Abstract: The invention provides isoform-selective anti-TGF? antibodies and methods of using the same. In particular, isoform-selective anti-TGF?2, anti-TGF?3, and anti-TGF?2/3 monoclonal antibodies are provided, e.g., for the treatment of fibrosis and other TGF?-related disorders.

Abstract: A complex vapor chamber structure includes a main body and at least one tubular body. The main body has a first chamber, a first opening and a second opening. A first capillary structure is disposed in the first chamber. A working fluid is filled in the first chamber. The first and second openings pass through one face of the main body to communicate with the first chamber. The tubular body has a first end, a second end and a passage. The first and second ends are respectively correspondingly inserted in the first and second openings, whereby the passage of the tubular body communicates with the first chamber via the first and second ends to form a loop for vapor-liquid circulation.

Abstract: A complex vapor chamber structure includes a main body and at least one tubular body. The main body has a first chamber, a first opening and a second opening. A first capillary structure is disposed in the first chamber. A working fluid is filled in the first chamber. The first and second openings pass through one face of the main body to communicate with the first chamber. The tubular body has a first end, a second end and a passage. The first and second ends are respectively correspondingly inserted in the first and second openings, whereby the passage of the tubular body communicates with the first chamber via the first and second ends to form a loop for vapor-liquid circulation.

Abstract: A water-cooling device includes a liquid reservoir main body having a heat exchange chamber, a pump having a stator and a rotor and a heat exchange component connected with the liquid reservoir main body. The heat exchange chamber is for a cooling liquid to pass through. The rotor is connected with an impeller and exposed to the cooling liquid in the heat exchange chamber. The stator is integrally embedded in the liquid reservoir main body by embedded injection molding. The stator is isolated from the heat exchange chamber. According to the design of the water-cooling device, the structural strength of the liquid reservoir main body is enhanced and a waterproof effect for the stator is achieved.

Abstract: A heat exchange structure of heat dissipation device includes a main body and a thermoelectric cooling chip. The main body has at least one first space in communication with at least one first opening and at least one second opening. The first space has an open side and a cooling fluid therein. The thermoelectric cooling chip has a cold face to contact with at least one heat source and a hot face to mate with the open side of the main body. In the present invention, the thermoelectric cooling chip is directly used instead of the metal-made heat conduction substrate of the conventional water-cooling heat dissipation device and serves to directly actively cool the heat source. The heat of the hot face of the thermoelectric cooling chip is absorbed by the cooling fluid inside the main body to dissipate. Accordingly, the heat dissipation performance is enhanced as a whole.

Abstract: A heat-exchange structure for water cooling device includes a main body and a first thermoelectric cooling chip. The main body internally defines at least one first space communicably connected to at least one first port and at least one second port; and the first space has a first open side and allows a cooling fluid to flow therethrough. The first thermoelectric cooling chip has a first cold side and a first hot side, and is connected to the main body with the first cold side facing toward and closing the first open side of the main body. The cooling fluid in the first space of the main body is directly cooled by the first thermoelectric cooling chip, so that the cooling fluid of the water cooling device can be cooled at a further upgraded cooling efficiency.

Abstract: A water cooling device with detachably assembled modularized units includes at least one modularized pump unit and at least one modularized heat exchange unit. Different number of the modularized heat exchange unit can be detachably assembled to the modularized pump unit according to the number of heat sources to be cooled.

Abstract: A liquid-cooling device and a liquid-cooling system thereof. The liquid-cooling device includes a liquid reservoir case having a heat exchange chamber for a cooling liquid to pass through. An impeller and multiple radiating fins in adaptation to the impeller are disposed in the heat exchange chamber. The impeller serves to drive the cooling liquid to circularly flow through the radiating fins so as to efficiently dissipate heat generated by a heat generation component.

Abstract: A water-cooling device includes a liquid reservoir main body having a heat exchange chamber, a pump having a stator and a rotor and a heat exchange component connected with the liquid reservoir main body. The heat exchange chamber is for a cooling liquid to pass through. The rotor is connected with an impeller and exposed to the cooling liquid in the heat exchange chamber. The stator is integrally embedded in the liquid reservoir main body by embedded injection molding. The stator is isolated from the heat exchange chamber. According to the design of the water-cooling device, the structural strength of the liquid reservoir main body is enhanced and a waterproof effect for the stator is achieved.

Abstract: A water cooling device with detachably assembled modularized units includes at least one modularized pump unit and at least one modularized heat exchange unit. Different number of the modularized heat exchange unit can be detachably assembled to the modularized pump unit according to the number of heat sources to be cooled.

Abstract: A liquid-cooling device and a liquid-cooling system thereof. The liquid-cooling device includes a liquid reservoir case having a heat exchange chamber for a cooling liquid to pass through. An impeller and multiple radiating fins in adaptation to the impeller are disposed in the heat exchange chamber. The impeller serves to drive the cooling liquid to circularly flow through the radiating fins so as to efficiently dissipate heat generated by a heat generation component.

Abstract: The present invention discloses a method for Multiple Input Multiple Output (MIMO) channel information feedback, and the method includes: a terminal selecting part of column vectors for MIMO system feedback from a codebook matrix W corresponding to a Precoding Matrix Indicator (PMI) and marking the selected part of column vectors as Wpart; the terminal determining information O which represents high-precision vector quantification information of MIMO along with the part of column vectors Wpart according to a common representation relationship F, and feeding back the information O to a base station. The present invention also discloses a terminal and a base station which support MIMO. The present invention achieves high-precision and low-overhead channel information feedback and can well support multiple vector feedback needed by high rank (more layer multiplexing) MIMO transmission and high-precision feedback needed by low rank MIMO transmission simultaneously.

Abstract: The present invention discloses a method for Multiple Input Multiple Output (MIMO) channel information feedback, and the method includes: a terminal selecting part of column vectors for MIMO system feedback from a codebook matrix W corresponding to a Precoding Matrix Indicator (PMI) and marking the selected part of column vectors as Wpart; the terminal determining information O which represents high-precision vector quantification information of MIMO along with the part of column vectors Wpart according to a common representation relationship F, and feeding back the information O to a base station. The present invention also discloses a terminal and a base station which support MIMO. The present invention achieves high-precision and low-overhead channel information feedback and can well support multiple vector feedback needed by high rank (more layer multiplexing) MIMO transmission and high-precision feedback needed by low rank MIMO transmission simultaneously.

Abstract: Disclosed is a new LED structure comprising a substrate, and a light emitting die entrained on the substrate. The substrate is made of the lower temperature co-fired ceramic or high temperature co-fired ceramic. The substrate is provided with a printed circuit which can be electrically in connection with an electric circuit board when it entrains the light emitting die. On the surface of the substrate where the light emitting die is to be set, is formed of a flared annular groove which has a light reflection pallet affixed to its lower surface. The surface of the light reflection pallet is coated with the silver glue, fluorescent powder, or other metallic substances. Under the annular groove and above the substrate is interposed an insulation bottom plate to entrain the light emitting die on and the die is connected to the positive and negative electrodes of the substrate with conductors. A number of pores are formed in the substrate and filled with heat dissipation substances.