Micromechanical properties of chondrocytes and chondrons: relevance to articular cartilage tissue engineering

Ofek, Gidon; Athanasiou, Kyriacos A.

doi:10.2140/jomms.2007.2.1059

Cited by 18 publications

(16 citation statements)

References 117 publications

(124 reference statements)

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“…Most of these techniques required cells to be anchorage-dependent (Ofek & Athanasiou 2007), while micropipette aspiration and AFM in conjunction *Author for correspondence (z.zhang@bham.ac.uk).…”

Section: Introductionmentioning

confidence: 99%

Biomechanical properties of single chondrocytes and chondrons determined by micromanipulation and finite-element modelling

Nguyen

Wang

Kuiper

et al. 2010

J. R. Soc. Interface.

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A chondrocyte and its surrounding pericellular matrix (PCM) are defined as a chondron. Single chondrocytes and chondrons isolated from bovine articular cartilage were compressed by micromanipulation between two parallel surfaces in order to investigate their biomechanical properties and to discover the mechanical significance of the PCM. The force imposed on the cells was measured directly during compression to various deformations and then holding. When the nominal strain at the end of compression was 50 per cent, force relaxation showed that the cells were viscoelastic, but this viscoelasticity was generally insignificant when the nominal strain was 30 per cent or lower. The viscoelastic behaviour might be due to the mechanical response of the cell cytoskeleton and/or nucleus at higher deformations. A finite-element analysis was applied to simulate the experimental force-displacement/time data and to obtain mechanical property parameters of the chondrocytes and chondrons. Because of the large strains in the cells, a nonlinear elastic model was used for simulations of compression to 30 per cent nominal strain and a nonlinear viscoelastic model for 50 per cent. The elastic model yielded a Young's modulus of 14 + 1 kPa (mean + s.e.) for chondrocytes and 19 + 2 kPa for chondrons, respectively. The viscoelastic model generated an instantaneous elastic modulus of 21 + 3 and 27+ 4 kPa, a long-term modulus of 9.3 + 0.8 and 12 + 1 kPa and an apparent viscosity of 2.8 + 0.5 and 3.4 + 0.6 kPa s for chondrocytes and chondrons, respectively. It was concluded that chondrons were generally stiffer and showed less viscoelastic behaviour than chondrocytes, and that the PCM significantly influenced the mechanical properties of the cells.

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Section: Introductionmentioning

confidence: 99%

Biomechanical properties of single chondrocytes and chondrons determined by micromanipulation and finite-element modelling

Nguyen

Wang

Kuiper

et al. 2010

J. R. Soc. Interface.

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“…These results improve our knowledge of the chondrocyte micromechanical environment and intracellular changes in response to applied loads. A firm understanding of the physical characteristics of single chondrocytes may shed light on the role of mechanical forces in promoting cartilage regeneration or degeneration (Ofek and Athanasiou 2007;Shieh and Athanasiou 2007).…”

Section: Discussionmentioning

confidence: 99%

“…The particular stress and strain fields that the chondrocyte experiences within its microenvironment are influenced by its physical properties relative to its immediate tissue matrix surroundings (Guilak and Mow 2000). Cellular interpretations of these mechanical signals through mechanotransductive pathways may induce either catabolic or anabolic gene expression changes, thereby altering the essential extracellular matrix synthesis for cartilage tissue (Ofek and Athanasiou 2007). In addition, chondrocyte mechanical characteristics will affect cellular deformations and the transmission of direct strain to the nucleus (Guilak 1995;Ofek et al 2009), which also alters biosynthetic activity (Buschmann et al 1996;Leipzig and Athanasiou 2008).…”

