The use of computer-aided design and computer-aided manufacturing (CAD/CAM) planning software and intraoperative navigation is becoming standard. It reduces the overall operation time and allows safer manipulation in close proximity to delicate structures.

An accurate registration process is essential for successful intraoperative navigation. It is necessary to define the location of the patient for the computer-aided surgery (CAS) system. Preoperative planning should enable registration of the patient to the navigation unit in less than a minute. In the field of neurosurgery, a Mayfield clamp is used for registration purposes during rigid patient fixation. Maxillofacial surgery, however, requires patient flexibility in order to gain better access and visibility. Therefore, an invasive navigation star is placed on the outer cortex of the patient’s skull. The position of the star remains unchanged, even if the patient is moved during the operation. However, when making therapeutic decisions, a risk–benefit analysis should always be carried out. Cortical fixation is not possible in the paediatric population. The outer cortex of the temporal skull of a young child is too thin to place an intracortical screw, which may cause dural perforation, screw migration, and neurological bleeding.

A systematic online PubMed search was performed to look for non-invasive alternatives in the application of intraoperative navigation in the paediatric population. The following search terms were used: “intraoperative”, “navigation”, “maxillofacial”, and “paediatric”. This search revealed several different, non-invasive approaches. Schramm et al. suggested the use of anatomical markers, namely soft tissue and bony landmarks that are correlated to computed tomography (CT) or magnetic resonance imaging (MRI) data. However, this is time-consuming and operator-dependent. The use of adhesive skin markers was suggested by Wolfsberger et al., but these are not adapted to intraoperative movements and can lose their accuracy. Moreover, soft tissue-based fiducial markers are subject to errors due to soft tissue shifts as a result of, for instance, oedema. Headsets could provide a good alternative, although they have to remain in place, limiting intraoperative patient positioning. Furthermore, they can interfere with the maxillofacial operation field.

None of these tools was considered appropriate for use in a paediatric patient presenting for treatment. Thus it was decided to attach the navigation star to a reference headband (Brainlab AG, Feldkirchen, Germany), in combination with the use of a custom-made registration splint.

Patient case

In February 2012, a 2-year-old patient was referred for the treatment of an infraorbital zygomatic lesion. The lesion, a desmoplastic fibroma, was located in a challenging anatomical location. It extended from the right lateral orbital wall to the infraorbital foramen, and invaded the orbital floor ( Fig. 1 ). A complete resection of the lesion was required due to the high tendency for recurrence of such lesions and its critical location, close to the right bulbus.

Imaging of an infraorbital zygomatic lesion and preoperative Brainlab trajectory planning on multi-slice CT.