Neuronavigation

The term neuronavigation is a neologism used to describe the set of computer-assisted technologies used by neurosurgeons to guide or "navigate” within the confines of the skull or vertebral column during surgery. The term is also used in a more universal sense outside the field of neurosurgery in areas of medicine such as otorhinolaryngology (ENT), orthopedics, general surgery and urology, with similar purposes in different anatomical areas. The set of hardware for these purposes is referred to as a neuronavigator.

Stereotactic Surgery

Neuronavigation is recognized as the next evolutionary step of stereotactic surgery, a set of techniques that dates back to the early 1900s and that gained popularity during the 1940s, particularly in Germany, France and the U.S., with the development of surgery for the treatment of movement disorders such as Parkinson's disease and dystonias. In its infancy the purpose of this technology was to create a mathematical model describing a proposed coordinate system for the space within a closed structure, e.g., the skull. This "fiducial spatial coordinate system” uses fiduciary markers as a reference to describe with high accuracy the position of specific structures within this arbitrarily defined space. The surgeon then refers to that data in order to target particular structures within the brain. This technology was boosted by the collection of data on human anatomy in “stereotactic atlases”, expanding the quantitatively defined “targets” that could be readily used in surgery. Finally, the advent of modern neuro-imaging technologies such as computed tomography (CT) and magnetic resonance imaging (MRI)—along with the ever-increasing capabilities of digitalization, computer-graphic modelling and accelerated manipulation of data through complex mathematical algorithms via robust computer technologies—made possible the real-time quantitative spatial fusion of images of the patient's brain with the created “fiducial coordinate system” for the purpose of guiding the surgeon's instrument or probe to a selected target. In this way the observations done via highly sophisticated neuro-imaging technologies (CT, MRI, angiography) are related to the actual patient during surgery.

Neuro Imaging

The ability to relate the position of a real surgical instrument in the surgeon’s hand or the microscope’s focal point to the location of the imaged pathology, updated in “real time” in an "integrated operating room", highlights the modern version of this set of technologies at its finest.^[1][2][3] In its current form, neuronavigation began in the 1990s and has adapted to new neuro-imaging technologies, real-time imaging capabilities, new technologies to transfer the information in the operating room for 3-D localization, real-time neuro-monitoring, robotics, and new and better algorithms to handle data via more sophisticated computer technology.

Surgical Virtualization

In its later conceptualization the term neuronavigation has started to fuse with that of “surgical-virtualization”, e.g., the Dextroscope^{TM [4]}, in which a neurosurgeon is able to vizualize the scenario for surgery in a 3-D model of manipulable computer data. In this way the physician can "practice and check" the surgery, try alternative approaches, assess possible difficulties, etc., before the real surgery takes place.

External links

• American Association of Neurological Surgeons (AANS.org) | Library. Research List.
• ANT - Advanced Neuro Technology: Your single source for clinical and research neuroscience systems.

References

1. ^ Stryker iNtellect Cranial on Navigation System II
2. ^ Medtronic StealthStation TREON plus.
3. ^ BrainLAB Global Site.
4. ^ Bracco AMT: Video Overview: Intro.