compound action potentials of the AN referred to as the N1 potential evoked by low intensity click stimuli 24 This basic finding was repeatedly confirmed Desmedt and Monaco 1961 Fex 1962 Desmedt 1962 Wiederhold 1970 An efferent suppression of N1 was also observed by stimulating the MOCS cells bodies in the medial SOC 25 confirming that the N1 suppression was the result of MOC not LOC stimulation More recently several researchers have observed a suppression of cochlear neural output during stimulation of the inferior colliculus IC in the midbrain which projects to the superior olivary complex SOC Rajan 1990 Mulders and Robertson 2000 Ota et al 2004 Zhang and Dolan 2006 Ota et al 2004 also showed that the N1 suppression in the cochlea was greatest at the frequency corresponding to the frequency placement of the electrode in the IC providing further evidence for tonotopic organisation of the efferent pathways These findings led to the current understanding that MOC activity decreases the active process of OHCs leading to a frequency specific reduction of cochlear gain Acoustically evoked responses of the MOCS edit nbsp The basic MOC acoustic reflex The auditory nerve responds to sound sending a signal to the cochlear nucleus Afferent nerve fibres cross the midline from the cochlear nucleus to the cell bodies of the MOCS located near the MSOC whose efferent fibres project back to the cochlea red In most mammals the majority of the reflex is ipsilateral shown as a thicker line effectuated by the crossed MOCS Electrical stimulation in the brainstem can result in i the entire MOCS being stimulated ii a discharge rate up to 400 s 1 much higher than is normally evoked by sound up to 60 s 1 and iii electrical stimulation of neurons other than MOCS fibres Therefore electrical stimulation of the MOCS may not give an accurate indication of its biological function nor the natural magnitude of its effect The MOCS response to sound is mediated through the MOC acoustic reflex pathway see inset which had been previously investigated using anterograde and retrograde labelling techniques Aschoff et al 1988 Robertson and Winter 1988 Acoustic stimulation of the inner hair cells sends a neural signal to the posteroventral cochlear nucleus PVCN and the axons of the neurons from the PVCN cross the brainstem to innervate the contralateral MOC neurons In most mammals the MOC neurons predominantly project to the contralateral side forming the ipsilateral reflex with the remainder projecting to the ipsilateral side forming the contralateral reflex The strength of the reflex is weakest for pure tones and becomes stronger as the bandwidth of the sound is increased Berlin et al 1993 hence the maximum MOCS response is observed for broadband noise Guinan et al 2003 Researchers have measured the effects of stimulating the MOCS with sound In cats Liberman 1989 showed that contralateral sound resulting in MOCS stimulation reduced the N1 potential a suppression which was eliminated upon transection of the olivocochlear bundle OCB In humans the largest amount of evidence for the action of efferents has come from the suppression of otoacoustic emissions OAEs following acoustic stimulation Using acoustic stimuli to activate the MOC reflex pathway recordings have been made from single efferent fibres in guinea pigs 13 and cats 6 Both studies confirmed that MOC neurons are sharply tuned to frequency as previously suggested by Cody and Johnstone 1982 and Robertson 1984 They also showed that the firing rate of MOC neurons increased as the intensity of sound increased from 0 to 100 dB SPL and have comparable thresholds within 15 dB to afferent neurons Furthermore both studies showed that most MOC neurons responded to sound presented in the ipsilateral ear consistent with the majority of mammalian MOC neurons being contralaterally located 2 7 No recordings have been made from MOC fibres in humans because invasive in vivo experiments are not possible In other primate species however it has been shown that about 50 60 of MOC fibres are crossed Bodian and Gucer 1980 Thompson and Thompson 1986 Proposed functions of the MOCS edit The hypothesised functions of the MOCS fall into three general categories i cochlear protection against loud sounds ii development of cochlea function and iii detection and discrimination of sounds in noise Cochlear protection