As technology develops and becomes more user-friendly, planning of operations and patient-specific surgical guides and fixation plates should be performed by the surgeon. We present a protocol for 3D planning of orthognathic skeletal movements and 3D planning and printing of patient-specific fixation plates and surgical guides.
Technological advancements in surgical planning and patient-specific implants are constantly evolving. One can either adopt the technology to achieve better results, even in the less experienced hand, or continue without it. As technology develops and becomes more user-friendly, we believe it is time to allow the surgeon the option to plan his/her operations and create his/her own patient-specific surgical guides and fixation plates allowing him full control over the process. We present here a protocol for 3D planning of the operation followed by 3D planning and printing of surgical guides and patient-specific fixation implants. During this process we use two commercial computer-assisted design (CAD) software. We also use a fused deposition modeling printer for the surgical guides and a selective laser sintering printer for the titanium patient-specific fixation implants. The process includes computed tomography (CT) imaging acquisition, 3D segmentation of the skull and facial bones from the CT, 3D planning of the operations, 3D planning of patient-specific fixation implant according to the final position of the bones, 3D planning of surgical guides for performing an accurate osteotomy and preparing the bone for the fixation plates, and 3D printing of the surgical guides and the patient-specific fixation plates. The advantages of the method include full control over the surgery, planned osteotomies and fixation plates, significant reduction in price, reduction in operation duration, superior performance and highly accurate results. Limitations include the need to master the CAD programs.
3D printing is an additive method based on gradual placement of layers from different materials, thus creating 3D objects. It was originally developed for rapid prototyping and was introduced in 1984 by Charles Hull, who is considered the inventor of the stereolithography method based on solidifying layers of photopolymer resin1. Technological advancements in virtual planning of surgeries and planning and printing of patient-specific implants are constantly evolving. Innovations arise both in the field of computer assisted design (CAD) software and in 3D printing technologies2. Simultaneous to developments in technology, the software and printers become more user-friendly. This shortens the time required for planning and printing and allows the surgeon the option to plan his/her operations and create his/her own patient-specific surgical guides and fixation plates in a field that was exclusively an engineer’s “playground”. These developments also allow for surgeons and engineers to introduce new applications and designs of patient-specific implants3,4,5.
One of these applications is 3D planning of orthognathic surgeries followed by 3D planning and printing of surgical guides and patient-specific fixation plates. Historically, orthognathic surgeries were planned using articulators. A facebow was used to register the relationship of the upper jaw to the temporomandibular joint thus positioning the patient’s casts in the articulator. Later, the surgical movements were performed on the casts and an acrylic wafer was prepared to help with proper positioning of the jaws during surgery. This method was used for many years and is still used nowadays by most, but the utilization of cone beam computed tomography (CT) together with intra-oral scanners and CAD software allowed for accurate planning, sparing the need for facebows or casts and moving towards creation of digitally planned wafers6. This method reduced the inaccuracy of manual manipulation and measurements but still had flaws including using the instable lower jaw as a reference point for positioning the upper jaw and lack of control over the vertical positioning of the upper jaw7. Thus, a new method was introduced. This method is called the “waferless” surgery and is based on repositioning of the jaws anatomically using surgical cutting guides and patient-specific fixation titanium plates8. This method resolves the disadvantages of the digital wafer method described before. We will describe this method, which allows the surgeon complete freedom in planning these surgeries in a patient-specific manner, with minimal possible errors and inaccuracies. This method allows for a “waferless” surgery, which means there is no need for using the opposed jaw as reference for repositioning the bones, thus decreasing the inaccuracies derived from this reliance9.
1. Repositioning of the jaws
NOTE: This section is performed using the imaging software (i.e., Dolphin).
2. Preparation of patient-specific fixation plates and surgical guides
NOTE: This section is performed using the 3D design software (i.e., Geomagic Freeform).
