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Journal of Applied Oral Science

versión impresa ISSN 1678-7757

J. Appl. Oral Sci. vol.18 no.1 Bauru enero./feb. 2010 



Hybrid fixation in the bilateral sagittal split osteotomy for lower jaw advancement



Felipe Ladeira PereiraI; Marcos JansonII; Eduardo Sant'AnaIII

IDDS, Oral and Maxillofacial Surgeon, Brazilian Army, Juiz de Fora General Hospital (HGeJF), Juiz de Fora, MG, Brazil
IIDDS, MS. Orthodontist, Private Practice, Bauru, SP, Brazil
IIIDDS, PhD, Associate Professor of Oral and Maxillofacial Surgery, Bauru School of Dentistry, University of São Paulo, Bauru, SP, Brazil

Corresponding address




Miniplate and screw fixation has been widely used in bilateral sagittal split osteotomy, but some issues remain unclear concerning its lack of rigidity when compared to Spiessl's bicortical technique. This paper demonstrates the hybrid fixation technique in a case report. A 34-year-old female patient underwent a double jaw surgery with counter-clockwise rotation of the mandible fixed using the hybrid fixation technique. The patient evolved well in the postoperative period and is still under follow up after 14 months, reporting satisfaction with the results and no significant deviation from the treatment plan up to now. No damage to tooth roots was done, maxillomandibular range of motion was within normality and regression of the inferior alveolar nerve paresthesia was observed bilaterally. The hybrid mandibular fixation is clearly visible in the panoramic and cephalometric control radiographs. It seems that the hybrid fixation can sum the advantages of both monocortical and bicortical techniques in lower jaw advancement, increasing fixation stability without significant damage to the mandibular articulation and the inferior alveolar nerve. A statistical investigation seems necessary to prove its efficacy.

Key words: Bilateral sagittal split osteotomy. Orthognathic surgery. Monocortical fixation. Bicortical fixation. Mandibular advancement. Condylar torque.




Bilateral sagittal split osteotomy (BSSO) is commonly used to treat mandibular discrepancies7,11,28. The ability to rigidly and properly fix the fractured segments at the time of surgery may facilitate healing in the immediate postoperative period and reduce the displacement possibility of the bony segments, particularly the condylar proximal segment27. The technique that uses bicortical compressive screws was first described by Spiessl25 (1974) while the technique that uses miniplates and monocortical screws was introduced by Luhr14 (1986).

Monocortical osteosynthesis has been widely used in the fixation of BSSO8, leading to stable results according to the literature3,8,15,19-21, in spite of being considered as a semi-rigid fixation21. Since monocortical fixation is not as rigid as bicortical osteosynthesis, the excessive shear force stress, produced by the compressive action of the masseter muscle to the osteotomy line, may transform the mandibular shape postoperatively9,18. On the other hand, other authors have found no differences in the stability promoted by both techniques8,11,26.

Concerning the surgical treatment in Class II patients, fixation should be stable and precise enough to allow great advance without compromising the bone healing and stability. In skeletal Class II malocclusion, the following characteristics can be observed, alone or in association: mandibular retrusion; vertical deficiency or excess of the maxilla and maxillomandibular retrusion17.

This paper describes, through a case report, the routine use of the hybrid fixation technique for BSSO in mandibular advancement, which associates the advantages of two commonly used techniques: the positional bicortical screws and the monocortical plate osteosynthesis.



A 34-year-old female patient searched Dr. E.S. complaining the "lack of chin", "reversed lower lip" and gummy smile. The patient had previous orthodontic treatment with dental compensation, having both maxillary first premolars already extracted and the gap closed. Clinically, the patient presented symmetric dolicocephalic face with maxillomandibular retrusion; maxillary vertical excess; chin deficiency and an accentuated facial convexity. In addition, healthy periodontal tissues and temporomandibular joints (TMJs), tension of the orbicularis oris and mental muscles during function and lower lip incompetency when relaxed were also observed.