against loud sounds edit Cody and Johnstone 1982 and Rajan and Johnstone 1988a 1988b showed that constant acoustic stimulation that in which evokes a strong MOCS response Brown et al 1998 reduced the severity of acoustic trauma This protection was negated in the presence of a chemical known to suppress the action of the olivocochlear bundle OCB strychnine implicating the action of the MOCS in protection of the cochlea from loud sounds Further evidence for the auditory efferents having a protective role was provided by Rajan 1995a and Kujawa and Liberman 1997 Both studies showed that the hearing loss sustained by animals due to binaural sound exposure was more severe if the OCB was severed Rajan 1995b also showed a frequency dependence of MOC protection roughly consistent with the distribution of MOC fibres in the cochlea Other studies supporting this function of the MOCS have shown that MOC stimulation reduces the temporary threshold shift TTS and permanent threshold shift PTS associated with prolonged noise exposure Handrock and Zeisberg 1982 Rajan 1988b Reiter and Liberman 1995 and that animals with the strongest MOC reflex sustain less hearing damage to loud sounds Maison and Liberman 2000 This proposed biological role of the MOCS protection from loud sounds was challenged by Kirk and Smith 2003 who argued that the intensity of sounds used in the experiments 105 dB SPL would rarely or never occur in nature and therefore a protective mechanism for sounds of such intensities could not have evolved This claim that MOC mediated cochlear protection is an epiphenomenon was recently challenged by Darrow et al 2007 who suggested that the LOCS has an anti excitotoxic effect indirectly protecting the cochlea from damage Development of cochlea function edit Evidence also exists for the role of the olivocochlear bundle OCB in the development of cochlear function Liberman 1990 measured the responses from single AN fibres of adult cats for 6 months after the OCB was severed Liberman did not find any change in AN fibres thresholds tuning curves and I O functions Walsh et al 1998 performed a similar experiment however the researchers severed the OCB of neonatal cats and recorded from AN fibres one year later In the cats without efferent input to the cochlea elevated thresholds of the AN a decreased sharpness of the tuning curves and decreased SRs were recorded Walsh et al 1998 proposed that neonatal de efferentation interferes with normal OHC development and function hence implicating the OCB in the development of the active processes in the cochlea Detection and discrimination of sounds in noise edit The MOC induced effects discussed thus far have all been observed in experiments conducted in silence generally in sound attenuated booths or rooms However measuring the cochlea s response to sounds in these conditions may not reveal the true biological function of the MOCS since evolving mammals are rarely in silent situations and the MOCS is particularly responsive to noise Guinan et al 2003 The first experiments investigating the effects of MOC stimulation in the presence of noise were conducted on guinea pigs by Nieder and Nieder 1970a 1970b 1970c who measured cochlear output evoked by click stimuli presented in constant background noise BGN In this condition they found that the N1 potential evoked by click stimuli was enhanced during a period of MOC stimulation This finding has been confirmed using both electrical stimulation Dolan and Nuttall 1988 Winslow and Sachs 1987 and acoustic activation Kawase et al 1993 Kawase and Liberman 1993 of the mammalian MOCS Winslow and Sachs 1987 found that stimulating the OCB enables auditory nerve fibres to signal changes in tone level with changes in discharge rate at lower signal to noise ratios than would be possible otherwise Page 2002 One interpretation of these findings is that MOC stimulation selectively reduces the auditory nerve s response to constant background noise allowing a greater response to a transient sound 15 In this way MOC stimulation would reduce the effect of both suppressive and adaptive masking and for this reason the process has been referred to as unmasking or antimasking Kawase et al 1993 Kawase and Liberman 1993 Antimasking has been suggested to occur in a similar fashion in humans Kawase and Takasaka 1995 and has implications for selective listening since