Abstract: A charging device for a physiological signal transmitter used to receive a physiological signal from the subcutaneous tissue of a living body and having a first electrical connecting port is disclosed. The charging device includes a transmitter placing seat and a charging module. The transmitter placing seat includes a bearing surface for placing the physiological signal transmitter and an opening configured to align with the first electrical connection port of the physiological signal transmitter. The charging module includes a second electrical connecting port, a third electrical connecting port, a circuit assembly and a control module. The second electrical connecting port is disposed in the opening, and driven to move between a first position and a second position. The third electrical connecting port connects to a power source.

Abstract: A charging device for a physiological signal transmitter is disclosed, wherein the physiological signal transmitter is to receive and transmit a physiological signal from a subcutaneous tissue of a living body, and has a first electrical connecting port. The charging device comprises a body including a placing portion, a charging module and an operating module. The placing portion disposes thereon the physiological signal transmitter, and includes a bearing surface and a first opening. The bearing surface disposes thereon the physiological signal transmitter, and the first opening aligns therewith the first electrical connecting port of the physiological signal transmitter. The charging module is accommodated in the body and includes a second electrical connecting port, a third electrical connecting port and a circuit assembly. The second electrical connecting port is disposed in the opening and protrusive beyond or beneath the bearing surface.

Abstract: A test strip code reader is provided. The test strip code reader includes a test strip carrier for accommodating a test strip, a first conductive element for decoding a code of the test strip, a second conductive element configured to be in a contact state or a separation state with the first conductive element, and an activation element having a body and a plurality of protrusions, wherein the body is used to prevent the first conductive element from being contaminated, and according to whether the plurality of protrusions are actuated by the test strip, the contact state or the separation state between the first conductive element and the second conductive element is determined to decode the code of the test strip.

Abstract: A physiological signal monitoring device is adapted for monitoring a physiological signal of a biofluid, and includes: a biosensor strip that has at least one signal output end adapted for outputting the physiological signal; a strip reciprocating module that includes a strip seat for receiving the biosensor strip, a guide seat mounted to the strip seat, and a rotating plate mounted rotatably to the strip seat for triggering reciprocating movement of the biosensor strip and the guide seat relative to the strip seat; and a contact module that includes an electronic module, and at least one extending piece connected electrically with the at least one signal output end to transmit the physiological signal to the electronic module.

Abstract: Molybdenum-silicon carbide composite powder and a fabrication method thereof are provided. The molybdenum-silicon carbide composite powder includes a micro-scale silicon carbide powder and a plurality of submicron-scale molybdenum particles bonding on the surface of the silicon carbide powder.

Abstract: A patch, comprising: a backing disposing thereon an adhesive layer having an adhesive surface for being adhered to a skin surface; and a peelable sheet detachably adhered to the adhesive surface for preserving the adhesive surface and providing a supporting force for the backing. The peelable sheet includes an inner peelable sheet and an outer peelable sheet. After the inner peelable sheet is peeled off, the outer peelable sheet continuously provides the supporting force to allow the backing to be adhered easily and evenly.

Abstract: A patch for increasing an adhesive strength of a physiological parameter detection device on a skin surface includes a backing and a peelable sheet. The backing is disposed with an adhesive layer having an adhesive surface. The adhesive surface includes a central adhesive portion and an outer adhesive portion, and, upon the central adhesive portion is exposed, the patch is caused to apply a pressure toward the physiological parameter detection device so as to allow the central adhesive portion to be adhered to a top surface of the physiological parameter detection device. The peelable sheet, which is detachably adhered to the adhesive surface for preserving the adhesive surface, includes an inner peelable portion and an outer peelable portion. After the central adhesive portion is exposed, the outer peelable sheet continuously provides a supporting force for the backing so as to allow the backing to be easily and evenly adhered.

Abstract: A moisture-proof assembly for keeping away from a moisture comprises a housing, a cover, a physiological signal transmitter, a charging device and a desiccant. The housing has an opening. The cover is detachably disposed on the housing, configured to seal the opening, and forms an accommodating space together with the housing. The physiological signal transmitter is disposed in the accommodating space for measuring and transmitting a physiological signal. The charging device is combined with the physiological signal transmitter and disposed together or the charging device and the physiological signal sensor are separate disposed in the accommodating space. The desiccant is disposed in the accommodating space to prevent the physiological signal transmitter from moisture, wherein when the physiological signal transmitter is in need of being charged, the charging device is taken out of the accommodating space, and connected to an external power source to charge the physiological signal transmitter.

