| Abstract|| |
Context, Aim, and Objectives: Diagnosis of temporomandibular joint (TMJ) disc displacement with reduction (DDR) is difficult. Literature combining different subjective parameters of TMJ function with an objective evaluation of TMJ function using joint vibration analysis (JVA) is limited. Hence, the study was planned to diagnose temporomandibular disorder accurately, to do a subjective and objective evaluation of TMJ function, and to assess the effectiveness of different types of splint therapy over the conventional anterior repositioning appliance (ARA) group. Design: Single-blind, randomized, comparative clinical trial conducted in thirty patients, 18–55 years of age, allocated to three groups, i.e., ARA conventional group, centric stabilization splint (CSS), and Soft splint (SS) groups. Subjects and Methods: Preoperative values of comfortable mouth opening (CMO) in mm, maximum mouth opening (MMO) in mm, TMJ clicking and tenderness (grading 0–3), visual analog scale pain score (0–10 cm), and total energy (TE) integral values of both TMJs using JVA were recorded. Postoperative values were taken at the time of delivery of splint at 1st, 2nd, 6th, and 10th week. Statistical Analysis and Results: Intergroup comparison – Kruskal–Wallis test showed no statistically significant difference in CMO, MMO, and TE values of right TMJs among three groups at any point. No significant difference was seen in TMJ clicking and tenderness among groups at any point of time except at 10 weeks and at 2 weeks, respectively, by Chi-square test. Intragroup comparison - Wilcoxon signed-rank test showed the significance of difference (P < 0.05*) in postoperative visits for CMO, MMO, pain score, and TE values. Clinical effect size, extent, consistency, and percentage of cases showing improvement were maximum for CSS group. Conclusions: The study concludes that the use of JVA for diagnosis along with history and clinical examination increases the accuracy of the diagnosis of DDR. ARA group was used as a conventional treatment option. Although statistically significant difference in pre- and post-treatment values was obtained in all the three groups, CSS group patients showed consistent clinically effective responses and more significant improvement in the subsequent follow-up visits than SS group. Hence, it is advisable to start therapy with CSS splint in TMJ DDR patients to get sooner and effective results without minimum side effects.
Keywords: Clicking, disc displacement, pain, splints, temporomandibular disorder, vibration
|How to cite this article:|
Devi J, Verma M, Gupta R. Assessment of treatment response to splint therapy and evaluation of TMJ function using joint vibration analysis in patients exhibiting TMJ disc displacement with reduction: A clinical study. Indian J Dent Res 2017;28:33-43
|How to cite this URL:|
Devi J, Verma M, Gupta R. Assessment of treatment response to splint therapy and evaluation of TMJ function using joint vibration analysis in patients exhibiting TMJ disc displacement with reduction: A clinical study. Indian J Dent Res [serial online] 2017 [cited 2021 Dec 1];28:33-43. Available from: https://www.ijdr.in/text.asp?2017/28/1/33/203619
| Introduction|| |
Temporomandibular disorder (TMD) is a cluster of coexisting conditions and clinical problems, where the occurrence of muscle-related TMDs is more than intracapsular joint-related TMDs. Due to diverse clinical presentations, corresponding different modifications were done in original Research and Diagnostic Criteria for Temporomandibular Disorders (RDC-TMD criteria) and multiple treatment options are being devised. Apart from thorough history, clinical examination, and instrumental and diagnostic casts analysis, the advanced electronic recording techniques such as electromyography, electrovibratography (EVG), electrosonography, thermography, and electrokinetic and axiographic measuring were documented since the 1980s for better diagnosis and more efficient treatment of disc displacement with reduction (DDR)., The recording of temporomandibular joint (TMJ) sounds is an important tool for the diagnosis and clinical examination of TMDs. So far, only palpation or auscultation (with stethoscope) methods were used, and joint clicking could be classified based on the frequency or velocity of the clicking sound, but its degree could not be classified or quantitatively measured. The joint vibration analysis (JVA) based on EVG was such a quantitative technique with 70%–85% sensitivity and specificity in diagnosing DDR which measured the small vibrations produced by condyle during translation., The SonoPAK Q/S recording system (BioResearch System, Inc., Wisconsin, USA) gives accurate values of intensity, frequency, duration, and precise closing or opening point of occurrence of joint noises of bilateral TMJs of reducing displaced discs by generating vibrations which are distinguishable from vibrations of normal joints on visual inspection of the wavelet transforms. Reliability of the phenomenon (vibration) was evaluated by two studies, which found a large range of reliability values of joint sounds.,