the rapid unmasking of a sound resulting from MOC activation would increase the overall signal to noise ratio SNR thus facilitating better detection of a target sound nbsp Attentional filter depths from 12 subjects who underwent a vestibular neurectomy for the same ear triangles or different ears crosses Combined mean and 95 confidence intervals are shown An average 15 decline in attentional filter depth can be seen following olivocochlear bundle OCB lesion Data taken from Scharf et al 1997 26 In humans psychophysical experiments conducted in constant BGN have also implicated the olivocochlear bundle OCB in selective listening The research perhaps most relevant to this thesis has been performed by Scharf and his colleagues In 1993 Scharf et al presented data from eight patients who had undergone unilateral vestibular neurectomy to treat Meniere s disease a procedure which severs the OCB presumably both the MOCS and the LOCS Scharf et al 1993 did not find any clear differences in subjects thresholds to tones in noise before and after surgery Shortly after this finding Scharf et al 1994 1997 performed a comprehensive set of psychophysical experiments from a total of sixteen patients who had undergone unilateral vestibular neurectomy including the original eight subjects 26 27 They measured performance in the psychophysical listening tasks before and after surgery and found no significant difference in performance for i detection of tones ii intensity discrimination of tones iii frequency discrimination of tones iv loudness adaptation and v detection of tones in notched noise 26 27 Their only positive finding was that most patients detected unexpected sounds in the operated ear better than in the healthy ear or the same ear before surgery This result was obtained using a truncated probe signal procedure which led the patient to expect a certain frequency on each trial Twelve subjects completed this experiment 26 27 Their procedure was similar to that of Greenberg and Larkin 1968 except only 50 of trials not 77 contained a target whose frequency matched that of the auditory cue The other 50 of trials containing a probe whose frequency differed from that of the cue Also only two probe frequencies were used one whose frequency was higher than the target and one whose frequency was lower than the target All trials contained an auditory cue at the target frequency prior to the first observation interval The results were used to construct a basic attentional filter which displayed detection level of the expected and cued target frequency and the two unexpected probe frequencies 26 27 From the two published reports Scharf et al 1994 1997 ears for which the OCB has been lesioned showed an attentional filter with an average depth of about 15 correct less than those ears for which the OCB was intact 26 27 Although there is no way to empirically convert this value to dB a rough estimate based on psychometric functions presented by Green and Swets 1966 yields a value of 2 3 dB Their results have been summarised in the inset figure 26 Scharf and his colleagues argued that sectioning the OCB in these patients released suppression of unexpected frequencies This effect was not present in all subjects and large variation between subjects was observed Nevertheless no other psychophysical characteristics of hearing were affected following sectioning of the OCB Scharf et al 1997 concluded that OCB mediated suppression of sounds in the cochlea was responsible for the suppression of unexpected sounds and thus plays a role in selective attention in normal hearing 26 In contrast to Scharf s theory Tan et al 2008 argued that the OCB s role in selective listening pertains to the enhancement of a cued or expected tone This enhancement may be caused by the activity of the MOCS on the outer hair cells resulting in antimasking 28 Although Scharf et al s 1993 1994 1997 experiments failed to produce any clear differences in the basic psychophysical characteristics of hearing other than the detection of unexpected sounds many other studies using both animals and humans have implicated the OCB in listening in noise tasks using more complex stimuli In constant BGN rhesus monkeys with intact OCBs have been observed to perform better in vowel discrimination tasks than those without Dewson 1968 In cats an intact OCB is associated with better