Nanotip acetylcholine biosensor reveals cholinergic differentiated SH-SY5Y cells release partial vesicle content during exocytosis

IF 4.5 2区化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Bioelectrochemistry Pub Date : 2026-10-01 Epub Date: 2026-02-26 DOI:10.1016/j.bioelechem.2026.109260

Yuanmo Wang , Ajay Pradhan , Pankaj Gupta , Jörg Hanrieder , Henrik Zetterberg , Ann-Sofie Cans

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引用次数: 0

Abstract

Acetylcholine (ACh) is a central neurotransmitter in cognitive function, motor control, and synaptic modulation, yet its electrochemical inactivity and the rapid kinetics of exocytosis have hindered real-time quantal measurements. Micrometer-scale enzymatic ACh biosensors previously enabled sub-millisecond extracellular recordings but were too large for synaptic positioning and intracellular recordings. Here we present a short, ultrafast and low-noise amperometric ACh biosensor based on a needle-shaped carbon fiber nanotip electrode functionalized with gold nanoparticles and enzymes. The miniaturized geometry allows precise placement at neurite release sites and minimally invasive insertion into the cell cytoplasm, enabling high-temporal resolution monitoring of presynaptic exocytosis together with quantification of intracellular ACh vesicle content. We applied this platform to differentiated human cholinergic SH-SY5Y neuroblastoma cells, an established yet underutilized cell model for cholinergic signaling. The nanotip sensor successfully captured amperometric spikes from both intracellular vesicle burst events and presynaptic ACh release. Intracellular events released a larger amount of ACh than presynaptic exocytosis events, indicating a predominance of partial exocytosis mode in these cells. These results demonstrate the nanotip ACh biosensor as a unique tool for probing fusion pore dynamics at subcellular resolution and for providing quantitative insight into the quantal nature of cholinergic signaling in human neuronal models.

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纳米尖端乙酰胆碱生物传感器显示胆碱能分化的SH-SY5Y细胞在胞吐过程中释放部分囊泡内容物

乙酰胆碱（ACh）是认知功能、运动控制和突触调节的中枢神经递质，但它的电化学不活性和胞吐的快速动力学阻碍了实时量子测量。微米级的酶促ACh生物传感器以前可以进行亚毫秒级的细胞外记录，但对于突触定位和细胞内记录来说太大了。本文提出了一种短、超快、低噪声的基于针状碳纤维纳米电极的ACh生物传感器，该电极具有金纳米粒子和酶的功能。小型化的几何结构允许精确放置在神经突释放位点，并微创插入细胞质，从而实现突触前胞吐的高时间分辨率监测以及细胞内ACh囊泡含量的定量。我们将该平台应用于分化的人胆碱能SH-SY5Y神经母细胞瘤细胞，这是一种已建立但未充分利用的胆碱能信号传导细胞模型。纳米尖端传感器成功捕获了细胞内囊泡破裂事件和突触前乙酰胆碱释放的电流峰值。细胞内事件比突触前胞吐事件释放更多的乙酰胆碱，表明这些细胞以部分胞吐模式为主。这些结果表明，纳米尖端ACh生物传感器是一种独特的工具，可以在亚细胞分辨率下探测融合孔动力学，并为人类神经元模型中胆碱能信号的量子性质提供定量的见解。

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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来源期刊

Bioelectrochemistry 生物-电化学

CiteScore

9.10

自引率

6.00%

发文量

238

审稿时长

38 days

期刊介绍： An International Journal Devoted to Electrochemical Aspects of Biology and Biological Aspects of Electrochemistry Bioelectrochemistry is an international journal devoted to electrochemical principles in biology and biological aspects of electrochemistry. It publishes experimental and theoretical papers dealing with the electrochemical aspects of: • Electrified interfaces (electric double layers, adsorption, electron transfer, protein electrochemistry, basic principles of biosensors, biosensor interfaces and bio-nanosensor design and construction. • Electric and magnetic field effects (field-dependent processes, field interactions with molecules, intramolecular field effects, sensory systems for electric and magnetic fields, molecular and cellular mechanisms) • Bioenergetics and signal transduction (energy conversion, photosynthetic and visual membranes) • Biomembranes and model membranes (thermodynamics and mechanics, membrane transport, electroporation, fusion and insertion) • Electrochemical applications in medicine and biotechnology (drug delivery and gene transfer to cells and tissues, iontophoresis, skin electroporation, injury and repair). • Organization and use of arrays in-vitro and in-vivo, including as part of feedback control. • Electrochemical interrogation of biofilms as generated by microorganisms and tissue reaction associated with medical implants.