Fabrication of hollow mesoporous silica-based nanoreactors for enzyme immobilization: high loading capacity, effective protection, and recyclability

“…38,41 Additionally, the terephthalic acid (BDC 2− ) are coordinated with Cu 2+ in a bidentate bridging fashion to prepare stable carrier, providing a gentle environment to protect the enzyme from the bad environment and thereby reducing the conformational change of enzyme. 64–67…”

“…38,41 Additionally, the terephthalic acid (BDC 2− ) are coordinated with Cu 2+ in a bidentate bridging fashion to prepare stable carrier, providing a gentle environment to protect the enzyme from the bad environment and thereby reducing the conformational change of enzyme. [64][65][66][67] Fig. 8b and c demonstrate that the Sna&β-G@H-Cu-BDC biocomposite had good stability, which is conductive to the recovery of the enzyme.…”

Construction of a hollow MOF with high sedimentation performance and co-immobilization of multiple-enzymes for preparing rare ginsenoside CK

“…38,41 Additionally, the terephthalic acid (BDC 2− ) are coordinated with Cu 2+ in a bidentate bridging fashion to prepare stable carrier, providing a gentle environment to protect the enzyme from the bad environment and thereby reducing the conformational change of enzyme. 64–67…”

“…38,41 Additionally, the terephthalic acid (BDC 2− ) are coordinated with Cu 2+ in a bidentate bridging fashion to prepare stable carrier, providing a gentle environment to protect the enzyme from the bad environment and thereby reducing the conformational change of enzyme. [64][65][66][67] Fig. 8b and c demonstrate that the Sna&β-G@H-Cu-BDC biocomposite had good stability, which is conductive to the recovery of the enzyme.…”

Construction of a hollow MOF with high sedimentation performance and co-immobilization of multiple-enzymes for preparing rare ginsenoside CK