As TMDs share multifactorial etiology and many coexisting factors contribute in the progression and management of disease, it becomes disorienting to treat a TMD in the correct manner. Hence, the treatment of all TMDs cannot be same, and treatment plan for each type of TMD should follow a specific guideline by starting with conservative therapies such as physical therapy, pharmacotherapy, splint therapy, and more stringent nonconservative therapies (comprehensive occlusal rehabilitation and TMJ surgeries) should be considered only when former fails. As the nonconservative therapies are irreversible, they should be used only as the last resort; also reevaluation and long-term follow-up are obligatory for nonconservative therapies to ensure complete remission of the disease. While treating TMDs, challenge for clinician is to choose the correct type of splint although some studies suggested that success of splint therapy has less to do with the splint make or type and more to do with the primary disjunction of ingrained neuromuscular reflexes due to partial nonengagement of maxillary and mandibular teeth., The conventional routinely followed design, i.e., anterior repositioning appliance (ARA) requires regular and repeated evaluation with risk of posterior open bite in the long run. There are studies in literature suggesting centric stabilization splints (CSSs) show fewer problems in comparison to ARA after treatment , and that soft splints (SSs) should be used more in cases of myofascial pain dysfunction syndrome (MPDS) than intracapsular TMDs.
Whether to use JVA or imaging or any other technique for diagnosis of DDR, this decision should be made depending on many factors such as patient condition, affordability, radiation exposure, and invasiveness. In confusing situations where diagnosis is difficult, JVA comes out as an easy, noninvasive radiation free quantitative technique to assist in diagnosis., The plausive natural course of DDR justifies active treatment reserved for symptomatic cases where primary treatment is a conservative, nonsurgical reversible splint therapy which focuses on hastening the natural process of pain alleviation and increased mouth opening. Although literature contains numerous studies about the treatment of TMDs using ARA or CSS or SS either alone or with other modalities such as physical therapy or counseling, there is no study in the past which combines the use of JVA with other parameters of TMJ function and compares three different splints simultaneously and this is from where the current study finds its basis.
The current study thus intends to give diagnosis-based treatment and evaluation of its response subjectively and objectively using JVA and compare the effectiveness of three different types of splints in TMJ DDR patients while focusing on the specific individual needs rather than relying on preconceptualized notions or on an universally applicable stereotyped concept as radiographic diagnostic techniques such as arthrography, computed tomography, and magnetic resonance imaging (MRI) which are either invasive, with radiation risk, or expensive.
| Subjects and Methods|| |
This was single-blind, randomized, parallel group, and comparative clinical trial carried out at the Department of Prosthodontics of Maulana Azad Institute of Dental Sciences, New Delhi in the year 2012–2014.
The Ethical Committee of the institution approved the study, and the participants also provided their informed consent to participate in the study after receiving a full explanation of its purpose and methods by patient information sheet.
Inclusion and exclusion criteria
After diagnosis of DDR cases of 18–55 years of age group complaining of TMJ pain and/or clicking (palpable or audible stethoscope not used) and/or reduced mouth opening and/or deviated mandibular movements/any other symptom with the help of RDC-TMD criteria, total thirty dentate patients were selected and divided randomly into three groups (ten each): ARA group (conventional treatment), CSS group, and SS group. Patients having pacemakers, metallic stents, etc., having TMJ ankylosis; having symptoms related to other stomatognathic system diseases (e.g., toothache and neuralgia); having cervical spondylitis referring to TMJ; and having systemic diseases with referred pain to TMJ (e.g., rheumatoid arthritis, etc.) were excluded from the study.
The planned sample size was ten patients in each treatment group with a total sample size of thirty based on the previous study conducted by Mazzeto et al. which had a total sample size of 31 (n1 = 23, n2 = 8); hence, in the current study, final sample size was fixed at ten patients per group (total 30).
The characteristics of participants included in each group (age, sex, and other important variables) were assessed and analyzed before intervention to see if groups were comparable.
