Abstract: Tumors in portions of a subject's body that have a longitudinal axis (e.g., the torso, head, and arm) can be treated with TTFields by affixing first and second sets of electrodes at respective positions that are longitudinally prior to and subsequent to a target region. An AC voltage with a frequency of 100-500 kHz is applied between these sets of electrodes. This imposes an AC electric field with field lines that run through the target region longitudinally. The field strength is at least 1 V/cm in at least a portion of the target region. In some embodiments, this approach is combined with the application of AC electric fields through the target region in a lateral direction (e.g., front to back and/or side to side) in order to apply AC electric fields with different orientations to the target region.

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 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: Treatment of a target region using alternating electric fields (e.g., TTFields) may be planned by determining, based on a plurality of impedance measurements obtained during a first window of time, a first impedance at each of a plurality of voxels that correspond to the target region. Then, based on the first impedances, a plan for treating the target region with alternating electric fields is generated. Subsequently, an electric field may be induced in the target region based on the plan. In some embodiments, a baseline MRI of the target region is obtained, and contemporaneous baseline impedances are registered to the MRI. In these embodiments, the plan for treating the target region is further based on a comparison between the first impedances and the baseline impedances.

Abstract: A method of applying tumor treating fields to a region of interest of a subject's body corresponding to a tumor, the method including: alternately applying to the region of interest a first electric field between a first pair of locations of the subject's body and a second electric field between a second pair of locations of the subject's body; detecting a change in the region of interest of the subject's body; ceasing applying the first and second electric fields; selecting, based on the detected change, a third pair of locations of the subject's body and a fourth pair of locations of the subject's body, the third and fourth pairs of locations being different than the first and second pairs of locations; and alternately applying to the region of interest a third electric field between the third pair of locations and a fourth electric field between the fourth pair of locations.

Abstract: Tumors in portions of a subject's body that have a longitudinal axis (e.g., the torso, head, and arm) can be treated with TTFields by affixing first and second sets of electrodes at respective positions that are longitudinally prior to and subsequent to a target region. An AC voltage with a frequency of 100-500 kHz is applied between these sets of electrodes. This imposes an AC electric field with field lines that run through the target region longitudinally. The field strength is at least 1 V/cm in at least a portion of the target region. In some embodiments, this approach is combined with the application of AC electric fields through the target region in a lateral direction (e.g., front to back and/or side to side) in order to apply AC electric fields with different orientations to the target region.

Abstract: A hydrogel phantom is herein described. The hydrogel phantom includes a plurality of adjacently disposed hydrogel elements. A first one of the hydrogel elements has a first electrical impedance and a second one of the hydrogel elements has a second impedance. The first impedance is different from the second impedance.

Abstract: A method is described. The method includes dispensing a first conductive gel on a support layer in a first predetermined pattern of target locations on a first side of the support layer to form a plurality of first conductive gel layers. The support layer is a flexible material having a plurality of voids intersecting the first side and a second side of the support layer. A second conductive gel is dispensed on the second side of the support layer in a second predetermined pattern of target locations to form a plurality of second conductive gel layers with each of the second conductive gel layers overlapping a corresponding first conductive gel layer to form conductive gel elements. The first conductive gel and the second conductive gel may then be cured.

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 using electrode elements that are arranged in sets, wherein each set includes a respective first electrode element and a respective second electrode element disposed in thermal contact with each other. Individual first conductors provide an electrically conductive path between each of the first electrode elements and a respective pin of a connector. And a second conductor provides an electrically conductive path between all of the second electrode elements and another pin of the connector. Temperature sensors are disposed in thermal contact with each set of electrode elements. Because the electrode elements are arranged in sets, the current that flows through any given set can be reduced (with respect to its maximum value) by switching off the first electrode element within the given set, in order to prevent the area that corresponds to the given set from overheating.

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.

Abstract: TTFields are applied using transducer arrays made from a plurality of individual electrode elements. The temperatures of those electrode elements can be normalized by positioning respective regions of pyroelectric material in thermal contact with the electrode elements, and subsequently applying an AC signal to each of the electrode elements at respective duty cycles so that an alternating electric field is induced within the subject. For each of the regions of the pyroelectric material, an electrical characteristic that is related to temperature is measured after the AC signal turns off. The duty cycles of the AC signals that are applied to the electrode elements is adjusted until the measured electrical characteristics indicate that the temperatures of all the regions of the pyroelectric material have equalized to within 1° C.

Abstract: Apparatus and methods for imposing electric fields through a target region in a body of a patient are described. The apparatus includes a sensor array having a plurality of temperature sensors with a plurality of first temperature sensors of the sensor array connected to a first conductor, and a plurality of second temperature sensors connected to a second conductor. A circuit is configured to provide a known amount of electricity via the first conductor and the second conductor to a third temperature sensor, the third temperature sensor within the plurality of first temperature sensors, and within the plurality of second temperature sensors.

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: 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: Apparatus and methods for imposing electric fields through a target region in a body of a patient are described. Generally, the apparatus includes at least one transducer array and a connector electrically connected to the at least one transducer array. The connector has at least one indicator electrical connector configured to provide feedback related to a status of the connector.

Abstract: Conventional transducer arrays for applying tumor treating fields (TTFields) include a set of individual electrode elements, and the more peripherally-located electrode elements (e.g., electrode elements at the corners or edges of the transducer arrays) tend to get hotter than the more centrally located electrode elements. This situation can be ameliorated by reducing the capacitance of the more peripherally-located electrode elements. Reducing the capacitance of those elements reduces the current that travels through those elements (at any given voltage), which reduces the temperature of those elements. Once the capacitance of the more peripherally-located electrode elements is reduced, higher voltages can be used without overheating. This leads to an increase in the overall current, which can improve the efficacy of the TTFields treatment.