Temporomandibular joint disorders (TMJD) are an important national health problem affecting more than 35 million people in the United States. Mechanical dysfunction of TMJ disc, especially displacement due to tissue degeneration, is central to many TMJ disorders. It is generally believed that pathological mechanical loadings, e.g. sustained jaw clenching or malocclusion, trigger a cascade of molecular events leading to TMJ disc degeneration. However, the mechanism is poorly understood. The normal TMJ disc is a large avascular structure and nutrient supply is crucial for maintaining disc health. The objective of this project is to develop a non-invasive integrated dynamic measuring system (with TMJ imaging, jaw tracking, and TMJ disc finite element model) to establish quantitative relationships between jaw loading (pattern and magnitude), nutrient concentration profiles (oxygen/glucose/lactate), and metabolic rates (oxygen/glucose use and ATP/Lactate production) in TMJ disc. We hypothesize that the nutrient concentrations and cell metabolic rates in TMJ disc are sensitive to the pattern and magnitude of the mechanical loading during jaw function and are therefore potential early bio-indicators for evaluating the impact of mechanical loading on TMJD.
Four specific aims will be pursued to test this hypothesis.
Aim 1 : Determine transport properties of porcine TMJ discs in relation to mechanical strains.
Aim 2 : Determine porcine TMJ disc cell energy metabolic rates in relation to nutrient concentrations.
Aim 3 : Develop a non-invasive integrated dynamic measuring system to determine the profiles of nutrient concentrations and cell metabolic rates in TMJ disc.
Aim 4 : Test the impact of mechanical loading pattern and magnitude on nutrient concentrations and cell metabolic rates in TMJ disc and identify potential bio-indicators based on their mechanical sensitivities. Subject-specific nutrient environment and corresponding cell metabolic rates in TMJ disc during jaw function (Aim 4) will be determined using a mechano-electrochemical signal analyzer (i.e., validated finite element model) with inputs of dynamic TMJ anatomy from Aim 3 as well as tissue transport properties from Aim 1 and cell energy metabolic rates from Aim 2. Successful completion of the proposed aims will 1) establish a new approach to our understanding of TMJ pathology related to joint loading, tissue nutrition, and cell metabolism;2) identify potential bio-indicators of early TMJ disc degeneration;3) establish a novel dynamic measuring system to patient-specifically determine those bio-indicators for early diagnosis;4) provide foundational transport and energy metabolic data for TMJ disc tissue regeneration since nutrition is a key prerequisite for cartilaginous tissue engineering;and 5) demonstrate the feasibility and importance to take this multiscale approach to study joint mechanobiology in general. Although our focus will be on the porcine model, since it is the closest to human TMJ properties, the bio-indicators and measuring systems will all be directly translated to human studies in the future, demonstrating the long term and significant impact of this proposed project in TMJ research.

Public Health Relevance

By elucidating the impact of mechanical loading on cell nutrition/metabolism of the temporomandibular joint (TMJ) disc, we will establish a foundation to delineate the biomechanical etiology of TMJ disorders. This will lead to identifying potential metabolic bio-indicators of early TMJ disc degeneration and develop a novel integrated dynamic measuring system to determine patient-specific bio-indicators for early diagnosis.

Agency
National Institute of Health (NIH)
Institute
National Institute of Dental & Craniofacial Research (NIDCR)
Type
Research Project (R01)
Project #
1R01DE021134-01A1
Application #
8239280
Study Section
Skeletal Biology Development and Disease Study Section (SBDD)
Program Officer
Kusiak, John W
Project Start
2012-03-06
Project End
2017-02-28
Budget Start
2012-03-06
Budget End
2013-02-28
Support Year
1
Fiscal Year
2012
Total Cost
$394,925
Indirect Cost
$75,098
Name
Clemson University
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
042629816
City
Clemson
State
SC
Country
United States
Zip Code
29634
Wright, Gregory J; Coombs, Matthew C; Wu, Yongren et al. (2018) Electrical Conductivity Method to Determine Sexual Dimorphisms in Human Temporomandibular Disc Fixed Charge Density. Ann Biomed Eng 46:310-317
Cisewski, Sarah E; Wu, Yongren; Damon, Brooke J et al. (2018) Comparison of Oxygen Consumption Rates of Nondegenerate and Degenerate Human Intervertebral Disc Cells. Spine (Phila Pa 1976) 43:E60-E67
Nickel, J C; Iwasaki, L R; Gonzalez, Y M et al. (2018) Mechanobehavior and Ontogenesis of the Temporomandibular Joint. J Dent Res 97:1185-1192
She, Xin; Wei, Feng; Damon, Brooke J et al. (2018) Three-dimensional temporomandibular joint muscle attachment morphometry and its impacts on musculoskeletal modeling. J Biomech 79:119-128
Coombs, M C; Petersen, J M; Wright, G J et al. (2017) Structure-Function Relationships of Temporomandibular Retrodiscal Tissue. J Dent Res 96:647-653
Wu, Y; Cisewski, S E; Wei, F et al. (2017) Fluid pressurization and tractional forces during TMJ disc loading: A biphasic finite element analysis. Orthod Craniofac Res 20 Suppl 1:151-156
Wu, Yongren; Cisewski, Sarah E; Sun, Yi et al. (2017) Quantifying Baseline Fixed Charge Density in Healthy Human Cartilage Endplate: A Two-point Electrical Conductivity Method. Spine (Phila Pa 1976) 42:E1002-E1009
Wei, F; Van Horn, M H; Coombs, M C et al. (2017) A pilot study of nocturnal temporalis muscle activity in TMD diagnostic groups of women. J Oral Rehabil 44:517-525
Hepfer, R Glenn; Brockbank, Kelvin G M; Chen, Zhen et al. (2016) Comparison and evaluation of biomechanical, electrical, and biological methods for assessment of damage to tissue collagen. Cell Tissue Bank 17:531-9
Wright, Gregory J; Coombs, Matthew C; Hepfer, R Glenn et al. (2016) Tensile biomechanical properties of human temporomandibular joint disc: Effects of direction, region and sex. J Biomech 49:3762-3769

Showing the most recent 10 out of 26 publications