A medication dispensing system that includes a housing for at housing at least one medication in bulk, the at least one medication including a plurality of doses of the at least one medication; and a dispenser for separating a single dose from the at least one medication in bulk, the dispenser moving the single dose of the at least one medication from a position within the housing to a position outside the housing. The medication dispensing system also includes an optical verification sensor for verifying the at least one medication is a correct medication; a weight verification sensor for verifying the at least one medication is a correct medication; and an interface for receiving a plurality of inputs and displaying a plurality of outputs. The medication dispensing system also includes a network connection; and a virtual health advisor module associated with the medication dispensing apparatus which includes an instruction set. The instruction set, when executed by a processor associated with the medication dispensing apparatus causes the medication dispensing apparatus to produce a prompt at the interface, the prompt seeking an input related to human health; receive at least one input related to human health; and implement an action in response to the at least one input.

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.

An activity monitor is associated with a container, such as a medication bottle, and includes one or more detectors configured to detect activity associated with the bottle, such as movement, opening and/or closing, and changes in volume and/or mass. The activity monitor may include alerting devices and be programmed with scheduling information. The activity monitor may also, or instead, be part of a system and communicate with one or more remote devices such as a user device or monitoring system, such as to receive programming information from those devices or to output activity information to those devices.

The presently disclosed device includes a plurality of vials each bearing a unique identifier and in discrete locations in the device. An alignment assembly aligns one of the discrete locations with an access point for dispensing one of the vials. Computer executable instructions select a vial to be dispensed and store inventory information of the vials. The inventory information associates the unique identifiers with a status for each the plurality of vials indicating whether a vial is: loaded, dispensed, returned, or remaining undispensed in the device. The computer executable instructions also deactivate dispensing of the vials from the device based on at least one signal received from at least one environmental sensor configured to detect one of: location, temperature, humidity, vibration, shock, blood alcohol content (BAC), and light intrusion. A deactivation assembly deactivates dispensing of the vials based on the instructions.

Embodiments relate to a system comprising a drug dispenser; a user interface to receive a user information; a bio-feedback monitoring device to monitor at least one vital of a user as an input to the bio-feedback monitoring device; a communication module; a processor; a database; a memory; wherein the processor is communicatively coupled with the memory; and wherein the processor is configured to: receive a prescription; dispense a drug through the drug dispenser on authenticating the user information with at least one vital of the user and the prescription; update an inventory of the drug through the communication module; log record of dispensing of the drug; maintain a ledger of the record of dispensing of the drug, use blockchain technology. The output of the bio-feedback monitoring device controls a quantity of drug dispensed from the drug dispenser.

A substance dispensing apparatus comprises a housing for handheld use and a mouthpiece coupled to the housing. The housing comprises a biometric sensor and a cavity sized to receive a reservoir. The mouthpiece comprises a recess and a capacitive sensor array. The apparatus further comprises a pump coupled to the mouthpiece and couplable to the reservoir and comprises a processor in communication with the biometric sensor, capacitive sensor array, and pump. The processor is configured to cause the pump to automatically dispense a substance from the reservoir to a mouth of an intended user via the mouthpiece in response to determining that: a unique biometric attribute of the intended user is detected by the biometric sensor based on biometric data from the biometric sensor; and a unique dentition of the intended user is positioned within the recess of the mouthpiece based on dentition data from the capacitive sensor array.

Embodiments relate to a system comprising a drug dispenser; a user interface to receive a user information; a bio-feedback monitoring device to monitor at least one vital of a user as an input to the bio-feedback monitoring device; a communication module; a processor; a database; a memory; wherein the processor is communicatively coupled with the memory; and wherein the processor is configured to: receive a prescription; dispense a drug through the drug dispenser on authenticating the user information with at least one vital of the user and the prescription; update an inventory of the drug through the communication module; log record of dispensing of the drug; maintain a ledger of the record of dispensing of the drug, use blockchain technology. The output of the bio-feedback monitoring device controls a quantity of drug dispensed from the drug dispenser.

A lid counts a number of patient accesses to a pill bottle. The lid has an actuator, a main housing containing the actuator and an access counter responsive to the actuator. The actuator stores energy in response to axial force manually applied to mount the lid on the bottle and releases the stored energy in response to counter-axial force manually applied to remove the lid from the bottle. Each release of energy causes the access counter to advance one interval, indicating an accumulated total of advances and, therefore, the total number of times the bottle has been accessed. The lid can be adjusted to account for taking various numbers of pills per dosage over a predetermined time period.

A programmable pill dispensing device, system, and methods are provided. A programmable pill dispensing device may be used to automatedly dispense a pill, such as a prescription medication, at a programmed predetermined time.

Embodiments for scheduling the delivery of multiple medications to a patient by a processor. Any interactions between the multiple medications or between one of the multiple medications and a type of food are considered to construct an analytical model to identify an optimized schedule for delivery of the multiple medications to the patient. The optimized schedule is adjusted in real time as additional information concerning the multiple medications and the type of food are introduced, and delivered to a dispensing device associated with the one of the multiple medications.