In order to acquire proper positioning of the mandibular incisors, the right and left first premolars were extracted and levelling and alignment of the maxillary arch was performed to create a positive overjet (Figures 1 and 2). For the planning, Arnett, et al.2 (1999) soft tissue analysis was used. The surgical plan consisted in maxillary impaction and advancement, mandibular counter-clockwise rotation with an overall advancement of 9 mm in B point, 13.7 mm in Pog and 3 mm of genioplasty. Under general anesthesia, the mandible was managed and fixed as described below, followed by usual maxillary Le Fort I.





After BSSO according to Epker's6 (1977) modified technique, the condyle was properly positioned1 and the osteotomy fixed with a 2.0 mm miniplate and two monocortical screws in each segment. An inset bend was made at the plate to maintain the gap and avoid condylar torque1,19,20. Having the 4 screws in position, a transorally oblique perforation was drilled in the retromolar region (visualising the proximal end of the distal fragment), the hole was tapped and a 2.0 mm diameter x 16 mm long screw was inserted. A second screw was placed distally from the first in the same manner. These screws were positional and do not exert pressure between segments (Figure 3). The same fixation was done on the other side. After completion of the osteosynthesis, maxillomandibular immobilization (MMI) was removed and occlusion and mouth opening were checked. The wounds were then sutured as usual.



The patient evolved well in the postoperative period and is still under follow up after 14 months, reporting satisfaction with the results (Figures 4 to 5). No damage to tooth roots was done, maxillomandibular range of motion is within normality and regression of the inferior alveolar nerve (IAN) paresthesia is observed bilaterally. The hybrid mandibular fixation is clearly visible in the panoramic and cephalometric control radiographs (Figure 6 and 7). Figure 8 shows cephalometric tracing of the preoperative position and postoperative changes along the 16 months of treatment, including the removal of brackets.












The hybrid fixation technique in the BSSO with one 2.0 mm miniplate, four monocortical and two positional screws was initially described for management of cases where the lingual cortical plate of the distal segment had fractured27,28. The purpose of the suggested technique is to be the routine fixation method in mandibular advancements in order to increase stability of the single 4-hole miniplate while maintaining its advantages, such as: lower possibility of IAN compression, absence of skin scars (since the retromolar screws are placed transorally) and passive condyle accommodation at the glenoid fossa. Moreover, the earlier release of the elastic MMI in the postoperative period, the sooner the patient will start soft diet ingestion (while using guiding elastics for intercuspation) without significant increase of the total fixture cost.

Among the drawbacks of the bicortical screw technique are IAN compression, scars in the face or neck made by the transcutaneous perforation and rotation of the mandibular condyles1,3,9,11,19,20,23. In the method proposed for this case, mandibular third molar extraction prior to surgery is necessary for bicortical screw placement. Since extractions are not absolutely necessary when miniplates are the only fixation method, it can be considered an advantage of this technique18.

Concerning the miniplate advantages, the three-dimensional relationship between the segments is established by the miniplate, with the condyle in the glenoid fossa and the proximal and distal segments in their initial contact point21. No compression is made between the segments and the result is immediate and functionally stable3,8,15,19-21. The miniplate applied in the anterior border of the buccal osteotomy facilitates manipulation of the proximal segment and seating of the condyle; after fixed it is stable enough to permit release of the MMI and intraoperative inspection of the occlusion23. Any corrections may be easily achieved at this stage by releasing and reattaching the distal ends of the miniplates19,23. Also, plates can be easily removed transorally in the postoperative period if necessity rises19. Moreover, passive plate bending and application helps maintaining the axial condylar orientation within the fossa19. It is also conceivable that the fragments fixed by miniplates, which are bent to accommodate the step at the buccal surface, would tend to cause less harm to the IAN20,23, and also reduces the risk of damaging the roots11.

After monocortical osteosynthesis have been applied, small forces directed across the osteotomy can still change the relative positions of the segments. This can lead to occlusal changes when patients return to function early or when they are noncompliant21. The unpredictable fixation provided by the miniplates alone may compromise the clinical outcome if the patient is restored to early function23. Therefore, if the patient's postsurgical occlusion is unstable, monocortical osteosynthesis will lead to too much rotation of the mandible and may cause delayed union and breakage of the miniplates4,8. Therefore, especially in these patients or those who underwent an overcorrection, osteosynthesis should be performed bicortically8.

