The cells of the rabbit meniscus: their arrangement, interrelationship, morphological variations and cytoarchitecture

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Graverand, Marie-Pierre Hellio Le¹; Ou, Yongchung¹; Schield-Yee, Teresa¹; Barclay, Leona¹; Hart, David¹; Natsume, Takashi¹; Rattner, J. B.¹

The cells of the rabbit meniscus: their arrangement, interrelationship, morphological variations and cytoarchitecture

J Anat. May 2001;198(5):525-535

Affiliations

¹McCaig Center for Joint Injury and Arthritis Research, Faculty of Medicine, University of Calgary, Alberta, Canada
Abstract and keywords

Four major morphologically distinct classes of cells were identified within the adult rabbit meniscus using antibodies to cytoskeletal proteins. Two classes of cell were present in the fibrocartilage region of the meniscus. These meniscal cells exhibited long cellular processes that extended from the cell body. A third cell type found in the inner hyaline-like region of the meniscus had a rounded form and lacked projections. A fourth cell type with a fusiform shape and no cytoplasmic projections was found along the superficial regions of the meniscus. Using a monoclonal antibody to connexin 43, numerous gap junctions were observed in the fibrocartilage region, whereas none were seen in cells either from the hyaline-like or the superficial zones of the meniscus. The majority of the cells within the meniscus exhibited other specific features such as primary cilia and 2 centrosomes. The placement of the meniscal cell subtypes as well as their morphology and architecture support the supposition that their specific characteristics underlie the ability of the meniscus to respond to different types of environmental mechanical loads.

Keywords: Joints; fibrocartilage; cytoskeleton; primary cilia; centrosomes
Links

DOI: 10.1046/j.1469-7580.2000.19850525.x

PubMed: 11430692

WoS: 000169339500002
History

Accepted: 2000-11-21

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2011	Makris EA, Hadidi P, Athanasiou KA. The knee meniscus: structure–function, pathophysiology, current repair techniques, and prospects for regeneration. Biomaterials. October 2011;32(30):7411-7431.
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2007	Upton ML. Theoretical Predictions and Experimental Measurements of the Micromechanical Environment of Meniscus Cells [PhD thesis]. Duke University; 2007.
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2013	Son M-S. Defining and Detecting Meniscal Heterogeneityc: Implications on Treatment and Diagnosis of Osteoarthritis [PhD thesis]. Stanford University; March 2013.
2005	Adeeb SM. Load-Bearing Across Diaiihrodial Joints With Special Reference to Peripheral Structures and the Menisci of the Knee [PhD thesis]. Calgary, AB: University of Calgary; January 2005.
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2014	Hadidi P. Enhancing the Biochemical and Mechanical Properties of a Self-Assembling Scaffold-Free Tissue Engineered Knee Meniscus [PhD thesis]. Davis, University of California; 2014.
2010	Baker BM. Meniscus Tissue Engineering With Nanofibrous Scaffolds [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2010.
2016	Peloquin JM. Tensile Mechanics of the Knee Meniscus in the Context of Cracks: Failure and Fracture Mechanisms, Strain Concentrations, and the Effect of Specimen Shape [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2016.
2016	Qu F. Biomaterial-Mediated Reprogramming of the Wound Interface to Enhance Meniscal Repair [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 2016.