Diagnostic use of computerized axiography in TMJ disc displacements.

Application of paraclinical methods for investigating the temporomandibular joint (TMJ) has been a subject of constant controversy due to the absence of universally-accepted criteria and lack of consensus regarding their usage. Compared with medical imaging, which provides a structural analysis of the TMJ, axiography involves the functional recording of condylar movements. The aim of the present study was to explore the diagnostic value of computerized axiography for TMJ disc displacements using MRI as the reference standard. The present study included 33 (66 TMJs) patients clinically diagnosed with TMJ disc displacements. On the same day, all patients underwent clinical examination and computerized axiography measurements using Cadiax Compact® II before undergoing MRI (1.5 T) 1-7 days later. The characteristics of the diagnostic parameters, namely sensitivity, specificity, positive and negative predictive values, accuracy, Youden index and the 95% confidence intervals (CI), were all computed. Compared with MRI, computerized axiography yielded a sensitivity of 85.11%, specificity of 94.74%, positive predictive value of 97.56%, negative predictive value of 72% and a diagnostic accuracy of 87.88% for any disc displacements. This suggests that computerized axiography can confer high sensitivity, specificity and accuracy for the diagnosis of TMJ disc displacements. However, axiographic analysis has no diagnostic significance in TMJ function if not associated with clinical examination. Copyright: © Talmaceanu et al.

Introduction

The potential application of paraclinical methods for investigating the temporomandibular joint (TMJ) has been a subject of constant controversy due to the absence of definitive criteria and the lack of consensus regarding usage. The mechanism underlying mandibular movements is highly complex and it is mandatory that novel examination methods are developed to further the understanding in the function of this joint. Apart from clinical evaluation and medical imaging, graphical recordings of mandibular movements obtained using computerized axiography can make a significant contribution to the functional evaluation of the TMJ (1). Compared with medical imaging, which provides a structural analysis of the TMJ, axiography consists of making functional recordings of condylar movements (2). Initially implemented as a mechanical measurement method, axiography is also called condylography and is currently being applied on digital platforms (3).

Computerized axiography reveals information on the opening, closing, lateral and protrusive movements (2,3), where its graphical output can be analyzed in the horizontal as well as the sagittal planes (4). This method also enables the quantitative and qualitative analysis of pathways in both the orbiting and pivoting condyle in terms of symmetry, speed during articular movements and aspect of the condylar pathway (5). In addition to information on the optimal or suboptimal TMJ performance, computerized axiography provides data required to program the semi-adjustable articulator, which includes Bennett angle values and the sagittal condylar inclination (6). This characteristic of computerized axiography have proven useful in the dental treatment industry, including prosthetic, orthodontic and orthognathic surgery, all of which requires the faithful replication of musculo-articular dynamics data of the dento-maxillary system (7).

The aim of the present study was to determine the accuracy of using computerized axiography for diagnosing TMJ displacements, using MRI as the reference standard. In addition, another objective of the present study was to calculate the mean values of the Bennett angle and sagittal condylar inclination and determine their variations according to the pathology of each case examined.

Patients and methods

Patients

In total, 33 (66 TMJs) with signs and symptoms of TMJ disc displacement according to the Research Diagnostic Criteria for Temporomandibular Disorders (RDC/TMD) (8) were enrolled in this prospective study performed over 6 months (between May and October 2017). Of the 33 patients enrolled in the present study, there were five males and 28 females. The age of the patients ranged from 14 to 65, with a mean ± SD age of 28.4±11.3 years. On the same day, each patient underwent clinical examination and computerized axiography, which was performed by a single clinician (DT). MRI was performed 1-7 days after clinical examination. The clinical examination and computerized axiography were performed at ‘Stomestet’ Dental Clinic (Cluj-Napoca, Romania), whereas MRI was performed at ‘Skyra Vision’ Imaging Center (Cluj-Napoca, Romania). Only patients with the following clinical TMJ disorders were included in the study: Disc displacement with reduction (DDwR) and disc displacement without reduction (DDwoR). The following signs were necessary for DDwR diagnosis: i) Joint noise reported by patient; ii) click detection during opening/closing cycles; and iii) click detection during lateral and protrusive movements. For DDwoR diagnosis, the following signs were considered: i) Unassisted opening <35 mm and assisted opening <4 mm more than the unassisted opening; ii) contralateral movements <7 mm and/or uncorrected deviation to the ipsilateral side on opening; and iii) absence of clicking noise (8).

Patients with contraindication to MRI, including claustrophobia, cardiac pacemakers or ferromagnetic metals carriers, those who were unable to undergo computerized axiography due to muscular instability or inability to correctly perform mandibular movements, in addition to patients with masticatory muscles disorders, were excluded.