The fixation relapse rate in the bicortical screws technique ranges from 8 to 11%12,13, while for the miniplates this value ranges from 5.2 to 15%3,19,20. According to a recent literature review10, bicortical screws show only slight differences regarding skeletal stability compared to miniplates in short-term, but a large number of studies with higher skeletal long-term relapse rates were seen in patients treated with bicortical screws instead of miniplates. By advancing the mandible, the submandibular soft tissue drape is stretched together with the suprahyoid and infrahyoid muscles. As a consequence, the hyoid, fixed by these muscles, is pulled forward, but will return to its original position several months postoperatively. Stretching of theses tissues gives rise to a constant force opposite to the vector of the mandibular advancement1,3,11,16. Relapse seems to be a multifactorial phenomenon affected by many variables, such as (from strongest to weakest evidence): amount of advancement; type and material of fixation; low and high mandibular plane angle; control of proximal segment; soft tissue and muscles; remaining growth and remodeling; preoperative age and surgeon skills10. Although relapse can occur after 6 months, the greatest amount of relapse occurs in the early postoperative time (6 weeks to 6 months)5,16,29. A correlation between the amount of advancement and relapse may occur only when the advancement exceeds 7 mm3,10,16,19,29. Furthermore, the MMI period in the first weeks seems to reduce the relapse rate5,16, without great significant risks of muscular atrophy if this time is short16.

In a study investigating the skeletal stability following sagittal split osteotomy using monocortical miniplate internal fixation, Rubens, et al.19 (1988) observed that all patients who presented some sort of symptom related to the TMJ in the preoperative period had its resolution in the postoperative period, while three patients (15%) that were symptom-free before surgery, started having symptoms after surgery. In a similar study, Scheerlinck, et al.20 (1994) noted that among patients who presented TMJ dysfunction in the preoperative period, 68% showed improvement or resolution, 20% noted no difference and 12% reported worsening of the symptoms. Among the patients who didn't present symptoms of TMJ dysfunction in the preoperative period, 80% still had no complaints in the postoperative period, 13% had muscular pain, 5.5% an intermediate click and 1.5% closed lock20. Kahnberg, et al.11 (2007) reported that more than a half of the pre-surgical symptomatic patients had its signs and symptoms solved in the postoperative period, while approximately 25% of those without TMJ dysfunction in the preoperative period developed it after surgery. Nevertheless, in a study investigating sagittal split advancement osteotomies stabilized with miniplates, approximately 7% of the patients underwent progressive condylar resorption (PCR), which generated relapse in the B-point, and whose initial signs are usually seen 6 months postoperatively, showing a direct connection between the amount of advancement and the risk of PCR20. In fact, the endorotation movement that happens in the TMJ in mandibular advancements has major potential to cause dysfunction in the TMJ than the exorotation observed in surgeries for mandibular prognathism19.

Shetty, et al.24 (1994), in a study using a biomechanical model of the BSSO, showed that, within a physiologic range of loading, their hybrid technique using one positional screw (different from the method reported in this paper), produced stability that was comparable with or superior to that produced by conventional methods of rigid internal fixation. Because the plate and the monocortical screws are placed first, a bone clamp is never applied across the osteotomy21. The segment clamping negates advantage of the positional screw, and makes it function as a lag screw21. This could produce lingual or rotational movement of the proximal segment, with consequent condylar displacement, occlusal changes and TMJ problems, in addition to the possibility of IAN compression between the segments, producing numbness or paresthesia1,12,13,21,23. Since the positional bicortical screw from the technique is placed far anteriorly than those normally placed in the Spiessl's25 (1974) technique, it can be placed transorally, avoiding a transcutaneous stab incision and thus an unfavorable scar21,22. In the technique described for the present case, the two non-compressive bicortical screws are easily placed transorally, by angulating the drill and inserting the screw while visualizing if the gap between the fragments stays still. If the gap starts to increase, the screw should be removed, reangulated and reinserted. When the gap is greater than 2 mm, particulated bone graft are usually used.