Abstract: A charging device for a physiological signal transmitter is disclosed. The charging device includes a transmitter placing seat, and a controlling module controlling an operation between the charging device and the physiological signal transmitter in a safe state. When the physiological signal transmitter is at the predetermined position, the locking portion unlocks the operating portion to perform one of driving the second electrical connecting port to move from the first position to the second position to electrically connect to the first electrical connecting port and driving the second electrical connecting port to move from the second position to the first position to electrically disconnect to the first electrical connecting port.

Abstract: A charging device for a physiological signal transmitter is disclosed, wherein the physiological signal transmitter is to receive and externally transmit a physiological signal from a subcutaneous tissue of a living body, and has a first electrical connecting port. The charging device comprises a transmitter placing seat, a charging module and a locking module. The transmitter placing seat includes a bearing surface, and a first opening. The bearing surface disposes thereon the physiological signal transmitter; and the first opening aligns therewith the first electrical connecting port of the physiological signal transmitter. The charging module includes a second electrical connecting port, a third electrical connecting port and a circuit assembly. The second electrical connecting port is disposed in the first opening and moveable between a first position and a second position. The third electrical connecting port is for connecting thereto a power source.

Abstract: A charging device for a physiological signal transmitter used to receive a physiological signal from the subcutaneous tissue of a living body and having a first electrical connecting port is disclosed. The charging device includes a transmitter placing seat and a charging module. The transmitter placing seat includes a bearing surface for placing the physiological signal transmitter and an opening configured to align with the first electrical connection port of the physiological signal transmitter. The charging module includes a second electrical connecting port, a third electrical connecting port, a circuit assembly and a control module. The second electrical connecting port is disposed in the opening, and driven to move between a first position and a second position. The third electrical connecting port connects to a power source.

Abstract: A charging device for a physiological signal transmitter used to receive a physiological signal from the subcutaneous tissue of a living body and having a first electrical connecting port is disclosed. The charging device includes a transmitter placing seat and a charging module. The transmitter placing seat includes a bearing surface for placing the physiological signal transmitter and an opening configured to align with the first electrical connection port of the physiological signal transmitter. The charging module includes a second electrical connecting port, a third electrical connecting port, a circuit assembly and a control module. The second electrical connecting port is disposed in the opening, and driven to move between a first position and a second position. The third electrical connecting port connects to a power source.

Abstract: A charging device for a physiological signal transmitter is disclosed, wherein the physiological signal transmitter is to receive and transmit a physiological signal from a subcutaneous tissue of a living body, and has a first electrical connecting port. The charging device comprises a body including a placing portion, a charging module and an operating module. The placing portion disposes thereon the physiological signal transmitter, and includes a bearing surface and a first opening. The bearing surface disposes thereon the physiological signal transmitter, and the first opening aligns therewith the first electrical connecting port of the physiological signal transmitter. The charging module is accommodated in the body and includes a second electrical connecting port, a third electrical connecting port and a circuit assembly. The second electrical connecting port is disposed in the opening and protrusive beyond or beneath the bearing surface.

Abstract: A physiological sensing device for reading an elongated test strip having an insertion end, a test strip width and a test strip length is provided. The physiological sensing device includes a housing, a test strip slot and a first protruding portion. The housing has a front surface, a rear surface opposite to the front surface, and a lateral surface. The test strip slot is disposed on the lateral surface, and having a first slot wall adjacent to the front surface; a second slot wall adjacent to the rear surface, and disposed opposite to the first slot wall; and a slot opening having a slot width, formed between the first slot wall and the second slot wall for accommodating the elongated test strip, and allowing the insertion end to enter the housing through the slot opening.

Abstract: A physiological signal monitoring device includes a base, a biosensor mounted to the base, a transmitter, and a sealing unit. The base is adapted to be mounted to a skin surface of a host. The biosensor includes a mounting seat and a sensing member that is mounted to the mounting seat. The sensing member is adapted to be partially inserted underneath the skin surface of the host for measuring an analyte of the host and to send a corresponding physiological signal. The transmitter is for receiving and transmitting the physiological signal, and has a bottom portion. The transmitter covers the base while the bottom portion faces the base. The sensing member is coupled to the transmitter. The sealing unit is used to seal paths through which a liquid possibly penetrates into an interior of the physiological signal monitoring device so as to avoid damage of the device.

Abstract: A physiological signal monitoring device includes a biosensor, and a transmitter including a bottom casing, a processing unit and a battery. The bottom casing has a first stepped section, a second stepped section, and a riser section interconnecting the first stepped section and the second stepped section. The processing unit corresponds in position to the first stepped section. The battery corresponds in position to the first stepped section, and is configured not to overlap the processing unit in a direction of a first axis so as to reduce a thickness of the transmitter.