Hydrogel-Embedded Quantum Dot–Transcription Factor Sensors for Quantitative Progesterone Detection
Mingfu Chen, Chloé Grazon, Prerana Sensharma, Thuy Thi Thanh Nguyen, Yunpeng Feng, Margaret Chern, R C. Baer, Nitinun Varongchayakul, Katherine Cook, Sébastien Lecommandoux, Catherine M. Klapperich, James E. Galagan, Allison M. Dennis, Mark W. Grinstaff
Abstract
Immobilization of biosensors in or on a functional material is critical for subsequent device development and translation to wearable technology. Here, we present the development and assessment of an immobilized quantum dot–transcription factor–nucleic acid complex for progesterone detection as a first step toward such device integration. The sensor, composed of a polyhistidine-tagged transcription factor linked to a quantum dot and a fluorophore-modified cognate DNA, is embedded within a hydrogel as an immobilization matrix. The hydrogel is optically transparent, soft, and flexible as well as traps the quantum dot–transcription factor DNA assembly but allows free passage of the analyte, progesterone. Upon progesterone exposure, DNA dissociates from the quantum dot–transcription factor DNA assembly resulting in an attenuated ratiometric fluorescence output via Förster resonance energy transfer. The sensor performs in a dose-dependent manner with a limit of detection of 55 nM. Repeated analyte measurements are similarly successful. Our approach combines a systematically characterized hydrogel as an immobilization matrix and a transcription factor–DNA assembly as a recognition/transduction element, offering a promising framework for future biosensor devices.