Abstract: Provided in the present invention are a substituted fused bicyclic compound as a kinase inhibitor and the use thereof. The substituted fused bicyclic compound has a structure as represented by formula I below, wherein a ring A, R0, B1-B3, D1-D3, R7 and R8 are defined herein. The compound of formula I is an NUAK1/2 inhibitor. Therefore, the compound of the present invention can be used for treating and preventing NUAK1/2-mediated diseases, disorders and conditions, such as cancer, and used in the preparation of drugs for treating and preventing NUAK1/2-mediated diseases, disorders and conditions.

Abstract: Provided is a use of Wee1 kinase inhibitors in the treatment of cancer. In particular, provided is a use of Wee1 kinase inhibitors in the preparation of drugs for the treatment of cancers with Histone H3K27M mutation.

Abstract: An artificial timber comprises the following components in parts by weight: 35-50 parts of cellulose, 20-35 parts of hemicellulose and 15-35 parts of lignin, wherein the artificial timber has a density of 0.01-0.05 g/cm3. The preparing method comprises: (1) dissolving 15-35 parts by weight of lignin, 35-50 parts by weight of cellulose and 20-35 parts by weight of hemicellulose with an ionic liquid; (2) cleaning and replacing it with water to obtain a lignocellulose hydrogel; and (3) drying the lignocellulose hydrogel to obtain an artificial timber. The artificial timber prepared by the present invention is large in specific area, low in density, low in material energy consumption, moderate in condition and easy for operation. The artificial timber obtained by the present invention is regular in shape and is shaped like a sandy beige cylinder without obvious damage and deformation, which indicates that such artificial timber with high specific area has well molding capacity.

Abstract: An artificial timber comprises the following components in parts by weight: 35-50 parts of cellulose, 20-35 parts of hemicellulose and 15-35 parts of lignin, wherein the artificial timber has a density of 0.01-0.05 g/cm3. The preparing method comprises: (1) dissolving 15-35 parts by weight of lignin, 35-50 parts by weight of cellulose and 20-35 parts by weight of hemicellulose with an ionic liquid; (2) cleaning and replacing it with water to obtain a lignocellulose hydrogel; and (3) drying the lignocellulose hydrogel to obtain an artificial timber. The artificial timber prepared by the present invention is large in specific area, low in density, low in material energy consumption, moderate in condition and easy for operation. The artificial timber obtained by the present invention is regular in shape and is shaped like a sandy beige cylinder without obvious damage and deformation, which indicates that such artificial timber with high specific area has well molding capacity.

Abstract: An electronic device includes a substrate with a plurality of LDS antennas and a conductive member, the substrate defines a first surface and a second surface opposite to the first surface. A decorative ink layer coats to the first surface of the substrate facing the interior of the electronic device, several LDS ink layers coat to the decorative ink layer, the LDS antennas are disposed on the corresponding LDS ink layers. The LDS antenna defines feed-in portion connecting with the conductive member, the conductive member comprises a flexible printed circuit and an anisotropic conductive adhesive connecting the flexible printed circuit and feed-in portion. Therefore, the transmission and reception of signal data can be realized through the connection between the flexible print circuit and the LDS antenna thereby enhance the effect of signal transmission and meet the needs of flexibility and miniaturization.

Abstract: An artificial timer and preparing method thereof. The artificial timber includes the following components in parts by weight: 35-50 parts of cellulose, 20-35 parts of hemicellulose and 15-35 parts of lignin, wherein the artificial timber has a density of 0.01-0.05 g/cm3. The preparing method includes: (1) dissolving 15-35 parts by weight of lignin, 35-50 parts by weight of cellulose and 20-35 parts by weight of hemicellulose with an ionic liquid; (2) cleaning and replacing it with water to obtain a lignocellulose hydrogel; and (3) drying the lignocellulose hydrogel to obtain an artificial timber. The prepared artificial timber is large in specific area, low in density, low in material energy consumption, moderate in condition and easy for operation. The obtained artificial timber is regular in shape and shaped like a sandy beige cylinder without obvious damage and deformation, which indicates that such artificial timber with high specific area has well molding capacity.

Abstract: Described herein is a method for treating and/or ameliorating at least one symptom associated with traumatic brain injury in a subject, the method comprises administering a safe and therapeutically effective amount of a composition comprising exosomes generated from hMSCs in 2D or 3D cultures.

Abstract: An electronic device includes a substrate with a plurality of LDS antennas and a conductive member, the substrate defines a first surface and a second surface opposite to the first surface. A decorative ink layer coats to the first surface of the substrate facing the interior of the electronic device, several LDS ink layers coat to the decorative ink layer, the LDS antennas are disposed on the corresponding LDS ink layers. The LDS antenna defines feed-in portion connecting with the conductive member, the conductive member comprises a flexible printed circuit and an anisotropic conductive adhesive connecting the flexible printed circuit and feed-in portion. Therefore, the transmission and reception of signal data can be realized through the connection between the flexible print circuit and the LDS antenna thereby enhance the effect of signal transmission and meet the needs of flexibility and miniaturization.

