Power sources that enable in-body devices, such as implantable and ingestible devices, are provided. Aspects of the in-body power sources of the invention include a solid support, a first high surface area electrode and a second electrode. Embodiments of the in-power sources are configured to emit a detectable signal upon contact with a target physiological site. Also provided are methods of making and using the power sources of the invention.

To enable detection of a plurality of capsule ingestions, the ingestible capsules include a transmitter and processing hardware to generate and transmit the signals. Each ingestible capsule obtains a serial number for distinguishing between the ingestible capsules, and generates a signal indicating that the capsule has been ingested. The signal includes a series of pulses having a particular pulse space and indicating the serial number. Each ingestible capsule transmits the signal to a receiver via the transmitter, where each ingestible capsule is identified based on at least one of: the particular pulse space and the serial number for the ingestible capsule.

Various methods and apparatuses are presented for an ingestible capsule that includes a digital, ingestible sensor component—or ingestible sensor—embedded 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.

Introduced here is an ingestible device comprising a capsule, a camera, an antenna, and a propulsion component. The camera can capture images of various in vivo environments as the ingestible device traverses the gastrointestinal tract, and these images can be wirelessly transmitted to an electronic device located outside of the living body. The images may be transmitted to the electronic device for review by an operator responsible for controlling the ingestible device.

A gastrointestinal treatment system including a gastrointestinal capsule adapted to treat a subject following ingestion of the gastrointestinal capsule. The gastrointestinal capsule includes: (a) a housing; (b) a vibrating agitator, powered by the battery, the vibrating agitator adapted such that, in a first vibrating mode of operation, the housing exerts vibrations on an environment surrounding the capsule; (c) a power supply disposed within the housing and adapted to power the vibrating agitator; and (d) a controller adapted, in response to receipt of an activation input, to activate the vibrating agitator to operate in the first vibrating mode of operation at at least one predetermined time of day. The system and method may be used to treat an ailment of the gastrointestinal tract and/or to mitigate at least one symptom of jetlag in a subject travelling from an origin location to a destination location.

A patch configured for being applied to a patients skin, said patch comprising a contact area configured for being in direct contact with the patients skin when applied thereto, and a detector configured for detecting contact between the contact area and the patients skin.

An ingestible electronic capsule for the collection of samples along a gastric intestinal tract and methods relating thereto are provided. The ingestible electronic capsule includes a housing and a cap that form an interior chamber. The cap includes a sampling port and one or more sample collection chambers are disposed within the interior chamber. A motor is also disposed within the interior chamber and is configured to rotate one of the cap and the one or more sample collection chambers so to align one or the one or more sample collection chambers and the sampling port of the cap so to allow for sample collection. A microcontroller is also disposed within the interior chamber and is in communication with at least the motor. The microcontroller is configured to control the selective alignment of the sampling port and one of the one or more sample collection chambers and induce gastric intestinal fluid sampling.

Introduced here is a digital pill comprised of a capsule, an ingestible sensor, and a slot antenna. The ingestible sensor can be configured to generate a signal indicative of a characteristic of the living body in which the digital pill is located. Biometric data can be stored, at least temporarily, in a memory in the form of signal values. For example, the slot antenna may transmit biometric data to a computing device across a network on a periodic basis (e.g., every 5 minutes, 15 minutes, 60 minutes, etc.). Alternatively, the slot antenna may stream biometric data to a computing device across the network in real time.

A vibrating gastrointestinal capsule and method of use thereof for treating Parkinsonism in a subject, the method including: (a) providing a vibrating gastrointestinal capsule having a housing; a vibrating agitation mechanism adapted such that, in a vibrating mode of operation, the housing exerts vibrations on an environment surrounding the capsule; and a power supply disposed within the housing and adapted to power the vibrating agitation mechanism; (b) ingesting the capsule, by the subject; and (c) controlling the vibrating agitation mechanism such that at least a portion of the vibrating mode of operation occurs within the stomach and/or the small intestine of the subject.

Provided according to embodiments of the invention pharmaceutical capsules that include a capsule body and a capsule cap, wherein the capsule cap envelops an open end of the capsule body to form a capsule core; and an adherence sheath that envelops a portion of the capsule core. Related capsules and methods of making such capsules are also provided herein.