This study presents an innovative solution to the escalating issue of river eutrophication by combining real-time monitoring with nutrient removal using a microbial fuel cell (MFC) system. Eutrophication, often caused by excess nitrogen and phosphorus from agricultural runoff and wastewater discharge, leads to the degradation of water quality and harm to aquatic ecosystems. The MFC system developed in this study measures changes in electrical current to track nutrient concentrations, offering continuous, real-time data. As nutrient levels rise, the system activates a purification mechanism using biological activated carbon immobilized with Pseudomonas putida, which helps to decompose and remove excess nutrients. FT-IR analysis confirmed that Shewanella putrefaciens generates current through nutrient uptake, with current production increasing from 2.93 µA to 27.63 µA as nutrient concentrations increase. Once the nutrient removal process is triggered, current levels decrease to 21.30 µA, indicating successful nutrient depletion and purification. The system's design is self-sustaining, powered entirely by electricity produced by the microbial fuel cell, which makes it energy-efficient and particularly suitable for regions with limited access to external power. This autonomous operation requires minimal human intervention, reducing operational costs and ensuring long-term, continuous monitoring and nutrient removal. By combining monitoring with active purification, the system not only detects changes in water quality but also serves as an early intervention tool to prevent eutrophication from worsening. Furthermore, the study suggests that this system could be applied to a range of freshwater environments, from small rivers to larger lakes, offering a scalable solution for eutrophication management. With its potential for real-time monitoring and sustainable nutrient removal, this system could play a key role in improving water quality, enhancing ecosystem health, and addressing long-term environmental challenges posed by nutrient pollution.