Methods for designing a computer-aided design/computer-aided manufacturing (CAD/CAM) surgical guide are shown. Cutting planes are separated, united, and thickened to easily visualize the necessary bone transfer. These designs can be three-dimensional printed and checked for accuracy.
Computer-aided design/computer-assisted manufacturing (CAD/CAM) is now being evaluated as a preparative technique for maxillofacial surgery. Because this technique is expensive and available in only limited areas of the world, we developed a novel CAD/CAM surgical guide using an in-house approach. By using the CAD software, the maxillary resection area and cutting planes and the fibular cutting planes and angles are determined. Once the resection area is decided, the necessary faces are extracted using a Boolean modifier. These superficial faces are united to fit the surface of the bones and thickened to stabilize the solids. Not only the cutting guides for the fibula and maxilla but also the location arrangement of the transferred bone segments is defined by thickening the superficial faces. The CAD design is recorded as .stl files and three-dimensionally (3-D) printed as actual surgical guides. To check the accuracy of the guides, model surgery using 3-D-printed facial and fibular models is performed. These methods may be used to assist surgeons where commercial guides are not available.
The use of CAD/CAM techniques has recently increased in dental and denture work. Following this evolution of CAD/CAM, osteocutaneous flap transfers using CAD/CAM are now used in the field of mandibular reconstruction after an oncologic wide resection of malignant tumors1,2,3. Several companies in Western countries have begun to supply and sell a CAD/CAM cutting guide for the mandible region. A CAD/CAM reconstruction of the mandible is considered to have an advantage in terms of accuracy4,5,6,7,8,9,10,11. However, a disadvantage is that this technique is available in limited areas worldwide and it is very expensive12. Thus, CAD/CAM reconstruction for maxillary lesions has not yet become popular. The number of the cases of maxillary reconstruction is lower than that for the mandible, and commercial guides are not common.
Because commercial maxillary CAD/CAM guides are not sold in Japan, we have developed CAD/CAM surgical guides using an in-house approach. The clinical effectiveness of the CAD/CAM guides has already been reported13,14,15,16,17,18,19, but there is no report of how to design them. The purpose of the present report is to show the CAD/CAM design method using a low-cost in-house approach.
This study was approved by the authors' institutional review board, and written consent forms were completed by all patients.
1. Preparation of Materials
2. Design
3. 3-D Printing for Model Surgery and Real Guides
NOTE: The main purpose of this report is to show the method of designing surgical guides; the procedure described below is not necessary if 3-D printing is not needed.
Using the procedure presented here, the resection area was determined first. Using CAD software, the resection area was completely circumscribed by the faces. This area was subtracted from the facial bone by a Boolean operation. The fibula image was placed on the defect, and fibular cutting faces were placed in the appropriate reconstructed points. All fibular cutting faces were linked to the fibula in a parent setting. These faces were made smaller and were united to make solids. The fibula was subtracted from these solids and then became the fibular cutting guides. The remaining surfaces of the facial bone were also thickened; these became the maxillary cutting guides. The superficial sides of the fibular segments are united and extracted to become a fixation guide. Finally, the fibular cutting guide, the maxillary cutting guide, and the fibular fixation guide were designed in Blender. These designs of the guides were exported in .stl format. They became real plastic objects by 3-D printing (Figures 9a and 9b).
Model surgery was performed (Figures 9c–9f). A maxillary cutting guide and fibular cutting guide were completely fitted to the facial bone and fibular bone models. Cutting the models with a saw and fixing the results with titanium plates and screws were also done. After the fixation, a 3-D-reconstructed image was determined by the 3-D scanner24. The post-model surgery .stl file and the CAD reconstructed design were compared in terms of accuracy of the guides and procedures using comparison software25. The data from the model surgery are shown in Figure 10; the reconstruction can be performed approximately within a 2 mm deviation.
Figure 1: Deciding on the area of maxillary resection. (a) The original facial bone .stl file is imported to Blender. (b) The first cutting plane is inserted in the zygomatic lesion. (c) The next cutting plane is placed. (d) The cutting plane of the alveolar area is also set. (e) The cutting planes must be united and surround the excision area completely. (f) By using a Boolean modifier, the maxillectomy area is subtracted from the facial bone. Please click here to view a larger version of this figure.
Figure 2: Planning the location of the fibular segments. (a) The fibular .stl file is imported to Blender. The distal portion of the fibula is placed in the alveolar area first. (b) The cutting plane is copied and linked to the fibula as a parent setting. (c) According to the preference of the planning surgeon, the next cutting plane is placed on the fibula. The fibular area that is sandwiched between these two planes becomes the first necessary fibular segment. (d) To determine the location of the next fibular segment, the copied fibula is placed. The next cutting planes are also placed according to the judgment of the surgeon. (e) Finally, three fibular blocks are designed, as in this example. Please click here to view a larger version of this figure.
Figure 3: Sliding the vertex along the edge. (a) Three pairs of the cutting planes are linked to the fibula as a parent setting. (b–d) To obtain an appropriate guide design, the vertex of the plane is moved along the edge in the edit mode. Please click here to view a larger version of this figure.