The research protocol in the present study was analyzed and approved by the Ethics Committee of the University of Medicine and Pharmacy ‘Iuliu Hatieganu’ Cluj-Napoca (approval no. 403/02.07.2015). Written informed consent was obtained from each participant or guardian/parent of the participant enrolled in the study.

Clinical examination

Clinical examination was performed by a single oral surgeon (DT). Diagnosis was made based on the patient's history and physical examination. The clinician investigated the masticatory and cervical muscles and both TMJs. Dental occlusion was also analyzed, both static and dynamic. The diagnostic decision tree was elaborated according to the RDC/TMD (8).

Computerized axiography

Computerized axiography and clinical examination were performed on the same day by the same specialist. Axiography was performed using the Cadiax Compact® II device (GAMMA Medizinisch-wissenschaftliche Fortbildungs GmbH). Prior to examination, each patient was informed about the movements required during the examination. The Cadiax Compact® II device consists of the following elements: A face bow; a mandibular bow; a bite fork; two stilettos; two recording sensors; a central unit; and a computer with the required software (Figs. 1 and 2; Cadiax Compact 2 Version 2.9.2; GAMMA Medizinisch-wissenschaftliche Fortbildungs GmbHJ) (5).

Figure 1

Frontal view of the computerized axiograph mounted onto the face of the patient.

Figure 2

Lateral view of the computerized axiograph mounted onto the face of the patient.

Recording mandibular movements

The reference position, which is the starting point for all the movements, was always recorded first. This is followed by maximum protrusion measurements, right laterotrusion measurements, left laterotrusion measurements and maximum opening, in that order. The recording is immediately displayed on the computer screen, where the measurement procedure would be repeated if the quality of the recording is of poor quality (due to patient incoordination). The mandible would start moving from the reference position, reaching maximum amplitude before returning to the reference position. In total, two recordings were saved and stored for each type of movement. The device allows for the superposition of curves, which enables the verification of the reproducibility of joint movements (9).

Diagnosis was made in accordance with the graphic records, which were interpreted as follows: i) Normal TMJ was defined as clear, regular, superimposed curves, with ≥14 mm quantity for opening, 9 mm for maximum propulsion and laterotrusion (Fig. 3); ii) TMJ with DDwR was defined as observations that the advancement and return pathways to the reference position do not overlap, but movement is not limited from a quantitative point of view (Fig. 4); and iii) TMJ with DDwoR was defined as significant quantitative limitation, with straight, linear pathways (Fig. 5). In addition, Bennett angle values and the condylar sagittal inclination were also measured using computerized axiography.

Figure 3

Axiographic pathway for the opening-closing movements of a healthy temporomandibular joint. Clear, overlapping, quantitatively normal (≥14 mm quantity for opening) pathways can be observed. The x-axis- sagittal and horizontal. The y-axis- transverse and horizontal. The z-axis- frontal and vertical. The red circles represent the starting point.

Figure 4

Axiographic pathway for the opening-closing movements of a temporomandibular joint with disc displacement with reduction. The lack of superposition of the opening and closing pathways on the right side can be observed. The x-axis- sagittal and horizontal. The y-axis- transverse and horizontal. The z-axis- frontal and vertical. The red circles represent the starting point. Clicking appears at the point of intersection of the two pathways (arrow).

Figure 5

Axiographic pathway for the opening-closing movements of a temporomandibular joint with disc displacement without reduction. The pathway on the right side is quantitatively reduced and completely straight, lacking the specific concavity of a normal pathway. The x-axis- sagittal and horizontal. The y-axis- transverse and horizontal. The z-axis- frontal and vertical. The red circles represent the starting point.

MRI examination

All MRI examinations were performed using a 1.5-T MRI equipment (Siemens Avanto; Siemens Healthineers). MRI assessment was performed by a radiologist (NB) blinded to both the clinical and axiographic findings. Bilateral MR imaging of the TMJs was performed using the same protocol. The data were collected on a 205/256 matrix, with a field of view of 120 mm and a flip angle of 150 degrees. Oblique-sagittal and coronal images were obtained of both closed- and opened-mouth positions, perpendicular and parallel to the long axis of the condyle. The MRI protocol included T2-weighted and proton density sequences, with the thickness of slices at 3 mm.

Disc displacement was considered to be present if the posterior margin of the posterior band was situated anteriorly to the vertical orientation of the condyle (the ‘12 o'clock line’) (10). The MRI examination was performed within 1-7 days following clinical examination and computerized axiography. The results were interpreted by a single specialist in maxillofacial imaging (NB; Figs. 6 and 7).

