A computer implemented method for providing pain management using a wearable device determines a predictive model estimating an intensity level of pain as a function of at least one physiological parameter of a user of the wearable device and at least one activity of the user. The activity of the user includes one or combination of a type of the activity, a level of the activity, a location of the activity, and a duration of the activity. The method determines measurements of physiological and activity sensors of the wearable device to produce values of the physiological parameter and the activity of the user and predicts the intensity level of the pain based on the predictive model and the values of the physiological parameter and the activity of the user. The method executes actions based on the predicted intensity level of pain.

A connector (140) is provided with a holding component (141), a support component (148), a terminal (144) electrically connected to a contact of a guide wire (130) held by the holding component (141), and a guide component (147) rotatable around an axial line (130A) of the guide wire (130) with respect to the support component (148). The holding component (141) is provided with a body (150) having an insertion hole (150a) for the guide wire (130) and a holding piece (151) extending along an axial line of the insertion hole (150a) from the body (150) and capable of being elastically deformed inward in a radial direction with respect to the axial line. The guide component (147) has a guide surface (165a) guiding the holding piece (151) inward in the radial direction. The holding component (141) is slid along the axis line of the insertion hole (150a) with respect to the guide component (147), whereby the holding piece abuts on the guide surface (165a) to be elastically deformed inward in the radial direction.

A diaper with urine detection functionalities is provided. The diaper includes a urine isolation layer, an absorbent core layer, and an outer layer. A urine detection device is disposed between the urine isolation layer and the absorbent core layer. The isolation layer has an open end that is embedded in a sleeve of the absorbent core layer. The urine detection device comprises a detection circuit and a test paper composite. The test paper composite includes: a trace element test paper, an antibiotic test paper, and a urine routine test paper. Each test paper is made up of a plurality of test strips for detecting different elements. Each test strip produces results according to a different color indicator scheme.

A diaper with urine detection functionalities is provided. The diaper includes a urine isolation layer, an absorbent core layer, and an outer layer. A urine detection device is disposed between the urine isolation layer and the absorbent core layer. The isolation layer has an open end that is embedded in a sleeve of the absorbent core layer. The urine detection device comprises a detection circuit and a test paper composite. The test paper composite includes: a trace element test paper, an antibiotic test paper, and a urine routine test paper. Each test paper is made up of a plurality of test strips for detecting different elements. Each test strip produces results according to a different color indicator scheme.

A diaper, having urine detection functionalities, comprises a urine isolation layer, an absorbent core layer and an outer layer. A urine detection device is disposed in between the urine isolation layer and the absorbent core layer. The urine isolation layer has an open end embedded in a sleeve of the absorbent core layer. The urine detection device comprises a detection circuit and a test paper composite. The test paper composite includes: a trace element test paper, an antibiotic test paper and a urine routine test paper. Each test paper is made up of test strips for detecting different elements. Each test strip produces results according to a different color indicator scheme. The antibiotic test paper includes a specimen absorption pad, a specimen binding pad, a reaction membrane, and an absorbent pad. An antibiotic detection method is provided.

A diaper, having urine detection functionalities, comprises a urine isolation layer, an absorbent core layer and an outer layer. A urine detection device is disposed in between the urine isolation layer and the absorbent core layer. The urine isolation layer has an open end embedded in a sleeve of the absorbent core layer. The urine detection device comprises a detection circuit and a test paper composite. The test paper composite includes: a trace element test paper, an antibiotic test paper and a urine routine test paper. Each test paper is made up of test strips for detecting different elements. Each test strip produces results according to a different color indicator scheme. The antibiotic test paper includes a specimen absorption pad, a specimen binding pad, a reaction membrane, and an absorbent pad. An antibiotic detection method is provided.

A personal wearable headband having far infrared and temperature measurement functions includes a headband body defining a headband receiving space and having a plurality of far infrared particles blended in the headband body, a window communicating with the headband receiving space, and a through hole communicating with the headband receiving space and opposite to the window. A temperature measuring unit is disposed in the headband receiving space and includes a temperature measuring element configured to contact the forehead of a user for detecting a temperature thereof, and a display screen corresponding in position to the window and configured to display the temperature detected by the temperature measuring element.

A personal wearable headband having far infrared and temperature measurement functions includes a headband body defining a headband receiving space and having a plurality of far infrared particles blended in the headband body, a window communicating with the headband receiving space, and a through hole communicating with the headband receiving space and opposite to the window. A temperature measuring unit is disposed in the headband receiving space and includes a temperature measuring element configured to contact the forehead of a user for detecting a temperature thereof, and a display screen corresponding in position to the window and configured to display the temperature detected by the temperature measuring element.

User comfort control system having non-invasive bio-patch. In some embodiments, a system for providing comfort of a person can include a wearable patch configured to be attached to a skin of the person and sense a biological condition of the skin, and to transmit information representative of the sensed biological condition. The system can further include a controller configured to receive the information and generate a control signal. The system can further include an adjustment element associated with a furniture item implemented to support and provide comfort for the person. The adjustment element can be in communication with the controller and be configured to adjust a comfort level of the furniture item for the person in response to the control signal.

User comfort control system having non-invasive bio-patch. In some embodiments, a system for providing comfort of a person can include a wearable patch configured to be attached to a skin of the person and sense a biological condition of the skin, and to transmit information representative of the sensed biological condition. The system can further include a controller configured to receive the information and generate a control signal. The system can further include an adjustment element associated with a furniture item implemented to support and provide comfort for the person. The adjustment element can be in communication with the controller and be configured to adjust a comfort level of the furniture item for the person in response to the control signal.