The characterization of topology is crucial in understanding network evolution and behavior. This paper presents an innovative approach, the GHuST framework to describe complex-network topology from graphlet decomposition. This new framework exploits the
Fig. 2: Structure, mechanics, and characteristics of the TCR–pMHC-I catch-bond model. a Force-induced conformational changes of a TCR–pMHC-I complex as it traverses from the bound state (left) to the transition state (right). The diagrams of the 2C TCR α (yellow) β (green) subun...
21. Our experiments also produce plasma jets that have magnetic Reynolds numbers large enough for the magnetic field to be ‘frozen into’ the plasma flow. Consequently, the plasma in the jet must follow the field topology and its evolution, which is locally kinked but globally ‘collimated’ a...
Fig. 2: Structure, mechanics, and characteristics of the TCR–pMHC-I catch-bond model. a Force-induced conformational changes of a TCR–pMHC-I complex as it traverses from the bound state (left) to the transition state (right). The diagrams of the 2C TCR α (yellow) β (green) subun...
cancer prognosis, in most of the situations considered. This finding contrasts with other reviews and meta-analyses considering only tumor characteristics, such as site or stage, to stratify patients and investigate the association between regulatory cells and prognosis [10,11,20,42,43]....