Nocturnal Mouth Guards, SOVA vs. Standard Acrylic Orthotic; Phase IV (SISU-SOVA)

Preliminary Phase IV Trial Comparing the SOVA Night Guard With the Clinical Standard Acrylic Orthotic

Clinical trials of bite splint use and night time tooth grinding have not been performed. Consequently, there are no definitive outcome measures or efficacy standards that can be applied to large clinical trials. The present preliminary trial will determine what objective measures can be used to evaluate efficacy. The outcome variables will fall into four categories: (1) fabrication efficacy, (2) compliance, (3) functional efficacy, and (4) user satisfaction. The immediate goals will: (1) focus on the over-the counter SOVA night guard, (2) conduct tests under controlled clinical conditions using the 'gold standard', the acrylic 'bite splint' or 'orthotic', hereafter called the "Michigan bite splint", to compare the performance and efficacy of the SOVA night guard. Subsequent studies will be able to use the outcome variables identified in this study for broader clinical trials. Specific Aim 1. To compare the SOVA night guard to the custom-acrylic Michigan bite splint in clinical laboratory conditions. Hypothesis: There will be no significant differences between the devices in terms of fabrication efficacy, functional efficacy or user satisfaction. Specific Aim 2. To compare the SOVA night guard to the custom-acrylic Michigan bite splint under ecologically relevant conditions, i.e., the home environment. Hypothesis: There will be no significant differences between the devices in terms of compliance or functional efficacy.

