To distribute electrical treatment to a treatment area of a patient, described herein are electrical therapy devices, methods of their operation and methods for delivery of the electrical therapy to the patient. In some embodiments, the electrical therapy device comprises an electrode assembly that includes at least two electrodes, and a conductive spacer positioned between the electrodes. Methods of selection of the electrical therapy devices and methods of their operation are also provided.

An electrical stimulation method is provided in the disclosure. The electrical stimulation method is applied to a non-implantable electrical stimulation device, wherein the non-implantable electrical stimulation device includes an electrical stimulator and an electrode assembly. The electrical stimulator is detachably electrically connected to the electrode assembly. The electrical stimulation method includes the following steps. The electrical stimulator provides an electrical stimulation signal. The electrical stimulation signal is transmitted to a target area through the electrode assembly. The total energy value is calculated according to the energy value of the electrical stimulation signal.

An electrical stimulation method for impedance compensation is applied to a non-implantable electrical stimulation device that provides high-frequency electrical stimulation. The non-implantable electrical stimulation device includes an electrical stimulator and an electrode assembly. The electrical stimulator is detachably electrically connected to the electrode assembly. The electrical stimulation method for impedance compensation includes the following steps. A high-frequency environment is provided and the first impedance value of the electrode assembly is calculated according to at least one of the measured first resistance value, first capacitance value, or first inductance value of the electrode assembly. The high-frequency environment is provided and the second impedance value of the electrical stimulator is calculated according to at least one of the measured second resistance value, second capacitance value, or second inductance value of the electrical stimulator. The first impedance value, and the second impedance value are stored for calculating the tissue impedance value.

An electrode assembly that includes an electrically conductive layer, a first impedance reduction system, and a second impedance reduction system. The electrically conductive layer forms an electrode portion of the electrode assembly and a first surface to be placed adjacent a person's skin. The first impedance reduction system is configured to dispense a first amount of an electrically conductive gel onto the first surface of the electrically conductive layer in response to a first activation signal. The second impedance reduction system is configured to dispense a second amount of the electrically conductive gel onto the first surface of the electrically conductive layer in response to a second activation signal.

An apparatus can include a subassembly having one or more electrode elements, each electrode element having a skin-facing side and a skin-facing surface. The apparatus can further comprise a skin contact layer comprising a conductive adhesive. The skin contact layer can be coupled to the subassembly and can be disposed on the skin-facing side of the electrode elements. The conductive adhesive is electrically coupled to the electrode and configured to contact skin of a subject. At least a portion of the skin contact layer is selectively removable from the subassembly.

A system and method for electrical stimulation of the human body, and in particular, to systems and methods for electrode systems and signal delivery used in electrical-stimulation treatment, testing and monitoring of vision problems of a patient, analyzing the results of the treatments, and monitoring to determine, for example, whether a medical treatment for the patient needs to be continued and/or altered, wherein the design and placement of the electrode systems and adjustment of signals delivered to the electrodes facilitate adjustment of the geometry of signal flow through the tissues of the patient.

A transducer apparatus for delivering tumor treating fields to a subject's body, the transducer apparatus including: an array of electrodes, the array configured to be positioned over the subject's body with a face of the array facing the subject's body, the array including electrode elements positioned in existing electrode positions arranged around a centroid of the array; and at least one void space in the array capable of enclosing an areal footprint equivalent to at least 40% of an areal footprint of at least one existing electrode position, and superimposable on at least 40% of at least one existing electrode position by rotation of the array around the centroid.

A transducer apparatus for delivering tumor treating fields to a subject's body, the transducer apparatus including: an array of electrodes configured to be positioned over the subject's body with a face of the array facing the subject's body; a substrate including an adhesive layer, wherein the array of electrodes is disposed entirely on a first side of the substrate, the face of the array faces away from the substrate, the adhesive layer is on the first side of the substrate facing the same direction as the face of the array; and, when viewed from a direction perpendicular to the face of the array, a non-adhesive region is located between a pair of adjacent electrodes of the array, the non-adhesive region spanning at least 25% of a total distance between the pair of adjacent electrodes for at least one measurement measured along a straight line between the pair of adjacent electrodes.

A transducer apparatus for delivering tumor treating fields to a subject's body, the transducer apparatus including: a substrate and an array of electrodes disposed on the substrate, the array configured to be positioned over the subject's body with a face of the array facing the subject's body; wherein, when viewed from a direction perpendicular to the face of the array, the substrate has at least one concave edge forming at least a portion of a boundary of the array, the at least one concave edge defines an opening between two opposing sides of the substrate, no electrodes are present in the opening, and the substrate has a substantially C-shaped, U-shaped, rounded V-shaped, or annular shaped surface.

To provide a biomedical electrode which is capable of restraining displacement or release of the electrode even if a living body takes a hard action, and which is mountable without an occurrence of discomfort. This biomedical electrode has conductive gels 11, 11, retaining members 12, 12 to retain the conductive gels 11, 11, and an adhesive surface 31a, and comprises a sheet-shaped adhesive member 30 to adhere the conductive gels 11, 11 to a living body surface S via the retaining members 12, 12, and further, the adhesive member 30 is formed in an enough size to cover substantially all regions of the retaining members 12, 12, and is configured to have liquid through holes 30b to 30b, 30c, 30c to discharge sweat which is accumulated in internal spaces R, R formed between the living body surface S and the retaining members 12, 12.