Step 1: Preoperative examination
Preoperative baseline values of comfortable mouth opening (CMO) in mm [Figure 1]a; maximum mouth opening (MMO) in mm [Figure 1]b; TMJ clicking/noise (Grade 0–3 for no clicking/noise; faint clicking/noise only on palpation; clicking, clearly felt on palpation; and loud audible clicking even without palpation) [Figure 1]c; TMJ tenderness (Grade 0–3 for no pain/pressure only on palpation; mild pain on palpation; moderate pain on palpation; and severe pain on palpation) [Figure 1]d and [Figure 1]e; pain score (measured on a visual analog scale [VAS] of 0–10 cm); and total energy (TE) integral values of right and left TMJs obtained by JVA record were taken.
|Figure 1: Parameters for assessment of temporomandibular joint function. (a) Comfortable mouth opening without any pain or discomfort (mm). (b) Maximum mouth opening even with pain or discomfort (mm). (c) Temporomandibular joint clicking or noise while opening or closing. (d) Temporomandibular joint palpation (lateral pole) for tenderness. (e) Temporomandibular joint palpation (posterior border) for tenderness|
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Step 2: Joint vibration analysis record
JVA sensors (BioJVA ™, BioResearch) [Figure 2]a were placed over the patient's TMJs, and sensor wires were plugged into the amplifier [Figure 2]c. Patient was trained to achieve synchronization of the jaw movements with the metronome on laptop (with Windows XP or latest). Both right and left TMJ vibrations were recorded by asking the patient to follow the metronome of opening and closing movements [Figure 2]b, and summary was stored in the software [Figure 2]d. Joint vibrations recorded also helped in the reverification of diagnosis of DDR with the help of flowchart provided with the software [Figure 3].
|Figure 2: Joint vibration analysis record. (a) Materials used. (b) Patient observing and following metronome on laptop screen. (c) Joint vibration analysis sensors with amplifier box. (d) Joint vibration analysis summary saved by software|
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Step 3: Bite registration and splint fabrication
ARA and CSS fabrication: Casts were poured in dental stone for maxillary and mandibular irreversible hydrocolloid impressions made using perforated impression trays. JT-3D Jaw Tracker equipment (JT/TENS ™, BioResearch Associates Inc.) capable of measuring three dimensions of translational movement: Vertical, lateral, and anterior/posterior and Magnet (BioPAK) secured on labial surface of mandibular anteriors with Stomahesive tape (BioPAK) were used for making bite registration with PVS material (CADBITE, IVOCLAR) [Figure 4]a,[Figure 4]b,[Figure 4]c,[Figure 4]d. Casts were mounted with plaster on HANAU Wide-Vue 183-2 articulator with the help of HANAU Spring bow and the bite registration record. The wax-up of splint with modeling wax; processing with transparent clear heat cure resin Dental Products of India (DPI, Mumbai, India) was done; splint was retrieved and polished.
|Figure 4: Bite registration record using jaw tracker. (a) Materials used. (b) Electrognathographic (EGN) trace showing three-dimensional position of mandible in sagittal and frontal plane. (c) Bite registration for anterior repositioning appliance. (d) Bite registration for centric stabilization splint|
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SS Fabrication: BIOSTAR vacuum former was turned on after placing a 3 mm thick rubber sheet Scheu Dental, (SCHEU, Iserlohn, Germany) inside it. Once properly adapted to the cast, it was taken out on cooling, and the edges were trimmed with scissors to obtain the final shape.
Step 4: Insertion of splint and follow-ups
Splint was checked for retention and any occlusal interferences present on the day of delivery and on subsequent appointments were adjusted using articulating paper (BAUSCH, 40 μ thickness) and Miller's forceps accordingly in each patient [Figure 5]a,[Figure 5]b,[Figure 5]c,[Figure 5]d,[Figure 5]e,[Figure 5]f. Patients were recalled at 1st, 2nd, 6th, and 10th week after therapy for follow-up assessment.
|Figure 5: Insertion and adjustment of splints. (a and d) Intercuspal and occlusal view of anterior repositioning appliance. (b and e) Intercuspal and occlusal view of centric stabilization splint. (c and f) Intercuspal and occlusal view of SS|
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Data obtained were fed to Statistical Package for the Social Sciences (SPSS software, IBM, Bangalore, India) and following tests were performed.
Kruskal–Wallis test was used to determine significant intergroup differences in mean values of CMO, MMO, VAS pain score, and TE values of right and left TMJs before and after intervention to check if the groups were comparable. Pearson Chi-square test was used for intergroup comparison of a number of patients with absent or present TMJ clicking or noise and TMJ tenderness.
For comparison of change with subsequent follow-up visits within each group, Friedman test was done.
