Abstract: Provided an end cover assembly, a battery cell, a battery, and an electric apparatus. The end cover assembly in the embodiments of the present application includes: an end cover provided with a first through hole; and an electrode leading-out member including a connecting plate and a post terminal protruding from a surface of the connecting plate, at least part of the post terminal being disposed in the first through hole, and the connecting plate being located on one side of the end cover, where the connecting plate is connected to a tab of an electrode assembly. In the technical solutions of the embodiments of the present application, the electrode leading-out member is provided, which increases contact area between a post and a tab, expands overcurrent area between the post terminal and the connecting plate, reduces internal resistance, lowers temperature rise, and improves the safety performance of a battery cell.

Abstract: A battery related shell, a battery cell, a battery, and an electrical device are disclosed. The shell includes a frame and two end caps. The frame includes two openings opposite to each other along a first direction. The two end caps are connected to two ends of the frame respectively along the first direction. The two end caps respectively seal the two openings. The two end caps and the frame together define an accommodation space configured to accommodate an electrode assembly. The two openings created on the frame make it convenient to put the electrode assembly into the shell, thereby reducing the risk that the electrode assembly is damaged by excessive friction between the electrode assembly and an inner side of the frame during encasing of the electrode assembly, and improving the yield rate of encasing of the electrode assembly.

Abstract: The application discloses a connection member, a battery cell, a battery and an electric device. The connection member is used to achieve an electrical connection between an electrode terminal and an electrode tab of a battery cell. The connection member includes a body portion and an electrode terminal welding portion connected to the body portion. The body portion is used to be connected to the electrode tab, and the electrode terminal welding portion is used to be welded to the electrode terminal. A hardness of the electrode terminal welding portion is greater than a hardness of the body portion. The embodiments of the application can enhance the service life of the battery cell.

Abstract: Embodiments of this application provide a battery cell, a battery, and an electric device. The battery cell includes: a first wall, where the first wall is provided with a first limiting structure; and an insulating structure, where the insulating structure is disposed on a side of the first wall facing the interior of the battery cell, and the insulating structure is provided with a second limiting structure corresponding to the first limiting structure. The second limiting structure and the first limiting structure cooperate with each other to prevent relative movement between the insulating structure and the first wall. The battery cell, battery, and electric device according to the embodiments can improve the processing efficiency of battery cells.

Abstract: A battery cell, a battery, and an electrical device are described. The battery cell includes: a housing of a hollow structure with an opening; and a cover plate, configured to fit and cover the opening. An extension portion extending toward the housing is disposed at an edge region of the cover plate, and/or, an extension portion extending toward a center of the opening is disposed at an edge region of a sidewall of the housing, where the sidewall is configured to form the opening. The extension portion is configured to connect the housing and the cover plate. The battery cell, battery, and electrical device provided can improve processing efficiency of the battery cell.

Abstract: The present application provides an end cover assembly for a battery cell. The end cover assembly includes: an end cover, an exhaust mechanism being provided on the end cover; and an insulating component provided on the side of the end cover close to the interior of the battery cell. An exhaust channel is provided between the insulating component and the end cover to communicate the exhaust mechanism with the interior of the battery cell. The end cover assembly can improve the exhaust efficiency of the battery cell, thereby improving the reliability of the battery cell.

Abstract: An end cover assembly, a battery, and an electric device are provided. The end cover assembly is applied to a battery and includes an end cover, a breather valve, and a protective patch. The end cover has a first side facing inside of the battery and a second side opposite the first side and includes a first channel in communication with the first side and the second side. The breather valve includes a gas-permeable membrane in gas communication with the first channel. The gas-permeable membrane includes a gas-permeable portion opened towards the second side of the end cover. The protective patch is provided on the second side of the end cover and covers the gas-permeable portion. The battery includes the end cover assembly. The electric device includes the battery.

Abstract: The invention relates to an inducer of senescence, in combination with a short-lived, selective Death Receptor 5 (DR5) agonist, for use in a method of treating a patient suffering from a tumor. The invention further relates to a pharmaceutical composition, comprising a short-lived, selective Death Receptor 5 (DR5) agonist and, optionally, an inducer of senescence. The invention further relates to methods of treating a patient having a tumor, and to a selective, short-lived DR5 agonist, for use in a method of selectively killing senescent cells, including senescent cancer cells.

