无线植入式压力监测器用于条件膀胱神经调节。

Steve Majerus, Iryna Makovey, Hui Zhui, Wen Ko, Margot S Damaser
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引用次数: 17

摘要

条件神经调节是一种可行的增强膀胱功能刺激的方法,其中神经刺激是基于反馈的应用或修改。目前测量膀胱压力的方法完全依赖于放置在膀胱腔内的外置导管。这种方法在慢性神经调节治疗的门诊使用中效用有限。我们开发了一种无线膀胱压力监测器,提供实时、无导管的膀胱压力测量,以支持条件神经调节。该装置适合于粘膜下膀胱镜植入膀胱。该可植入微系统由超低功耗专用集成电路(ASIC)、微机电(MEMS)压力传感器、射频天线和微型可充电电池组成。电源管理的战略方法是通过减少电池容量要求来使植入物小型化。这里我们描述了两种降低微系统平均电流消耗的方法:开关偏置功率控制和自适应速率传输。人体膀胱跟踪测量表明,自适应传输速率比全速率传输平均节省96%的功率,同时增加1.6%的RMS误差。我们在大型动物体内长期植入无线压力监测器长达4周。据我们所知,这些发现是第一个通过长期植入膀胱逼尿肌的压力监测器实现无导管、实时膀胱压力传感的例子。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Wireless Implantable Pressure Monitor for Conditional Bladder Neuromodulation.

Conditional neuromodulation in which neurostimulation is applied or modified based on feedback is a viable approach for enhanced bladder functional stimulation. Current methods for measuring bladder pressure rely exclusively on external catheters placed in the bladder lumen. This approach has limited utility in ambulatory use as required for chronic neuromodulation therapy. We have developed a wireless bladder pressure monitor to provide real-time, catheter-free measurements of bladder pressure to support conditional neuromodulation. The device is sized for submucosal cystoscopic implantation into the bladder. The implantable microsystem consists of an ultra-low-power application specific integrated circuit (ASIC), micro-electro-mechanical (MEMS) pressure sensor, RF antennas, and a miniature rechargeable battery. A strategic approach to power management miniaturizes the implant by reducing the battery capacity requirement. Here we describe two approaches to reduce the average microsystem current draw: switched-bias power control and adaptive rate transmission. Measurements on human cystometric tracings show that adaptive transmission rate can save an average of 96% power compared to full-rate transmission, while adding 1.6% RMS error. We have chronically implanted the wireless pressure monitor for up to 4 weeks in large animals. To the best of our knowledge these findings represent the first examples of catheter-free, real-time bladder pressure sensing from a pressure monitor chronically implanted within the bladder detrusor.

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