This review explores the synergy of synthetic biology and AI in developing intelligent bacterial biosensors. It covers core design principles, AI-driven optimization, and diverse detection applications across various fields.
Dipole-inducing side chains in amorphous polymers boost dielectric constants above 6 while preserving good insulation, enabling 3 V operating organic transistors with high mobility (∼1.90 cm² V−1 s−1) and operation stability.
Synthetic biology acts as a game-changer for endangered medicinal orchids, enabling a transition from resource scarcity and extraction inefficiency to sustainable conservation through pathway decoding, chassis engineering and green biomanufacturing.
Realizing spin-operated quantum logic circuits at the nanoscopic level has been one of the major challenges in designing modern computing architectures by encoding quantum information in the spin states of electrons.
We introduce a three-level circuit concept, which clarifies the distinction between the OFF state and logic 0 in prior DNA circuits. This design allows a DNA circuit to attain a true closed state instead of a misleading closed state of logic 0.