In this research editorial, we offer a novel design for a quantum-based nanosensor node architecture suitable for next-generation wireless sensor networks. The need detection of analytes in the environment is increasingly important for a variety of applications, including environmental monitoring, healthcare, and security. The proposed architecture employs a band to generate surface plasmon polaritons (SPPs) directly on the graphene outward, which provides a highly sensitive and selective mechanism for detecting analytes. Graphene, a twodimensional material with exceptional electrical, optical, and mechanical properties, has recently emerged as a promising candidate for various sensing applications. The GFET converts the SPPs into an electrical signal, which can be read out using conventional electronics. The proposed architecture offers several advantages over existing nanosensor node designs, including high sensitivity and selectivity, low power consumption, and compatibility with wireless communication networks. Simulation results establish the effectiveness of the proposed architecture in terms of its sensing performance.