Abstract: An artificial timer and preparing method thereof. The artificial timber includes the following components in parts by weight: 35-50 parts of cellulose, 20-35 parts of hemicellulose and 15-35 parts of lignin, wherein the artificial timber has a density of 0.01-0.05 g/cm3. The preparing method includes: (1) dissolving 15-35 parts by weight of lignin, 35-50 parts by weight of cellulose and 20-35 parts by weight of hemicellulose with an ionic liquid; (2) cleaning and replacing it with water to obtain a lignocellulose hydrogel; and (3) drying the lignocellulose hydrogel to obtain an artificial timber. The prepared artificial timber is large in specific area, low in density, low in material energy consumption, moderate in condition and easy for operation. The obtained artificial timber is regular in shape and shaped like a sandy beige cylinder without obvious damage and deformation, which indicates that such artificial timber with high specific area has well molding capacity.

Abstract: An antenna includes a substrate and an antenna body disposed on the substrate. The substrate includes a first surface and a second surface connecting to the first surface. The antenna body includes a first radiator and a second radiator. The first radiator is disposed on the first surface of the substrate, the second radiator is disposed on the second surface. The first radiator is disposed by pad printing a conductive slurry, the second radiator is disposed by dispensing the conductive slurry.

Abstract: An antenna testing device includes an analyzer, a transmission probe electrically connected to the analyzer, a receiving probe electrically connected to the analyzer, and a shielded box having a cutoff frequency. The analyzer generates a test signal the frequency of which is lower than the cutoff frequency, the transmission probe receive the test signal and sends the test signal to the shielded box. The antenna is coupled with the transmission probe and generates a coupled signal, the receiving probe receives the coupled signal and sends the coupled signal to the analyzer. The analyzer analyzes the coupled signal and the test signal, the analyzer calculates the return loss of the antenna.

Abstract: An antenna module includes a frequency modulation radiator and a T-coil radiator electronically connecting to the frequency modulation radiator. The T-coil radiator and the frequency modulation radiator are made of conductive nano material. The present further discloses a wireless communication device using the antenna module.

Abstract: An antenna module includes a radiator made of nanomaterials; the conductivity of the nanomaterials are greater than or equal to about 5.8×107 S/m. The present further discloses a wireless communication device using the antenna module.

Abstract: A device housing has a transparent or translucent film, an antenna, and a substrate. The antenna is a conductive coating designed and configured in a pattern and is formed on portions of one surface of the film. The substrate is molded on the antenna and on the area of the film not covered by the antenna. A method for making the device housing is also described.

Abstract: An antenna module includes a supporting layer, a plurality of antenna layers; and at least one insulating layer. The antenna layers are conductive nanometric material formed on the supporting layer. The at least one insulating layer defines at least one through hole therein between and electronically connecting each two adjacent antenna layers to form an FM radiator. A housing utilizing the antenna module is also described.

Abstract: An antenna module includes a carrier and an antenna formed on the carrier. The carrier includes a first surface, a second surface, and a side surface. The antenna includes a first antenna portion and a second antenna portion. The first antenna portion includes a first radiation segment formed on the first surface and a second radiation segment formed on the side surface, the first radiation segment connects to the second radiation segment. The second antenna portion includes a third radiation segment formed on the first surface and a fourth radiation segment formed on the second surface, and the third radiation segment connects to the fourth radiation segment.

Abstract: An antenna module includes a radiator made of nanomaterials; the conductivity of the nanomaterials are greater than or equal to about 5.8×107 S/m. The present further discloses a wireless communication device using the antenna module.

Abstract: An antenna module includes a frequency modulation radiator and a T-coil radiator electronically connecting to the frequency modulation radiator. The T-coil radiator and the frequency modulation radiator are made of conductive nano material. The present further discloses a wireless communication device using the antenna module.

Abstract: An antenna testing device includes an analyzer, a transmission probe electrically connected to the analyzer, a receiving probe electrically connected to the analyzer, and a shielded box having a cutoff frequency. The analyzer generates a test signal the frequency of which is lower than the cutoff frequency, the transmission probe receive the test signal and sends the test signal to the shielded box. The antenna is coupled with the transmission probe and generates a coupled signal, the receiving probe receives the coupled signal and sends the coupled signal to the analyzer. The analyzer analyzes the coupled signal and the test signal, the analyzer calculates the return loss of the antenna.

Abstract: One embodiment of the present invention provides a circuit which blocks a keeper from interfering with a dynamic node during an evaluation phase for a dynamic wide-NOR structure. The circuit contains a precharge device which is coupled to the dynamic node. The precharge device precharges the dynamic node during a precharge phase. The circuit also contains a plurality of parallel pull-down transistors which are coupled to the dynamic node. The pull-down transistors conditionally discharge the dynamic node during the evaluate phase. The keeper sustains a precharged value on the dynamic node, thereby preventing a false evaluation caused by a leakage current through the parallel pull-down transistors. In addition, the circuit contains a feedback gating device which is coupled between the keeper and the dynamic node. During the evaluation phase, the feedback gating device blocks the keeper, so that the parallel pull-down transistors can discharge the dynamic node without interference from the keeper.