Abstract: A medical device, a stapler, and a rotation locking mechanism, the medical device including a handheld mechanism, a connecting mechanism, and an actuator. The connecting mechanism is connected to the handheld mechanism and the actuator. The handheld mechanism is internally provided with a first rotation locking mechanism and a first transmission mechanism connected to the first rotation locking mechanism. A second rotation locking mechanism matching the first rotation locking mechanism is disposed on the connecting mechanism. When the first transmission mechanism is in a first state, the first rotation locking mechanism and the second rotation locking mechanism are in an unlocked state, such that the connecting mechanism is rotatable. When the first transmission mechanism is in a second state, the first rotation locking mechanism and the second rotation locking mechanism are in a locked state, such that the connecting mechanism is locked, thereby improving surgery safety and surgery efficiency.

Abstract: An optical element drive mechanism is provided. The optical element drive mechanism includes an immovable part, a movable part, a drive assembly, and a strengthening assembly. The movable part is connected to an optical element. The movable part is movable relative to the immovable part. The drive assembly drives the movable part to move relative to the immovable part. The strengthening assembly strengthens the driving force of the drive assembly. The strengthening assembly is close to the drive assembly.

Abstract: A haptic feedback module with a touch panel and a piezoelectric haptic feedback module is disclosed. The piezoelectric haptic feedback module contacts with the touch panel and has a first soft circuit board and a plurality of piezoelectric units. The first soft circuit board has a plurality of first electrode areas and each first electrode area has a first length. Each of the piezoelectric units is respectively configured below each of the first electrode areas. Each of the piezoelectric units has a second length, wherein the first length is 10% to 20% of the second length.

Abstract: The disclosure is directed to compounds of Formula I Pharmaceutical compositions comprising compounds of Formula I, as well as methods of their use and preparation, are also described.

Abstract: A composition with exogenous mitochondria as active ingredients, and a use thereof and a cell repairing method therefor. The composition includes exogenous mitochondria and at least one pharmaceutically or cosmetically acceptable carrier. The composition may further include an adjuvant, and the adjuvant is selected from a group consisting of serum, plasma, complement and at least the above two ingredients. The exogenous mitochondria are obtained from cells by a centrifugal purification method.

Abstract: Techniques described herein provide means by which cell information indicative of a location of a UE may be conveyed to a location server over a 5G NR data connection using a SUPL message with an LTE cell ID data field. In some embodiments, for example, the UE may include the Cell ID of a LTE neighbor cell or information regarding a 5G NR serving cell, such as a portion of the 5G NR Cell ID or a reserved value or sequence identifying the 5G NR serving cell. The techniques may be applicable to the Secure User Plane Location (SUPL) solution defined by OMA and may enable a UE and a SUPL Location Platform (SLP) to support location of the UE using a version of SUPL without explicit support of 5G NR wireless access.

Abstract: This present invention provides a method for continuously maintaining growth of a motor neuron progenitor cell and a pharmaceutical composition. Wherein, the method for continuously maintaining growth of a motor neuron progenitor cell is to culture the motor neuron progenitor cell in an environment which is constructed by the olfactory ensheathing cells to make the motor neuron progenitor cell sustain the ability to self-replicate and to be induced for differentiating into mature neuron, and therefore to elaborate the effect to protect the motor neuron. The motor neuron progenitor cell produced from the method disclosed in this present invention can be an effective ingredient of the pharmaceutical composition for treating related diseases of damaged motor neuron.

Abstract: The disclosure is directed to crystalline forms of the compound of Formula I, pharmaceutically acceptable salts of the compound of Formula I, and crystalline forms thereof. Pharmaceutical compositions comprising said crystalline forms and salts, as well as methods of their use and preparation, are also described.

Abstract: The disclosure is directed to methods of treating disease using compounds of Formula (I).

Abstract: The disclosure is directed to compounds of Formula I Pharmaceutical compositions comprising compounds of Formula I, as well as methods of their use and preparation, are also described.

Abstract: The disclosure is directed to methods of treatment using compounds of Formula (I).

