Abstract: Tumors inside a person's head (e.g., brain tumors) can be treated using tumor treating fields (TTFields) by positioning capacitively coupled electrodes on opposite sides of the tumor, and applying an AC voltage between the electrodes. Unlike the conventional approach (in which all of the electrodes are positioned on the person's scalp) at least one of the electrodes is implemented using an implanted apparatus. The implanted apparatus includes a rigid substrate shaped and dimensioned to replace a section of the person's skull. At least one electrically conductive plate is affixed to the inner side of the rigid substrate, and a dielectric layer is disposed on the inner side of the conductive plate or plates. An electrically conductive lead is used to apply an AC voltage to the conductive plate or plates.

Abstract: Disclosed are electrode assemblies having at least two layers of conductive adhesive material separated by an anisotropic material and methods of using the electrode assemblies in Tumor Treating Fields (TTFields) therapy.

Abstract: An apparatus includes a bottom panel with a transparent region and ceramic sidewalls affixed to the bottom panel to form a container. Electrodes are disposed on the outer surface of the sidewalls at positions selected so that when a sample is positioned in the container, applying a voltage between the electrodes induces an electric field through the sample. Electrical conductors provide contact with the electrodes. All the components are sized and shaped to facilitate positioning of the container on the stage of an inverted microscope so that when the sample is positioned in the container, light emanating from a light source is free to travel along an optical path that passes through the sample, through the transparent region, and into the objective of the inverted microscope. The electrodes and conductors are positioned with respect to the transparent region so as not to interfere with the optical path.

Abstract: When electrodes are used to impose an electric field in target tissue within an anatomic volume (e.g., to apply TTFields to treat a tumor), the position of the electrodes can be optimized by generating a 3D map of electrical conductivity or resistivity of the anatomic volume. A location of the target tissue within the anatomic volume is identified, and a dipole is added to the 3D map at a location that corresponds to the target tissue. positions for the electrodes that maximize a potential attributable to the dipole are determined based on the 3D map of electrical conductivity or resistivity and the location of the dipole.

Abstract: Tumor treating fields (TTFields) can be delivered by implanting a plurality of sets of implantable electrode elements within a person's body. Temperature sensors positioned to measure the temperature at the electrode elements are also implanted, along with a circuit that collects temperature measurements from the temperature sensors. In some embodiments, an AC voltage generator configured to apply an AC voltage across the plurality of sets of electrode elements is also implanted within the person's body.

Abstract: This application describes a variety of approaches for generating high voltage sinusoidal signals whose output voltage can be adjusted rapidly, without introducing high-frequency artifacts on the output. When these approaches are used, stronger electric fields can be applied to the tumor for a higher percentage of time, which can increase the efficacy of TTFields therapy. In some embodiments, this is accomplished by preventing adjustments to a DC power source during times when the output of that DC power source is powering the output signal. In some embodiments, this is accomplished by synchronizing the operation of an AC voltage generator and an electronic switch that is connected to the output of the AC voltage generator.

Abstract: Alternating electric fields (e.g., TTFields) may be applied to a subject's body using an electrode assembly that includes a skin contact layer formed at least partially of a conductive adhesive composite. An electrode element is electrically coupled to the conductive adhesive composite. Optionally, the electrode assembly can include a layer (e.g., sheet) of anisotropic material between the electrode element and the skin contact layer. Optionally, the skin contact layer may comprise an outer adhesive layer comprising conductive adhesive composite, an inner adhesive layer comprising conductive adhesive composite, and a substrate positioned between the inner and outer adhesive layers.

Abstract: An apparatus for delivering tumor treating fields to a subject's body. The apparatus comprises: a plurality of electrically coupled electrode elements to be located on a subject's body and able to deliver tumor treating fields to the subject's body, wherein at least one electrode element of the plurality of electrically coupled electrode elements comprises a dielectric layer, the dielectric layer has a first surface to face the subject's body and a second surface opposite the first surface, and at least one of the first surface and the second surface of the dielectric layer is a non-planar surface.

Abstract: A transducer apparatus for delivering tumor treating fields to a subject's body, the transducer apparatus including: a plurality of electrode elements; wherein the plurality of electrode elements comprises a first electrode element and a second electrode element, wherein the first electrode element and the second electrode element are substantially located in a plane of the transducer apparatus; and when viewed from a direction perpendicular to the plane, the first electrode element and the second electrode element have edges located adjacent each other without any other electrodes between them, wherein the edges of the first electrode element and the second electrode element extend parallel to each other along their length.

Abstract: A data transfer apparatus (“DTA”) connects to the field generator in a TTFields therapy system using the same connector on the field generator that is used to connect a transducer interface to the field generator. The field generator automatically determines whether the transducer interface or the DTA is connected to it. When the transducer interface is connected to the field generator, the field generator operates to deliver TTFields therapy to a patient. On the other hand, when the DTA is connected to the field generator, the field generator transfers patient-treatment data to the DTA, and the DTA accepts the data from the field generator. After the field generator and the DTA have been disconnected, the DTA transmits the data to a remote server, e.g., via the Internet or via cellular data transmission.

