Incidence and Characterization of Unifocal Mandible Fractures on CT

Methods

Results

After reviewing the radiology reports and images of unifocal fractures (except the single case in which only a report was available) and multifocal fractures when reports were ambiguous, 41 patients were excluded, and a total of 102 patients were left in the study. Most were excluded for not having a dedicated face CT scan and/or having the fracture diagnosed only on conventional radiographs or panoramic tomographs (14 cases). After the images were reviewed, additional fractures were identified on the scans of 4 patients initially reported as having unifocal fractures.

Of all 102 eligible patients, 43 fractures were unifocal (42%; 95% CI, 33%–52%) and 59 were multifocal (58%). Of the unifocal fractures, 25 (58%) were simple unifocal, 11 (26%) were comminuted, and 7 (16%) were associated with a condylar subluxation (these fractures might be either simple or comminuted). If the number of fractures that were comminuted was evaluated without regard to whether there was associated condylar subluxation, 16 (37%) of the unifocal fractures were comminuted (Table). Most of the fractures had minimal or no displacement or distraction, though this varied with fracture location (Table). The angle was the most frequently involved site, and many of these fractures involved the sockets of the posterior molars (Fig 1). The body was the next most frequent site.

• Download figure
• Open in new tab
• Download powerpoint

Fig 1.

A, Sagittal reformatted image through the mandibular angle shows a nondisplaced very minimally distracted left mandibular angle fracture (long arrow), extending mildly obliquely anteriorly. Note that the fracture just enters the socket of the left third molar (short arrow). B, Axial CT scan shows the left mandibular angle fracture (long arrow) entering the socket of the third molar (short arrow).

Condylar subluxation occurred in 7 cases (16%), predominantly with condylar fractures (5 out of the 7 cases with subluxation), and all of the condylar fractures (5/5) had associated subluxation. All subluxations associated with condylar fractures were of the ipsilateral condyle. All except 1 of the condylar fractures with subluxation were associated with a characteristic anterior-inferior and medial displacement of the condylar head and “telescoping” with upward displacement of the ramus or condylar neck component of the fracture (Fig 2). The remaining condylar fracture was associated with rotation of the condylar head, with mild widening of the joint space, as well as telescoping with upward displacement of the ramus component. The other 2 fractures associated with condylar subluxation were a mildly comminuted fracture of the posterior body, with a contralateral lateral subluxation, and a comminuted right parasymphyseal fracture with contralateral inferior, lateral, and anterior subluxation. Five other cases had mild temporomandibular joint asymmetries, but these were likely due to factors other than trauma and included the following: the appearance of slight ipsilateral joint space narrowing likely due to patient rotation, a likely degenerative joint space narrowing of the contralateral side, a contralateral joint space widening likely due to the effects of a large osteophyte, ipsilateral joint space narrowing likely due to degenerative changes, and ipsilateral joint space widening likely due to a developmentally small hemimandible and associated degenerative changes. The remaining joints did not demonstrate any additional derangements, asymmetries, or rotation.

• Download figure
• Open in new tab
• Download powerpoint

Fig 2.

A, Axial CT scan at the level of the glenoid fossa shows a right condylar fracture, with typical displacement. Note that the condylar head (solid arrow) is dislocated and displaced anteriorly and inferiorly from the glenoid fossa (asterisk) and that the ramus/neck component of the fracture (dashed arrow) is “telescoped” with respect to the condylar head component and displaced superiorly toward the glenoid fossa. Note the overlapping of the fracture fragments, with the condylar head component lying medial to the ramus/neck component. B and C, Coronal reformatted images through the mandibular condyle show the “telescoping,” with upward retraction of the ramus/neck component (dashed arrow) and anterior inferior medial displacement of the condylar head component (solid arrow) and resultant overlap of fracture fragments. This is the typical pattern of dislocation/displacement seen in this type of fracture and was present in all but 1 of the fractures that involved the condylar head or condylar neck. (The asterisk in C indicates the glenoid fossa.)

Most comminuted fractures involved the body, with a similar percentage of the parasymphyseal and condylar fractures being comminuted, and proportionally fewer of the angle fractures were comminuted.