Abstract: The present disclosure discloses a flexible antenna structure and an electronic device having the same. The flexible antenna structure includes a flexible printed circuit board, a mm-Wave antenna disposed on the flexible printed circuit board and conformal with the flexible printed circuit board, and a non-mm-Wave antenna disposed on the flexible printed circuit board and conformal with the flexible printed circuit board. Compared with the existing art, by means of the flexible antenna structure provided with the mm-Wave antenna and the non-mm-Wave antenna on the flexible printed circuit board, the present disclosure realizes integration of the mm-Wave antenna and the non-mm-Wave antenna, solves a challenge of numerous antennas in the electronic device, and realizes conformation with a bent part of a shell 1, thereby increasing the space utilization rate in a limited space. Furthermore, the overall size and cost cannot be increased, thus improving the competitiveness of a product.

Abstract: The present disclosure discloses an antenna device and an electronic apparatus having the antenna device. The antenna device includes a first antenna structure and a second antenna structure; the first antenna structure includes a first mm-wave antenna and a first mm-wave RFIC electrically connected with the first mm-wave antenna; and the second antenna structure includes a flexible printed circuit board and a second mm-wave antenna arranged on the flexible printed circuit board. The first antenna structure includes a first non-mm-wave antenna and/or the second antenna structure includes a second non-mm-wave antenna arranged on the flexible printed circuit board.

Abstract: The present disclosure discloses an antenna apparatus and an electronic device. The antenna apparatus includes a circuit board, an antenna stand arranged on the circuit board, and an antenna structure arranged on the antenna stand. The antenna structure includes a flexible printed circuit board, a millimeter wave (mm-wave) antenna arranged on the flexible printed circuit board, and a non-mm-wave antenna arranged on the flexible printed circuit board.

Abstract: A method includes depositing a first dielectric layer over a substrate; forming a first dummy metal layer over the first dielectric layer, wherein the first dummy metal layer has first and second portions laterally separated from each other; depositing a second dielectric layer over the first dummy metal layer; etching an opening having an upper portion in the second dielectric layer, a middle portion between the first and second portions of the first dummy metal layer, and a lower portion in the first dielectric layer, wherein a width of the lower portion of the opening is greater than a width of the middle portion of the opening, and a bottom of the opening is higher than a bottom of the first dielectric layer; and forming a dummy via in the opening and a second dummy metal layer over the dummy via and the second dielectric layer.

Abstract: The present disclosure discloses an antenna device and an electronic apparatus having the antenna device. The antenna device includes a first antenna structure and a second antenna structure; the first antenna structure includes a first mm-wave antenna and a first mm-wave RFIC electrically connected with the first mm-wave antenna; and the second antenna structure includes a flexible printed circuit board and a second mm-wave antenna arranged on the flexible printed circuit board. The first antenna structure includes a first non-mm-wave antenna and/or the second antenna structure includes a second non-mm-wave antenna arranged on the flexible printed circuit board.

Abstract: The present invention relates to an integration module system of millimeter-wave and non-millimeter-wave antennas and an electronic apparatus, the system comprising a millimeter-wave antenna module and a non-millimeter-wave environment, the millimeter-wave antenna module forming a communication connection with the non-millimeter-wave environment for realizing reusing of the millimeter-wave antenna module to achieve a function of non-millimeter-wave antenna(s). The present invention proposes directly reusing a millimeter-wave antenna module, which is designed so that this module also has an antenna function of a non-millimeter-wave module, while an individual module's own volume does not need to be increased, and the module itself does not need to have additionally-added antenna traces, that is, with the same volume, a function of non-millimeter-wave antenna(s) may be further added.

Abstract: The present disclosure discloses an antenna apparatus and an electronic device. The antenna apparatus includes a circuit board, an antenna stand arranged on the circuit board, and an antenna structure arranged on the antenna stand. The antenna structure includes a flexible printed circuit board, a millimeter wave (mm-wave) antenna arranged on the flexible printed circuit board, and a non-mm-wave antenna arranged on the flexible printed circuit board.