Enantiospecific Detection of D‐Amino Acid through Synergistic Upconversion Energy Transfer

D‐amino acids (DAAs) are indispensable in regulating diverse metabolic pathways. Selective and sensitive detection of DAAs is crucial for understanding the complexity of metabolic processes and managing associated diseases. However, current DAA detection strategies mainly rely on bulky instrumentation or electrochemical probes, limiting their cellular and animal applications. Here we report an enzyme‐coupled nanoprobe that can detect enantiospecific DAAs through synergistic energy transfer. This nanoprobe offers near‐infrared upconversion capability, a wide dynamic detection range, and a detection limit of 2.2 μM, providing a versatile platform for in vivo noninvasive detection of DAAs with high enantioselectivity. These results potentially allow real‐time monitoring of biomolecular handedness in living animals, as well as developing antipsychotic treatment strategies. A nanoprobe for D‐amino acid enantiospecific detection was proposed based on synergistic upconversion energy transfer, featuring a wide detection range, low detection limit, and in vivo noninvasive detection with high enantioselectivity.