The early cardiac biological pacemaker studies were mostly around HCN channel, and how to build a biological pacemaker through the enhanced If current. In recent years, however, people found that the genes of Tbx3 could play an important role in the development of cardiac conduction system, especially in processes of the maturity of the sinoatrial node and maintenance of its function. And the Tbx3 can further optimize the biological pacemaker. Therefore, it could be a new therapeutic focus in biological pacemaker and treatment of cardiac conduction system disease. This paper summarizes some of the latest research progress of the Tbx3 in biological pacemaker in recent years. We hope that this review could provide theoretical basis for the clinical applications of Tbx3.
The biological pacemaker has become a new strategy in the treatment of severe bradycardias, in which a kind of ideal pacemaker cells is a pivotal factor. Here we reviewed the progress in the differentiation of bone-marrow mesenchymal stem cells and adipose-derived stem cells into pacemaker-like cells by means of gene transfer, chemical molecules, co-culture with other cells and specific culture media, and we also analyzed the potential issues to be solved when they are used as seeding cells of biological pacemaker.