break with convention! Reveal the new mechanism of nanoparticles into tumor!

Researchers from the University of Toronto found that it is the active process rather than the passive process that determines which nanoparticles enter the solid tumor This discovery overturned previous ideas in the field of cancer nano medicine and pointed out the direction for more effective nano therapy The relevant research results were recently published in nature materials The main theory of cancer nanomedicine is that nanoparticles passively diffuse into tumors through tiny gaps between endothelial cells Endothelial cells are arranged on the inner wall of blood vessels to support the growth of tumors Previous studies by researchers have shown that less than 1% of nanoparticle drugs can reach their tumor targets In the current study, the team found that more than 95% of nanoparticles that can penetrate tumors can penetrate endothelial cells, rather than gaps between these cells "Our work challenges a long held belief in a new theory," said Abdullah Syed, a postdoctoral fellow at Warren Chan laboratory, a co-author of the study Professor Warren Chan is a professor at the Institute of biomaterials and Biomedical Engineering (ibbme) and the Donnelly Center for cell and biomolecular research "We see many nanoparticles entering endothelial cells from blood vessels and into tumors under various conditions Endothelial cells seem to be the key gatekeepers in the transport of nanoparticles " Syed likens nanoparticles to people trying to enter popular restaurants on busy nights "Some restaurants don't need to be booked, while others have security to check if customers have booked," he said Gatekeepers are much more common than researchers think, and most places only accept customers with appointments " Through multiple evidences, the researchers determined that passive diffusion was not the main entry mechanism They extracted more than 400 images of tissue samples from animal models and found that compared with nanoparticles, endothelial cells had almost no gaps They observed the same trend with 3-D fluorescence imaging and live animal imaging Similarly, they found almost no gaps between endothelial cells in samples from human cancer patients The team then designed an animal model that completely blocked the transport of nanoparticles through endothelial cells This allowed them to separate the contribution of passive transport through the gap between endothelial cells, which proved to be very small Researchers have proposed several active mechanisms for endothelial cells to transport nanoparticles into tumors, including binding mechanisms, endothelial pathways and undiscovered processes, all of which they are studying At the same time, this result is of great significance for the treatment based on nanoparticles Shrey sindhwani, a PhD student at Chan lab and another co-author of the study, said: "these findings will change our idea of using nanoparticles to provide drugs for tumors A better understanding of the transport of nanoparticles will help researchers design more effective treatments "