The screw applied bicortically in the retromolar region inhibits the displacement tendencies through its resistance to axial and shear forces9,23. A second screw, as proposed in our technique, would guarantee the immobility of the segments. The use of 2 miniplates on each side to increase fixation stability in great mandibular advancements has been described7,15,23. In the technique proposed here, stability can be increased without the expense of these additional two plates and eight screws usually necessary in these cases, but using four bicortical screws, two on each side, lowering the total fixture costs. Within the anatomic limits imposed by the BSSO, it is known that the greater the separation between the retromolar screw and the miniplate, the better the expected functional stability23.

The goal of the technique proposed in this paper is to associate the rigidity of the bicortical positional screws with the advantages of the monocortical miniplates in lower jaw advancement, without increasing the treatment cost or TMJ damage, allowing early release of the MMI and probably reducing the relapse rate. Further investigations comparing clinical relapse rate of the suggested technique to other technique are still necessary.



1- Arnett GW. A redefinition of bilateral sagittal osteotomy (BSO) advancement relapse. Am J Orthod Dentofacial Orthop. 1993;104:506-15.         [ Links ]

2- Arnett GW, Jelic JS, Kim J, Cummings DR, Beress A, Worley CM Jr, et al. Soft tissue cephalometric analysis: Diagnosis and treatment of dentofacial deformity. Am J Orthod Dentofac Orthop. 1999;116:239-53.         [ Links ]

3- Borstlap WA, Stoelinga PJW, Hoppenreijs TJM, van't Hof MA. Stabilization of sagittal split advancement osteotomies with miniplates: a prospective study with two-year follow-up Part II. Radiographic parameters. Int J Oral Maxillofac Surg. 2004;33:535-42.         [ Links ]

4- Champy M, Pape HD, Gerlach K, Lode JP. Oral and maxillofacial traumatology. In: Schilli W, Kruger E, editors. The strasbourg miniplate osteosynthesis. v. 2. Mandibular fractures. Chicago: Quintessence; 1986. p.19-43.         [ Links ]

5- Ellis E, Reynolds S, Carlson DS. Stability of the mandible following advancement: a comparison of three postsurgical fixation techniques. Am J Orthod Dentofacial Orthop. 1988;94:38-49.         [ Links ]

6- Epker BN. Modifications in sagittal osteotomy for the mandible. J Oral Surg. 1977;35:157-9.         [ Links ]

7- Erkmen E, ªimºek B, Yücel E, Kurt A. Comparison of different fixation methods following sagittal split ramus osteotomies using three-dimensional finite elements analysis. Part 1: advancement surgery - posterior loading. Int J Oral Maxillofac Surg. 2005;34:551-8.         [ Links ]

8- Fujioka M, Fujii T, Hirano A. Comparative study of mandibular stability alter sagittal split osteotomies: bicortical versus monocortical osteosynthesis. Cleft Palate Craniofac J. 2000;37:551-5.         [ Links ]

9- Hammer B, Ettlin D, Rahn B, Prein J. Stabilization of the short sagittal split osteotomy: In vitro testing of different plate and screw configurations. J Craniomaxillofac Surg, 1995;23:321-4.         [ Links ]

10- Joss CU, Vassalli IM. Stability after bilateral sagittal split osteotomy advancement surgery with rigid internal fixation: a systematic review. J Oral Maxillofac Surg. 2009;67:301-13.         [ Links ]

11- Kahnberg KE, Kashani H, Owman-Moll P. Sagittal split advancement osteotomy: Comparison of the tendency to relapse after two different methods of rigid fixation. Scand J Plast Reconstr Surg Hand Surg. 2007;41:167-72.         [ Links ]

12- Kirkpatrick TB, Woods MG, Swift JQ, Markowitz NR. Skeletal stability following mandibular advancement and rigid fixation. J Oral Maxillofac Surg. 1987;45:572-6.         [ Links ]

13- Lindorf HH. Sagittal ramus osteotomy with tandem screw fixation. J Maxillofac Surg. 1986;14:311-6.         [ Links ]

