Abstract: A physiological signal monitoring device includes a base including a base body that has a bottom plate and an opening, a biosensor mounted to the base, and a transmitter removably mounted to the base body. The base further includes a first coupling structure disposed on a top surface of the bottom plate, and the transmitter includes a second coupling structure coupled to the first coupling structure when the transmitter is mounted to the base body. When the first and second coupling structures are coupled to each other, they are disposed to be distal from a periphery cooperatively defined by the base and the transmitter. They are uncoupled from each other when an external force is applied through the opening of the base body to separate the transmitter from the base.

Abstract: An insertion needle structure includes a needle sharp and a needle body. The needle body is integrally connected to the needle sharp and has a receiving space for receiving the biosensor. The needle body includes a base wall, two side walls, two slope sections and two curved connecting sections. The side walls are located at two sides of the base wall, respectively, the side walls are at least partially nonparallel, and each of the side walls is at least partially flat. Each of the slope sections is connected between each of the side walls and the needle sharp, and each of the slope sections is curved. Each of the curved connecting sections is connected between each of the side walls and the base wall and between each of the slope sections and the base wall. The needle sharp extends from the base wall and the curved connecting sections.

Abstract: The present invention provides a measuring method for prolonging a usage lifetime of a biosensor to measure a physiological signal representative of a physiological parameter associated with an analyte in a biofluid. The biosensor includes two working electrodes at least partially covered by a chemical reagent and two counter electrodes having silver and a silver halide, and each silver halide has an initial amount.

Abstract: An implant device for a biosensor comprises a housing unit, an implant module, a bottom seat and a sensor component. The implant module is disposed in an accommodating space of the housing unit. The implant module includes a main body unit, a guiding set, an implant seat, a first elastic member, a needle withdrawal seat, a second elastic member, and a needle implant member. When the housing unit is pressed downwardly, the implant seat is displaced downwardly to perform automatic needle implantation by virtue of an resilient force of the first elastic member; when the needle implantation is completed, a limiting relationship of the implant seat and the needle withdrawal seat is released, so the needle withdrawal seat completes automatic needle withdrawal by releasing a resilient force of the second elastic member.

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: An insertion needle structure includes a needle sharp and a needle body. The needle body is integrally connected to the needle sharp and has a receiving space for receiving a biosensor. The needle body includes a base wall, two side walls and two slope sections. The side wall has a first inner edge and a first outer edge. The first inner edge is near the receiving space, and the first outer edge faces away from the receiving space. The slope section is connected between the side wall and the needle sharp. The slope section has a second inner edge connected to the first inner edge, and a second outer edge connected to the first outer edge. The first inner edge, the second inner edge, the first outer edge and the second outer edge are curved. A condition of R11>R12 is satisfied.

Abstract: An implantation device for prompt subcutaneous implantation of a sensor to measure a physiological signal of an analyte in a biofluid of a living body is disclosed. The implantation includes a housing, an implantation module, a detachable module and a bottom cover. The housing has a bottom opening, the implantation module including an implanting device and a needle extracting device, the detachable module includes the sensor configured to be detachably engaged with the implantation module and a base configured to mount the sensor thereon, wherein the base is separated from the sensor before sensor implantation; and the bottom cover configured to be detachably coupled to the bottom opening so that the housing and the bottom cover together form an accommodating space. The base includes an adhesive pad, and a release layer is attached to the adhesive pad.

Abstract: A insertion module includes a main body, an auxiliary insertion seat, an insertion needle assembly and a sensor assembly. The main body has a plurality of slide grooves. The auxiliary insertion seat has a base portion, and a plurality of wing portions. The insertion needle assembly is fixed through the interference between the wing portions and wall surfaces of the slide grooves, such that the insertion needle is prevented from being oblique to an insertion direction before the insertion needle is inserted into a host.

Abstract: An implantable micro-biosensor includes at least one counter electrode, a first working electrode, a chemical reagent layer, and at least one second working electrode. The chemical reagent layer reacts with an analyte to product a product, such that a first sensing section of the first working electrode is driven to perform a measurement action. A second sensing section of the second working electrode is driven to perform an interference-eliminating action to consume interference. The second working electrode cooperates with the counter electrode to permit the counter electrode to be driven to perform a regeneration action to regenerate silver halide.

Abstract: The present invention provides a micro biosensor for reducing a measurement interference when measuring a target analyte in the biofluid, including: a substrate; a first working electrode configured on the surface, and including a first sensing section; a second working electrode configured on the surface, and including a second sensing section which is configured adjacent to at least one side of the first sensing section; and a chemical reagent covered on at least a portion of the first sensing section for reacting with the target analyte to produce a resultant. When the first working electrode is driven by a first working voltage, the first sensing section measures a physiological signal with respect to the target analyte. When the second working electrode is driven by a second working voltage, the second conductive material can directly consume the interferant so as to continuously reduce the measurement inference of the physiological signal.