Figure 4: Designing the box for preparation to make the fibular cutting guide. (a) This cutting plane is going to be reduced in size to become an appropriate cutting guide size. (b) The final size of the cutting plane is highlighted. (c) The cutting plane is determined by sliding the vertex along the edge, similarly to Figure 3. (d) Both cutting planes are united by adding the new plane in the object mode. (e) Finally, the planes are added to surround the whole surface in the edit mode. Please click here to view a larger version of this figure.
Figure 5: Making the fibular cutting guide. (a) Using the procedures shown in Figure 4, three boxes are designed. (b) Each box is shared by the fibula using the subtraction of a Boolean modifier. (c) The opposite surface of each box is completely the same as the fibular surface. (d) To make pillars, a cube is placed near the subtracted solids. (e) A face of this cube is extruded. (f) By repeating this extrude, the main pillar is made. (g) By adding other pillars, attachments to the subtracted solids are made. (h) The pillar and the subtracted solids are united. (i and j) This cutting guide completely fits to the surface of the fibula. Each edge becomes the cutting plane, which guides the cutting saw. Please click here to view a larger version of this figure.
Figure 6: Designing the maxillary cutting guide. (a) The remaining surfaces of the maxilla and the zygoma are prepared just adjacent to the cutting area. (b) These planes are thickened to construct the solid to fit to the zygomatic and maxillary bones, using a solidifying modifier in the edit mode. The edge of this solid becomes the bone saw cutting plane. Please click here to view a larger version of this figure.
Figure 7: Taking out the transfer plane. (a) Each fibular segment is separated using the intersection of a Boolean modifier. (b) In this case, alveolar reconstruction is given priority over the zygomatic prominence. (c) Every superficial face is collected and united to prepare for the construction of the fixation guide. Please click here to view a larger version of this figure.
Figure 8: Designing the fixation guide of the fibular segments. (a) Using a knife tool, the lines are designed to the superficial surface. (b) A small window is made by deleting the vertices and faces. This window is used for the titanium plate fixation. (c) After making several windows, the superficial surface is thickened using a solidifying modifier. (d and e) Only the fixation guide is visualized. On both ends, the wings are added to fix this guide to the remaining facial bone. Please click here to view a larger version of this figure.
Figure 9: Model surgery. (a) Using a 3-D printer, the facial bone, fibular bone, and surgical guides can be realized. (b) The cutting guide is examined to fit to the fibula completely. (c and d) The fibular segments that were cut by using the cutting guide are set to the fixation guide. The fixation guide can completely fit to the cut segments. (e and f) Using the titanium plates and screws, fibular segments are transferred to the maxilla. After removing the fixation guide, additional plates and screws are added for a stronger fixation. Please click here to view a larger version of this figure.
Figure 10: Comparing the model to the plan. The post-surgery model is 3-D scanned and compared to the virtual plan. The scale (millimeter) shows the deviation distance from the virtual plan. The transferred bones mostly have a low deviation (green), while the metal fixation plates have a higher deviation (red). However, the deviation is largely below 2 mm. This image is different from the sample shown in Figure 9. Please click here to view a larger version of this figure.
CAD/CAM reconstruction is considered to contribute to the attainment of an accurate osteotomy length, width, and angle in cutting bones while using cutting guides4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19. The transferred arrangements of the bones are also considered to be accurate using a fixation guide11. Because the order, process, cutting plane, and arrangement plan are already decided upon before the actual surgery, time-saving is another advantage2,12,13,14.
Moreover, in addition to these theoretical advantages, a strength of the CAD/CAM technique is that because of the surgical guides, any surgeon can cut in the same place in the same way, thus standardizing the technique. If the guides are very accurate, it is possible that every surgeon can obtain accurate reconstruction results rather than using a free-hand approach where results are rather dependent on expertise. Because this CAD/CAM technique has emerged quite recently, reports similar to this are few. Commercial guides are available in Western countries; however, design methods are not open to the public. As this design method is new, we expect it to be developed and spread widely in the future.
This in-house CAD/CAM approach does not always demonstrate superiority. One clinical problem is that this technique becomes useless when the CT exam data is not made of thin and fine slices or is obtained just before the surgery, and the surgeon either does not decide on the resection area quickly or suddenly changes the resection area intra-operatively.
A design-making problem is that, if the designer does not have sufficient experience to see and learn the surgical procedure, an appropriate surgical guide design cannot be obtained. After all, in that situation, the designer does not know what exact space the actual surgeon would make in order to be free of objects in every surgical situation.
As a cost problem, a 3-D printer is necessary for a beginner designer to create trial-and-error designs to materialize the actual guides. After becoming a well-experienced designer, the materialization of the design is no longer indispensable. Luckily, computers and 3-D printers are becoming cheaper, which means we can design and manufacture surgical guides independently without having to rely on the services of expensive companies. A disadvantage is that we cannot yet 3-D print the metal plates used for the fixation. Plastic is the main material we can use for 3-D printing. Thus, we must pre-bend the metal plates before the surgery. As inexpensive 3-D printers that can handle metals are expected to come into use in the future, fixation plates may also be designed then, and all procedures will be less dependent on free-hand techniques.