Section: Introductionmentioning

confidence: 99%

Biomechanics of single chondrocytes under direct shear

Ofek

Dowling

Raphael

et al. 2009

Biomech Model Mechanobiol

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Articular chondrocytes experience a variety of mechanical stimuli during daily activity. One such stimulus, direct shear, is known to affect chondrocyte homeostasis and induce catabolic or anabolic pathways. Understanding how single chondrocytes respond biomechanically and morphologically to various levels of applied shear is an important first step toward elucidating tissue level responses and disease etiology. To this end, a novel videocapture method was developed in this study to examine the effect of direct shear on single chondrocytes, applied via the controlled lateral displacement of a shearing probe. Through this approach, precise force and deformation measurements could be obtained during the shear event, as well as clear pictures of the initial cell-to-probe contact configuration. To further study the non-uniform shear characteristics of single chondrocytes, the probe was positioned in three different placement ranges along the cell height. It was observed that the apparent shear modulus of single chondrocytes decreased as the probe transitioned from being close to the cell base (4.1 +/- 1.3 kPa), to the middle of the cell (2.6 +/- 1.1 kPa), and then near its top (1.7 +/- 0.8 kPa). In addition, cells experienced the greatest peak forward displacement (approximately 30% of their initial diameter) when the probe was placed low, near the base. Forward cell movement during shear, regardless of its magnitude, continued until it reached a plateau at ~35% shear strain for all probe positions, suggesting that focal adhesions become activated at this shear level to firmly adhere the cell to its substrate. Based on intracellular staining, the observed height-specific variation in cell shear stiffness and plateau in forward cell movement appeared to be due to a rearrangement of focal adhesions and actin at higher shear strains. Understanding the fundamental mechanisms at play during shear of single cells will help elucidate potential treatments for chondrocyte pathology and loading regimens related to cartilage health and disease.

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“…While experimental studies at the body and joint level have explored functional mechanics of the cartilage from a load sharing perspective, tissue and cell level studies commonly targeted the basic mechanical properties of chondrocytes and chondrons 120 and the biomechanics of the cartilage in relation to its micro-mechanical and chemical environment 140 . Much of the information currently available on chondrocyte response to mechanical stress has been determined using tissue explant culture experiments, which provide a more controlled mechanical and biochemical environment than the in vivo condition (e.g.…”

Section: Introductionmentioning

confidence: 99%

Multiscale Mechanics of Articular Cartilage: Potentials and Challenges of Coupling Musculoskeletal, Joint, and Microscale Computational Models

et al. 2012

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Articular cartilage experiences significant mechanical loads during daily activities. Healthy cartilage provides the capacity for load bearing and regulates the mechanobiological processes for tissue development, maintenance, and repair. Experimental studies at multiple scales have provided a fundamental understanding of macroscopic mechanical function, evaluation of the micromechanical environment of chondrocytes, and the foundations for mechanobiological response. In addition, computational models of cartilage have offered a concise description of experimental data at many spatial levels under healthy and diseased conditions, and have served to generate hypotheses for the mechanical and biological function. Further, modeling and simulation provides a platform for predictive risk assessment, management of dysfunction, as well as a means to relate multiple spatial scales. Simulation-based investigation of cartilage comes with many challenges including both the computational burden and often insufficient availability of data for model development and validation. This review outlines recent modeling and simulation approaches to understand cartilage function from a mechanical systems perspective, and illustrates pathways to associate mechanics with biological function. Computational representations at single scales are provided from the body down to the microstructure, along with attempts to explore multiscale mechanisms of load sharing that dictate the mechanical environment of the cartilage and chondrocytes.

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Micromechanical properties of chondrocytes and chondrons: relevance to articular cartilage tissue engineering

Cited by 18 publications

References 117 publications

Biomechanical properties of single chondrocytes and chondrons determined by micromanipulation and finite-element modelling

Biomechanical properties of single chondrocytes and chondrons determined by micromanipulation and finite-element modelling

Biomechanics of single chondrocytes under direct shear

Multiscale Mechanics of Articular Cartilage: Potentials and Challenges of Coupling Musculoskeletal, Joint, and Microscale Computational Models

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