Wilcoxon signed-rank test was done to see the significance of difference in the CMO, MMO, VAS pain score, and TE values of right and left TMJs; thus to evaluate the change in variables in each subsequent follow-up visit and from appliance delivery to 10 weeks to assess the treatment response.
Clinical effect size was calculated using ARA group as control group applying Morris pretest–posttest control group design formula comparing CSS with ARA and SS with ARA.
| Results|| |
A total of thirty participants were randomly selected and allocated to a splint therapy group. Baseline demographic variables of three groups such as age, gender, and other variables such as CMO, MMO, pain VAS score, and TE energy of right and left TMJ were comparable before intervention [Table 1].
|Table 1: Baseline demographic and clinical characteristics of study groups|
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No statistically significant difference was present in mean values of CMO, MMO, VAS pain score, and TE value of right TMJ among three groups at any point of time after therapy which shows that groups were comparable even after the intervention [Table 2],[Table 3],[Table 4],[Table 5],[Table 6]. There was no statistically significant difference in number of patients with present or absent TMJ clicking or noise among three groups at any point of time except at 10-week visit (P = 0.015* with Pearson Chi-square test); in TMJ tenderness on palpation among three groups at each point of time except at 2-week visit where it was significant (P = 0.015* with Pearson Chi-square test).
|Table 2: Mean comparison of comfortable mouth opening without pain or discomfort (mm)|
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|Table 3: Mean comparison of maximum mouth opening even with pain or discomfort (mm)|
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|Table 4: Mean comparison of pain score (visual analog scale score 0-10 cm)|
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|Table 5: Mean comparison of total energy integral right temporomandibular joint|
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|Table 6: Mean comparison of total energy integral left temporomandibular joint|
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In Friedman test, there were statistically significant differences between pre- and post-treatment mean ranks in CMO, MMO, VAS pain score, and TE integral in the right and left TMJs in all the three groups.
The Wilcoxon signed-rank test showed statistically significant difference in CMO, MMO, pain VAS score, and TE integral right and left in different follow-up visits in all the three groups [Table 7],[Table 8],[Table 9],[Table 10],[Table 11].
|Table 7: Wilcoxon signed-rank test for comfortable mouth opening without pain or discomfort|
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|Table 8: Wilcoxon signed-rank test for maximum mouth opening even with pain or discomfort|
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|Table 10: Wilcoxon signed-rank test for total energy integral right temporomandibular joint|
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|Table 11: Wilcoxon signed-rank test for total energy integral left temporomandibular joint|
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Medium to large clinical effect sizes were obtained in TE integral values of right and left TMJs [Table 12].
|Table 12: Effect size calculation and P values within groups from Wilcoxon signed-rank tests|
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The variation in grading of clicking/noise and tenderness on palpation with the progression of therapy was displayed as graphs [Figure 6]a,[Figure 6]b,[Figure 6]c,[Figure 6]d,[Figure 6]e,[Figure 6]f, and percentage of cases showing improvement in each group was shown in pie charts [Figure 7]a,[Figure 7]b,[Figure 7]c,[Figure 7]d,[Figure 7]e,[Figure 7]f. For TMJ clicking, a maximum number (100%) of cases with improvement are found in CSS group. For TMJ tenderness on palpation, a maximum number of cases with improvement are found in CSS group (90%).
|Figure 6: (a-f) Graphs of how gradation of temporomandibular joint clicking or noise and temporomandibular joint tenderness on palpation varies in each group, respectively. Number of patients, along x-axis and follow-up visits, along y-axis|
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|Figure 7: (a-f) Pie chart of percentage of cases showing improvement in temporomandibular joint clicking or noise and in temporomandibular joint tenderness on palpation, respectively in each group with progression of splint therapy|
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| Discussion|| |
This randomized trial was planned to evaluate and compare the effectiveness of three types of splint therapy. No study in the previous literature has combined different subjective parameters of TMJ function with an objective evaluation of TMJ function using JVA.
No statistically significant difference seen between the groups before and after the intervention showed that the baseline characteristics were comparable in pre- and post-treatment phases. Statistically significant difference in TMJ clicking or noise at 10-week visit and in TMJ tenderness on palpation at 2-week visit could be due to patients responding differently to a given type of splint therapy which will help in proving which type of splint is better.
