Described here are systems, devices, and methods for implanting a nasal stimulator into nasal tissue and electrically stimulating nasal tissue. In some variations, a nasal microstimulator implantation system may comprise an implantation tool and an implantable microstimulator. An implantation tool may comprise a shaft and features to releasably attach a microstimulator. A microstimulator may comprise a passive stimulation circuit and one or more electrodes. In other variations, a nasal implantation system may additionally comprise one or more additional devices, such as a controller, an electrical probe, and/or a dissection tool.

Temperature sensing circuitry for an Implantable Medical Device (IMD) is disclosed that can be integrated into integrated circuitry in the IMD and draws very little power, thus enabling continuous temperature monitoring without undue battery depletion. Temperature sensor and threshold setting circuitry produces analog voltage signals indicative of a sensed temperature and at least one temperature threshold. Such circuitry employs a Ptat current reference stage and additional stages, which stages contains resistances that are set based on the desired temperature threshold(s) and to set the voltage range of the sensed temperature. These analog voltages are received at temperature threshold detection circuitry, which produces digital signal(s) indicating whether the sensed temperature has passed the temperature threshold(s). The digital signal(s) are then provided to digital circuitry in the IMD, where they can be stored as a function of time for later review, or used to immediately to control IMD operation.

The invention relates to a testing device for checking at least one first medical electrode (1), wherein the testing device comprises at least one first measuring electrode (2), which can be arranged relative to the first medical electrode (1) to be checked in such a way that the at least one first measuring electrode (2) and the first medical electrode (1) to be checked form a first capacitance (C.sub.11); a signal generating device (3), by way of which an alternating current voltage can be generated, by means of which the first capacitance (Cn) can be acted upon; an evaluation device (4), which is designed to determine at least one first test result (P.sub.11) in relation to the first capacitance (C.sub.11) from a measured impedance curve (I) of an impedance caused in response to the first capacitance (C.sub.11).

A defibrillation pad for a defibrillator, includes: a pair of electrode pads (10) each including a gel portion (12); lead wires (21, 22); a pair of nonconductive release liners (30A, 30B) each detachably stuck to the corresponding gel portion (12) and each having a through hole (32A, 32B) opposed to the corresponding gel portion; and a connecting member (40) comprising an electric connecting pattern (41) having a predetermined electrical resistance, wherein the pair of gel portions (12), each of which is exposed from the corresponding through hole (32A, 32B), are electrically connected to each other through the electric connecting pattern (41) in a state where each of the pair of release liners (30A, 30B) are stuck to the corresponding gel portion. The connecting member (40) has a cut region (45) by which the pair of gel portions are electrically disconnected to each other when the pair of electrode pads are stuck to a living body.

An electrode set is disclosed for a defibrillator, the set including at least two electrodes each having a carrier layer, a conductive contact layer, a conductive gel layer, and a non-conductive electrode cover. In the storage state of the electrode set, the electrode covers lie against each other in a planar relationship at least portion-wise, on the side that is remote from the gel layer of the at least two electrodes. The gel layers of the electrodes are directly in contact with each other in a portion-wise manner by way of two openings in the electrode covers.

Described here are systems, devices, and methods for implanting a nasal stimulator into nasal tissue and electrically stimulating nasal tissue. In some variations, a nasal microstimulator implantation system may comprise an implantation tool and an implantable microstimulator. An implantation tool may comprise a shaft and features to releasably attach a microstimulator. A microstimulator may comprise a passive stimulation circuit and one or more electrodes. In other variations, a nasal implantation system may additionally comprise one or more additional devices, such as a controller, an electrical probe, and/or a dissection tool.

Various embodiments of a sealed package and a method of forming such package are disclosed. The package can include a non-conductive substrate that includes a cavity disposed in a first major surface. A cover layer can be disposed over the cavity and attached to the first major surface of the non-conductive substrate to form a sealed enclosure. The sealed package can also include a feedthrough that includes a via between a recessed surface of the cavity and a second major surface of the substrate, and a conductive material disposed in the via. An external contact can be disposed over the via on the second major surface of the non-conductive substrate, where the external contact is electrically connected to the conductive material disposed in the via. The sealed package can also include an electronic device disposed within the sealed enclosure that is electrically connected to the external contact.

Apparatus for transcutaneous electrical nerve stimulation in a user, the apparatus comprising: stimulation means for electrically stimulating at least one nerve with at least one stimulation pulse; control means connected to the stimulation means for controlling at least one characteristic of the at least one stimulation pulse; and modulating means connected to the control means for modulating the at least one characteristic of the at least one stimulation pulse according to the time of day.

An electrode test system of a defibrillator including electrodes in a face-to-face test arrangement forming a capacitor, an impedance measurement signal generator connected to the electrodes and configured to send an ac signal to the electrodes, an impedance measurement signal processor connected to the electrodes which is placeable in an electrode test state and configured to receive an electrode test ac signal from the electrodes and process the electrode test ac signal to obtain a processed electrode test ac signal, a defibrillator processor connected to the impedance measurement signal generator and the impedance measurement signal processor configured to place the impedance measurement signal processor in the electrode test state and to receive the processed electrode test ac signal, analyze the processed electrode test ac signal to obtain an electrode test impedance signal and analyze the electrode test impedance signal to determine a pass condition or a fail condition of the electrodes.

An implantable medical device (IMO) includes one or more stimulation engines (SEs) and selectively connectable output switching circuitry for driving a plurality of output nodes associated with a respective plurality of electrodes of the IMO's lead system when implanted in a patient. The output switching circuitry may be configured to facilitate self-test mode (STM) functionality in the IMO (e.g., when it is in a hermetically sealed package) by using a dual mode switch in series with a stimulation engine selection switch with respect to each output node in the output switching circuitry under mode selection control.