Soft robotics locomotion at the liquid–air interface
has
become more and more important for an intelligent society. However,
existing locomotion of soft robotics is limited to two dimensions.
It remains a formidable challenge to realize three-dimensional locomotion
(X, Y, and Z axes)
at the liquid–air two-phase interface due to the unbalanced
mechanical environment. Inspired by meniscus-climbing beetle larva Pyrrhalta, the mechanism of a three-phase (liquid–solid–air)
contact line is here proposed to address the aforementioned challenge.
A corresponding 3D printed fully soft robotics (named larvobot) based
on photoresponsive liquid crystal elastomer/carbon nanotubes composites
endowed repeatable programmable deformation and high degree-of-freedom
locomotion. Three-dimensional locomotion at the liquid–air
interface including twisting and rolling-up has been developed. The
equation of motion is established by analyzing the mechanics along
the solid–water surface of the larvobot. Meanwhile, ANSYS is
used to calculate the stress distribution, which coincides with the
speculation. Moreover, soft robotics is remotely driven by light in
a precise spatiotemporal control, which provides a great advantage
for applications. As an example, we demonstrate the controllable locomotion
of the soft robotics inside closed tubes, which could be used for
drug delivery and intelligent transportation.
Pancreatic ductal adenocarcinoma (PDAC) is one of the most malignant and lethal human cancers in the world due to its high metastatic potential, and patients with PDAC have a poor prognosis, yet quite little is understood regarding the underlying biological mechanisms of its high metastatic capacity. Baicalein has a dramatic anti-tumor function in the treatment of different types of cancer. However, the therapeutic effects of baicalein on human PDAC and its mechanisms of action have not been extensively understood. In order to explore the biological characteristic, molecular mechanisms, and potential clinical value of baicalein in inhibiting the metastatic capacity of PDAC. We performed several in vitro, in vivo, and in silico studies. We first examined the potential regulation of baicalein in the metastatic capacity of PDAC cells. We showed that baicalein could dramatically suppress liver metastasis of PDAC cells with highly metastatic potential in mice model. The high-throughput sequencing analysis was employed to explore the biological roles of baicalein in PDAC cells. We found that baicalein might be involved in the infiltration of Cancer-Associated Fibroblasts (CAF) in PDAC. Moreover, a baicalein-related risk model and a lncRNA-related model were built by Cox analysis according to the data set of PDAC from TCGA database which suggested a clinical value of baicalein. Finally, we revealed a potential downstream target of baicalein in PDAC, we proposed that baicalein might contribute to the infiltration of CAF via FGFBP1. Thus, we uncovered a novel role for baicalein in regulation of PDAC liver metastasis that may contribute to its anti-cancer effect. We proposed that baicalein might suppress PDAC liver metastasis via regulation of FGFBP1-mediated CAF infiltration. Our results provide a new perspective on clinical utility of baicalein and open new avenues for the inhibition of liver-metastasis of PDAC.
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