Subjects. Sample size estimations are based upon a recent review of randomized clinical trials, in which acrylic appliances were evaluated (see Appendix 2 in (Huynh et al., 2007)). The mean +/- 1 standard deviation (SD) number of bruxism episodes per hour with a Michigan bite splint was 3.97 + 0.58, and for a palatal splint, the mean +/- 1 SD was 4.45 + 0.63. Using these means and the higher SD (0.63), along with an alpha = 0.05 and beta = 0.8, a study would be sufficiently powered with sample sizes of 29 per group. Based on other Michigan studies, wherein recruitment, exclusion and attrition rates are known, it is estimated that an initial screening sample size of 120 will be necessary to end up with 29 per group. There will be two treatment groups: a group receiving supervised training in the fabrication of the SOVA night guard (SOVA) and a group receiving the Michigan custom-acrylic bite splint (MI BS). Two groups times 29 subjects per group equals 58 total needed for analysis. Care will be taken to match the randomized groups for age, ethnicity, gender and temporomandibular disorders (TMD) signs/symptoms. Alternatively these will be modeled as nuisance variables if attrition rates create bias or there is a lack of sufficiently sized screening pools. Screening. Candidates will undergo a screening to assess co-morbidities and to identify inclusion and exclusion criteria. Standard questionnaires and screening instruments and a brief clinical exam will be performed. Subjects meeting the acceptance criteria will be randomly assigned to one of the two groups using stratified randomization procedures (Suresh, 2011). Alginate impressions will be taken, and impressions poured in stone. The models will be used either to fabricate the MI BS or to assess SOVA appliances for fabrication efficacy. Splint delivery. For the SOVA group, subjects will be asked to fabricate SOVA devices in the clinical laboratory while receiving feedback from trained and calibrated study 'instructors'. Fabrication will use manufacturer instructions. Calibrated instructors will be blinded to the study's objectives, as will subjects. A "Michigan" acrylic bite splint will be fabricated using standard clinical practice and checked for fit and quality on subjects assigned to the MI BS group. Subjective fabrication assessment. Standardized questionnaires and box scales will be used to assess ease of fabrication, ease of instructions, and other related issues for the devices. Quantitative fabrication assessments. Four aspects of fabrication will be evaluated by investigators: (1) stability-does the device move independently of the maxilla and is the mandible stabilized by the device, (2) retention-does the device resist displacement, (3) tissue adaptation-how much spacing exists between the maxilla and the device and between the device and mandible, and (4) health of the teeth, gingival, tongue, palate and lips. Stability and retention will be quantitatively assessed with jaw movement (MaxTraq motion analysis system, Innovision, Columbiaville, MI) and electromyography (EMG) (LabChart, ADInstruments, Colorado Springs, CO) data and force sensors. For position-stability assessment, maxilla, mandible and the splint will be simultaneously recorded from at least three sites to capture 6 degrees of movement freedom. Subjects will clench, grind, perform closed border movements and vacuous chewing (verified with EMG and force sensors). For retention assessment, subjects will perform a series of tests designed to dislodge the device, e.g., tapping, forced blowing, coughing, chewing on gum. Stability and retention indices will be created based on whether device movements vary independently of jaw movements and applied bite forces, and how force sensor output varies during dislodgement exercises. Deviations will be used to form standardized indices of stability and retention, with smaller values representing greater stability and retention. Note that a major part of the study will be to develop the appropriate methods to make these measurements, as it is not clear how this should be done ideally. Tissue adaptation will be assessed by 3D laser scanner. The occlusal, facial and lingual surfaces of the upper arch will be scanned as will the inner surface of the night guards. An index of adaptation will be developed based on the volumetric spaces separating the teeth from the device, using topological software. Smaller volumes will represent better tissue adaptation. Volumetric indices will be compared between devices via ANOVA or appropriate statistical methods. Note that a major part of this study will be to develop an accurate and precise way of measuring volumetric spacing, as such methods have not yet been developed. Tissue health will be assessed via appropriate, standard methods currently used in cariology and periodontology clinical studies (Monse et al., 2012; Tirapellia et al., 2010). Baseline measurements will be compared with post-device wear measurements. Between-group differences will be studied with a repeated measures ANOVA or appropriate statistical methods. Compliance assessment. Compliance assessments will focus on: (1) how often the device is worn, (2) whether the device is removed at inappropriate times during the night, (3) whether alternative devices are used. Compliance will be assessed via subject self-report, nocturnal EMG recording devices and microwear methods. Subjects would be blinded to the purpose of the technological methods. Occlusal microwear patterns are unique to the surfaces against which occlusion occurs, and the microwear changes on a daily basis (Ungar et al., 2003). Hence, microwear assessment should provide definitive evidence of splint compliance. Microwear analysis methods will be developed as part of this study for these purposes. Functional efficacy. Two questions will be addressed under functional efficacy: (1) does the device alter bruxing activity, and (2) how do the teeth and device hold up under bruxing activity. Some of the technology used for compliance assessment, above, can be used here. Gold standard methods for evaluating bruxing activity rely on polysomnography (PSG) and EMG activity; therefore, it these technologies will be used as well. To address the second question, how do the teeth hold up, 3-D laser scanning technology will be developed and used to measure changes in macroscopic tooth structure, and confocal microscopy and scale-sensitive fractal analysis will be assessed for utility in diagnosing microwear. User satisfaction. This will be assessed through a series of standardized questionnaires adopted from other clinical studies, e.g., the Oral Health Impact Profile (Slade and Spencer, 1994), the Tampa Scale for Kinesiophobia: TMD (Visscher et al., 2010), the TMD pain screener (Gonzalez et al., 2011). Questionnaires used in the SISU field tests (SISU mouthguards preliminary results), as well as forced choice, box scales and statistical methods developed in another study (Lin, 2008; Lin et al., 2013) will also prove useful for assessment of patient satisfaction. Also questions such as, does the device hurt or pinch anywhere, does your bite feel 'off' when you first remove the guard, etc. will be used to assess specific aspects of user satisfaction. Repeated measures (Week 1 check-up and 4 Month check-up). Compliance, stability, retention, tissue adaptation and health, functional efficacy and user satisfaction will be assessed two times, viz., 1 week after delivery and 4 months after delivery. This will provide a rigorous data set, reduce subject attrition and thus allow for both publications and further clinical trials to be pursued.

SOVA Bite splint: Over-the-counter, heat-and-mold bite splint. Investigators evaluate subject self-fabrication, and evaluate fit. Subjects wear splint nightly for one week. Polysomnographic data obtained from one night during the week. Subjects continue to wear splint for 3 months, dairy kept of nightly wear. Polysomnographic data obtained from one night at the end of three months.

Michigan bite splint: Gold standard, custom acrylic bite splint made for subjects. Investigators evaluate fit. Subjects wear splint nightly for one week. Polysomnographic data obtained from one night during the week. Subjects continue to wear splint for 3 months, dairy kept of nightly wear. Polysomnographic data obtained from one night at the end of three months.

Count of the total number of entire nights that subjects wore the splint provided to them in the study.

