Abstract: A semiconductor device includes a stacked gate structure, a plurality of stacks and a first conductive layer. The stacks are disposed aside the stacked gate structure and arranged along both a first direction and a second direction perpendicular to the first direction, wherein the stacks are extended continuously along the first direction and segmented in the second direction. The first conductive layer is disposed between segmented portions of the stacks along the second direction, wherein top surfaces of the segmented portions of the stacks are higher than a top surface of the first conductive layer.

Abstract: An electronic device is disclosed. The electronic device includes a substrate, a plurality of color filters disposed on the substrate, an optical film disposed on the plurality of color filter, and a defect disposed between the substrate and the optical film. The optical film has a first base, a protective layer on the first base, and a second base between the first base and the protective layer and having a first processed area. In a top view of the electronic device, the first processed area corresponds to the defect and at least partially overlaps at least two color filters.

Abstract: A semiconductor device is provided. The semiconductor device includes a substrate, a stacked gate structure, and a wall structure. The stacked gate structure is on the substrate and extending along a first direction. The wall structure is on the substrate and laterally aside the stacked gate structure. The wall structure extends along the first direction and a second direction perpendicular to the first direction. The stacked gate structure is overlapped with the wall structure in the first direction and the second direction.

Abstract: The present disclosure provides an immunomodulation and anti-tumor-related nanobody that specifically binds to a human leukocyte antigen-G, a programmed cell death ligand 1, and CD3 ?. The present disclosure also provides the nucleic acid sequence of the immunomodulation and anti-tumor-related nanobody, and use of the immunomodulation and anti-tumor-related nanobody for treating cancer and immune-related disorders.

Abstract: The present disclosure provides an anti-T-cell nanobody that specifically binds to CD3 ?. The present disclosure also provides the nucleic acid sequence of the anti-T-cell nanobody, use of the anti-T-cell nanobody for treating cancer, immunoregulation and activating immune cells, and a method for detecting expression levels of CD3 ?.

Abstract: A method for producing exosomes in a large-scale by using a cyclic tensile bioreactor to stimulate cells to release exosomes. In addition, the exosome having an anti-HLA-G protein specific for cancer is used as a delivery vehicle to deliver therapeutic agents for treating cancer.

Abstract: The present disclosure provides an anti-immune-checkpoint nanobody that specifically binds to a programmed cell death ligand 1. The present disclosure also provides the nucleic acid sequence of the anti-immune-checkpoint nanobody, use of the anti-immune-checkpoint nanobody for treating cancer and immune-related disorders, and a method for detecting expression levels of PD-L1.

Abstract: A multispecific nanobodies chimeric antigen receptor and T-cell engager includes an HLA-G nanobody chimeric antigen receptor and a bispecific T-cell engager. The HLA-G nanobody chimeric antigen receptor includes an HLA-G nanobodies unit, a transmembrane domain, and a CD3z signaling domain. The bispecific T-cell engager includes a PD-L1 nanobodies unit and a CD3e nanobody.

Abstract: The present disclosure relates to a chimeric antigen receptor, a nucleic acid, a chimeric antigen receptor expression plasmid, a chimeric antigen receptor expressing cell, a pharmaceutical composition for treating cancer, and use of the chimeric antigen receptor expressing cell. The chimeric antigen receptor is specific to human leukocyte antigen G. The nucleic acid encodes the chimeric antigen receptor. The chimeric antigen receptor expression plasmid expresses the chimeric antigen receptor. The chimeric antigen receptor expressing cell is obtained by transducing the chimeric antigen receptor into an immune cell. The pharmaceutical composition for treating cancer includes the chimeric antigen receptor expressing cell and a pharmaceutically acceptable carrier.

