Development of a waterlily-inspired autonomous cloud connected platform for Ca²⁺ monitoring.

IF 2.6 3区化学 Q2 CHEMISTRY, ANALYTICAL

Analytical Methods Pub Date : 2025-09-26 DOI:10.1039/d5ay01095k

İsmail Ağır

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Abstract

In this study, we developed an innovative water quality monitoring platform that enables cloud-based data transmission using a calcium ion-selective electrode. On-field measurement systems offer significant advantages for water quality monitoring, as they eliminate the need for laboratory infrastructure and associated logistics required by traditional methods. However, to achieve effective implementation with in situ measurement instruments such as sensors, challenges related to data transmission, energy supply, sampling, and field distribution need to be addressed. To this end, we designed a modular 3D-printed platform inspired by the waterlily, whose broad floating leaves offer natural stability on water surfaces. A custom microfluidic chip was produced to support sensor operation, and a micro-pump was integrated to sample and analyze water samples. We performed all system operations using software algorithms and electronic circuits developed in-house for overall control. The microfluidic system was optimized to enable efficient sampling and reliable delivery of water to the sensor for accurate measurement. The platform was utilised to carry out operations with low energy consumption and low cost, while the data were successfully transmitted and stored in a cloud database.

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一种以睡莲为灵感的自主云连接Ca2+监测平台的开发。

在这项研究中，我们开发了一种创新的水质监测平台，该平台使用钙离子选择电极实现基于云的数据传输。现场测量系统为水质监测提供了显著的优势，因为它们消除了传统方法所需的实验室基础设施和相关物流的需要。然而，为了有效地实施现场测量仪器，如传感器，需要解决与数据传输、能源供应、采样和现场分布相关的挑战。为此，我们设计了一个模块化的3d打印平台，灵感来自睡莲，睡莲宽阔的漂浮叶子在水面上提供自然的稳定性。定制微流控芯片支持传感器工作，集成微泵对水样进行采样和分析。我们使用内部开发的软件算法和电子电路执行所有系统操作，以进行整体控制。微流体系统进行了优化，以实现高效采样和可靠的水输送到传感器进行精确测量。利用该平台进行低能耗、低成本的作业，同时数据成功传输并存储在云数据库中。

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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