Discussion

As described by Santamaria,Reference Santamaria and Cordeiro⁹ maxillectomy defects present three specific reconstructive challenges: (1) restoration of an adequate orbital support, (2) restoration of the oronasal separation and of the functional aspects of both elements, and (3) reestablishment of the facial contour. The four cases presented in this article reflect all these challenges.

Angular branch-based scapula tip free flaps are both reliable and versatile for midface reconstruction.Reference Piazza, Paderno, Taglietti and Nicolai¹ Their versatility allows for optimal adaptation to the deficit, with both vertical and horizontal positioning being possible, depending on the architecture of the osteotomies. No complications specifically related to the flap have been encountered in this series.

As suggested by Feinchtinger et al.,Reference Feichtinger, Pau, Zemann, Aigner and Kärcher⁵ navigation is helpful in assessing the bony margins of resection, which are often challenging for midface. In all these cases, navigation also allowed optimal positioning of the scapular tip free flaps. This tool has been particularly useful for securing the height of the reconstructed palate and the alignment of the nasal spine, evaluating nasal and malar projection, and assessing orbital floor position for reconstruction of total maxillectomy defects. A typical pitfall is to base the appreciation of a reconstruction on the appearance of overlying soft tissues. Because most head and neck cancer patients will undergo adjuvant post-operative radiotherapy, it is predictable that significant modifications and resorption of the soft tissues will occur. Such a situation may often lead to good immediate post-operative aesthetic results, which will, however, decline in the longer term. Navigation-assisted bony reconstruction of midface defects allows for precise free flap positioning and compensation for the expected post-radiation soft tissue volume variations.

Previously published studies concerning the use of surgical navigation to guide various reconstructions have come to similar conclusions. Harbison et al.,Reference Harbison, Shan, Douglas, Bevans, Li and Moe¹⁰ compared mandibular alignment following segmental mandibulectomy on cadavers using surgical navigation, surgical templates and freehand techniques. Surgical navigation proved to be similar to template-guided reconstruction, but with the added benefit of permitting real-time adjustment independently of the initial resection and reconstruction plans, and was superior to freehand reconstruction.

The use of computer-assisted design with pre-operative 3D printing has gained popularity in the recent decades. However, computer-assisted designs require additional time for pre-operative virtual planning and involves a significant learning curve for the surgeon.Reference Sozzi, Filippi, Canzi, De Ponti, Bozzetti and Novelli¹¹ Furthermore, computer-assisted design incurs costs exceeding up to $10,000 per case and models cannot be adjusted if cutting guides are incorrectly positioned or if resection margins need updating during the case.Reference Harbison, Shan, Douglas, Bevans, Li and Moe¹⁰ In our hospital, current prices are between $3,300 and $3,700 Canadian per case for 3D planning, whereas the neuronavigation equipment costs approximately $790 Canadian per case (Instrument Tracker (wire) – Navigation-Fusion: $150; Cranial Navigation Tracker (screw) – Navigation-Fusion: $640).

Since navigation-assisted functional endoscopic sinus surgery has become the standard of care in many situations,⁴ navigation equipment is often readily available for the reconstructive surgeon. In our experience, the few minutes spent calibrating the machine are more than made up by the expedited flap positioning. We have found that the use of a stand for the electromagnetic device, such as in functional sinus surgery, is not practical. Therefore, we have elected to drape the electromagnetic device in a sterile fashion and move it near the midface whenever a reading is needed.

The principal caveat that has been encountered in our experience is the tendency for the navigation device to decalibrate throughout surgery. The causes of these decalibrations, which have been discussed by Sorriento et al.,Reference Sorriento, Porfido, Mazzoleni, Calvosa, Tenucci and Ciuti¹² include metal and ferromagnetic sources in the operating theatre, such as nearby cell phones. This remains, however, unusual. Calibration of the instruments should be verified periodically throughout the case using reliable anatomical landmarks in proximity to the resection site, such as the glabella and lateral orbit, and the instruments should be recalibrated if required.