Control of Tire Wear Particulate Matter through Tire Tread Prescription.

This study aims to analyze tire wear particulate matter (TWP) from tread rubber with different formulations and to compare the concentration of TWP with different wear devices. The TWP generated during the abrasion of truck and bus radial (TBR) tires were examined, and the effect of using different types of rubber and carbon black (CB) were investigated. When natural rubber (NR) was solely used as the tire tread rubber material, there was a higher concentration of 5-10 µm TWP. However, when the tread formulation consisted of NR mixed with butadiene rubber, the TWP concentration decreased. Changing the type of CB also reduced the amount of TWP in the 2.5 µm size range. The TWP concentration in the specimens increased with increasing speed and vertical load. The TWP generated during the abrasion tests using wear testers and tire simulators exhibited similar trends. These findings suggest that modifying tire tread formulations can effectively control the distribution and amount of TWP generation.

Adult stem cells from the hyaluronic acid-rich node and duct system differentiate into neuronal cells and repair brain injury.

The existence of a hyaluronic acid-rich node and duct system (HAR-NDS) within the lymphatic and blood vessels was demonstrated previously. The HAR-NDS was enriched with small (3.0-5.0 µm in diameter), adult stem cells with properties similar to those of the very small embryonic-like stem cells (VSELs). Sca-1(+)Lin(-)CD45(-) cells were enriched approximately 100-fold in the intravascular HAR-NDS compared with the bone marrow. We named these adult stem cells "node and duct stem cells (NDSCs)." NDSCs formed colonies on C2C12 feeder layers, were positive for fetal alkaline phosphatase, and could be subcultured on the feeder layers. NDSCs were Oct4(+)Nanog(+)SSEA-1(+)Sox2(+), while VSELs were Oct4(+)Nanog(+)SSEA-1(+)Sox2(-). NDSCs had higher sphere-forming efficiency and proliferative potential than VSELs, and they were found to differentiate into neuronal cells in vitro. Injection of NDSCs into mice partially repaired ischemic brain damage. Thus, we report the discovery of potential adult stem cells that may be involved in tissue regeneration. The intravascular HAR-NDS may serve as a route that delivers these stem cells to their target tissues.

4-1BB signal stimulates the activation, expansion, and effector functions of γδ T cells in mice and humans.

We show here that the expression of 4-1BB is rapidly induced in γδ T cells following antigenic stimulation in both mice and humans, and ligation of the newly acquired 4-1BB with an agonistic anti-4-1BB augments cell division and cytokine production. We further demonstrate that γδ rather than αß T cells protect mice from Listeria monocytogenes (LM) infection and 4-1BB stimulation enhances the γδ T-cell activities in the acute phase of LM infection. IFN-γ produced from γδ T cells was the major soluble factor regulating LM infection. Vγ1(+) T cells were expanded in LM-infected mice and 4-1BB signal triggered an exclusive expansion of Vγ1(+) T cells and induced IFN-γ in these Vγ1(+) T cells. Similarly, 4-1BB was induced on human γδ T cells and shown to be fully functional. Combination treatment with human γδ T cells and anti-hu4-1BB effectively protected against LM infection in human γδ T cell-transferred NOD-SCID mice. Taken together, these data provide evidence that the 4-1BB signal is an important regulator of γδ T cells and induces robust host defense against LM infection.