14- Luhr HG, Schauer W, Jaeger A. Formveränderung des Unterkiefers durch kieferorthopädisch-chirurgische Massnahmen mit stabiler Fixation der Segmente. Fortschr Kieferorthop. 1986;47:39-47.         [ Links ]

15- McDonald WR, Stoelinga PJW, Blijdorp PA. Champy bone plate fixation in sagittal split osteotomies for mandibular advancement. Int J Adult Orthodon Orthognath Surg. 1987;2:89-97.         [ Links ]

16- Perrot DH, Lu YF, Pogrel MA, Kaban LB. Stability of sagittal osteotomies. A comparison of three stabilization techniques. Oral Surg Oral Med Oral Pathol. 1994;78:696-704.         [ Links ]

17- Proffit WR, White RP Jr, Sarver DM. Mandibular deficiency. In: Sarver DM, Proffit WR, Ackerman Jl, editors. Contemporary treatment of dentofacial deformity. St. Louis: Mosby; 2003. p.418-63.         [ Links ]

18- Righi E, Carta M, Bruzzone AA, Lonardo PM, Marinaro E, Pastorino A. Experimental analysis of internal rigid fixation osteosynthesis performed with titanium bone screw and plate systems. J Craniomaxilofac Surg, 1996;24:53-7.         [ Links ]

19- Rubens BC, Stoelinga PJW, Blijdorp PA, Schoenaers JHA, Politis C. Skeletal stability following sagittal split osteotomy using monocortical miniplate internal fixation. Int J Oral Maxillofac Surg. 1988;17:371-6.         [ Links ]

20- Scheerlinck JPO, Stoelinga PJW, Blijdorp PA, Brouns JJA, Nijs MLL. Sagittal split advancement osteotomies stabilized with miniplates. A 2-5 year follow-up. Int J Oral Maxillofac Surg. 1994;23:127-31.         [ Links ]

21- Schwartz HC, Relle RJ. Bicortical-monocortical fixation of the sagittal mandibular osteotomy. J Oral Maxillofac Surg. 1996;54:234-5.         [ Links ]

22- Shepherd JP, Dohvoma CN, Harradine NWT. Screw fixation after mandibular sagittal split osteotomy: an intraoral approach. Br J Oral Maxillofac Surg. 1991;29:325-9.         [ Links ]

23- Shetty V, Freymiller E, McBrearty D, Caputo AA. Experimental analysis of functional stability of sagittal split ramus osteotomies secured by miniplates and position screws. J Oral Maxillofac Surg. 1996;54:1317-24.         [ Links ]

24- Shetty V, McBrearty D, Fourney M. In vitro evaluation of internal fixation techniques for sagittal split ramal osteotomies. J Dent Res. 1994;73:1.         [ Links ]

25- Spiessl B. Osteosynthese bei sagittaler osteotomie nach Obwegeser/Dal Pont. Fortschr Kiefer Gesichtschir. 1974;18:145-8.         [ Links ]

26- Tharanon W. Comparison between the rigidity of bicortical screws and a miniplate for fixation of a mandibular setback after a simulated bilateral sagittal split osteotomy. J Oral Maxillofac Surg. 1998;56:1055-8.         [ Links ]

27- Tucker MR, Ochs MW. Use of rigid internal fixation for management of intraoperative complications of mandibular sagittal split osteotomy. Int J Adult Orthod Orthognath Surg. 1988;3:71-80.         [ Links ]

28- Van Sickels JE, Jetter TS, Theriot BA. Management of an unfavorable lingual fracture during a sagittal split osteotomy. J Oral Maxillofac Surg. 1985;43:808-9.         [ Links ]

29- Van Sickels JE, Larsen AJ, Thrash WJ. Relapse after rigid fixation of mandibular advancement. J Oral Maxillofac Surg. 1986;44:698-702.         [ Links ]



Corresponding address:
Felipe Ladeira Pereira
Av. Dr. Paulo Japiassú Coelho, 209/701 - Cascatinha
36033-310 - Juiz de Fora, MG - Brasil
Phone: +55-32-3236-3150/9111-3900

Received: September 10, 2008
Modification: May 18, 2009
Accepted: June 02, 2009

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