Discussion

As prior studies have shown, mandibular fractures are more frequently multifocal but occur as unifocal fractures a substantial proportion of the time.^1,3,4 Mandibular fractures have been classified in a variety of ways, and because there is no definitive classification system used in all publications, we chose to use modifications of 2 of these systems, those of Dingman and Natvig⁶ and Sinn et al.⁷ These 2 classification systems are based on anatomy, and we chose to modify these systems on the basis of the patterns of fracture that we most commonly observed. Thus, our modifications consisted of using “subcondylar” from the Sinn et al classification to refer to a fracture that extends through the condylar base at the sigmoid notch, rather than classifying this fracture as “region of the condyle” as in the Dingman and Natvig system. Likewise, we have reclassified the “region of the symphysis” and “symphysis” to “parasymphyseal,” because this term is more accurate. The Dingman and Natvig system describes the “region of the angle” fracture as “a triangular region bounded by the anterior border of the masseter muscle and an oblique line extending from the mandibular third molar to the posterior superior attachment of the masseter muscle,” and the Sinn et al classification, though not as specific with respect to the relationship to the masseter or exact boundaries, includes the extent into the socket of the third molar. We have noted this to be a common extension of angle fractures, so we have included the socket of the third molar as our anterior boundary.

We have not been as rigid with respect to the overlying masseter muscle, similar to Sinn et al,⁷ and consider the angle to be the general region of curvature. Otherwise our system is quite similar to that of Dingman and Natvig.⁶ Few of the current articles have described in detail their classification schemes, other than to list the sites without explicitly defining them, particularly with respect to regions that may include the ramus.^1,3,9 In some of the larger series describing mandibular fractures, Greene et al³ do not include ramus at all in their categorization scheme (but do include subcondylar, angle, and coronoid process). King et al¹ include ramus, subcondyle, and angle but do not specifically mention coronoid process; and Rhea et al⁹ include ramus, coronoid process, and angle. In studies in which the ramus is considered a separate site, it has a low incidence of fracture (Stacey et al,¹⁰ 3%; King et al,¹ 5.7%). Likewise, there is discrepancy in the literature in the separate classification of condylar from condylar neck fractures. We chose to group these together, as did Lindahl,¹¹ (though he included subcondylar fractures as well), though there was a difference in the pattern between fractures that involved the condylar head (tendency for anterior-inferior dislocation of the head from the glenoid fossa and upward retraction of the neck component) versus isolated fractures of the neck (less likely to be have significant displacement and dislocation).

There have been few published studies comparing CT with panoramic tomography in the evaluation of mandibular fractures. Wilson et al⁵ compared panoramic tomography and CT and found that 7 fractures in 6 patients (of 42 patients with 73 fractures) were seen only on CT. Six of the 7 missed fractures were in the posterior mandible (angle, ramus, or condyle/subcondyle), and 1 was symphyseal/parasymphyseal. Because CT was the gold standard in this study, its false-negative rate was unknown. Rhea et al⁹ state that the sagittal condylar fracture cannot be seen by radiographs and that condylar fractures are the most frequently missed facial fracture. Roth et al² evaluated CT-versus-panoramic tomography for fracture detection, characterization, and physician agreement and found that all fractures not seen by panoramic tomography but seen on high-resolution CT were in the angle, ramus, or subcondylar region and that there was greater interobserver agreement with CT than with panoramic tomography. Therefore, from these few studies, it would seem that CT is more sensitive than panoramic tomography, particularly for fractures of the angle, ramus, or condyle. The incidence of unifocal fractures in our study was concordant with the existing plain film, panoramic tomography, and mixed-technique literature, despite the assumed higher sensitivity of CT that might be expected to yield a lower incidence of unifocal fractures.