Polysomnographic monitors were used to evaluate masticatory muscle activity during sleep. Activity of jaw closing muscles found in the cheeks (masseter muscles) occur in bursts, where a burst is taken as evidence for a jaw clench. The total number of bursts recorded during the night was tabulated and then divided by the total hours of sleep. Means presented are based on data gathered on night 122 (4 months of splint wear) and compared with ANOVA.

Splint wear measured in millimeters. The number is negative to reflect the amount lost, e.g., -0.1 = a tenth of a millimeter lost. High-resolution, computer-scanned models of the splint on the delivery date were combined with high-resolution, computer-scanned models of the same splint after 4 months of wear. Sites where teeth contacted the splints were identified, and material loss in these areas was quantified using a computer program designed to quantify differences between two computer models. The measurement represents the difference between the two models, defined by a mean value sampled from a standard-sized area, which was set to be about the size of a tooth cusp (~ 3 millimeters in diameter). Group means were compared with t-tests.

Responses to the question, "I frequently remove the splint during the night" with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out at the end of 4 months of splint wear.

Responses to the question, "I use an additional splint" with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out at the end of 4 months of splint wear.

Tooth wear measured in millimeters. The number is negative to reflect the amount lost, e.g., -0.1 = a tenth of a millimeter lost. High-resolution, computer-scanned models of the teeth in the lower jaw on the delivery data were combined with high-resolution, computer-scanned models of the same teeth and jaw after 4 months of splint wear. Sites where teeth showed cratering due to dentin exposure were targeted to make these measurements. Changes in these areas was quantified using a computer program designed to quantify differences between two computer models. The measurement represents the difference between the two models, defined by a mean value sampled from a standard-sized area, which was set to be about the size of dentin exposure areas (~ 1 millimeter in diameter). Group means were compared with t-tests.

Responses to the question, "The splint helps my bruxism." with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out at the end of 4 months of splint wear.

Responses to the question, "The splint relaxes my jaw muscles." with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out at the end of 4 months of splint wear.

Responses to the question, "The splint was easy to fabricate" with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out at the end of the appointment during which time the splints were made by participants.

Responses to the question, "The instructions were easy to follow" with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out at the end of the appointment during which time the splints were made by participants.

Responses to the question, "The splint fits well" with a 5-point Likert scale, anchored on the left with "Strongly Disagree" (receiving a score of 0) and on the right with "Strongly Agree" (receiving a score of 4). Question was filled out during the final appointment.

Estimated bite forces in kilograms associated with performing each of the following tasks: moving the jaw in extreme positions with pressure against the splint (Border), clenching (Clench), grinding side to side (Grind Lateral), grinding front to back (Grind Protrusive), tapping hard on splint (Tap). Overall means for each treatment group (SOVA and Michigan splints) are also reported.

Number of times splint was dislodged while performing eight different movements, with each movement being performed five times (maximum number therefore = 40). Dislodgement meant that, after performing the movement, the splint either fell off the teeth completely or that biting down on the splint resulted in its being reseated on the teeth.

Number of times splint was dislodged while performing eight different movements, with each movement being performed five times (maximum number therefore = 40). Dislodgement meant that, after performing the movement, the splint either fell off the teeth completely or that biting down on the splint resulted in its being reseated on the teeth.

Palate-side of splints was evaluated for contact with the palate. Splints that were > 1 mm from contact with palate, from molar to molar were graded as 1 (poor adaptation); splints in continuous contact or lacking contact < 1mm with palate, from molar to molar were graded as 0 (good adaptation). Number of participants with splints in each group with poor adaptation is reported.

Lip- and cheek-sides of splints were evaluated for contact with the premolar and molar teeth. Splints lacking contact (> 1 mm space between splint and teeth) were graded as 1 (poor adaptation); splints with < 1 mm space between splint and teeth, from molar to molar as 0 (good adaptation). Inter-proximal contacts Number of total participants with splints in each group with poor adaptation is reported.

Splint rims were evaluated for thickness. Splints requiring modification by the attending dentist to remove excess material were graded as 1 (poor adaptation); splints that did not require removal of excess material were graded as 0 (good adaptation). Number of participants in each group whose splint manifest poor adaptation is reported.