Abstract: Alternating electric fields (e.g., TTFields) may be applied to a subject's body using one or more electrode assemblies that includes a sheet of graphite, at least one layer of conductive material disposed on the front face of the sheet of graphite, and an electrode element positioned behind the sheet of graphite. The electrode element has a front face disposed in electrical contact with the rear face of the sheet of graphite. The sheet of graphite spreads both heat and current out in directions that are parallel to the front face of the sheet, which eliminates or at least minimizes hot spots on the electrode assembly. This in turn makes it possible to increase the current without exceeding a temperature safety threshold (e.g., 41° C.).

Abstract: Alternating electric fields (e.g., TTFields) may be applied to a subject's body using one or more electrode assemblies that includes a sheet of anisotropic material, at least one layer of conductive material disposed on the front face of the sheet of anisotropic material, and an electrode element positioned behind the sheet of anisotropic material. The electrode element has a front face disposed in electrical contact with the rear face of the sheet of anisotropic material. The sheet of anisotropic material spreads both heat and current out in directions that are parallel to the front face of the sheet, which eliminates or at least minimizes hot spots on the electrode assembly. This in turn makes it possible to increase the current without exceeding a temperature safety threshold (e.g., 41° C.).

Abstract: An apparatus includes a bottom panel with a transparent region and ceramic sidewalls affixed to the bottom panel to form a container. Electrodes are disposed on the outer surface of the sidewalls at positions selected so that when a sample is positioned in the container, applying a voltage between the electrodes induces an electric field through the sample. Electrical conductors provide contact with the electrodes. All the components are sized and shaped to facilitate positioning of the container on the stage of an inverted microscope so that when the sample is positioned in the container, light emanating from a light source is free to travel along an optical path that passes through the sample, through the transparent region, and into the objective of the inverted microscope. The electrodes and conductors are positioned with respect to the transparent region so as not to interfere with the optical path.

Abstract: A cage assembly can have at least one enclosure. Each enclosure can have a floor defining a floor area having a major dimension and a cover having a bottom surface. A spacing between the bottom surface of the cover and the floor can define a cage height. At least one sidewall can extend between the floor and the cover. A ratio of the cage height to the major dimension of the floor area of each enclosure of the at least one enclosure can be at least 0.70.

Abstract: Transducer arrays for applying alternating electric fields (e.g., tumor treating fields a.k.a. TTFields) to a subject's body typically include a plurality of capacitively coupled electrode elements. Often, certain electrode elements on a given array tend to run hotter than other electrode elements. For example, in many anatomical contexts, the corner elements of the transducer array tend to run hotter than the non-corner elements. The spread of operating temperatures between the electrode elements that tend to run hotter and the other electrode elements can be reduced by wiring a capacitor in series with those electrode elements that tend to run hotter (e.g., the corner elements).

Abstract: Tumor treating fields (TTFields) can be delivered by implanting a plurality of sets of implantable electrode elements within a person's body. Temperature sensors positioned to measure the temperature at the electrode elements are also implanted, along with a circuit that collects temperature measurements from the temperature sensors. In some embodiments, an AC voltage generator configured to apply an AC voltage across the plurality of sets of electrode elements is also implanted within the person's body.

Abstract: A treatment assembly can have an inner layer having an inner surface and an outer surface and defining a plurality of openings extending therethrough. The treatment assembly can further comprise a plurality of plates, each plate being at least partially received within a respective opening of the plurality of openings of the inner layer. The treatment assembly can further comprise treatment circuitry comprising a cable having a plurality of electrical leads and a plurality of lead ends, each electrical lead being electrically connected to a respective lead end of the plurality of lead ends. A cover layer can be attached to the outer surface of the inner layer and overlie the plurality of lead ends of the cable. The plurality of lead ends can be in contact with respective plates of the plurality of plates to define a plurality of electrodes.

Abstract: Tumor treating fields (TTFields) can be delivered to a subject's body with improved safety and efficacy by determining the condition of participating electrode elements and/or the subject's skin condition under positioned electrode elements. This may be accomplished by applying an AC signal to pairs or groups of electrode elements and taking corresponding impedance measurements. In some embodiments, the impedance measurements are indicative of electrode element condition and/or skin condition. These determined conditions can be used to adjust or pause TTFields treatment, for example to permit skin recovery or to ensure that participating electrode elements will properly function.

Abstract: A transducer array including a conductive layer and a conductive gel layer is described. The conductive layer has one or more electrode element. The one or more electrode element is configured to receive electrical signals from an electric field generator producing an electric signal as a Tumor Treating Field. The conductive gel layer overlaps the one or more electrode element of the conductive layer. The conductive gel layer has a first region and a second region. The first region has a first resistivity and the second region having a second resistivity with the first resistivity being different from the second resistivity.

Abstract: Tumor treating fields (TTFields) can be delivered to a subject's body at higher field strengths by switching off one or more electrode elements that are overheating without switching off other electrode elements that are not overheating. This may be accomplished using a plurality of temperature sensors, with each of the temperature sensors positioned to sense the temperature at a respective electrode element; and a plurality of electrically controlled switches, each of which is wired to switch the current to an individual electrode element on or off. A controller input signals from the temperature sensors to determine the temperature at each of the electrode elements, and controls the state of the control input of each of the electrically controlled switches to selectively switch off the current or adjusted the duty cycle at any electrode element that is overheating.