Abstract: A method of using deep brain stimulation (DBS) for treating mental disorders associated with high connectivity in brain circuits, such as cortico-striato-thalamo-cortical (CSTC) circuits, is provided. The method comprises providing a first electrical signal having a first frequency to a first electrode implanted at a first location within a brain circuit and providing a second electrical signal having a second frequency to a second electrode implanted at a second location within the brain circuit. The first frequency and the second frequency are unequal.

Abstract: A method for controlling synchrony in a plurality of brain regions of a subject includes receiving signals from a source region of the subject's brain, determining at least one phase of the signals from the source region in a predetermined frequency band and delivering at least one stimulation pulse to at least one target region of the subjects brain based on the at least one phase of the signals from the source region to synchronize oscillations of the source region and the at least one target region.

Abstract: Systems and methods for controlling brain activity are provided. In some aspects, a method for controlling a synchrony in brain activity of a subject is provided. The method includes positioning stimulators to stimulate a first region and a second region of a subject's brain, and selecting a pulsed stimulation sequence comprising a first stimulation to the first region and a second stimulation to the second region, wherein the stimulations are timed to be substantially concurrent and separated by a phase lag. The method also includes delivering the pulsed stimulation sequence, using the stimulators, to control a synchrony between the first region and the second region at a predetermined frequency.

Abstract: A method for controlling synchrony in a plurality of brain regions of a subject includes receiving signals from a source region of the subject's brain, determining at least one phase of the signals from the source region in a predetermined frequency band and delivering at least one stimulation pulse to at least one target region of the subjects brain based on the at least one phase of the signals from the source region to synchronize oscillations of the source region and the at least one target region.

Abstract: A system and method for diagnosing mental or emotional disorders is disclosed. An affective BCI component is incorporated into a closed loop, symptom—responsive psychiatric DBS system. A series of input data related to a brain of the patient is acquired while the patient performs a battery of behavioral tasks. From the patient's performance on the task battery, the system identifies what is abnormal for that individual patient in terms of functional domains. Patient-specific behavioral measurements are then linked to patterns of activation and de-activation across different brain regions, identifying specific structures that are the source of the patient's individual impairment.

Abstract: A method of using deep brain stimulation (DBS) for treating mental disorders associated with high connectivity in brain circuits, such as cortico-striato-thalamo-cortical (CSTC) circuits, is provided. The method comprises providing a first electrical signal having a first frequency to a first electrode implanted at a first location within a brain circuit and providing a second electrical signal having a second frequency to a second electrode implanted at a second location within the brain circuit. The first frequency and the second frequency are unequal.

Abstract: A closed-loop brain computer interface (BCI) system for treating mental or emotional disorders with responsive brain stimulation is disclosed. The system includes an implanted module including a processor configured to process neural data acquired from one or more electrodes in communication with one or more brain regions of a patient. The implanted module is configured to deliver stimulation to electrodes in contact with the brain regions. An interface is in wireless communication with the implanted module and configured to receive the neural data from the implanted module. A controller processes the patient's brain and body signals to provide patient intentional control over the stimulation applied to the one or more electrodes and to control the stimulation.

Abstract: A closed-loop brain computer interface (BCI) system for treating mental or emotional disorders with responsive brain stimulation is disclosed. The system includes an implanted module including a processor configured to process neural data acquired from one or more electrodes in communication with one or more brain regions of a patient. The implanted module is configured to deliver stimulation to electrodes in contact with the brain regions. An interface is in wireless communication with the implanted module and configured to receive the neural data from the implanted module. A controller processes the patient's brain and body signals to provide patient intentional control over the stimulation applied to the one or more electrodes and to control the stimulation.

Abstract: Systems and methods for controlling brain activity are provided. In some aspects, a method for controlling a synchrony in brain activity of a subject is provided. The method includes positioning stimulators to stimulate a first region and a second region of a subject's brain, and selecting a pulsed stimulation sequence comprising a first stimulation to the first region and a second stimulation to the second region, wherein the stimulations are timed to be substantially concurrent and separated by a phase lag. The method also includes delivering the pulsed stimulation sequence, using the stimulators, to control a synchrony between the first region and the second region at a predetermined frequency.

Abstract: A closed-loop brain computer interface (BCI) system for treating mental or emotional disorders with responsive brain stimulation is disclosed. The system includes an implanted module including a processor configured to process neural data acquired from one or more electrodes in communication with one or more brain regions of a patient. The implanted module is configured to deliver stimulation to electrodes in contact with the brain regions. An interface is in wireless communication with the implanted module and configured to receive the neural data from the implanted module. A controller processes the patient's brain and body signals to provide patient intentional control over the stimulation applied to the one or more electrodes and to control the stimulation.

Abstract: A system and method for diagnosing mental or emotional disorders is disclosed. An affective BCI component is incorporated into a closed loop, symptom—responsive psychiatric DBS system. A series of input data related to a brain of the patient is acquired while the patient performs a battery of behavioral tasks. From the patient's performance on the task battery, the system identifies what is abnormal for that individual patient in terms of functional domains. Patient-specific behavioral measurements are then linked to patterns of activation and de-activation across different brain regions, identifying specific structures that are the source of the patient's individual impairment.

Abstract: The systems and methods described herein include an external base station with a tethered transceiver, an implanted hub that includes power, telemetry, and processing electronics, and a plurality of implanted satellite that contain reconfigurable front-end electronics for interfacing with electrodes. The system can operate in different modes. In a first mode, called a base boost mode, the external base station is used for closed-loop control of stimulation therapies. In a second, autonomous mode, closed-loop control is performed in the hub without direct influence from the base station. In a third mode, streams of neural data are transmitted to an offline processor for offline analysis.