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.

Abstract: An implantable micro-biosensor a substrate, a first electrode, a second electrode, a third electrode, and a chemical reagent layer. The first electrode is disposed on the substrate and used as a counter electrode. The second electrode is disposed on the substrate and spaced apart from the first electrode. The third electrode is disposed on the substrate and used as a working electrode. The chemical reagent layer at least covers a sensing section of the third electrode so as to permit the third electrode to selectively cooperate with the first electrode or the first and second electrodes to measure a physiological signal in response to the physiological parameter of the analyte.

Abstract: An implantable micro-biosensor a substrate, a first electrode, a second electrode, a third electrode, and a chemical reagent layer. The first electrode is disposed on the substrate and used as a counter electrode. The second electrode is disposed on the substrate and spaced apart from the first electrode. The third electrode is disposed on the substrate and used as a working electrode. The chemical reagent layer at least covers a sensing section of the third electrode so as to permit the third electrode to selectively cooperate with the first electrode or the first and second electrodes to measure a physiological signal in response to the physiological parameter of the analyte.

Abstract: An insertion device includes an upper casing, an insertion module and a lower casing. The insertion module is disposed in the upper casing, and includes a main body assembly, an insertion seat, a first elastic member, a retraction seat and a second elastic member. When the upper casing is depressed, the insertion seat is driven by the first elastic member to perform an automatic-insertion operation, such that limiting structure between the insertion seat and the retraction seat collapses upon the collapse of another limiting structure between the insertion seat and the main body assembly, and that the retraction seat is driven by the second elastic member to perform an automatic-retraction operation.

Abstract: The present invention provides a micro biosensor for reducing a measurement interference when measuring a target analyte in the biofluid, including: a substrate; a first working electrode configured on the surface, and including a first sensing section; a second working electrode configured on the surface, and including a second sensing section which is configured adjacent to at least one side of the first sensing section; and a chemical reagent covered on at least a portion of the first sensing section for reacting with the target analyte to produce a resultant. When the first working electrode is driven by a first working voltage, the first sensing section measures a physiological signal with respect to the target analyte. When the second working electrode is driven by a second working voltage, the second conductive material can directly consume the interferant so as to continuously reduce the measurement inference of the physiological signal.

Abstract: A physiological signal monitoring device includes a base, a sensor, a transmitter, an adhesive layer and a pad. The sensor is carried by the base. The transmitter is coupled to the sensor. The adhesive layer is arranged on a bottom surface of the base. The pad includes an adhesive backing and a coupling backing. The adhesive backing is fabricated by weaving first threads and includes first holes. The coupling backing provides a coupling surface, and is fabricated by weaving second threads and includes second holes and piques. The piques are arranged on the coupling surface to form convex and concave three-dimensional textures on the coupling surface. The adhesive layer soaks the pad through the second holes and wraps at least one of the second threads and the first threads, so as to make the pad be connected to the base through the adhesive layer.

Abstract: An elastic physiological patch includes a patch assembly and an implant assembly. The patch assembly includes an electronic device, and a soft patch body defining a chamber for receiving the electronic device. The implant assembly is mountable to the electronic device and includes an implant which is capable of being driven to partially pass through the patch body and which is adapted to be implanted in the skin of a subject. The implant and the patch body cooperatively seal the chamber.

Abstract: The present invention discloses a holder carrying thereon a sensor to measure a physiological signal of an analyte in a biological fluid, wherein the sensor has a signal detection end and a signal output end, and the holder includes an implantation hole being a channel for implanting the sensor and containing a part of the sensor, a fixing indentation containing the sensor, a filler disposed in the fixing indentation to retain the sensor in the holder, and a blocking element disposed between the implantation hole and the fixing indentation to hold the sensor in the holder and restrict the filler in the fixing indentation.

Abstract: An insertion device includes an upper casing, an insertion module and a lower casing. The insertion module is disposed in the upper casing, and includes a main body assembly, an insertion seat, a first elastic member, a retraction seat and a second elastic member. When the upper casing is depressed, the insertion seat is driven by the first elastic member to perform an automatic-insertion operation, such that limiting structure between the insertion seat and the retraction seat collapses upon the collapse of another limiting structure between the insertion seat and the main body assembly, and that the retraction seat is driven by the second elastic member to perform an automatic-retraction operation.

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.