Abstract: Provided is an anti-HER3 humanized monoclonal antibody. The antibody binds HER3 antigen, has high affinity and biological activity and low immunogenicity, and is stable in structure. The antibody can be used for preparing drugs for preventing or treating HER3-related diseases.

Abstract: Systems and methods are provided for water electrolysis. The system includes an ion exchange membrane, a first electrode catalyst layer on a first side of the ion exchange membrane, wherein the first electrode catalyst layer includes a transition metal-phosphorus-based compound on the first side of the ion exchange membrane, and a second electrode catalyst layer on a second side of the ion exchange membrane opposite the first side. In some embodiments, the first electrode catalyst layer is electroplated to the first side of the ion exchange membrane. In some embodiments, the second electrode catalyst layer includes a compound comprising the same transition metal as the first electrode catalyst layer.

Abstract: This disclosure relates generally to vaporizing devices having short-circuit and leak proof capabilities. Specifically, embodiments of the present disclosure provide vaporizing devices including an atomizer wrapped with a non-woven wick and received by a distal cavity in a center post. The non-woven wick is in fluid communication with a reservoir, placing the atomizer also in fluid communication with the reservoir. Fluid travels from the reservoir, through the wick, to the atomizer to be atomized, and vaporized fluid can be pulled proximally out of the vaporizing device. A clearance of approximately 1.0 to 2.5 mm separates a top surface of the atomizer from a top surface of the distal cavity. The vaporizing devices additionally include an electrode (e.g., an anode) in electrical communication with an anode wire of the atomizer. An insulating sleeve maintains the position of the anode wire against the electrode, allowing for good electrical conductivity and communication.

Abstract: This application discloses a wireless charging system, and pertains to the field of wireless charging technologies. The system includes: a transmit apparatus and a receive apparatus; the transmit apparatus includes an inverter circuit and two transmit electrodes, an input terminal of the inverter circuit is connected to a direct-current power supply, and two output terminals of the inverter circuit are connected to the two transmit electrodes respectively; the receive apparatus includes two receive electrodes and a rectifier circuit, two input terminals of the rectifier circuit are connected to the two receive electrodes respectively, and an output terminal of the rectifier circuit is connected to a load.

Abstract: The present invention relates to the field of agriculture biotechnology, specially relates to an amylase mutant having high specific activity and thermal stability, gene and use thereof. Said amylase mutant is obtained by performing substitution of S33A/S34E/V35H, and deletion of amino acids at the sites of 178 and 179 of the wild type amylase having amino acid sequence of SEQ ID NO:1, and having improved enzymatic activity and thermal stability than the wild type amylase.

Abstract: This application provides a charging pad used in a wireless charger. The charging pad can be wound. Specifically, the charging pad includes a rigid region and a flexible region, and a structure of the rigid region is different from a structure of the flexible region. A rigid support plate is disposed in the rigid region, and a metal line in the flexible region is in a metal hinge structure or is a bendable metal conducting wire. In addition, this application further provides a wireless charger to which the charging pad is applied.

Abstract: The present invention relates to the field of agriculture biotechnology, specially relates to an amylase mutant having high specific activity and thermal stability, gene and use thereof. Said amylase mutant is obtained by performing substitution of S33A/S34E/V35H, and deletion of amino acids at the sites of 178 and 179 of the wild type amylase having amino acid sequence of SEQ ID NO:1, and having improved enzymatic activity and thermal stability than the wild type amylase.

Abstract: A MEMS device includes at least one proof mass, the at least one proof mass is capable of moving to contact at least one target structure. The MEMS device further includes at least one elastic bump stop coupled to the proof mass and situated at a first distance from the target structure. The MEMS device additionally includes at least one secondary bump stop situated at a second distance from the target structure, wherein the second distance is greater than the first distance, and further wherein the at least one elastic bump stop moves to reduce the first distance when a shock is applied.

