The Biomechanics of Cartilage—An Overview
Abstract
:1. Introduction
2. Anatomy of Hyaline Articular Cartilage
2.1. General Composition
2.2. Chondrocytes
2.3. Zonal Regions
2.4. Collagens
2.5. Protein Network
3. Biomechanics of Articular Cartilage
4. Biomechanical Testing of Hyaline Cartilage
5. Creep and Relaxation of Soft Tissue
6. Modeling of Hyaline Articular Cartilage
6.1. General Theoretical and Technical Approximation
6.2. Specific Models of Articular Cartilage
7. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Chondrocytes | 1–10% |
Water | 70–80% |
Collagen | 12–14% |
- Type II | 10–12% |
- Type IX | ~1% |
- Type XI | ~1% |
Proteoglycans | 7–9% |
- Hyaluronic acid—proteoglycan—aggregates | 6–8% |
- Other proteoglycans | ~1% |
Mineralic materials | <4% |
Matrix proteins | <1% |
Zone | Name | Description | Functional Behaviour |
---|---|---|---|
Zone I | superficial (tangential) zone | The superficial zone makes up approximately 10% to 20% of AC thickness. The collagen fibers of this zone are packed tightly and aligned parallel to the articular surface. The chondrocytes in the superficial zone are flatter and smaller and generally have a greater density than that of the cells deeper in the matrix. It protects deeper layers from shear stresses. The zona superficialis has most of the water and very little proteoglycans. In general, the cells are not very active, which means that there is little wear and tear. The zone can also be used as a barrier against large molecules, for example antibodies. | The superficial zona is responsible for the behavior of the cartilage under stress. It deforms more strongly and is therefore less rigid than the underlying zones (Guili.k et al., 1995b). If this zone is disturbed tissue permeability increases, leading to greater fluid exchange of the cartilage with its surroundings and during compression, this leads to greater mechanical stress on the macromolecular network. |
Zone II | middle (transitional) zone, | The middle zone represents 40% to 60% of the total AC volume, and it contains proteoglycans and thicker collagen fibrils. In this layer, the collagen is organized obliquely. Chondrocytes are spherical and at low density. | Functionally, the middle zone is the first line of resistance against compressive forces. |
Zone III | deep zone | The deep zone represents approximately 30% of the AC volume. The deep zone contains the largest diameter collagen fibrils in a radial disposition, the highest proteoglycan content, and the lowest water concentration. The chondrocytes are typically arranged in a columnar orientation, parallel to the collagen fibers and perpendicular to the joint line. | It is responsible for providing the greatest resistance to compressive forces, given that collagen fibrils are arranged perpendicular to the articular surface. This creates a arcade formation. These arcades are to be created by the attempt to transfer the initial fibril network to a higher order, whereby the arcadic structure supports the overlying load. |
Interface | tide mark | The tide mark distinguishes the deep zone from the calcified cartilage. This irregularly salty layer lies between the Zonae radiata and calcificata and separates the lime-poor from the lime-rich cartilage. O’Connor describes this area as the mineralization front of the cartilage [27]. According to Mankin, this layer arises by causing the collagen bundles to twist before going deeper to penetrate the zona calcificata and the bone tissue [28]. | It consists of a band of fibrils attached to the collagen fibers which are anchored in the lime-poor layer, and thus prevent them from tearing off cartilage from bone [29]. |
Zone IV | calcified zone | The calcified zone plays an integral role in securing the cartilage to bone by anchoring the collagen fibrils of the deep zone to subchondral bone. In this zone, the cell population is scarce and chondrocytes are hypertrophic. | The calcified zone has numerous protrusions, hollows, and interlacing, which gives an excellent resistance to shear forces to prevent the cartilage detaching from the underlying bone. |
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Eschweiler, J.; Horn, N.; Rath, B.; Betsch, M.; Baroncini, A.; Tingart, M.; Migliorini, F. The Biomechanics of Cartilage—An Overview. Life 2021, 11, 302. https://doi.org/10.3390/life11040302
Eschweiler J, Horn N, Rath B, Betsch M, Baroncini A, Tingart M, Migliorini F. The Biomechanics of Cartilage—An Overview. Life. 2021; 11(4):302. https://doi.org/10.3390/life11040302
Chicago/Turabian StyleEschweiler, Joerg, Nils Horn, Bjoern Rath, Marcel Betsch, Alice Baroncini, Markus Tingart, and Filippo Migliorini. 2021. "The Biomechanics of Cartilage—An Overview" Life 11, no. 4: 302. https://doi.org/10.3390/life11040302