Mechanical Signaling in Dental Pulp Stem Cells.

Dental pulp stem cells (DPSCs) are a type of mesenchymal stem cells derived from dental pulp that serves as an important model for investigating biological regeneration. DPSCs have a multipotent differentiation capacity and can promote different biological processes, including osteogenesis, odontogenesis, chondrogenesis, and angiogenesis. These biological processes are regulated by an extensive range of intra- and extra-cellular factors. Further, biomechanical cues, such as substrate stiffness, physical stress, and cell spreading, have been highlighted as particularly important modulators of DPSC function. This review sought to discuss various related signaling components involved in biomechanical cues and their respective roles in cellular and tissue responses in DPSCs, summarize current findings, and provide an outlook on the potential applications of biomechanics in regenerative medicine and tissue engineering.

Melamine-based Covalent Organic Polymers (MCOPs) as Lipase Nanocarrier for Recyclable Esters Hydrolysis and Transesterification.

Present study has successfully synthesized melamine-based covalent organic polymers (MCOPs) and applied it as lipase carrier for recyclable esters hydrolysis and transesterification. The synthesized MCOPs are composed of dense nanosheet structures having a thickness of 3.5 nm. Three immobilization methods namely physical adsorption, cross-linking and carrier activation were employed to prepare the MCOPs-immobilized CRL. Cross-linked MCOPs-immobilized CRL (41.30 mg protein/g MCOPs) and carrier activated MCOPs-immobilized CRL (33.20 mg protein/g MCOPs) had higher enzyme loading as compared to physical absorb MCOPs-immobilized CRL (29.30 mg protein/g MCOPs). Nevertheless, physical absorb MCOPs-immobilized CRL demonstrated the highest esters hydrolysis (49.85 U) and transesterification (1.04 U) activities. Despite having the highest enzymatic activity, physical absorb MCOPs-immobilized CRL were not able to maintain its catalytic stability with more than 30% decreased in enzymatic activity during consecutive hydrolysis and transesterification activities. Meanwhile, cross-linked MCOPs-immobilized CRL demonstrated highest catalytic stability with highest enzymatic activities at the end of consecutive reactions. All the MCOPs-immobilized CRL can be easily recovered and reused through centrifugation with more than 85% of recovery rate.