Figure 6

Sagittal proton density MRI image of a normal temporomandibular joint. (A) Mouth-closed. (B) Mouth-opened. The disc (arrow) is in the correct position.

Figure 7

Sagittal proton density MRI image of an anterior disc displacement without reduction. (A) Mouth-closed. (B) Mouth-opened. Note the displaced disc (arrow) when the mouth is closed does not return to its normal position at the maximal mouth opening position.

Statistical analysis

The characteristics of diagnostic tests (computerized axiography being the index test, whilst MRI being the standard test), namely sensitivity, specificity, positive and negative predictive values, accuracy, Youden index and the 95% confidence intervals (CI), were all computed. Exact binomial confidence limits were calculated for the sensitivity, specificity, positive and negative predictive values. Positive and negative likelihood ratios were also assessed. All analyses were performed using the R environment for statistical computing and graphics, version 3.2.3(11).

Results

Comparison of the three techniques

Clinical examination revealed 23 (34.85%) TMJs with DDwR, 18 (27.27%) TMJs with DDwoR and 25 (37.88%) healthy TMJs. Computerized axiography detected 22 (33.33%) TMJs with DDwR, 21 (31.82%) TMJs with DDwoR and 23 (34.85%) healthy TMJs. MRI identified 30 (45.45%) TMJs with DDwR, 17 (25.76%) TMJs with DDwoR and 19 (28.79%) healthy TMJs. In total, clinical examination revealed 41/66 (62.12%) TMJs with disc displacements, whereas computerized axiography showed 43/66 (65.15%). MRI indicated 47/66 (71.21%) TMJs with disc displacements (Table I). The number of disc displacements diagnosed clinically and that diagnosed using computerized axiography are comparable (41 vs. 43%; Table I). MRI, being the gold standard for disc visualization, revealed the real number of disc displacements, which was 47.

Table I

The results of the clinical examination, computerized axiography and MRI.

Examination	Total % of disc displacements	Total % of normal temporomandibular joints
Clinical examination	62.12	37.88
Computerized axiography	65.15	34.85
MRI	71.21	28.79

Statistical indicators of computerized axiography, including the sensitivity, specificity, diagnostic accuracy, Youden index, positive predictive value, negative predictive value, positive likelihood ratio and negative likelihood ratio were assessed, using MRI as a reference standard (Table II). The sensitivity and specificity of computerized axiography for detection of TMJ disc displacements were 85.11 and 94.74%, respectively. The Youden index was also found to be high (0.8), showing a viable diagnostic accuracy for computerized axiography.

Table II

Computerized axiography findings compared with MRI findings.

Statistical parameter	Disc displacement	95% confidence interval
Sensitivity, %	85.11	71.69-93.8
Specificity, %	94.74	73.97-99.87
PPV, %	97.56	87.14-99.94
NPV, %	72	50.61-87.93
LR+	16.17	2.39-109.36
LR-	0.16	0.08-0.31
Diagnostic accuracy, %	87.88	77.51-94.62
Youden index	0.8	0.46-0.94
Number necessary for diagnosis	1.25	1.07-2.19

PPV, positive predictive value; NPV, negative predictive value; LR+, positive likelihood ratio; LR-, negative likelihood ratio.

The values of the Bennett angle and of the sagittal condylar inclination were also calculated. The sagittal condylar inclination had a mean ± SD of 42.08±8.02 (95% CI, 40.1-44.05), with values ranging from 20 to 60. The Bennett angle variable (transversal condylar guidance) had a median (IQR) of 9 (7-13) with values ranging from 5 to 30 (95% CI, 7.5-11).

Discussion

The patient's clinical history and the observation of articular noises, such as clicking, are typically used to diagnose DDwR clinically (12). However, clicking may be the result of other causes, not only disc displacement (13). For instance, articular ligaments may produce such noises, where a clicking sound may occur during the rotational movement of the collateral lateral ligament due to its fragility (13). Synovial noises, which occurs especially when chewing solid food, are also described as having the characteristics of clicking sounds. In addition, condylar surface irregularities may be the cause of articular noises during the rotational movement occurring in the lower compartment of the joint, between the condylar surface and the articular disc (12,14). Such cases are difficult to diagnose clinically, rendering the axiographic investigation of the TMJ potentially beneficial for obtaining additional important data for accurate clinical diagnosis.

The high statistical values of specificity and sensitivity obtained in the present study suggest computerized axiography to be an important screening method for confirming or exclude disc displacement. The resulting Youden index also exhibited diagnostic value for the use of computerized axiography. However, incipient DDwR cannot be diagnosed using axiography due to the thickness of the bite fork applied on the lower arch. The presence of the fork slightly increases the vertical dimension of occlusion, where if the displacement is mild, the disc would adjust itself to the new vertical dimension so that it appears as ‘normal’ in the reference position according to the axiograph recording. The present study reported six such false negative cases. In this situation, accurate diagnosis was required using MRI examination.