vowel identification Heinz et al 1998 sound localisation May et al 2004 and intensity discrimination May and McQuone 1995 All of these studies were performed in constant BGN In humans speech in noise discrimination measurements have been performed on individuals who had undergone unilateral vestibular neurectomy resulting in OCB sectioning Giraud et al 1997 observed a small advantage in the healthy ear over the operated ear for phoneme recognition and speech intelligibility in BGN Scharf et al 1988 had previously investigated the role of auditory attention during speech perception and suggested that speech in noise discrimination is assisted by attentional focus on frequency regions In 2000 Zeng et al reported that vestibular neurectomy did not directly affect pure tone thresholds or intensity discrimination 29 confirming earlier findings of Scharf et al 1994 1997 26 27 For the listening in noise tasks they observed a number of discrepancies between the healthy and operated ear Consistent with the earlier findings of May and McQuone 1995 intensity discrimination in noise was observed to be slightly worse in the ear without olivocochlear bundle OCB input However Zeng et al s main finding related to the overshoot effect which was found to be significantly reduced 50 in the operated ears 29 This effect was first observed by Zwicker 1965 and was characterised as an increased detection threshold of a tone when it is presented at the onset of the noise compared to when it is presented in constant steady state noise 30 Zeng et al proposed that this finding is consistent with MOCS evoked antimasking that is MOCS evoked antimasking being absent at the onset of noise however becoming active during steady state noise This theory was supported by the time course of MOC activation 6 31 being similar to the time course of the overshoot effect Zwicker 1965 30 as well as the overshoot effect being disrupted in subjects with sensorineural hearing loss for whom the MOCS would be most likely ineffectual Bacon and Takahashi 1992 References edit a b Rasumssen G L 1960 Chapter 8 Efferent Fibers of the Cochlear Nerve and Cochlear Nucleus In Rasmussen G L Windle W F eds Neural Mechanisms of the Auditory and Vestibular System Springfield IL Charles C Thomas pp 105 115 a b c Warr WB Guinan JJ Sep 1979 Efferent innervation of the organ of corti two separate systems Brain Res 173 1 152 5 doi 10 1016 0006 8993 79 91104 1 PMID 487078 S2CID 44556309 WARR W B GUINAN J J Jr WHITE J S 1986 Richard A Altschuler Richard P Bobbin Douglas W Hoffman eds Organization of the efferent fibers The lateral and medial olivocochlear systems New York Raven Press ISBN 978 0 89004 925 9 OCLC 14243197 a href Template Cite book html title Template Cite book cite book a work ignored help Guinan JJ Warr WB Norris BE Dec 1983 Differential olivocochlear projections from lateral versus medial zones of the superior olivary complex J Comp Neurol 221 3 358 70 doi 10 1002 cne 902210310 PMID 6655089 S2CID 20885545 Vetter DE Mugnaini E 1992 Distribution and dendritic features of three groups of rat olivocochlear neurons A study with two retrograde cholera toxin tracers Anat Embryol 185 1 1 16 doi 10 1007 bf00213596 PMID 1736680 S2CID 24047129 a b c d Liberman MC Brown MC 1986 Physiology and anatomy of single olivocochlear neurons in the cat Hear Res 24 1 17 36 doi 10 1016 0378 5955 86 90003 1 PMID 3759672 S2CID 6532711 a b W B Warr September October 1980 Efferent components of the auditory system The Annals of Otology Rhinology and Laryngology Supplement 89 5 Pt 2 114 120 doi 10 1177 00034894800890S527 PMID 6786165 S2CID 25200230 Thompson GC Thompson AM Dec 1986 Olivocochlear neurons in the squirrel monkey brainstem J Comp Neurol 254 2 246 58 doi 10 1002 cne 902540208 PMID 3540042 S2CID 36785026 Robertson et al 1989 Azeredo WJ Kliment ML Morley BJ Relkin E Slepecky NB Sterns A Warr WB Weekly JM Woods CI Aug 1999 Olivocochlear neurons in the chinchilla a retrograde fluorescent labelling study Hear Res 134 1 2 57 70 doi 10 1016 S0378 5955 99 00069 6 PMID 10452376 S2CID 44854559 Arnesen AR 1984 Fibre population of the vestibulocochlear anastomosis in humans Acta Otolaryngol 98 5 6 501 18 doi 10 3109 00016488409107591 PMID 6524346 Arnesen AR 1985 Numerical estimations of structures in the cochlear nuclei and cochlear afferents and efferents Acta Otolaryngol Suppl 423 81 