用于大脑记录和刺激模式的无线代理。

Ilhan Bok, Adam Vareberg, Yash Gokhale, Suyash Bhatt, Emily Masterson, Jack Phillips, Tianxiang Zhu, Xiaoxuan Ren, Aviad Hai
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引用次数: 0

摘要

与医疗模式无线交互的新型传感器和调制器为原位大脑记录和刺激开辟了未知的途径。持续的小型化、材料精细化以及对特定神经生理学和神经化学过程的敏感性正在激发新的能力,这些能力开始超越传统笨重和侵入性有线探针的限制。在这里,我们调查了不同操作领域的当前最先进的代理,并根据规模、交付、特异性和时空分辨率评估了可能性。我们首先描述了在射频(RF)范围或以下操作、具有简单近场传输的可植入和可注射微纳米级电子设备,并继续描述了在磁共振成像(MRI)中用作动态造影剂的更复杂的设备、纳米颗粒和生物化学分子偶联物,超声(US)转导和其他功能性断层摄影模式。我们评估了其中一些技术通过新兴的探针和材料提供刺激和神经调控的能力,这些探针和材料可提供微创磁、电、热和光遗传学刺激。这些方法正在改变与兼容成像系统相结合的现成技术,并有望扩大神经和神经科学诊断和治疗的范围。
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Wireless agents for brain recording and stimulation modalities.

New sensors and modulators that interact wirelessly with medical modalities unlock uncharted avenues for in situ brain recording and stimulation. Ongoing miniaturization, material refinement, and sensitization to specific neurophysiological and neurochemical processes are spurring new capabilities that begin to transcend the constraints of traditional bulky and invasive wired probes. Here we survey current state-of-the-art agents across diverse realms of operation and evaluate possibilities depending on size, delivery, specificity and spatiotemporal resolution. We begin by describing implantable and injectable micro- and nano-scale electronic devices operating at or below the radio frequency (RF) regime with simple near field transmission, and continue with more sophisticated devices, nanoparticles and biochemical molecular conjugates acting as dynamic contrast agents in magnetic resonance imaging (MRI), ultrasound (US) transduction and other functional tomographic modalities. We assess the ability of some of these technologies to deliver stimulation and neuromodulation with emerging probes and materials that provide minimally invasive magnetic, electrical, thermal and optogenetic stimulation. These methodologies are transforming the repertoire of readily available technologies paired with compatible imaging systems and hold promise toward broadening the expanse of neurological and neuroscientific diagnostics and therapeutics.

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来源期刊
CiteScore
6.90
自引率
0.00%
发文量
0
审稿时长
8 weeks
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