Previous studies performed by Ahangari et al (15) and Torabi et al (16) substantiated the accuracy of the Cadiax Compact® II device recordings, in terms of both the resulting graphical output and values used for programming the semi-adjustable articulator. In particular, the semi-adjustable articulator program were compared to the wax records used for programming the articulator.

Controversies remain regarding the application of electronic devices for diagnosing TMJ disorders. Electronic methods include axiography, electromyography and Doppler ultrasound for recording articular noises (17). A number of previous accounts (18-20) asserted that using devices for recording mandibular dynamics serve no diagnostic value. Cooper and Rabuzzi (21) reported that any movements recorded by axiography are slower in patients with TMD compared with those in healthy individuals (<300 mm/sec). By contrast, Feine et al (22) found that slower speeds, even bellow the aforementioned value, can also be recorded in healthy individuals. In addition, Romanelli et al (23) proposed that axiography is an accurate method for diagnosing disc displacements in the TMJ. Due to insufficient clinical data being available in this field, in a 2018 review Constantinides et al (24) concluded that computerized axiography is not a useful tool for detecting internal TMJ disturbances. In a previous study of Manfredini et al (25), which evaluated the diagnostic value of axiography in disc displacements and joint effusion, reached the same conclusion. Indeed, controversial opinions and findings have been reported on the potential diagnostic value of axiography. The values obtained for sensitivity and specificity are summarized in Table III. All previous studies (26-30) presented in Table III indicate a very good specificity for computerized axiography, which is in agreement with the results from the present study. Axiography appeared to be a highly specific form of TMJ examination. In terms of sensitivity, it appears to be lower (between 56 and 86%). As also found in the present study and mentioned by Ozawa and Tanne (28), the false negative results are likely to be due to the application of the bite fork, which could change the condylar starting position and is an important factor in cases with incipient TMJ disc displacements. In the present study, only six such cases were reported and the sensitivity for the overall diagnosis of disc displacements was 85.11%. In addition, the diagnostic sensitivity obtained in the studies mentioned in Table III could be dependent on the multiple systems of classification used for TMJ disc displacements (in terms of clinical and MRI classification). The classification system differs from one study to another and could affect the values of statistical indicators.

Table III

Results of the main studies that previously evaluated the sensitivity and specificity of axiography compared with MRI results.

Author	Year	Sensitivity, %	Specificity, %	(Refs.)
Parlet et al	1993	64	100	(26)
Rammelsberg et al	1996	86	90	(27)
Ozawa and Tanne	1997	40	94	(28)
Bracco et al	1997	56	96	(29)
Kobs et al	2004	80	90	(30)

Piancino et al (31) previously analyzed the association between computerized axiography and MRI data, which yielded a very low kappa index of 13%. They then concluded that MRI and computerized axiography are two completely different types of examination methods that should instead be used in conjunction with one another (31). The same conclusion has also been reached by Piehslinger et al (32), who obtained a concordance of only 45% between MRI and computerized axiography.

In the present study, a mean value of the sagittal condylar inclination of 42 degrees was found, whereas the Bennett angle was 9 degrees. However, these values obtained were heterogeneous, rendering correlation analysis between these two parameters and the TMJ pathological parameters impossible. However, a significant difference between a normal TMJ on one side and a displaced TMJ on the other side for the same subject, regarding the Bennett angle and the sagittal condylar inclination, was found.

Computerized axiography can also be used as a tool for monitoring treatment progression by analyzing the graphic outputs at different times, as suggested by a previous study performed by Piancino et al (33). However, similar types of data can be obtained by clinical examination of the muscles and TMJ (17).

A number of studies (30,34) emphasized the importance of associating clinical examination parameters with computerized axiography, suggesting that axiography should be used as an extension of clinical examination as part of the clinical analysis. As a result, axiography can increase the diagnostic value to contribute to the differential diagnosis of intra-articular pathology (32,34). The present study proposes that computerized axiography, when used as an additional diagnostic strategy, should be incorporated into the clinical examination procedure. However, a limitation of the present study is that the sample size is small and that the calculation of intra- and inter-examiner agreement was not performed.

To conclude, computerized axiography is a simple and fast method that is capable of reproducing the functional movement of the TMJ, which offers the opportunity to perform comparative analyzes of the two joints. In addition, it can also be used for the periodic evaluation of treatment progression of TMJ pathology. MRI and computerized axiography can produce different types of data regarding the TMJ status. Whilst MRI can yield important structural data, axiography can reveal data on TMJ function.