Abstract: Device and method for forming a device are disclosed. The method includes providing a substrate prepared with a memory cell region having a pair of non-volatile memory cells with a split gate. A split gate includes first and second gates. The first gate is an access gate and the second gate is a storage gate with a control gate over a floating gate. A common second S/D region is disposed adjacent to second gates of the first and second memory cells and first S/D regions are disposed adjacent to the first gates of the first and second memory cells. An erase gate is disposed over the common second S/D region. The erase gate is isolated by the second S/D and second gates by dielectric layers. A silicide block is disposed over the memory cell pair, covering the erase gate at least portions of the second gates of the memory cells.

Abstract: Disclosed herein are isotopically labeled calcofluor derivatives and uses of such to detect fungi, such as filamentous fungi, including Aspergillus species, such as by positron emission tomography (PET) scanning.

Abstract: Disclosed herein are isotopically labeled calcofluor derivatives and uses of such to detect fungi, such as filamentous fungi, including Aspergillus species, such as by positron emission tomography (PET) scanning.

Abstract: Disclosed herein are isotopically labeled calcofluor derivatives and uses of such to detect fungi, such as filamentous fungi, including Aspergillus species, such as by positron emission tomography (PET) scanning.

Abstract: Device and method for forming a device are disclosed. The method includes providing a substrate prepared with a memory cell region having a pair of non-volatile memory cells with a split gate. A split gate includes first and second gates. The first gate is an access gate and the second gate is a storage gate with a control gate over a floating gate. A common second S/D region is disposed adjacent to second gates of the first and second memory cells and first S/D regions are disposed adjacent to the first gates of the first and second memory cells. An erase gate is disposed over the common second S/D region. The erase gate is isolated by the second S/D and second gates by dielectric layers. A silicide block is disposed over the memory cell pair, covering the erase gate at least portions of the second gates of the memory cells.

Abstract: Described herein is an accelerometer that can be sensitive to acceleration, but not anchor motion due to sources other than acceleration. The accelerometer can employ a set of electrodes and/or transducers that can register motion of the proof mass and support structure and employ and output-cancelling mechanism so that the accelerometer can distinguish between acceleration and anchor motion due to sources other than acceleration. For example, the effects of anchor motion can be cancelled from an output signal of the accelerometer so that the accelerometer exhibits sensitivity to only acceleration.

Abstract: A MEMS device including a first proof mass, a first magnetized magnetic material disposed partially on a surface of the first proof mass, a first spring anchored to a substrate to support the first proof mass, and a first sensing element coupled to the first proof mass and operable to sense the motion of the first proof mass caused by an ambient acceleration. The MEMS device further includes a second sensing element coupled to the first proof mass and operable to sense the motion of the first proof mass caused by an ambient magnetic field.

Abstract: Disclosed herein are isotopically labeled calcofluor derivatives and uses of such to detect fungi, such as filamentous fungi, including Aspergillus species, such as by positron emission tomography (PET) scanning.

Abstract: Described herein is an accelerometer that can be sensitive to acceleration, but not anchor motion due to sources other than acceleration. The accelerometer can employ a set of electrodes and/or transducers that can register motion of the proof mass and support structure and employ and output-cancelling mechanism so that the accelerometer can distinguish between acceleration and anchor motion due to sources other than acceleration. For example, the effects of anchor motion can be cancelled from an output signal of the accelerometer so that the accelerometer exhibits sensitivity to only acceleration.

Abstract: Described herein is an accelerometer that can be sensitive to acceleration, but not anchor motion due to sources other than acceleration. The accelerometer can employ a set of electrodes and/or transducers that can register motion of the proof mass and support structure and employ and output-cancelling mechanism so that the accelerometer can distinguish between acceleration and anchor motion due to sources other than acceleration. For example, the effects of anchor motion can be cancelled from an output signal of the accelerometer so that the accelerometer exhibits sensitivity to only acceleration.