A product interaction monitor includes sensors for measuring characteristics related to the product and/or product package or other type of container. The product interaction monitor can be installed in a container cap and used to monitor events associated with the container such as product usage. The product interaction monitor can utilize multiple sensor outputs to increase the accuracy of the detection of the events. The product interaction monitor can be used to estimate product inventory or product usage and communicate information regarding the product and/or product usage to a local display or a remote computer.

Provided are a smart bottle and a method for controlling the smart bottle. A smart bottle comprises a bottle for containing liquid; a base formed to be combined to one side of the bottle; a first sensor installed in the bottle or the base, and configured to obtain level information of liquid contained in the bottle; a third sensor configured to obtain inclination information of the bottle; a heater configured to heat the liquid contained in the bottle; a controller configured to control operation of the heater based on the temperature information, determine a feeding start and a feeding end based on the inclination information, and modify the level information based on the inclination information; a communication unit configured to transmit the inclination information and the level information to an external device; and a battery configured to supply power to the first sensor and the base.

A fluid heating device for on demand heating of fluids for feeding a child includes a pipe that is coupled to and extends from a control module, which comprises a power module. A first and a second tube are coupled to and extend from a first and a second end of the pipe, respectively. A terminus of the first tube is positionable in a reservoir that contains a fluid. A nipple that is coupled to the second tube distal from the pipe is configured to be positioned in a mouth of a child, positioning the child to suck on the nipple to draw the fluid from the reservoir through the first tube into the pipe. A heating element in the pipe heats the fluid as it passes through the pipe. The fluid then passes through the second tube and a hole in the nipple into the mouth of the child.

The disclosed systems and methods provide a smart container or bin. A container bin assembly includes a bin body, a latching mechanism, and controller. A method includes receiving, via a communication interface, an authenticated request to access the smart container, actuating an electromechanical latch to disengage a fastening hook, thereby initiating a mechanical movement of an access component to make an internal compartment accessible, outputting, via an audiovisual element, an alert to identify the container, confirming that the electromechanical latch has re-engaged with the fastening hook, thereby securing the internal compartment, determining a change in a local inventory, and updating the local inventory in a non-volatile data store according to the change.

Systems and methods of dynamic biometric detection and response are provided for the purpose of establishing baseline health status while conveying real-time drug prescription usages and reactions from baseline data. The dynamic monitoring system may be embedded within a wristband, ring, vest, and/or waistband in wireless communication with a computing device or server. Each wearable device may employ interchangeable and embedded sensors to detect inertia movements; 360-imaging fall detections; and a variety of body-emitting vital signs. The system may include a processor operable to sense user location, motion, activity, and biomarkers for the purpose of detecting the user's behavior pattern, wherein an enhanced machine-learning algorithm is used to identify repetitive actions within the user's behavior pattern; and, based upon this pattern, the system is able to detect one or more anomalies for the purpose of generating an anomaly alert for third party notification and quantitative analysis at a server.

A technique for tracking, for example, the temperature of one or more sample vials containing biological material stored in a low-temperature shipping vessel. Each sample vial has vial electronics that senses temperature and transmits temperature data to the reader head of a reader device, which has a controller that is not at the low temperature. In some implementations, the shipping vessel has a cap with a recess that houses the controller and a hollow plug that houses a cable that connects the controller to the reader head that is located in the vessel's cold interior sufficiently close to the sample vial to enable interaction with the vial electronics. In some implementations, the reader head transmits electrical power to the vial electronics. By tracking the temperature of individual sample vials rather than the temperature of the vessel interior, more-relevant temperature data is available.

An apparatus for automated storage and dispensing of medications. Medications are stored in one or more inventory storage foam storage plates attached to a frame of the apparatus. Medications are delivered to the apparatus via a locked delivery container. A carrier mechanism retrieves medications from the inventory storage container and delivery container and moves medications to various subsystems of the apparatus. Information related to medications is communicated to a remote pharmacist prior to dispensing the medication. Multiple installations of the apparatus are centrally coordinated.

Various methods and apparatuses are presented for an ingestible capsule that includes a digital, ingestible sensor componentor ingestible sensorembedded into the capsule. The ingestible sensor component may be configured to activate upon coming into contact with conductive fluid, such as a body's stomach fluid. Once activated, the ingestible sensor component may be configured to perform various tasks, such as transmitting one or more signals and obtaining biometric data about the body that ingested the capsule.

The present invention deals with an intelligent device, connected to the internet, providing for the safe storage and delivery of medicines in an automatic and controlled manner. In addition, it allows for health checks to be made on the patient using data obtained through peripheral devices, which are not the subject of this invention. Thus it is an electromechanical device together with the necessary software both in the device and in external applications, to improve compliance with pharmacological treatments for patients, also generating reliable information and enabling continuous monitoring of the patient by the responsible person.

Embodiments of the present disclosure are directed to devices, systems, and methods for controlling environmental conditions for a volume of material. In some embodiments, a handheld, portable environmental control sleeve (ECS) is disclosed which is configured for controlling at least one environmental condition of a drug contained within a drug delivery or storage device (DDSD). The ECS includes an environmental control mechanism (ECM), thermal insulation material, at least one of a power source, a processor, at least one electrical contact, at least one indicator, at least one switch, at least one environmental condition sensor, a wireless transceiver, a phase change material and at least one heat dissipater. Upon the ECS receiving at least a portion of the DDSD, the at least one environmental condition of a drug contained within the DDSD is controlled by the ECM to be within a predetermined range.