4 doi 10 3109 00016488509122916 PMID 3864352 a b Robertson D Gummer M 1985 Physiological and morphological characterization of efferent neurones in the guinea pig cochlea Hear Res 20 1 63 77 doi 10 1016 0378 5955 85 90059 0 PMID 2416730 S2CID 4701335 Robertson D Anderson C Cole K S 1987 Segregation of efferent projections to different turns of the guinea pig cochlea Hearing Research 25 1 69 76 doi 10 1016 0378 5955 87 90080 3 PMID 3804858 S2CID 45374194 a b c Guinan John J Jr 1996 Peter Dallos Arthur N Popper Richard R Fay eds The Physiology of Olivocochlear Efferents New York Springer pp 435 502 ISBN 978 0 387 94449 4 OCLC 33243443 a href Template Cite book html title Template Cite book cite book a work ignored help Warr WB Beck JE Neely ST 1997 Efferent innervation of the inner hair cell region origins and terminations of two lateral olivocochlear systems Hear Res 108 1 89 111 doi 10 1016 S0378 5955 97 00044 0 PMID 9213126 S2CID 4761304 Elgoyhen AB Johnson DS Boulter J Vetter DE Heinemann S Nov 1994 Alpha 9 an acetylcholine receptor with novel pharmacological properties expressed in rat cochlear hair cells Cell 79 4 705 15 doi 10 1016 0092 8674 94 90555 X PMID 7954834 S2CID 54360324 Elgoyhen AB Vetter DE Katz E Rothlin CV Heinemann SF Boulter J Mar 2001 alpha10 a determinant of nicotinic cholinergic receptor function in mammalian vestibular and cochlear mechanosensory hair cells Proc Natl Acad Sci U S A 98 6 3501 6 Bibcode 2001PNAS 98 3501B doi 10 1073 pnas 051622798 PMC 30682 PMID 11248107 Katz E Verbitsky M Rothlin CV Vetter DE Heinemann SF Elgoyhen AB Mar 2000 High calcium permeability and calcium block of the alpha9 nicotinic acetylcholine receptor Hear Res 141 1 2 117 28 doi 10 1016 S0378 5955 99 00214 2 PMID 10713500 S2CID 39776077 Lioudyno et al 2004 A Synaptoplasmic Cistern Mediates Rapid Inhibition of Cochlear Hair Cells Journal of Neuroscience 24 49 11160 4 doi 10 1523 JNEUROSCI 3674 04 2004 PMC 6730265 PMID 15590932 Walsh et al 1998 Long Term Effects of Sectioning the Olivocochlear Bundle in Neonatal Cats Journal of Neuroscience 18 10 3859 69 doi 10 1523 JNEUROSCI 18 10 03859 1998 PMC 6793155 PMID 9570815 Vetter et al 2002 Urocortin deficient mice show hearing impairment and increased anxiety like behavior Nature Genetics 31 4 363 9 doi 10 1038 ng914 PMID 12091910 S2CID 37838038 Groff JA Liberman MC Nov 2003 Modulation of cochlear afferent response by the lateral olivocochlear system activation via electrical stimulation of the inferior colliculus PDF J Neurophysiol 90 5 3178 200 doi 10 1152 jn 00537 2003 hdl 1721 1 28596 PMID 14615429 GALAMBOS R Sep 1956 Suppression of auditory nerve activity by stimulation of efferent fibers to cochlea PDF J Neurophysiol 19 5 424 37 doi 10 1152 jn 1956 19 5 424 PMID 13367873 Gifford ML Guinan JJ 1987 Effects of electrical stimulation of medial olivocochlear neurons on ipsilateral and contralateral cochlear responses Hear Res 29 2 3 179 94 doi 10 1016 0378 5955 87 90166 3 PMID 3624082 S2CID 4775494 a b c d e f g h i Scharf B Magnan J Chays A Jan 1997 On the role of the olivocochlear bundle in hearing 16 case studies Hear Res 103 1 2 101 22 doi 10 1016 S0378 5955 96 00168 2 PMID 9007578 a b c d e f Scharf B Magnan J Collet L Ulmer E Chays A May 1994 On the role of the olivocochlear bundle in hearing a case study Hear Res 75 1 2 11 26 doi 10 1016 0378 5955 94 90051 5 PMID 8071137 S2CID 4762642 Tan MN Robertson D Hammond GR Jul 2008 Separate contributions of enhanced and suppressed sensitivity to the auditory attentional filter Hearing Research 241 1 2 18 25 doi 10 1016 j heares 2008 04 003 PMID 18524512 S2CID 35376635 a b Zeng FG Martino KM Linthicum FH Soli SD Apr 2000 Auditory perception in vestibular neurectomy subjects Hear Res 142 1 2 102 12 doi 10 1016 S0378 5955 00 00011 3 PMID 10748333 S2CID 35805509 a b Zwicker E Jul 1965 Temporal Effects in Simultaneous Masking and Loudness PDF J Acoust Soc Am 38 1 132 41 Bibcode 1965ASAJ 38 132Z doi 10 1121 1 1909588 PMID 14347604 Backus BC Guinan JJ May 2006 Time course of the human medial olivocochlear reflex J Acoust Soc Am 119 5 Pt 1 2889 904 Bibcode 2006ASAJ 119 2889B doi 10 1121 1 2169918 PMID 16708947 External links edit Retrieved from https en wikipedia org w index php title Olivocochlear system amp oldid 1218120615, wikipedia, wiki, book, books, library,

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