CW Archer scite author profile

Articular cartilage is a challenging tissue to reconstruct or replace principally because of its avascular nature; large chondral lesions in the tissue do not spontaneously heal. Where lesions do penetrate the bony subchondral plate, formation of hematomas and the migration of mesenchymal stem cells provide an inferior and transient fibrocartilagenous replacement for hyaline cartilage. To circumvent the poor intrinsic reparative response of articular cartilage several surgical techniques based on tissue transplantation have emerged. One characteristic shared by intrinsic reparative processes and the new surgical therapies is an apparent lack of lateral integration of repair or graft tissue with the host cartilage that can lead to poor prognosis. Many factors have been cited as impeding cartilage:cartilage integration including; chondrocyte cell death, chondrocyte dedifferentiation, the nature of the collagenous and proteoglycan networks that constitute the extracellular matrix, the type of biomaterial scaffold employed in repair and the origin of the cells used to repopulate the defect or lesion. This review addresses the principal intrinsic and extrinsic factors that impede integration and describe how manipulation of these factors using a host of strategies can positively influence cartilage integration. Keywords IntroductionArticular cartilage is a highly organised avascular and aneural tissue that provides a smooth surface for the movement of articulating bones and transmission of loads (Muir, 1995). Cartilage carries out the latter function by transferring the forces generated by locomotion to the underlying bone. The resident cells of articular cartilage are chondrocytes that are surrounded by an extensive extracellular matrix whose primary constituents are water, aggrecans and type II collagen. Aggrecans are rich in covalently bonded glycosaminoglycans that are hydrophilic and whose electronegative properties resist applied compressive forces. The tensile strength required to constrain the electronegative force generated by the aggrecans is provided by an organised network of crosslinked fibrils principally containing type II collagen. In cross-section articular cartilage displays a pseudostratified appearance composed of three unmineralised layers; the superficial zone with small, dicoidal chondrocytes aligned parallel to the surface, a transitional zone where chondrocytes are rounded with no apparent organisation and the radial/deep zone where large chondrocytes are aligned in columns of 4-6 cells at right-angles to the surface, Figure 1. The fourth layer is the calcified zone where mineralisation is restricted to the interterritorial matrix of chondrocytes. The calcified zone borders and interdigitates with the subchondral bone. Cartilage defects TraumaIn younger patients who have generally suffered trauma to a joint, focal lesions may appear that if untreated may lead to further progressive degeneration over time. Clinically, focal lesions are graded from the appearance of superficial fissure...

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Three-dimensional collagen architecture in bovine articular cartilage

Jeffery

Blunn

Archer

et al. 1991

The Journal of Bone and Joint Surgery. British volume

260

181

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The ultrastructure of mouse articular cartilage: Collagen orientation and implications for tissue functionality. A polarised light and scanning electron microscope study and review.

Hughes

Archer²,

Gwynn³

2005

eCM

127

120

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Abstract.Adult mouse articular cartilage (AC) has not been thoroughly described using high resolution imaging techniques, despite the fact that the availability of knockout mice with specific extracellular matrix (ECM) mutations have renewed interest in using the mouse as a model for a variety of different human conditions. With osteoarthritis affecting millions of people worldwide, investigations into the structure and, therefore, the ability of AC to act as a load-bearing tissue, are crucial for developing treatments and prevention techniques to limit the degree of severity in this condition. Cryofixation and formaldehyde fixation as well as chemical digestion of the uncalcified regions of AC were used in combination with bright field light, polarised light and scanning electron microscopy to image the structure of adult mouse AC. Chemical digestion of the tissue revealed unique insights into the structure of mouse AC and the high cellular density of the tissue. Tightly packed sheets of collagen fibrils formed the territorial matrix (TM) of the deep zone. These were observed closely surrounding the chondrons, after applying both chemical and cryofixation techniques. The interterritorial matrix (IM), in contrast, was more isotropically arranged. The results of the study have implications for the interpretation of biomechanical functionality of mouse AC with probable applications to other species.

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Organisation of the chondrocyte cytoskeleton and its response to changing mechanical conditions in organ culture

et al. 1999

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Articular cartilage undergoes cycles of compressive loading during joint movement, leading to its cyclical deformation and recovery. This loading is essential for chondrocytes to perform their normal function of maintenance of the extracellular matrix. Various lines of evidence suggest the involvement of the cytoskeleton in load sensing and response. The purpose of the present study is to describe the 3-dimensional (3D) architecture of the cytoskeleton of chondrocytes within their extracellular matrix, and to examine cytoskeletal responses to experimentally varied mechanical conditions. Uniformly sized explants of articular cartilage were dissected from adult rat femoral heads. Some were immediately frozen, cryosectioned and labelled for filamentous actin using phalloidin, and for the focal contact component vinculin or for vimentin by indirect immunofluorescence. Sections were examined by confocal microscopy and 3D modelling. Actin occurred in all chondrocytes, appearing as bright foci at the cell surface linked to an irregular network beneath the surface. Cell surface foci colocalised with vinculin, suggesting the presence of focal contacts between the chondrocyte and its pericellular matrix. Vimentin label occurred mainly in cells of the deep zone. It had a complex intracellular distribution, with linked networks of fibres surrounding the nucleus and beneath the plasma membrane. When cartilage explants were placed into organ culture, where in the absence of further treatments cartilage imbibes fluid from the culture medium and swells, cytoskeletal changes were observed. After 1 h in culture the vimentin cytoskeleton was disassembled, leading to diffuse labelling of cells. After a further hour in culture filamentous vimentin label reappeared in deep zone chondrocytes, and then over the next 48 h became more widespread in cells of the explants. Actin distribution was unaffected by culture. Further experiments were performed to test the effects of load on the cytoskeleton. Explants were placed in culture and immediately subjected to static uniaxial radially unconfined compressive loads of 0.5, 1, 2 or 4 MPa for 1 h using a pneumatic loading device. Loads greater than 0.5 MPa maintained the vimentin organisation over the culture period. At 0.5 MPa, the chondrocytes within the explant behaved as in free-swelling culture. The rapid change in vimentin organisation probably relates to rapid swelling of the explants-under free-swelling conditions, these reached their maximum swollen size in just 15 min of culture. The chondrocytes' response to change in tissue dimensions, and thus to their relationship to their immediate environment, was to disassemble their vimentin networks. Loading probably counteracts the swelling pressure of the tissue. Overall, this work suggests that chondrocytes maintain their actin cytoskeleton and modify their vimentin cytoskeleton in response to changing mechanical conditions.

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CW Archer

Current strategies for articular cartilage repair

Evaluation of the reasons for failure of integration during cartilage repair. A review

Three-dimensional collagen architecture in bovine articular cartilage

The ultrastructure of mouse articular cartilage: Collagen orientation and implications for tissue functionality. A polarised light and scanning electron microscope study and review.

Organisation of the chondrocyte cytoskeleton and its response to changing mechanical conditions in organ culture

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