Abstract: The disclosure concerns a steerable device for use as e.g. a guidewire for insertion into a subject's body. The device features a single side deflection of a bendable portion located at its distal end by application of a longitudinally-directed force either on an inner pull wire or on the bendable portion. The bendable portion is characterized by the presence of a reinforcement structure on one lateral side and a stress relief portion on the opposed lateral side that, upon actuation of the device, allows single side bending thanks to the physical constriction of the reinforcement structure, limiting the compression of one side of the bendable portion. The disclosure further concerns a system further comprising the steerable device and an actuator, as well as methods for using thereof.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: The invention provides for a steerable guidewire for insertion into a body cavity, characterized in that is comprises an elongated body defining a longitudinally-arranged lumen comprising i) a proximal end portion and ii) a distal end portion comprising a spatially reconfigurable portion and a tip; a pull wire located along said lumen and affixed to said distal end portion and to said proximal end; an actuation region located on said proximal end portion adapted to impart a tension force on the pull wire resulting in a compression force to the spatially reconfigurable region; and an intermediate region tubular element on said body located between said spatially reconfigurable portion and said proximal end.

Abstract: Described herein are microelectrode devices to provide localized neural recording or neural stimulation to a neurological target. The device includes a plurality of electrodes disposed along the shafts of deployable flexible pins. The deployable flexible pins are enclosed within an elongated probe shaft and can be expanded from their enclosure. Additionally, a specifically manufactured outer housing can be coupled to at least a portion of the elongated probe shaft. During deployment of the flexible pins the outer housing of the microelectrode device reduces friction between the flexible pins and the probe shaft and reduces delamination of the flexible pins during deployment.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: Described herein are microelectrode devices to provide localized neural recording or neural stimulation to a neurological target. The device includes a plurality of electrodes disposed along the shafts of deployable flexible pins. The deployable flexible pins are enclosed within an elongated probe shaft, and can be expanded from their enclosure. Additionally, a specifically manufactured outer housing can be coupled to at least a portion of the elongated probe shaft. During deployment of the flexible pins the outer housing of the microelectrode device reduces friction between the flexible pins and the probe shaft and reduces delamination of the flexible pins during deployment.

Abstract: A steerable device for use as e.g. a guidewire for insertion into a subject's body is disclosed. The device features a single side deflection of a bendable portion located at its distal end by application of a longitudinally-directed force either on an inner pull wire or on said bendable portion. The bendable portion is characterized by the presence of a reinforcement structure on one lateral side and a stress relief portion on the opposed lateral side that, upon actuation of the device, allows single side bending thanks to the physical constriction of the reinforcement structure, limiting the compression of one side of the bendable portion. A system further comprising an actuator, as well as methods for using thereof, are also disclosed.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: Described herein are microelectrode devices to provide localized neural recording or neural stimulation to a neurological target. The device includes a plurality of electrodes disposed along the shafts of deployable flexible pins. The deployable flexible pins are enclosed within an elongated probe shaft and can be expanded from their enclosure. Additionally, a specifically manufactured outer housing can be coupled to at least a portion of the elongated probe shaft. During deployment of the flexible pins the outer housing of the microelectrode device reduces friction between the flexible pins and the probe shaft and reduces delamination of the flexible pins during deployment.

Abstract: Techniques using electrical stimulation for treating an Autoimmune Disease by means of an implantable pulse generator and at least one electrode. An electrode lead is surgically implanted in a region of the insular cortex to deliver electrical stimulation. The at least one electrode lead and implantable pulse generator contain features that allow the electrical stimulation to be directed to specific volumes of the insular cortex, and ensure that non-therapeutic volumes do not receive electrical stimulation.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: The present disclosure discusses a system and methods for a deep brain stimulation lead. More particularly, the disclosure discusses a stimulation lead that includes one or more silicon based barrier layers within a MEMS film. The silicon based barrier layers can improve device reliability and durability. The silicon based barrier layers can also improve adhesion between the layers of the MEMS film.

Abstract: Techniques using electrical stimulation for treating an Autoimmune Disease by means of an implantable pulse generator and at least one electrode. An electrode lead is surgically implanted in a region of the insular cortex to deliver electrical stimulation. The at least one electrode lead and implantable pulse generator contain features that allow the electrical stimulation to be directed to specific volumes of the insular cortex, and ensure that non-therapeutic volumes do not receive electrical stimulation.

Abstract: Techniques using electrical stimulation for treating an Autoimmune Disease by means of an implantable pulse generator and at least one electrode. An electrode lead is surgically implanted in a region of the insular cortex to deliver electrical stimulation. The at least one electrode lead and implantable pulse generator contain features that allow the electrical stimulation to be directed to specific volumes of the insular cortex, and ensure that non-therapeutic volumes do not receive electrical stimulation.

Abstract: Techniques using electrical stimulation for treating an Autoimmune Disease by means of an implantable pulse generator and at least one electrode. An electrode lead is surgically implanted in a region of the insular cortex to deliver electrical stimulation. The at least one electrode lead and implantable pulse generator contain features that allow the electrical stimulation to be directed to specific volumes of the insular cortex, and ensure that non-therapeutic volumes do not receive electrical stimulation.

Abstract: Described herein are microelectrode devices to provide localized neural recording or neural stimulation to a neurological target. The device includes a plurality of electrodes disposed along the shafts of deployable flexible pins. The deployable flexible pins are enclosed within an elongated probe shaft, and can be expanded from their enclosure. Additionally, a specifically manufactured outer housing can be coupled to at least a portion of the elongated probe shaft. During deployment of the flexible pins the outer housing of the microelectrode device reduces friction between the flexible pins and the probe shaft and reduces delamination of the flexible pins during deployment.