According to Stiesch-Scholz et al. (active jaw opening increased by a mean of 8.05 mm in stabilization splint therapy group patients versus 8.26 mm in pivot splint group), success of therapy was found independent of splint design and no significant difference was seen between two splint therapy groups they used in anterior disc displacement without reduction patients. In the current study, change in MMO was 4.4 mm for ARA, 5.3 mm for CSS, and 3.7 mm for SS splint therapy group. Other possible reason for no significant difference between groups could be small sample size. Efficacy may also be affected by psychological effects such as an increase in the cognitive awareness for oral habits, a placebo effect, and spontaneous remission of symptoms.
Comfortable mouth opening
The CSS group patients showed earliest and consistent significant improvement, whereas SS group showed delayed improvement only after 6 weeks. Sato et al. found that CSS group was 13% more successful than the natural course control group, and Minakuchi et al. also found surmountable improvement of mouth opening in CSS group. A study by Suvinen and Reade showed 7.4 mm betterment in mouth opening after therapy. Splint therapy in the present study similarly would have led to decreased TMJ pain and tenderness, thus increasing mouth opening.
Maximum mouth opening
The ARA group patients showed a significant improvement at the earliest within 1 week. CSS group patients started showing a significant improvement from 2 to 6 weeks and continued to show improvement till 10th week, whereas SS group showed delayed significant improvement only after 6 weeks. A study using SS by Elhayes and Hassanien showed decreased TMJ and muscular pain and tenderness, apparently allowing an increase in MMO. Block et al. also showed complete or almost complete abatement of symptoms in 74% patients after 6 weeks of SS therapy.
Visual analog scale pain score
For pain score, best treatment response was seen with CSS group. Ekberg et al. showed a successful significant decrease in the severity of arthrogenous TMJ pain using VAS over 10 weeks in the CSS splint group versus placebo splint. Raphael et al. found that SSs had reduced the VAS scores and the number of painful muscles in 6 weeks for MPDS patients similar to the SS group patients who started showing a significant improvement from 2- to 6-week visit.
Total energy integral right and left temporomandibular joint
For TE value of right TMJ, ARA group patients showed an earliest significant decrease in energy values and SS group patients showed delayed response, whereas CSS group patients continued to show a significant increase. For TE value of left TMJ, ARA group patients showed an earliest significant decrease in energy values, CSS also showed a significant response at the same time, but it continued to show a significant increase till 10 weeks, and SS group patients showed delayed response. Mazzeto et al. also obtained positive results in short-term assessment of TE value of right and left TMJs using ARA in anterior DDR patients and stabilizing splint in articular disc derangement patients. They concluded that stabilizing splints had satisfactorily reduced the total sound energies, but the use of ARA for no more than 4 weeks produced better results. Garcia et al. also deduced that decrease in joint vibrations was due to the reduction of displaced disc by interocclusal mandibular advancement device. In the present study also, the mean values of vibratory intensities decreased, probably due to increased separation between the dental arches by ARA, which could have caused a forward rotation of condyle favoring disc recapture partially or allowing a softer movement.
Temporomandibular joint clicking or noise
In ARA group, improvement seen was similar to the study by Clark where temporomandibular repositioning was moderately to highly successful in 86% patients. For CSS group, similar study conducted by Chang et al. showed that splint decreased joint noises by increasing the joint space, permitting smoother condylar translation beyond disc surface inhomogeneity, and positional aberrations to form a novel functional equilibrium in stomatognathic system. For SS group, similar study by Harkins et al. explained that splints with same intensity contact on all teeth, with disocclusion of posteriors and condylar guidance in all movements relaxes the elevator muscles which maintains jaw position and contributes to decreased muscle hyperactivity.
Tenderness on palpation
Relief of symptoms in pain or tenderness in ARA group may be because of the tendency of acute symptoms to regress as seen in control groups of a study. A second cause may be the natural course of disease to attain dormancy after long-term follow-up. A third cause may be ability of ARA to ease the adaptation of displaced retrodiscal tissues showing fibrosis. For CSS group, pain relief might be credited to discal elongation and horizontal decompression of posterior attachment space as speculated by Levandoski  or due to force redistribution and stabilization. For SS group, Kovaleski and De Boever showed a similar significant reduction in TMJ clicking and tenderness after 2 months of splint therapy.
To summarize, the clinical success of the splint therapy was made on the basis of the reduction in the leading symptoms, i.e., increase in comfortable and maximal mouth opening; decrease in TMJ clicking or noise, TMJ tenderness, pain score, and TE integral values for right and left TMJ inferring that patients were responding to the therapy.