Abstract: The present disclosure relates to a medical imaging method for enabling magnetic resonance imaging of a subject (318) using a set of imaging parameters of imaging protocols, the method comprising: receiving information related to the subject; using a predefined machine learning model for suggesting at least one imaging protocol for the received information, wherein the imaging protocol comprises at least part of the set of imaging parameters and associated values; providing the imaging protocol.

Abstract: The present disclosure relates to a medical imaging method for enabling magnetic resonance imaging of a subject (318) using a set of imaging parameters of imaging protocols, the method comprising: receiving information related to the subject; using a predefined machine learning model for suggesting at least one imaging protocol for the received information, wherein the imaging protocol comprises at least part of the set of imaging parameters and associated values; providing the imaging protocol.

Abstract: The current invention relates to treatment of drug resistant melanoma with histone deacetylase inhibitors (HDACi). In particular the invention relates to BRAF and NRAS mutated melanoma and that have acquired resistance to MAPK pathway inhibitors, for example due to previous treatment with such MAPK pathway inhibitors. The invention discloses HDACi and/or MAPK pathway inhibitors for use in such treatment and treatment regimens using such inhibitors.

Abstract: The current invention relates to treatment of drug resistant melanoma with histone deacetylase inhibitors (HDACi). In particular the invention relates to BRAF and NRAS mutated melanoma and that have acquired resistance to MAPK pathway inhibitors, for example due to previous treatment with such MAPK pathway inhibitors. The invention discloses HDACi and/or MAPK pathway inhibitors for use in such treatment and treatment regimens using such inhibitors.

Abstract: Disclosed a voltage-deviation detecting and adjusting system for a balance module of a battery.

Abstract: Disclosed a voltage-deviation detecting and adjusting system for a balance module of a battery.

Abstract: Methods for actuating a microshutter array with electromechanical resonance and electrostatic force are described herein. An alternating electrical field is created by applying an alternating current (AC) voltage across a pair of actuation electrodes. A shutter blade with a blade electrode thereon is disposed between the pair of actuation electrodes and vibrates in the alternating electrical field created. Direct current (DC) voltages are applied to a vertical electrode and the blade electrode. The shutter blade is attracted to the vertical electrode and captured to an open position.

Abstract: The invention relates to an imaging system for use in operating rooms and other applications. According to one example, the imaging system includes a plurality of imaging sensors that receive image information from a subject via a plurality of spectral channels and that convert the image information into an image signal. The imaging system may include a plurality of independent imaging optics systems, such as an independent visible imaging optics system and an independent fluorescent imaging optics system, that optically couple the image information to the plurality of imaging sensors. The plurality of independent imaging optics systems corresponds to the plurality of image sensors in order to independently adjust a plurality of optical parameters, such as a size of a field of view, a position of a focal plane, and a size of an optical aperture.

Abstract: An anode assembly (50) includes a thermally conductive bearing encasement (52) covering a portion of a bearing (64). An anode (56) rotates on the bearing (64) and has a target (58) with an associated focal spot (60). The thermally conductive bearing encasement (52) is configured and expansion limited to prevent displacement of the focal spot (60) of greater than a predetermined displacement during operation of the anode (56).

Abstract: A clip for a motor stator housing to engage at least a first magnet and at least a second magnet of the motor stator includes a generally annular plate having an outer circumferential edge and an inner side. A plurality of outer tabs are radially arranged on the outer circumferential edge and extend outward relative to the outer circumferential edge, wherein the outer tabs engage an inner surface of the stator housing. At least a pair of first inner tabs extend outward from the inner side of the annular plate and are configured to engage opposing sidewalls of the first magnet. At least a pair of second inner tabs extend outward from the inner side of the annular plate and are configured to engage opposing sidewalls of the second magnet.

Abstract: An anode assembly (50) includes a thermally conductive bearing encasement (52) covering a portion of a bearing (64). An anode (56) rotates on the bearing (64) and has a target (58) with an associated focal spot (60). The thermally conductive bearing encasement (52) is configured and expansion limited to prevent displacement of the focal spot (60) of greater than a predetermined displacement during operation of the anode (56).