Presumably, unifocal mandibular fractures can be explained by the temporomandibular joints absorbing force, transiently (or permanently) subluxing or rotating to allow this higher than anticipated incidence of unifocal fractures. Although one might expect that there would be CT evidence of either ipsilateral or contralateral mandibular condylar subluxation (referred to as displacement by some authors) or dislocation in most unifocal fractures, this was not the case. Subluxations were seen in only 7 cases, whereas slight asymmetry in the joints was seen in a slightly smaller number; however, in most of these latter cases, this finding could be potentially explained by other etiologies, such as degenerative changes, patient rotation, congenital anomalies, and intubation. It is possible that these other factors lead to some laxity of the joint as well, though future studies would be necessary to evaluate this. There is the possibility that internal derangement or ligamentous or capsular injury to the temporomandibular joints may occur in many of these cases but without a malalignment of the mandibular condyle within the condylar fossa, CT would be insensitive to this. MR imaging could potentially reveal injuries such as these. Also, because we do not have clinical correlation or follow-up for our cases in which the temporomandibular joints appeared normal or for those in which mild asymmetries were ascribed to causes other than the acute trauma, we cannot exclude the possibility that some of these joints may have been injured. A study evaluating all of these joints with follow-up MR imaging and clinical evaluation would be necessary to definitively evaluate this question.

Lindahl¹¹ found, in a study of mandibular condylar fractures (this includes head, neck, and subcondylar fractures), that in unilateral fractures in adults (older than 20 years), 17 (27%) patients did not have any condylar subluxation or dislocation, 32 (52%) had mild-to-moderate subluxation (which they refer to as displacement), and 13 (21%) had condylar dislocation.¹¹ Most interesting, he also found that the incidence of isolated unilateral condylar (or subcondylar) fractures (no additional mandibular fracture present) was 73 of 108 (68%). Unfortunately, it is not possible to tell from his data the relationship between isolated condylar fractures and condylar subluxation/dislocation, so direct comparison with our data cannot be performed, though the incidence in our study may be lower. His data are based entirely on radiographs, including orthopantomograms, and no CT scans were used.

One of the more evident limitations to our study is the diversity of imaging protocols used. This reflects the studies being performed at multiple hospitals within our institutional system, which includes both community hospitals and a large academic hospital, each with its own imaging protocols and CT scanners. Although axial images were available in most cases, a few studies consisted of coronal images alone. There was also variability in the creating of coronal and/or sagittal reformatted images. There is the potential that this variability could lead to a subtle additional fracture not being detected, potentially decreasing the incidence of unifocal fractures, but this is probably unlikely because all scans included were considered of diagnostic quality and considered “dedicated facial bone CT scans” by the radiology departments obtaining them. However, the lack of the availability of both sagittal and coronal reformatted images in all cases probably does limit the detection of subtle temporomandibular joint widening. A study using standardized protocols on a multisection scanner with both sagittal and coronal reformatted images performed in all cases would be a more ideal situation and could be the basis for future studies.

There is also the possibility that subtle mandibular fractures, either single or multiple, were missed on trauma facial bone CT scans, causing mandibular fractures that may have occurred during the inclusion period to be omitted from our data because only those fractures that were reported were included. It would have been ideal to have been able to review all the trauma facial bone CT scans obtained during the 3-year interval; however, due to the sheer number of scans obtained at our institutions (thousands over the 3-year interval), review of all of these scans would be logistically difficult and impractical. Because our study evaluated the incidence of unifocal mandibular fractures with respect to all mandibular fractures (rather than the incidence of unifocal mandibular fractures in all trauma facial bone CT scans), one could assume that if all the trauma facial CT scans were reviewed, there would likely be a higher incidence of unifocal mandibular fractures because it is probably more likely that a unifocal fracture would not be reported than a multifocal fracture, and thus it would be unifocal fractures that would be omitted from our data. In fact, this supposition is supported by the fact that 4 of our “unifocal fractures” were reclassified as multifocal fractures on further review.

Conclusion

Unifocal mandible fractures occur with greater frequency than anticipated by many radiologists. This may be due to the complex somewhat dynamic nature of the mandibular “ring,” which includes the temporomandibular joints, though radiographic subluxation is present in only a minority of cases and occurs most commonly with condylar fractures. Although radiologists should always seek out a second site of mandibular fracture, in a significant percentage of patients, a second fracture site will not be identified.