A fixation device including a base structure such as a faceplate having an inferior surface capable of contacting a surface of a skull of a patient, having a superior surface, and defining at least two securement features. Each securement feature can be engaged by a cranial fastener to attach the faceplate to the skull. The device further includes a fixation structure such as an alignment plate or a flexible fixation member carried by the base structure and positionable at least one of (i) over an opening in the skull and (ii) within an opening in the skull. At least one surface of the fixation structure defines at least one channel in which an intracranial device is capable of being placed, and further defines at least one fixation feature to enable the intracranial device to be secured to the fixation device.

A modular sensor system is disclosed. The system can include one or more sensors, a mounting unit, and a control unit. The mounting unit can enable the control unit and/or one or more sensors to be securely, but detachably, mounted to a patient's body. The control unit can include electronics and other components configured to interface with, monitor, and record data from the one or more sensors. The control unit can further include a wired bus, transceiver, antenna, or other suitable components to enable wireless communication between the system and a central control or monitor. Some or all of the components included in the control unit can be removable from the system to enable some or all of the electronics of the system to be removed.

A subdural sensor includes: a substrate formed of a flexible material; and at least one type of sensor part mounted on the substrate. The substrate has an elongated shape, and includes: a sensor area in which the sensor part is mounted and a wiring pattern connected to the sensor part is formed; a wiring area contiguous with the sensor area, the wiring pattern extending in the wiring area; and a connector area contiguous with the wiring area, the connector area being an area on which a connector to be connected to the wiring pattern extending from the wiring area is mounted. A tip part of the sensor area has a planar shape that curves convexly toward an outer periphery, and a side shape that curves toward a first surface, the first surface being on the side of a dura mater when the subdural sensor is inserted into the subdural space.

A signal tracking system including: one fixation element to be secured to a rigid body part of the patient surrounding a target body part, the fixation element further including a mapping element, one tracker element to be secured to the fixation element to track, in real time, the internal tracker, and a control unit including a memory to store an internal referential and one image displaying the target body part and one fixation element. The control unit is designed to define, inside the internal referential, at least one 3D frame position attached to the at least one fixation element, and to precisely locate each point of the target body part, the control unit is further designed to precisely localize, in real time, the internal tracker inside the target body part.

Provided herein are cranial implant devices that include at least one acoustic, optical, and/or photoacoustic lens element comprising one or more electromagnetically translucent, electromagnetically transparent, sonolucent, and/or acoustically active materials. The cranial implant devices are structured for subgaleal scalp implantation within, beneath, and/or over at least one cranial opening of a subject and typically includes a substantially anatomically-compatible shape. In addition, the cranial implant devices permit transcranial therapeutic ultrasound, transcranial diagnostic ultrasound, photoacoustic imaging, electromagnetic wave diagnostic imaging, and/or electromagnetic wave therapeutic intervention of intracranial matter of the subject via the acoustic, optical, and/or photoacoustic lens element when the cranial implant device is subgalealy implanted within, beneath, and/or over the cranial opening of the subject. Other aspects are directed to various related systems and methods of obtaining diagnostic information from, and/or administering therapy to, a subject.

A burr hole device is configured to receive a catheter and a cable of a sheath. The sheath is configured to receive a portion of the catheter and has an electrode. When the catheter and sheath are implanted with the burr hole device, the catheter and electrode of the sheath are implanted in a brain. Systems and apparatuses may include the burr hole device and/or a cranial port device, the catheter, and the sheath.