To observe the clinical use of the method, we present a case of a 23 year old female. She suffered from condylar hyperplasia at a younger age in the right condyle resulting in asymmetry of both jaws. Figure 1A shows the retrognathic upper jaw and prognathic lower jaw exhibiting the discrepancies between the jaws. In the frontal view, the severe asymmetry can be observed as detailed using the yellow and red lines. Using the imaging software (Supplemental Figure 1), a surgical treatment plan was performed (Supplemental Figure 2, Supplemental Figure 3, and Supplemental Figure 4). The surgical plan was based on lateral cephalometric analysis. The location of the planned bony osteotomy is important in order to preserve the healthy dentition and also to allow for proper placement of the fixation screws in intact bone. The 3D stl files were exported from the imaging software and imported to the 3D design software in both pre- and post-planned bony movement setups (Supplemental Figure 5). The patient-specific fixation plate was planned (Supplemental Figure 6, Supplemental Figure 7, Supplemental Figure 8, and Supplemental Figure 9) followed by the surgical guide planning (Supplemental Figure 10 and Supplemental Figure 11). The fixation plate was planned on the post-operative planned location and the surgical guide on the current status of the patient, based on the planned osteotomy. In the presented patient, a bimaxillary operation was performed. The upper jaw was repositioned in the first stage following by repositioning of the lower jaw according to the final dental occlusion. A vestibular incision above the mucogingival line in the upper jaw was performed to expose the bone. The nasal floor was elevated, the surgical guides were anatomically positioned followed by drilling holes in the bone through the holes in the guides (these holes would later match the patient-specific fixation plate following reposition of the jaw). An osteotomy at the LeFort I level based on the surgical guide was performed using a reciprocal saw. The septum, lateral walls of the nasal cavity and the pterygomaxillary junction were separated using appropriate osteotomes. The upper jaw was mobilized and repositioned symmetrically in the appropriate location based on the holes in the final patient-specific fixation plate which matched the previously drilled holes in the upper jaw and midface (using the surgical guides). The plate was fixated using titanium screws and the surgical wound was sutured. An osteotomy of the lower jaw was then performed using a sagittal split osteotomy and repositioned based on the dental occlusion. The final result is shown in Figure 1B; note the correction of the discrepancies of the jaws and the severe asymmetry.
Figure 1: Pre- and Post-operative imaging of a 23-year-old patient with asymmetry in the facial bones. (A) Pre-operation imaging. Left: a cephalometric image; Right: a frontal 3D reconstruction view of CT showing the severe asymmetry. (B) Post-operative imaging. Left: a lateral cephalometric image; Right: a posterior-anterior cephalometric image showing the perfect correction of the asymmetry. Please click here to view a larger version of this figure.
Supplemental Figure 1: A view of the workspace and the 3D button for importing and editing in the 3D mode. Please click here to view a larger version of this figure.
Supplemental Figure 2: Building an X-ray image. When planning a surgical plan, building a panoramic X-ray image from the CT image is mandatory. Please click here to view a larger version of this figure.
Supplemental Figure 3: Osteotomy in the imaging software. A Le-Fort I osteotomy is observed separating the upper jaw from the midface. The location of the osteotomy is crucial as it will be used in the next stages for surgical guides construction and fixation plate positioning. Avoid the dental roots. Please click here to view a larger version of this figure.
Supplemental Figure 4: Surgical treatment plan in the imaging software. The pre and post operation 3D planning can be observed. Pre-operative is shown on the left and post-operative is shown on the right. Please click here to view a larger version of this figure.
Supplemental Figure 5: Importing into the 3D design software. The 3D stl files were exported from the imaging software and imported to the 3D design software. (A) Pre-operative midface, upper jaw and lower jaw. (B) Post-operative upper jaw and lower jaw (notice that the midface does not change its location). Please click here to view a larger version of this figure.
Supplemental Figure 6: Planning the fixation plate. (A) A parallel plane is created. (B) The holes for the screws and the outer shape of the plate are planned on the plane. Please click here to view a larger version of this figure.
Supplemental Figure 7: Fixation plate construction. (A) Following projection from the plane and finalizing the outer form of the plate. (B) Creating the thickness of the plate. Please click here to view a larger version of this figure.
Supplemental Figure 8: Fixation plate hole preparation. (A) Using the Boolean function for separating the fixation plate. (B) Marking the holes in the plate using the SubD option. Please click here to view a larger version of this figure.