Fabrication Efficacy -- Tissue Adaptation, Tightness. Number of Participants Reporting Excessive Tightness

Splints were evaluated for sensation of tightness on the teeth. SOVA splints that were said to be too tight by the participants and that subsequently required intervention by the attending dentist to fix were graded as 1 (poor adaptation); Michigan splints that were said to be too tight by the participants and that required the attending dentist to spend > 15 minutes of the delivery appointment to fix were graded as 1 (poor adaptation); all splints not meeting these criteria were scored as 0 (good adaptation). Total participants in each group with poorly adapted splints is reported.

The Rustogi et al. Modification of the Navy Plaque Index method of scoring plaque was used. This involves dividing the cheek-facing (Buccal) and the tongue/palate-facing (Lingual) surfaces of each tooth into 9 regions and scoring whether disclosed plaque is present (1) or absent (0) in each of these 9 regions. The total number of regions with plaque was then tabulated as the proportion of total regions for four mouth areas, viz., the cheek sides of the upper teeth (Buccal Upper), the cheek sides of the lower teeth (Buccal Lower), the palate sides of the upper teeth (Lingual Upper) and the tongue sides of the lower teeth (Lingual Lower). Overall means for each treatment group (SOVA and Michigan splints) are also reported.

Gums or gingiva around each tooth is quantified for absence of inflammation (0), mild inflammation around part of the gingiva next to the tooth (1), mild inflammation involving all of the gingiva next to the tooth (2), moderate inflammation (3), or severe inflammation (4). Average scores are created for the cheek side of the upper teeth (Buccal Upper), palate side of upper teeth (Lingual Upper), cheek side of lower teeth (Buccal Lower) and tongue side of lower teeth (Lingual Lower). Mean and standard deviation scores for each of these regions and for week 1 and month 4 are shown as descriptive statistics; statistical results for the between-subject effects are reported. Overall means for each treatment group (SOVA and Michigan splints) are also reported.

Movement of each subject's splint on the teeth, due to rocking or dislodgement, measured in millimeters during five repetitions of the following five tasks: clenching, grinding, moving jaw to extreme positions on the splint, tapping, opening maximally. For control, movements of the splint while the jaw was in a rest position (teeth apart, jaw relaxed) were also measured. The maximum movement during the five repetitions of each task was calculated for each subject and used in statistical analyses.

Count of the number of participants whose individual splints were dislodged at least once when participants clenched their teeth against the splint five times. Numbers are sorted into those that moved < 1 mm, those that moved between 1 - 2 mm, those that moved between 2 - 3 mm and those that moved > 6 mm during the performance of five repeats of clenching. Categories from 3 mm to 6 mm are not included, because no splints fell into this range of values.

Count of the number of participants whose individual splints were dislodged at least once when participants ground their teeth against the splint to the left (5 times), to the right (5 times, and front to back (5 times). Count is partitioned into those dislodged by < 1 mm, between 1 - 2 mm, between 2 - 3 mm, between 3 - 4 mm, and > 6 mm. Categories between 4 and 6 mm are not included, as no splints fell into this range.

Count of the number of participants whose individual splints were dislodged at least once when participants performed grinding-like movements of the teeth against the splint in extreme positions. These extreme movements and positions were performed 5 times. Counts are partitioned into those dislodged > 1 mm, those dislodged between 1 - 2 mm, those dislodged 2 - 3 mm, those dislodged 3 - 4 mm, those dislodged 4 - 5 mm, those dislodged 5 - 6 mm and those dislodged > 6 mm.

Count of the number of participants whose individual splints were dislodged at least once when participants tapped their teeth on the splint 5 times. Counts are partitioned into the number dislodged < 1 mm, and those dislodged between 1 - 2 mm.

Count of the number of participants whose individual splints were dislodged at least once when participants opened as wide as possible and then closed. The task was repeated five times. Counts are partitioned into the number dislodged < 1 mm, number dislodged between 1 - 2 mm, number dislodged between 2 - 3 mm, number dislodged between 3 - 4 mm and number dislodged between 4 - 5 mm.

Inclusion Criteria: Adult Tooth wear Night time grinding and clenching noises Full dentition sans 3rd molars Ability to follow instructions Ability to report to the clinical laboratory at appointed times over the course of the study. Exclusion Criteria Decayed, missing teeth Cardiovascular disease Sleep apnea, sleep disorders, movement disorders Active orthodontics Periodontal disease Partial or full dentures Medications with movement disorders as side effects

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