In one aspect, a water-activated, ingestible battery, comprises a cathode comprising a metal oxide with a decreased amount of toxicity, relative to an amount of toxicity of other metal oxides; an anode comprising a biocompatible, water stable compound, the anode infused with benign cations; a separator between the cathode and the anode; a cathodic lead comprising a first conducting material, the cathodic lead in contact with the cathode; an anodic lead comprising a second conducting material, the anodic lead in contact with the anode; and a cell casing comprising a water-permeable biocompatible polymer, the cathodic lead, and the anodic lead, with the cell casing enclosing the cathode, the anode, and the separator.

In one aspect, a water-activated, ingestible battery, comprises a cathode comprising a metal oxide with a decreased amount of toxicity, relative to an amount of toxicity of other metal oxides; an anode comprising a biocompatible, water stable compound, the anode infused with benign cations; a separator between the cathode and the anode; a cathodic lead comprising a first conducting material, the cathodic lead in contact with the cathode; an anodic lead comprising a second conducting material, the anodic lead in contact with the anode; and a cell casing comprising a water-permeable biocompatible polymer, the cathodic lead, and the anodic lead, with the cell casing enclosing the cathode, the anode, and the separator.

The invention provides a water-activated, deferred-action battery having a housing containing at least one cell, comprising at least one anode selected from the group consisting of magnesium, aluminum, zinc and alloys thereof; a cathode comprising a skeletal frame including conductive metal and having a portion of its surface area formed as open spaces, and further comprising a heat-pressed, rigid static bed of active cathode material encompassing the skeletal frame, the cathode material comprising basic copper sulfate, said cathode material being compacted and fused to itself and to the skeletal frame under pressure and / or heat, to form a heat-fused, conductive, electrochemically active phase; at least one cavity separating the cathode and the at least one anode, and at least one aperture leading to the at least one cavity for the ingress of an electrolyte-forming, aqueous liquid.

A device is configured to be administered via an oral route by a subject. The device includes an anode, a seal disposed on the anode, and a cathode. When exposed to a liquid or a hydrogel, an exposed surface of the anode undergoes galvanic oxidation dissolution to provide DC power to the device. As the exposed surface of the anode undergoes galvanic oxidation dissolution, the seal incrementally detaches from the anode, and a substantially constant surface area of the exposed surface is maintained.

A solid state energy generator and storage device, comprising two layers, in contact with each other, of dissimilar materials in terms of electron density and configuration, sandwiched between an anode and a cathode. One of the layers is a stabilized mixture of carbon and an ionic material (carbon matrix) and the other layer is a stabilized manganese oxide mixed with an ionic material (oxide matrix). The built-in potential of the device is determined mathematically by integrating the electrostatic forces across the barrier and will rise or fall in direct proportion to the device temperature (in Kelvin). In addition the device can be charged and thus function as a charge storage device, with the rated voltage varying according to the temperature of the device. When a load is attached across the terminals of the device a current flows.