The number of patients in the present study was limited. Repetitive measurements should have been used during longer period of time (months) until any device can be considered satisfactory for the treatment. Although a conventional treatment option ARA group was chosen, there was no passive control group so that the responses to the splint therapies could not be distinguished from possible placebo responses or from the natural fluctuations in the complaints.
In a recent systemic review by Sharma et al. concluded that this literature is unable to provide evidence to support the reliability and diagnostic validity of the JVA for diagnosis of TMD. However, the current study was conducted before this review was available at the time when controversy about the use of JVA was still on. Moreover, the current study did not solely use JVA for diagnosis of DDR cases, RDC-TMD questionnaire was also taken into consideration along with proper history and clinical examination before starting the therapy. Although it was only in the year 2014 when Schiffman et al. suggested changes in the RDC/TMD to move on to the DC/TMD so that the latter can be used in both clinical settings and applied research settings. The extensive development process continues to be explored, and it is suggested that with increased sample size and with the use of new diagnostic criteria for temporomandibular disorders (DC/TMD) criteria, less reliability and discrepancy in the baseline TE integral values of right and left TMJs between the groups can be taken care of. It is also suggested that degree of clicking/tenderness before treatment and the prognosis after treatment should be correlated with actual degree of disc deformation present using MRI along with JVA whenever possible. Hence, in future randomized double-blinded trials with a larger sample size can be done to validate the effectiveness of one splint therapy over other using JVA.
| Conclusions|| |
In the current study, subjective analysis of TMJ function with parameters such as CMO, MMO, pain VAS score, TMJ clicking, and tenderness with objective evaluation of TMJ function using JVA TE integral values was done. The study thus concludes that the use of JVA for diagnosis along with history and clinical examination increases the accuracy of the diagnosis of DDR.
The study also compared the effectiveness of three types of splint therapy. ARA group was used as a conventional treatment option. Although statistically significant difference in pre- and post-treatment values was obtained in all the three groups, the CSS group patients showed consistent clinically effective responses and more significant improvement in the subsequent follow-up visits than SS group. Hence, it is advisable to start therapy with CSS splint in TMJ DDR patients to get sooner and effective results without minimum side effects.
Declaration of patient consent
The authors certify that they have obtained all appropriate patient consent forms. In the form the patient(s) has/have given his/her/their consent for his/her/their images and other clinical information to be reported in the journal. The patients understand that their names and initials will not be published and due efforts will be made to conceal their identity, but anonymity cannot be guaranteed.
The authors thank Dr. Dheeraj Koli and Dr. Aditi Nanda, for their kind assistance in successful completion of the research.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| References|| |
Elhayes KA, Hassanien N. Efficacy of soft occlusal splint therapy in management of temporomandibular disorders. J Am Sci 2012;8:1-8.
Dworkin SF, LeResche L. Research diagnostic criteria for temporomandibular disorders: Review, criteria, examinations and specifications, critique. J Craniomandib Disord 1992;6:301-55.
Alajbeg IZ, Valentic-Peruzovic M, Alajbeg I, Illes D. Influence of occlusal stabilization splint on the asymmetric activity of masticatory muscles in patients with temporomandibular dysfunction. Coll Antropol 2003;27:361-71.
Christensen LV, Donegan SJ, McKay DC. Temporomandibular joint vibration analysis in a sample of non-patients. Cranio 1992;10:35-41.
Chang SW, Chuang CY, Li JR, Lin CY, Chiu CT. Treatment effects of maxillary flat occlusal splints for painful clicking of the temporomandibular joint. Kaohsiung J Med Sci 2010;26:299-307.
Olivieri KA, Garcia AR, Paiva G, Stevens C. Joint vibrations analysis in asymptomatic volunteers and symptomatic patients. Cranio 1999;17:176-83.
Radke J, Garcia R Jr., Ketcham R. Wavelet transforms of TM joint vibrations: A feature extraction tool for detecting reducing displaced disks. Cranio 2001;19:84-90.
Mazzeto MO, Hotta TH, Mazzetto RG. Analysis of TMJ vibration sounds before and after use of two types of occlusal splints. Braz Dent J 2009;20:325-30.
Christensen LV, Orloff J. Reproducibility of temporomandibular joint vibrations (electrovibratography). J Oral Rehabil 1992;19:253-63.
