Abstract: A smart wearable device has a signal calibration function executed by a signal calibration method and applied to a finger, a limb and/or a neck of a user. The smart wearable device includes at least one physiological signal detector, at least one pressure detector and an operation processor. The at least one physiological signal detector is adapted to abut against a detection area of the user for detecting a physiological signal. The at least one pressure detector is disposed around the at least one physiological signal detector and adapted to detect a pressure value of the detection area. The operation processor is electrically connected with the at least one physiological signal detector and the at least one pressure detector. The operation processor is adapted to optimize the physiological signal when the pressure value exceeds a predefined pressure threshold.

Abstract: Provided herein are rodents that express the human endosialin gene. In preferred embodiments, the rodent is a mouse. Preferably, the human endosialin gene is integrated into the native or endogenous endosialin gene locus. More preferably, the host rodent is null for the endogenous endosialin gene product. The human endosialin gene is preferably expressed in a similar development and disease response pattern as that of the native endosialin gene product in parental or wild type rodents. This feature makes these rodents useful for studying the effects of test agents to positively or negatively affect endosialin biology for therapeutic use. Use of human endosialin expressing rodents lacking native endosialin gene product (HUE rodents) is proposed as a strategy for developing agents that can positively or negatively affect the endosialin pathway and also serve as a screening tool to identify those agents that may be useful as human therapies.

Abstract: This invention provides a method of producing chitosan non-woven fabrics and an apparatus thereof. At first, a chitosan acidic solution is extruded to form a chitosan fibrous stream. Then, a solidifying agent is ejected to form a solidifying agent stream. The solidifying agent stream and the chitosan fibrous stream are combined to form a pre-solidified chitosan fiber. Then, high-pressure air is ejected on the pre-solidified chitosan fiber to stretch the pre-solidified chitosan fiber. Finally, the chitosan fibers are collected to form chitosan non-woven fabrics.

Abstract: This invention provides a method of producing chitosan non-woven fabrics and an apparatus thereof. At first, a chitosan acidic solution is extruded to form a chitosan fibrous stream. Then, a solidifying agent is ejected to form a solidifying agent stream. The solidifying agent stream and the chitosan fibrous stream are combined to form a pre-solidified chitosan fiber. Then, high-pressure air is ejected on the pre-solidified chitosan fiber to stretch the pre-solidified chitosan fiber. Finally, the chitosan fibers are collected to form chitosan non-woven fabrics.

Abstract: A surface-finished yarn having multiple inorganic materials is provided. The surface-finished yarn comprises a yarn, a first material and a second material. The surface of the yarn comprises a plurality of the plurality of first regions and a plurality of second regions wherein the plurality of first regions and the plurality of second regions are alternately disposed along an axial direction of the yarn. The first material is disposed onto the plurality of first regions while the second material different from the first material is disposed onto the plurality of second regions.

Abstract: A textile with transparent light structure and heat-insulating construction and the method of manufacturing the same comprise a surface layer and an underlying layers the underlying layer and the surface layer have air layers and high shrinkage-rate yarns therein, and include non-transparent weft yarns and transparent yarns. By controlling the non-transparent yarn and the transparent yarn, the transparent light property can be obtained. Further, through the heat treatment, the multiple high shrinkage-percentage yarns thereto contract to make the surface layer and the underlying layer individually protruded. The air layers are just the heat insulating factor of the textile.

Abstract: A surface-finished yarn having multiple inorganic materials is provided. The surface-finished yarn comprises a yarn, a first material and a second material. The surface of the yarn comprises a plurality of the plurality of first regions and a plurality of second regions wherein the plurality of first regions and the plurality of second regions are alternately disposed along an axial direction of the yarn. The first material is disposed onto the plurality of first regions while the second material different from the first material is disposed onto the plurality of second regions.

Abstract: A micro-capsulated thermal-stable phase-change polymer is mixed with a melt-spinning polymer, and melt-spinning grains are obtained after processing the mixture described above. The thermal-stable phase-change polymer has a polyether main chain and two fatty acyl terminals. The polyether main chain is polyethylene glycol or polytetramethylene glycol. The two fatty acyl terminals are preferably stearoyl group, palmitoyl group, or lauroyl group.

Abstract: This invention provides a method of producing chitosan non-woven fabrics and an apparatus thereof. At first, a chitosan acidic solution is extruded to form a chitosan fibrous stream. Then, a solidifying agent is ejected to form a solidifying agent stream. The solidifying agent stream and the chitosan fibrous stream are combined to form a pre-solidified chitosan fiber. Then, high-pressure air is ejected on the pre-solidified chitosan fiber to stretch the pre-solidified chitosan fiber. Finally, the chitosan fibers are collected to form chitosan non-woven fabrics.

Abstract: A textile with transparent light structure and heat-insulating construction and the method of manufacturing the same comprise a surface layer and an underlying layer, and the weft yarns of the underlying layer and the surface layer include non-transparent weft yarns and transparent yarns. By controlling the arrangement and ratio of the non-transparent yarn and the transparent yarn, the transparent light property can be obtained. Further, between the underlying layer and the surface layer, there are a multiple of high shrinkage-rate yarns included. Through the heat treatment, it would cause the contraction of the multiple high shrinkage-percentage yarns thereto make the surface layer and the underlying layer individually protrude like a three-dimensional structure. Besides, because of the different shrinkage rates, the thickness of the air layer of the underlying layer, the surface layer and the multiple high shrinkage-percentage yarns would also vary.