Abstract: A programmed cell death ligand 1 (PD-L1) targeting polypeptide, a molecular imaging probe, and a use thereof are provided. The PD-L1 targeting polypeptide includes any one of the following polypeptides: (1) a polypeptide shown in at least one of SEQ ID NO: 1 to SEQ ID NO: 9; and (2) a polypeptide that is derived from an amino acid sequence of (1) through a substitution and/or a deletion and/or an addition of one or more amino acid residues and has the same function as the amino acid sequence. The magnetic resonance molecular imaging probe based on the PD-L1 targeting polypeptide enables the early diagnosis and evaluation of a tumor and an immune-mediated myocardial injury.

Abstract: A container system is disclosed herein. The container system may include a body and a liner. The liner may be removably inserted into a recess of the body. The body may include a lip extending around the recess a distance from an opening to the recess. The liner may include a rim configured to contact the lip of the body when the liner is inserted into the recess. The liner may be configured to be turned inside out.

Abstract: Disclosed herein are methods, systems, and apparatus, including computer programs encoded on computer storage media, for antibody structure prediction. In an example method, a target antibody sequence of a target antibody that includes a sequence of amino acids is received. The target antibody sequence is processed by an antibody language model (ALM) to obtain a residue encoding and an attention weight encoding without performing multiple sequence alignment (MSA), wherein the ALM is a protein language model trained from antibody sequences, and the ALM comprises a plurality of self-attention layers. The residue encoding and the attention weight encoding are transformed into a single representation and a pair representation that are input into a structure prediction model. A predicted structure of the target antibody is determined using the structure prediction model.

Abstract: A transport apparatus may include a patient bed unit for supporting the patient; a transferring unit for moving the patient bed unit along a first direction of the MRI device; and an elevating module for moving the patient bed unit along a second direction of the MRI device.

Abstract: The present invention relates to a method for producing a composite membrane, the method comprising impregnating a surface of a porous membrane substrate with an aqueous suspension comprising a mixture of at least one polyamine and at least one phospholipid; and contacting the impregnated surface with an organic phase containing a monomer to thereby deposit a polyamide layer on the impregnated surface. The present invention also relates to a composite membrane comprising at least one porous membrane substrate having nano-sized or micro-sized pores; and at least a polyamide layer disposed on a surface of the porous membrane substrate, the polyamide layer comprising at least one phospholipid dispersed therein, and wherein the polyamide layer is an interfacial polymerization product.

Abstract: This application provides an input interaction method, an electronic device, and a readable medium. In an application scenario in which the user views a notification, inputs a text, or the like, an interface displayed by the electronic device includes the first text input area. The user may lift the electronic device to the mouth to speak, and the electronic device enables the first voice-to-text function. The electronic device can display, in the first text input area without an additional operation performed by the user on a screen of the electronic device, a text corresponding to a voice input by the user.

Abstract: A method and apparatus for identifying a vulnerable coronary plaque based on a multimodal large language model (MM-LLM) are provided. The method includes: acquiring a target 3D coronary computed tomography angiography (CCTA) image and a target straightened curved planar reformation (SCPR) image; acquiring plaque mask information of a blood vessel based on the target SCPR image; acquiring basic plaque data based on the plaque mask information; acquiring fluid dynamics data of each plaque area based on the SCPR image; acquiring basic clinical testing information; standardizing above image data, structural data, and textual data separately, and performing, by a regression mapping network, feature fusion to acquire a first fusion feature; acquiring a trained vulnerable plaque identification LLM; and inputting the first fusion feature into the vulnerable plaque identification LLM to acquire an identification result.

Abstract: A container system is disclosed herein. The container system includes a cylindrical hollow body, a top cap, and a bottom cap. The body includes openings on a top end and bottom end. The body also includes a raised ridge system that can be disposed around the circumference of the top end of the body. The raised ridge system forms a plurality of locking channels, each with an entry and exit gap. The entry gaps are laterally and vertically offset from the exit gaps. The top cap is removably coupled to the top end of the body. The top cap includes a plurality of protrusions that are configured to engage with and pass through the plurality of locking channels to transition the top cap and the body between a locked state and an unlocked state.

Abstract: The present invention relates to a method for producing a composite membrane, the method comprising impregnating a surface of a porous membrane substrate with an aqueous suspension comprising a mixture of at least one polyamine and at least one phospholipid; and contacting the impregnated surface with an organic phase containing a monomer to thereby deposit a polyamide layer on the impregnated surface. The present invention also relates to a composite membrane comprising at least one porous membrane substrate having nano-sized or micro-sized pores; and at least a polyamide layer disposed on a surface of the porous membrane substrate, the polyamide layer comprising at least one phospholipid dispersed therein, and wherein the polyamide layer is an interfacial polymerization product.

Abstract: A multi-compartment container system is disclosed herein. The container system may include a body, a top cap, and a bottom cap. The body may include openings on a top end and bottom end. The body may also include two interior chambers separated by a divider. The top cap may be removably attached to the body and can cover the top opening. The bottom cap may be removably attached the bottom end of the body and can cover the bottom opening. The container system may also include locking mechanisms that can lock the top and bottom caps to the body.

Abstract: A child-resistant container that includes a cap and a bottle portion. The cap includes several inner engagement features protruding radially inwardly and the finish of the bottle portion includes a protrusion disposed about the opening with an overhanging ledge. Slots in the ledge correspond to the engagement features. In one particular embodiment, the cap includes two different length circumferential engagement features and two triangular engagement features.

Abstract: A container assembly includes an outer shell forming an interior cavity, an inner tray dimensioned to be received within the interior cavity of the outer shell, wherein the inner tray is rotatably coupled to the outer shell and configured to rotate between an open configuration and a closed configuration. The container assembly further includes a plurality of gripping members disposed within the inner tray, the gripping members being structured to flex outwardly to receive an item placed in the inner tray and apply an inward force to the item to releasably secure the item within the inner tray.

Abstract: A container system is disclosed herein. The container system may include a body and a liner. The liner may be removably inserted into a recess of the body. The body may include a lip extending around the recess a distance from an opening to the recess. The liner may include a rim configured to contact the lip of the body when the liner is inserted into the recess. The liner may be configured to be turned inside out.

Abstract: A container system is disclosed herein. The container system may include a body and a disposable cartridge. The disposable cartridge may include an outer liner and an inner liner. The disposable cartridge may be removably inserted into a recess of the body. The inner liner may be configured to hold a substance. The inner liner may be configured to be removably positioned within a recess of the outer liner. The inner liner may be configured to be turned inside out.

Abstract: A child-resistant container that includes a cap and a bottle portion. The cap includes several inner engagement features protruding radially inwardly and the finish of the bottle portion includes a protrusion disposed about the opening with an overhanging ledge. Slots in the ledge correspond to the engagement features. In one particular embodiment, the cap includes two different length circumferential engagement features and two triangular engagement features.