Abstract

Menisci function to distribution load and increase stability of the knee joint. Both partial and complete meniscectomy have been shown to increase the incidence of osteoarthritis. Meniscal replacement with allograft, synthetic or tissue engineered replacements, could act to reduce the occurrences of osteoarthritis. The success of meniscal replacements depends on their ability to restore normal meniscal function both biologically and biomechanically. Meniscal attachments are critical for proper meniscal function. Since rupture of the horn attachments of the menisci are rare it is likely that a gradient in mechanical properties and biochemical make-up exists through the attachment. Previous computational studies have shown that the material properties of the attachments dramatically affect the contact pressures on the meniscus and without gradual transition in the properties, large stress concentrations at the insertion zones into the meniscus and the bone are evident. Additionally, these stress concentrations are seen mostly in the deeper zones of the tissue, not on the proximal surface. Previous research has only documented the material properties on the proximal surface of the tissue. The goal of this project is to quantify the microstructure and material properties of the meniscal attachment where it inserts into the meniscus and bone, as well as in the deep layers of the tissue. Specifically this project will 1) determine the local fluid pressures in the deep layers of the tissue during both physiological loading (static and dynamic) levels and failure testing using a fibre-optic pressure microsensor, 2) determine the transverse material properties 2) quantify the collagen orientation in the transition zone from fibrocartilage to ligamentous attachment using scanning electron microscopy, and lastly the project will 3) determine the mechanical properties of the transition zones into the subchondral bone at the nanolevel. The results of these aims will then be used to quantify a relationship between the structure and function of the native meniscal attachments and validate the current finite element model of the attachments. This data can then be used to develop, design and evaluate meniscal replacements, including tissue engineered constructs. A successful meniscal replacement will work to prevent joint degeneration following meniscectomy.

Public Health Relevance

Menisci within the knee joint function to protect the underlying articular cartilage from degenerative osteoarthritis. The absence of a healthy meniscus can inhibit this function. The goal of this research is to determine the structure and function of native meniscal attachments such that effective meniscal replacements or therapies can be developed to reduce the incidences of knee joint osteoarthritis.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS)
Type
Academic Research Enhancement Awards (AREA) (R15)
Project #
2R15AR051906-02A2
Application #
7644188
Study Section
Skeletal Biology Structure and Regeneration Study Section (SBSR)
Program Officer
Tyree, Bernadette
Project Start
2005-02-01
Project End
2012-09-29
Budget Start
2009-09-30
Budget End
2012-09-29
Support Year
2
Fiscal Year
2009
Total Cost
$206,654
Indirect Cost

  Institution

Name
Michigan Technological University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
065453268
City
Houghton
State
MI
Country
United States
Zip Code
49931

  Publications

Abraham, A C; Pauly, H M; Donahue, T L Haut (2014) Deleterious effects of osteoarthritis on the structure and function of the meniscal enthesis. Osteoarthritis Cartilage 22:275-83
Abraham, Adam C; Villegas, Diego F; Kaufman, Kenton R et al. (2013) Internal pressure of human meniscal root attachments during loading. J Orthop Res 31:1507-13
Abraham, Adam C; Donahue, Tammy L Haut (2013) From meniscus to bone: a quantitative evaluation of structure and function of the human meniscal attachments. Acta Biomater 9:6322-9
Moyer, John T; Priest, Ryan; Bouman, Troy et al. (2013) Indentation properties and glycosaminoglycan content of human menisci in the deep zone. Acta Biomater 9:6624-9
Moyer, John T; Abraham, Adam C; Haut Donahue, Tammy L (2012) Nanoindentation of human meniscal surfaces. J Biomech 45:2230-5
Abraham, Adam C; Edwards, Christian R; Odegard, Gregory M et al. (2011) Regional and fiber orientation dependent shear properties and anisotropy of bovine meniscus. J Mech Behav Biomed Mater 4:2024-30
Abraham, Adam C; Moyer, John T; Villegas, Diego F et al. (2011) Hyperelastic properties of human meniscal attachments. J Biomech 44:413-8
Hauch, Karen N; Villegas, Diego F; Haut Donahue, Tammy L (2010) Geometry, time-dependent and failure properties of human meniscal attachments. J Biomech 43:463-8
Villegas, Diego F; Donahue, Tammy L Haut (2010) Collagen morphology in human meniscal attachments: a SEM study. Connect Tissue Res 51:327-36
Hauch, K N; Oyen, M L; Odegard, G M et al. (2009) Nanoindentation of the insertional zones of human meniscal attachments into underlying bone. J Mech Behav Biomed Mater 2:339-47

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