Effects of Acetazolamide on Acid-base Balance in the Endolymphatic Sac of the Guinea Pig

Tsujikawa, Satoshi; Yamashita, Toshio; Tomoda, Koichi; Iwai, Hiroshi; Kumazawa, Hirobumi; Cho, Hisayuki; Kumazawa, Tadami

doi:10.3109/00016489309126179

Cited by 12 publications

(15 citation statements)

References 14 publications

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“…The finding that isoproterenol, a ␤-adrenergic receptor agonist, at a dose of 12.5 g/kg decreases ESP without changing EP (16), suggests that isoproterenol would suppress active ion transport in the ES without inhibiting active ion transport in the cochlea. Acetazolamide, a potent carbonic anhydrase inhibitor, reportedly depresses ESP more sensitively than EP (32,33). The result that cotreatment with isoproterenol and acetazolamide at doses producing near-maximum reduction of ESP depresses almost all parts of the ESP, suggesting that isoproterenol and acetazolamide may depress ESP via different mechanisms and that ESP may be composed of isoproterenol-and acetazolamide-sensitive parts (17).…”

Section: The Endolymphatic Sac (Es)mentioning

confidence: 77%

Endolymphatic sac is involved in the regulation of hydrostatic pressure of cochlear endolymph

Inamoto

Miyashita

Akiyama

et al. 2009

American Journal of Physiology-Regulatory, Integrative and Comp

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To clarify the role of the endolymphatic sac (ES) in the regulation of endolymphatic pressure, the effects of isoproterenol, a ␤-adrenergic receptor agonist, and acetazolamide, a potent carbonic anhydrase inhibitor, both of which decrease ES direct current potential on cochlear hydrostatic pressure, were examined in guinea pigs. When isoproterenol was applied intravenously, hydrostatic pressures of cochlear endolymph and perilymph were significantly increased with no change in endocochlear potential or the hydrostatic pressure of cerebrospinal fluid. Acetazolamide produced no marked change in the hydrostatic pressure of cochlear endolymph. In ears with an obstructed ES, the action of isoproterenol on the hydrostatic pressure of cochlear endolymph and perilymph was suppressed. These results suggest that the ES may regulate the hydrostatic pressure of the endolymphatic system via the action of the agents such as catecholamines on the ES. direct current potential; isoproterenol; acetazolamide THE ENDOLYMPHATIC SAC (ES), which is a part of the inner ear, is believed to absorb endolymph, since surgical blockage of the ES and the endolymphatic duct causes accumulation of endolymph in the cochlea and vestibule, as so-called endolymphatic hydrops (11), a characteristic pathological finding in Meniere's disease. Endolymphatic hydrops in the cochlea causes deafness, while endolymphatic hydrops in the vestibule causes vertigo (22, 31). Endolymph regulation is thus important for hearing and the sense of equilibrium (7,29). Although the ES is generally accepted to contain active ion transport systems and may absorb endolymph (11), no mechanisms of endolymph regulation by the ES have actually been established.ES direct current potential (ESP) and endocochlear direct current potential (EP) are known to be present in the ES and the cochlea, respectively (3, 12, 15). ESP and EP are generated by active ion transports in the ES and cochlea, respectively (3, 15, 21). ESP and EP can thus be used as indices of function for the ES and cochlea, respectively (15, 21). Catecholamines reportedly depress ESP through ␤-adrenergic receptors (19). The finding that isoproterenol, a ␤-adrenergic receptor agonist, at a dose of 12.5 g/kg decreases ESP without changing EP (16), suggests that isoproterenol would suppress active ion transport in the ES without inhibiting active ion transport in the cochlea. Acetazolamide, a potent carbonic anhydrase inhibitor, reportedly depresses ESP more sensitively than EP (32, 33). The result that cotreatment with isoproterenol and acetazolamide at doses producing near-maximum reduction of ESP depresses almost all parts of the ESP, suggesting that isoproterenol and acetazolamide may depress ESP via different mechanisms and that ESP may be composed of isoproterenol-and acetazolamide-sensitive parts (17).The ES has been hypothesized to regulate endolymphatic hydrostatic pressure (4, 9). However, no reports have described hydrostatic pressure regulation by the ES, as direct measurement of endolymphatic hydrostatic ...

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Section: The Endolymphatic Sac (Es)mentioning

confidence: 77%

Endolymphatic sac is involved in the regulation of hydrostatic pressure of cochlear endolymph

Inamoto

Miyashita

Akiyama

et al. 2009

American Journal of Physiology-Regulatory, Integrative and Comp

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“…Dans le sac endolymphatique, les travaux effectués in vivo à l'aide de microélectrodes à sélectivité ionique ou par dosage ultramicrospectrophotométrique, ont montré que la composition du liquide luminal (toujours appelé endolymphe) est intermédiaire entre celles de l'endolymphe et de la péri-lymphe [26,27]. Le potentiel transépithélial mesuré entre les compartiments endolymphatique et périlymphatique est positif dans l'endolymphe, il varie en fonction de l'organe où il est mesuré: + 100 mV dans la cochlée et de + 8 à + 15mV dans le sac endolymphatique.…”

Section: Anomalies Du Sac Endolymphatique Dans La Maladie De Ménièreunclassified

“…En effet, les ARN messagers codant pour des canaux à eau de type aquaporines 2, 3 et 4, ont été détec-tés par RT-PCR dans le sac endolymphatique de rat [17,37]. Les échanges acido-basiques de part et d'autre de l'épithélium du sac sont assurés par différents enzymes et transporteurs, en particulier une H + -ATPase de type vacuolaire (inhibée par la bafilomycine) et un échangeur Na + /H + apical ainsi qu'une anhydrase carbonique intracellulaire [27,33,38]. Ces systèmes de transports acidobasiques sont responsables de l'acidité du pH luminal du sac endolymphatique (pH 7,0) par rapport au pH physiologique [27,38].…”

Section: Les Autres Fonctions Du Sac Endolymphatiqueunclassified

“…Les échanges acido-basiques de part et d'autre de l'épithélium du sac sont assurés par différents enzymes et transporteurs, en particulier une H + -ATPase de type vacuolaire (inhibée par la bafilomycine) et un échangeur Na + /H + apical ainsi qu'une anhydrase carbonique intracellulaire [27,33,38]. Ces systèmes de transports acidobasiques sont responsables de l'acidité du pH luminal du sac endolymphatique (pH 7,0) par rapport au pH physiologique [27,38]. L'acidité luminale pourrait favoriser l'activation des macrophages flottant dans la lumière du sac [39] et/ou activer certains canaux à eau de type aquaporine [40].…”

Section: Les Autres Fonctions Du Sac Endolymphatiqueunclassified

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Le sac endolymphatique : ses fonctions au sein de l’oreille interne

et al. 2004

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“…CA is widely present in the sensory and non-sensory epithelia of the inner ear Pedrozo et al 1997), especially the developing endolymphatic sac of mammalian embryos contain high levels of CA. Administration of acetazolamide, a CA inhibitor, in the latter tissue can decrease the luminal pH and HCO 3 -concentration Tsujikawa et al 1993). Injection of acetazolamide into the yolk sac of developing chick embryos alters and inhibits normal otoconial morphogenesis .…”

Section: Carbonic Anhydrase (Ca) Provides Hcomentioning

confidence: 99%