Abstract: The present disclosure relates to a HLA-G specific chimeric antigen receptor, a nucleic acid, a HLA-G specific chimeric antigen receptor expression plasmid, a HLA-G specific chimeric antigen receptor expressing cell, a pharmaceutical composition for treating cancer, and use of the HLA-G specific chimeric antigen receptor expressing cell. The chimeric antigen receptor specifically binds to human leukocyte antigen G. The nucleic acid encodes the HLA-G specific chimeric antigen receptor. The HLA-G specific chimeric antigen receptor expression plasmid expresses the HLA-G specific chimeric antigen receptor. The HLA-G specific chimeric antigen receptor expressing cell is obtained by transducing the HLA-G specific chimeric antigen receptor into an immune cell. The pharmaceutical composition for treating cancer includes the HLA-G specific chimeric antigen receptor expressing cell and a pharmaceutically acceptable carrier.

Abstract: The present disclosure provides an immunomodulation and anti-tumor-related nanobody that specifically binds to a human leukocyte antigen-G, a programmed cell death ligand 1, and CD3 ?. The present disclosure also provides the nucleic acid sequence of the immunomodulation and anti-tumor-related nanobody, and use of the immunomodulation and anti-tumor-related nanobody for treating cancer and immune-related disorders.

Abstract: The present disclosure provides an anti-immune-checkpoint nanobody that specifically binds to a programmed cell death ligand 1. The present disclosure also provides the nucleic acid sequence of the anti-immune-checkpoint nanobody, use of the anti-immune-checkpoint nanobody for treating cancer and immune-related disorders, and a method for detecting expression levels of PD-L1.

Abstract: The present disclosure provides an anti-tumor antigen nanobody that specifically binds to a human leukocyte antigen-G. The present disclosure also provides the nucleic acid sequence of the anti-tumor antigen nanobody, use of the anti-tumor antigen nanobody for treating cancer and immune-related disorders, and a method for detecting expression levels of HLA-G.

Abstract: The present disclosure provides an anti-T-cell nanobody that specifically binds to CD3 ?. The present disclosure also provides the nucleic acid sequence of the anti-T-cell nanobody, use of the anti-T-cell nanobody for treating cancer, immunoregulation and activating immune cells, and a method for detecting expression levels of CD3 ?.

Abstract: The present disclosure relates to a HLA-G specific chimeric antigen receptor, a nucleic acid, a HLA-G specific chimeric antigen receptor expression plasmid, a HLA-G specific chimeric antigen receptor expressing cell, a pharmaceutical composition for treating cancer, and use of the HLA-G specific chimeric antigen receptor expressing cell. The chimeric antigen receptor specifically binds to human leukocyte antigen G. The nucleic acid encodes the HLA-G specific chimeric antigen receptor. The HLA-G specific chimeric antigen receptor expression plasmid expresses the HLA-G specific chimeric antigen receptor. The HLA-G specific chimeric antigen receptor expressing cell is obtained by transducing the HLA-G specific chimeric antigen receptor into an immune cell. The pharmaceutical composition for treating cancer includes the HLA-G specific chimeric antigen receptor expressing cell and a pharmaceutically acceptable carrier.

Abstract: The present disclosure relates to a chimeric antigen receptor, a nucleic acid, a chimeric antigen receptor expression plasmid, a chimeric antigen receptor expressing cell, a pharmaceutical composition for treating cancer, and use of the chimeric antigen receptor expressing cell. The chimeric antigen receptor is specific to human leukocyte antigen G. The nucleic acid encodes the chimeric antigen receptor. The chimeric antigen receptor expression plasmid expresses the chimeric antigen receptor. The chimeric antigen receptor expressing cell is obtained by transducing the chimeric antigen receptor into an immune cell. The pharmaceutical composition for treating cancer includes the chimeric antigen receptor expressing cell and a pharmaceutically acceptable carrier.

Abstract: The present disclosure relates to a method for treating cancer including steps as follows. A chemotherapy drug is administered to a subject in need for a treatment of cancer. Then a composition containing a plurality of chimeric antigen receptor expressing cells is administered to the subject, wherein the chimeric antigen receptor expressing cells expresses a chimeric antigen receptor specific to human leukocyte antigen G (HLA-G).