首页> 外文期刊>Journal of the Association for Research in Otolaryngology >Perilymph Kinetics of FITC-Dextran Reveals Homeostasis Dominated by the Cochlear Aqueduct and Cerebrospinal Fluid
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Perilymph Kinetics of FITC-Dextran Reveals Homeostasis Dominated by the Cochlear Aqueduct and Cerebrospinal Fluid

机译:FITC-Dextran的淋巴动力学揭示了由耳蜗导水管和脑脊液主导的体内平衡

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Understanding how drugs are distributed in perilymph following local applications is important as local drug therapies are increasingly used to treat disorders of the inner ear. The potential contribution of cerebrospinal fluid (CSF) entry to perilymph homeostasis has been controversial for over half a century, largely due to artifactual contamination of collected perilymph samples with CSF. Measures of perilymph flow and of drug distribution following round window niche applications have both suggested a slow, apically directed flow occurs along scala tympani (ST) in the normal, sealed cochlea. In the present study, we have used fluorescein isothiocyanate-dextran as a marker to study perilymph kinetics in guinea pigs. Dextran is lost from perilymph more slowly than other substances so far quantified. Dextran solutions were injected from pipettes sealed into the lateral semicircular canal (SCC), the cochlear apex, or the basal turn of ST. After varying delays, sequential perilymph samples were taken from the cochlear apex or lateral SCC, allowing dextran distribution along the perilymphatic spaces to be quantified. Variability was low and findings were consistent with the injection procedure driving volume flow towards the cochlear aqueduct, and with volume flow during perilymph sampling driven by CSF entry at the aqueduct. The decline of dextran with time in the period between injection and sampling was consistent with both a slow volume influx of CSF (∼30 nL/min) entering the basal turn of ST at the cochlear aqueduct and a CSF-perilymph exchange driven by pressure-driven fluid oscillation across the cochlear aqueduct. Sample data also allowed contributions of other processes, such as communications with adjacent compartments, to be quantified. The study demonstrates that drug kinetics in the basal turn of ST is complex and is influenced by a considerable number of interacting processes.
机译:随着局部药物疗法越来越多地用于治疗内耳疾病,了解局部应用后药物在外周淋巴中的分布非常重要。半个世纪以来,脑脊液(CSF)进入周围淋巴稳态的潜在贡献一直存在争议,这主要是由于所采集的周围淋巴样品被CSF人为污染。圆形窗口利基应用后,对淋巴流量和药物分布的测量均表明,正常密封的耳蜗中沿着co鼓(ST)发生了缓慢的,根尖引导的血流。在本研究中,我们已使用异硫氰酸荧光素-葡聚糖作为标记来研究豚鼠的外周淋巴动力学。右旋糖酐从周淋巴中流失的速度比迄今为止定量的其他物质要慢。从密封在外侧半规管(SCC),耳蜗尖部或ST的基弯中的移液器注入右旋糖酐溶液。经过不同的延迟后,从耳蜗顶点或外侧SCC采集连续的淋巴样本,从而可以定量确定沿外周血空间的葡聚糖分布。变异性低,并且发现与注射程序驱动流向耳蜗导水管的流量一致,并且与在CSF进入导水管驱动的周围淋巴取样期间的流量一致。右旋糖酐在注射和采样之间的时间内随时间的下降与缓慢的CSF体积流入量(〜30 nL / min)进入耳蜗导水管的ST底弯以及通过压力驱动的CSF-外周淋巴交换有关。带动流体穿过耳蜗导水管振荡。样本数据还可以量化其他过程(例如与相邻隔间的通信)的贡献。该研究表明,ST基底转弯处的药物动力学非常复杂,并受相当多相互作用过程的影响。

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