Abstract: An aerosol medicament delivery system is provided, which includes a first pressure sensor configured to detect external air pressure outside the aerosol medicament delivery system; a second pressure sensor configured to detect air pressure in an airway of the aerosol medicament delivery system; a controller; a driver module, a nebulization module including a mesh, wherein the controller controls the driver module to drive the nebulization module for performing nebulization based on air pressure difference between the external air pressure and the air pressure in the airway; a detection module configured to detect pressure applied by a medicament onto the mesh, convert the pressure into a voltage signal or a current signal, and transmit the voltage signal or the current signal to the controller; and a power supply module configured to provide power for the aerosol medicament delivery system.

Abstract: A detection method for detecting blood glucose value and blood hemoglobin value includes the steps: applying a first voltage to a blood sample and obtaining a first blood glucose value; applying a second voltage to the blood sample and obtaining a second blood glucose value; applying a third voltage to the blood sample and obtaining a hematocrit index and a hemoglobin index; transforming the hematocrit index into a hematocrit value and calibrating the second blood glucose value according to the hematocrit value; and transforming the hemoglobin index into a hemoglobin value. The detection method is advantageous for simultaneously detecting the blood glucose and hemoglobin by a single meter with a single strip.

Abstract: An examination method for detecting abnormal electrochemical testing strip includes the steps of: applying a trigger voltage to a testing strip; injecting a target sample to the testing strip; obtaining a trigger current which is generated by injecting the target sample to the testing strip; comparing the trigger current with a first threshold, and determining whether the trigger current is lager than or equal to the first threshold; and when the trigger current is less than the first threshold, displaying a message for abnormality.

Abstract: A calibration method for blood glucose of blood sample comprises the following steps: applying a first voltage to a blood sample to obtain an original level of blood glucose of the blood sample; applying a second voltage to a blood sample to obtain a hematocrit index of the blood sample; and processing the hematocrit index and calibrating the original level of blood glucose of the blood sample. The absolute value of the first voltage is lower than 1 volt and is not equal to 0 volt. The absolute value of the second voltage is higher than or equal to 1 volt. A sensing current corresponding to the original blood level and the hematocrit index corresponding to blood sample are obtained by applying at least two-stage voltages in the specific range to the blood sample, thereby calibrating the original blood glucose according to the hematocrit index.

Abstract: A biosensor is provided. The biosensor is used to sense a biological sample and has a code representing features of the biosensor. The biosensor includes a substrate and a conductive layer. The conductive layer is disposed on a first side of the substrate and includes a first conductive loop and a second conductive loop. The first conductive loop is formed between a first node and a second node and has a first impedance. The second conductive loop is formed between the second node and a third node and has a second impedance. The code is determined according to a comparison result between the second impedance and the first impedance.

Abstract: An electrochemical test strip is provided, including a substrate, an electrode structure and an insulative film. The electrode structure is formed on the substrate, including a first electrode and a second electrode. The second electrode includes a first end, a second end, an extension portion, and a bent portion. The extension portion connects the first end with the bent portion, and the bent portion is connected to the second end. The extension portion and the first electrode define a space therebetween for receiving the bent portion. The insulative film covers at least a part of the electrode structure and forms an opening. A sample fluid enters the electrochemical test strip through the opening, and the sample fluid sequentially contacts the first electrode and the second electrode.

Abstract: A calibration method, including steps of: providing a test meter having a socket provided with a set of conductive pins; providing a biosensor test strip having a set of strip electrodes corresponding to the set of conductive pins, wherein the combination of lengths of the strip electrodes corresponds to a parameter code; inserting the biosensor test strip into the socket of the test meter so that each of the conductive pins and each of the corresponding strip electrode have a relative motion; reading out the parameter code by using a set of pulse widths detected by each of the conductive pins in the insertion period; and calibrating the test meter by using the parameter code to match a calibration parameter installed in the test meter.

Abstract: A calibration method for blood glucose of blood sample comprises the following steps: applying a first voltage to a blood sample to obtain an original level of blood glucose of the blood sample; applying a second voltage to a blood sample to obtain a hematocrit index of the blood sample; and processing the hematocrit index and calibrating the original level of blood glucose of the blood sample. The absolute value of the first voltage is lower than 1 volt and is not equal to 0 volt. The absolute value of the second voltage is higher than or equal to 1 volt. A sensing current corresponding to the original blood level and the hematocrit index corresponding to blood sample are obtained by applying at least two-stage voltages in the specific range to the blood sample, thereby calibrating the original blood glucose according to the hematocrit index.

Abstract: A calibration method, including steps of: providing a test meter having a socket provided with a set of conductive pins; providing a biosensor test strip having a set of strip electrodes corresponding to the set of conductive pins, wherein the combination of lengths of the strip electrodes corresponds to a parameter code; inserting the biosensor test strip into the socket of the test meter so that each of the conductive pins and each of the corresponding strip electrode have a relative motion; reading out the parameter code by using a set of pulse widths detected by each of the conductive pins in the insertion period; and calibrating the test meter by using the parameter code to match a calibration parameter installed in the test meter.

Abstract: An electrochemical test strip is provided, including a substrate, an electrode structure and an insulative film. The electrode structure is formed on the substrate, including a first electrode and a second electrode. The second electrode includes a first end, a second end, an extension portion, and a bent portion. The extension portion connects the first end with the bent portion, and the bent portion is connected to the second end. The extension portion and the first electrode define a space therebetween for receiving the bent portion. The insulative film covers at least a part of the electrode structure and forms an opening. A sample fluid enters the electrochemical test strip through the opening, and the sample fluid sequentially contacts the first electrode and the second electrode.

Abstract: A biosensor is provided. The biosensor is used to sense a biological sample and has a code representing features of the biosensor. The biosensor includes a substrate and a conductive layer. The conductive layer is disposed on a first side of the substrate and includes a first conductive loop and a second conductive loop. The first conductive loop is formed between a first node and a second node and has a first impedance. The second conductive loop is formed between the second node and a third node and has a second impedance. The code is determined according to a comparison result between the second impedance and the first impedance.