Fused deposition modeling (FDM) is one of the most used 3-D printing technologies. 3-D objects are built by extruding thermoplastic polymers through a nozzle. When the thermoplastic materials get cold, internal stresses may generate deformations (warping)26. Acrylonitrile butadiene styrene (ABS) and polylactic acid (PLA) are the predominant plastics used for thermoplastic filaments. Petropolis et al.7 mentioned that, because ABS mandible models are particularly prone to warping, ABS plastics are less ideal for surgical models when compared with PLA. Both ABS and PLA plastics are gas sterilizable and sufficiently rigid to serve as a template27. Compared with ABS, PLA is less flexible with a lower melting temperature. Thus, we used PLA and a low-temperature plasma sterilization method under 45 °C in a clinical situation. Because the glass temperature of the PLA we used is 60 °C, we did not use either autoclave sterilization (approximately 121 °C) or ethylene gas oxide sterilization (approximately 60 °C).
Warping deformation remains a possibility. However, previous reports validated the accuracy of FDM-printed models in the field of maxillofacial surgery28. Several articles used a comparative study of the dry human mandible and FDM-printed replica using scanned CT data. These studies showed that consumer-grade FDM-printed models have an acceptable accuracy, similar to the results of industrial selective laser sintering (SLS) printers27,29,30. Nizam et al.1 argued that the quality of the CT scan is also one of the main determinants of dimensional errors, alongside the rapid prototype machine.
Even if the precise guides are designed virtually, the printed guides sometimes do not fit the pre-operative surgical bone models. We considered there to be two reasons for this.
1. The superficial bony shape of the area where the guide is designed to be attached is too flat to be hooked (especially maxilla). If these surfaces are smooth and not uneven, the guide surface is prone to become slippery and has a possibility of mis-fitting to the wrong bony area. To avoid this situation, the attached area should be designed wider and broader to catch the exact bony area. At the same time, if the attached area becomes larger, the undermined area becomes larger, which results in a wider scar.
2. On the other hand, the plastic surgical guide is also difficult to fit if the shape of this surface is too uneven and complicated. Because a rough surface with many small processes of the CAD/CAM guides induces friction resistance when attached to the bone, overly winded and complicated guide surfaces are also prone to mis-fit to the wrong place. To avoid these situations, trial-and-error printing and model surgery prior to the actual surgery are necessary. As a result, outsourcing the 3-D printing is not recommended.
Finally, even if the guide was able to fit in the model surgery, when it does not fit in clinical situations, it should be considered to be a kind of reference guide. This is similar to when commercial guides do not fit. Final decisions in real surgery should be made based upon the recognition of occlusion and facial aesthetics by the surgeon, not by the guide.
Although the apparent cost seems to be cheaper using the in-house CAD/CAM approach than commercial approaches, the real cost, which includes the surgeon's voluntary work and the time for designing and printing, is always underestimated or neglected. However, even if commercial guides become cheaper, this in-house approach still has a unique advantage, which is that surgeons can directly and easily perform trial-and-error reconstructions in a virtual simulation and realize the location relationship between the facial bone and the fibular segments.
The design of guides is limited to hard tissue such as the bone in this report. However, surgical guides can be designed for soft tissue cutting and fixing such as fat or muscle tissues. Guides are considered to be applicable in surgeries for the purpose of performing 3-D structural reconstruction using soft tissues. Fixation guides will soon be designed for breast reconstructions after cancer ablative surgery in a best-fit reshaping of the transferred adipose tissue from the abdomen to the breast.
In conclusion, by using an in-house approach, CAD/CAM surgical guides can be designed and printed at a hospital. In addition to using an accurate reconstruction by CAD/CAM, these techniques can also be used by surgeons who live outside regions where commercial guides are available. This technique is an option for maxillary reconstructions.
The authors have nothing to disclose.
This work was partly supported by JSPS KAKENHI Grant Number JP17K11914.
Information Technology Center, Renato Archer, Campinas, Brazil | InVesalius | Free software https://www.cti.gov.br/en/invesalius | |
The Blender Foundation, Amsterdam, Netherlands | Blender | Free software https://www.blender.org/ | |
TurboSquid, Inc. 935 Gravier St., Suite 1600, New Orleans, LA. | Free 3D skeletal data file | Free3D https://free3d.com/3d-models/human | |
MakerBot Industries, LLC One MetroTech Center, 21st Fl, Brooklyn, NY. | MakerBot Replicator+ | https://www.makerbot.com/replicator/ | |
YouTube (Google, Inc.), 901 Cherry Ave. San Bruno, CA | video sharing website. | https://www.youtube.com/results?search_query=invesalius+dicom+to+stl | |
Artec 3D, 2, rue Jean Engling, Luxembourg | Artec Eva Lite | https://www.artec3d.com/portable-3d-scanners/artec-eva-lite | |
CloudCompare | CloudCompare | http://www.danielgm.net/cc/ |