Abstract: An extended wear electrocardiography patch is provided. An integrated flexible circuit includes a single piece of material and has an upper end and a lower end opposite the upper end. A mirror image of the upper end extends from at least a portion of one side of the upper end and folds over the upper end. One circuit trace is positioned on the upper end and one circuit trace is positioned on the lower end. Electrical pads are located on a contact surface of the upper end and on an outward facing surface of the mirror image of the upper end. An electrocardiographic electrode is positioned on the contact surface of the upper end and another electrocardiographic electrode is positioned on a contact surface of the lower end. A battery is directly adhered to the outward facing surface of the mirror image of the upper end.

Abstract: An extended wear electrocardiography patch is provided. An integrated flexible circuit includes a single piece of material and has an upper end and a lower end opposite the upper end. A mirror image of the upper end extends from at least a portion of one side of the upper end and folds over the upper end. One circuit trace is positioned on the upper end and one circuit trace is positioned on the lower end. Electrical pads are located on a contact surface of the upper end and on an outward facing surface of the mirror image of the upper end. An electrocardiographic electrode is positioned on the contact surface of the upper end and another electrocardiographic electrode is positioned on a contact surface of the lower end. A battery is directly adhered to the outward facing surface of the mirror image of the upper end.

Abstract: An extended wear electrocardiography and physiological sensor monitor is provided. An electrode patch includes an integrated flexible circuit having a single piece of material that includes a longitudinal midsection between upper and lower ends and a mirror image shape of the upper end extending from at least a portion of one side of the upper end that runs substantially parallel to the midsection and folds over the upper end. A receptacle is adhered on an outward surface of the mirror image when the integrated circuit is folded over the upper end. One electrode is positioned on a contact surface of the integrated circuit on the upper end and another electrode is positioned on the contact surface on the lower end. A battery is directly adhered to the outward surface of the mirror image and positioned under the receptacle. A monitor is configured to be removably secured in the receptacle.

Abstract: An extended wear electrocardiography and physiological sensor monitor is provided. An electrode patch includes an integrated flexible circuit having a single piece of material that includes a longitudinal midsection between upper and lower ends and a mirror image shape of the upper end extending from at least a portion of one side of the upper end that runs substantially parallel to the midsection and folds over the upper end. A receptacle is adhered on an outward surface of the mirror image when the integrated circuit is folded over the upper end. One electrode is positioned on a contact surface of the integrated circuit on the upper end and another electrode is positioned on the contact surface on the lower end. A battery is directly adhered to the outward surface of the mirror image and positioned under the receptacle. A monitor is configured to be removably secured in the receptacle.

Abstract: An extended wear electrocardiography patch is provided. An integrated flexible circuit includes a pair of circuit traces that each originate within one end. A pair of electrocardiographic electrodes are each electrically coupled to one of the circuit traces. A layer of adhesive is applied on a contact surface of the flexible circuit and includes an opening on each end. Conductive gel is provided in each of the openings of the adhesive layer and is in electrical contact with the electrocardiographic electrodes. A non-conductive receptacle is adhered on one end of an outward surface of the flexible circuit and is operable to removably receive an electrocardiography monitor. The non-conductive receptacle includes electrode terminals aligned to electrically interface the circuit traces to the electrocardiography monitor. A battery is affixed to the outward surface of the flexible circuit and electrically interfaced via battery leads to a pair of electrical pads.

Abstract: An extended wear electrocardiography patch is provided. An integrated flexible circuit includes a pair of circuit traces that each originate within one end. A pair of electrocardiographic electrodes are each electrically coupled to one of the circuit traces. A layer of adhesive is applied on a contact surface of the flexible circuit and includes an opening on each end. Conductive gel is provided in each of the openings of the adhesive layer and is in electrical contact with the electrocardiographic electrodes. A non-conductive receptacle is adhered on one end of an outward surface of the flexible circuit and is operable to removably receive an electrocardiography monitor. The non-conductive receptacle includes electrode terminals aligned to electrically interface the circuit traces to the electrocardiography monitor. A battery is affixed to the outward surface of the flexible circuit and electrically interfaced via battery leads to a pair of electrical pads.

Abstract: An implantable medical device may include a case which houses components of the implantable medical device. The implantable medical device may include an inductive coil coupled to a rechargeable battery. The inductive coil may be operative to inductively couple to an external coil and to transfer energy from the external coil to the rechargeable battery to recharge the rechargeable battery. The implantable medical device may include a cutout formed in the case of the implantable medical device and filled with a dielectric material. The cutout may be operative to reduce eddy currents in the case during recharge of the rechargeable battery. The implantable medical device may include a slot antenna disposed within the case. The slot antenna may be operative to communicate with an external device through the cutout in the case.

Abstract: An implantable medical device may include a case which houses components of the implantable medical device. The implantable medical device may include an inductive coil coupled to a rechargeable battery. The inductive coil may be operative to inductively couple to an external coil and to transfer energy from the external coil to the rechargeable battery to recharge the rechargeable battery. The implantable medical device may include a cutout formed in the case of the implantable medical device and filled with a dielectric material. The cutout may be operative to reduce eddy currents in the case during recharge of the rechargeable battery. The implantable medical device may include a slot antenna disposed within the case. The slot antenna may be operative to communicate with an external device through the cutout in the case.