There is described a system for providing an interface with personalized products or product recommendations by capturing user data with sensors and computing a physical and/or emotional signature of the user. The user data comprises at least image data, text input, biometric data, and audio data, and may have been captured using one or more sensors on the user device. The user data is processed using at least: facial analysis; body analysis; eye tracking; behavioural analysis; social network analysis; location analysis; user's activities analysis; speech analysis, and text analysis. Based on the user data, one or more states of one or more cognitive-affective competencies of the user may be determined. An is determined, based on the one or more states of the one or more cognitive-affective competencies of the user. Based on the physical and/or emotional signature, one or more personalized products or product recommendations are generating for improving the emotional signature or physical signature.

The subject invention provides sensor systems that can detect biomarkers related to wound healing (e.g., uric acid, adenosine, arginine and/or xanthine). In one embodiment, the subject invention pertains to materials and methods for monitoring biomarkers non-invasively in a wound and a biofluid (e.g., sweat) in the proximity of the wound, optionally, including other physiological fluids. Skin based, non-invasive enzymatic electrochemical biosensor on a wearable platform (e.g., sweat patch) that can evaluate the healing of wounds through assessment of its biomarker levels are provided. This non-invasive detection from physiologically biofluids can reduce or eliminate occlusion effects.

Disclosed are apparatuses, methods, and method of manufacture of a microfluidic device for detecting biomolecules in sweat, and a biosensor patch for detecting biomolecules in sweat, in which the microfluidic device and a biosensor are combined, the device and the patch being capable of detecting various target molecules present in sweat by electrochemical signals and also detecting the concentration of a target molecule. The microfluidic device includes a fluidic passing layer including an inlet part, a sensing element in communication with the inlet part, a reagent storage part in communication with the sensing element part, and a disposer in communication with the sensing element, and a fluidic connection layer including a microfluidic tube arranged in a vertical direction to the inlet part, a sensing space provided between the sensing element and the biosensor, and a reagent storage space positioned below the reagent storage part, the fluidic connection layer being disposed below the fluidic passing layer.

Methods, systems, and devices are described herein for various embodiments of using a sample analysis system to analyze a sample of bodily fluid from a user to determine parameters associated with the user including states of hydration, dehydration, rehydration, electrolyte loss, wellness, recovery, and the like. In some embodiments, the methods disclosed can be implemented using a device worn by a user, and operatively coupled to a sample analysis system configured to collect a sample of bodily fluid, and measure and analyze the bodily fluid to determine a property of the bodily fluid and/or a physiological/wellness parameter (e.g., degree of hydration, electrolyte losses, perspiration rate, etc.) of the user.

A system and method for facilitating dynamic biometric measurement is disclosed. In particular, the system may include a garment to be worn on the body of the user. The garment may include a flexible circuit upon which a plurality of sensor arrays and a processing unit may be disposed upon. Once activated, the sensors of the plurality of sensor arrays may continuously measure sensor data associated with the user, such as when the user is at rest and when the user in motion. The sensors may transmit signals including the sensor data to the processing unit for aggregation, processing, and filtration. The processing unit may also analyze the sensor data to determine a physiological condition of the user, a health condition of the user, a state of the user, or a combination thereof. The analyzed sensor data may be transmitted to a device for presentation, further processing, and storage.

A smart clothing and backpack system enables a user to perform many actions. The smart clothing includes circuitry and/or is made of a conductive material enclosed in an insulation material. The smart clothing includes a set of sensors configured to detect body information. The smart clothing includes multiple electromagnets configured to adjust a size of the smart clothing. The electromagnets are configured to have an increased attraction to make the smart clothing tighter on the body of the user. The system includes a smart backpack to communicate with the smart clothing. The smart backpack includes a Radio Frequency IDentification (RFID) reader configured to detect RFID tags on or in items within the smart backpack. Many other features are able to be implemented with the smart clothing and backpack system. The smart clothing is able to include a wetsuit configured to communicate with a surfboard and/or a backpack.

Systems and methods including a device having integrated sensor arrays constructed and configured to measure and analyze multiple biosignatures concurrently in real time and a mobile application to control the device, process data, and transmit data wirelessly via at least one network to at least one remote computing device for analyzing the multiple biosignatures and cross-correlation with at least one external factor resulting in the creation of personal and situation profiles for continued on-going real time monitoring, refinement, alerting, and action recommendations.

A skin measuring apparatus measures a skin moisture level using a voltage application electrode and a current detection electrode. The skin measuring apparatus includes an electrode driving module applying sinusoidal wave voltage to skin of a user through the voltage application electrode so that an amount of current is output from the skin through the current detection electrode, a signal detecting unit detecting the amount of current from the skin through the current detection electrode to calculate at least one of an impedance signal and an admittance signal, and a skin information determination unit analyzing the at least one of the impedance signal and the admittance signal to calculate the skin moisture level and a sweat production rate of the user, thereby analyzing the skin moisture level and the sweat generation rate more precisely without distortion.

Provided herein are epidermal microfluidic systems and methods that allow for the collection of biofluids in a wet or aquatic environment, for example, from the surface of the skin. The described systems allow for the efficient collection of biofluids, without loss of the biofluid to the surrounding environment or introduction of extraneous liquids from the environment. The described microfluidic systems are versatile and can provide information regarding a number of biofluid properties both electronically and colorimetrically/visually.

The present invention relates generally to systems and methods for measuring an analyte in a host. More particularly, the present invention relates to systems and methods for transcutaneous measurement of glucose in a host.