Tallents RH, Hatala M, Katzberg RW, Westesson PL. Temporomandibular joint sounds in asymptomatic volunteers. J Prosthet Dent 1993;69:298-304.
Okeson JP. Joint intracapsular disorders: Diagnostic and nonsurgical management considerations. Dent Clin North Am 2007;51:85-103, vi.
Sollecito T. Role of splint therapy in treatment of temporomandibular disorders. In: Fonseca RJ, editor. Oral and Maxillofacial Surgery: Temporomandibular Disorders. 1st
ed., Vol. 4. Philadelphia: Saunders Publishers; 2007. p. 145-60.
Morris SB. Estimating effect sizes from pretest-posttest-control group designs. Organ Res Methods 2008;11:364-86.
Stiesch-Scholz M, Kempert J, Wolter S, Tschernitschek H, Rossbach A. Comparative prospective study on splint therapy of anterior disc displacement without reduction. J Oral Rehabil 2005;32:474-9.
Sato S, Kawamura H, Motegi K. Management of nonreducing temporomandibular joint disk displacement. Evaluation of three treatments. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 1995;80:384-8.
Minakuchi H, Kuboki T, Matsuka Y, Maekawa K, Yatani H, Yamashita A. Randomized controlled evaluation of non-surgical treatments for temporomandibular joint anterior disk displacement without reduction. J Dent Res 2001;80:924-8.
Suvinen T, Reade P. Prognostic features of value in the management of temporomandibular joint pain-dysfunction syndrome by occlusal splint therapy. J Prosthet Dent 1989;61:355-61.
Block SL, Apfel M, Laskin DM. The use of a resilient rubber bite appliance in the treatment of MPD syndrome. J Dent Res 1978;57:92.
Ekberg EC, Vallon D, Nilner M. Occlusal appliance therapy in patients with temporomandibular disorders. A double-blind controlled study in a short-term perspective. Acta Odontol Scand 1998;56:122-8.
Raphael KG, Marbach JJ, Klausner JJ, Teaford MF, Fischoff DK. Is bruxism severity a predictor of oral splint efficacy in patients with myofascial face pain? J Oral Rehabil 2003;30:17-29.
Garcia AR, Folli S, Zuim PR, de Sousa V. Mandible protrusion and decrease of TMJ sounds: An electrovibratographic examination. Braz Dent J 2008;19:77-82.
Clark GT. Treatment of jaw clicking with temporomandibular repositioning: Analysis of 25 cases. J Craniomandibular Pract 1984;2:263-70.
Harkins S, Marteney JL, Cueva O, Cueva L. Application of soft occlusal splints in patients suffering from clicking temporomandibular joints. Cranio 1988;6:71-6.
Dao TT, Lavigne GJ, Charbonneau A, Feine JS, Lund JP. The efficacy of oral splints in the treatment of myofascial pain of the jaw muscles: A controlled clinical trial. Pain 1994;56:85-94.
Scapino RP. Histopathology associated with malposition of the human temporomandibular joint disc. Oral Surg Oral Med Oral Pathol 1983;55:382-97.
Levandoski RR. The MRI study as a diagnostic and therapeutic indicator in the non-surgical management of temporomandibular joint disorders: Phase I management – A case report. Cranio 1995;13:57-64.
Kovaleski WC, De Boever J. Influence of occlusal splints on jaw postion and musculature in patients with temporomandibular joint dysfunction. J Prosthet Dent 1975;33:321-7.
Sharma S, Crow HC, McCall WD Jr., Gonzalez YM. Systematic review of reliability and diagnostic validity of joint vibration analysis for diagnosis of temporomandibular disorders. J Orofac Pain 2013;27:51-60.
Schiffman E, Ohrbach R, Truelove E, Look J, Anderson G, Goulet JP, et al.
Diagnostic criteria for temporomandibular disorders (DC/TMD) for clinical and research applications: Recommendations of the International RDC/TMD Consortium Network and Orofacial Pain Special Interest Group. J Oral Facial Pain Headache 2014;28:6-27.
Dr. Jyoti Devi
E-603, Nav Sanjivan CGHS Ltd., Plot No. 1, Sector-12, Dwarka, New Delhi - 110 078
Source of Support: None, Conflict of Interest: None
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6], [Figure 7]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6], [Table 7], [Table 8], [Table 9], [Table 10], [Table 11], [Table 12]