Supplemental Figure 9: Finalized patient-specific fixation plate. (A) The finalized plate. (B) The plate on the bone following the planned bony movement. Notice the perfect fit. Please click here to view a larger version of this figure.
Supplemental Figure 10: Surgical guide planning. The planning is performed using the holes planned on the upper jaw in the final position (to receive a perfect fit with the holes in the fixation plate) but after moving the jaw to the pre-operative position, as the guides are the first to be used during the operation for bone osteotomy preparation. Please click here to view a larger version of this figure.
Supplemental Figure 11: Finalized surgical guides. (A) The finalized surgical guides on the pre-operative bony facial bones. (B) Both the surgical guides and the final fixation plates. Please click here to view a larger version of this figure.
3D planning and printing is one of the most rapidly evolving methods in the surgical field. It is not only a promising tool for the future, but a practical tool used nowadays for highly accurate surgical results and patient-specific solutions. It allows for highly accurate results and reduces the dependency on the surgeon’s experience10. It solves many of the disadvantages of previous old fashion surgical methods, but the costs delay the full implementation of the method10. In-house planning and printing of the surgical guides reduce the costs to a neglectable expanse and reduces dramatically the cost of the patient-specific fixation plate. In this report we describe a method for 3D planning of orthognathic surgery followed by 3D planning and printing of surgical guides and patient-specific fixation plates as a basis for the surgeon to perform the whole process in-house. This protocol can be used for any orthognathic surgery, implementing all the above advantages.
This protocol is based on two CAD software. The first is the imaging software, which allows for segmentation and surgical planning including osteotomy location and bony movements. The second is the 3D design software, which allows for the planning of the surgical guides and the patient-specific fixation implants.
When using the imaging software, it is crucial to acquire a proper CT image, to properly plan the osteotomy location, avoiding damage to dental roots and to always keep in mind where the future fixation plates will be placed thus leaving enough room for the planned plates and screws. Keep in mind the holes prepared in the surgical guides need to match the holes of the final fixation plate. Be sure to export the proper stages of the surgical planning, the position of the upper jaw after the osteotomy but before the movement, and another stl file with the final position of the upper jaw.
When using the 3D design software, it is important to first plan the final patient-specific fixation plates. Following the hole preparation for the screws, the upper jaw with the holes needs to be repositioned according to the location before the surgical movement for preparation of the surgical cutting guide with the holes in the right position. Thus, the order of the steps is crucial for accurate positioning and proper surgical guide preparation. Always remember that if there is a doubt regarding discrepancies in bone continuity due to artifacts or improper bone segmentation it is preferred to add bone in the missing part because a slight space between the fixation plate and the bone in a specific area is preferred over bony interfere with the placement of the plate. It is important to remember that at times orthodontic preparation can result in bony deficiencies and exposed dental roots, so one should not assume this is due to artifacts.
This method describes basic principals in surgical planning of orthognathic cases including the planning of surgical guides and patient-specific fixation plates. It solves the inaccuracies existing in previous non-computed and semi-computed methods such as digital wafers and allows full control over the vertical dimension that did not receive a definite solution in those methods. Other advantages of the method include complete control over the surgery by performing a virtual plan of the operation, including the planned osteotomies and fixation plates, significant reduction in price (compared to outsourcing the planning), and reduction in operation duration. Limitations include the need to master the CAD programs and the price of the 3D printed titanium plates which is significantly higher than using wafers and stock titanium plates. The methods described here, especially the planning of surgical guides and plates can be further modified for many surgical purposes. We describe the use of this method for the surgical planning of bony resection and reconstruction in facial bones. This method can be used to innovate in the field of surgical planning and reconstruction3,5 and can also be applied in research, for example in planning of sophisticated scaffold designs for bone regeneration.
The authors have nothing to disclose.
No funding was received for this work.
Dolphin imaging software | Dolphin Imaging Systems LLC (Patterson Dental Supply, Inc) | 3D analysis and virtual planning of orthognathic surgeries | |
Geomagic Freeform | 3D systems | Sculpted Engineering Design |