Topographic features of nano-pores within the osteochondral interface and their effects on transport properties –a 3D imaging and modeling study

Publication date

2021-06-23

Authors

Pouran, Behdad
Raoof, Amir
de Winter, D T C
Arbabi, VahidORCID 0000-0003-3347-2891ISNI 0000000419547591
Bleys, Ronald L A WISNI 0000000050357498
Beekman, Freek J.ISNI 0000000390395095
Zadpoor, Amir A.
Malda, JosORCID 0000-0002-9241-7676
Weinans, HarrieORCID 0000-0002-2275-6170ISNI 0000000393288658

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Abstract

Recent insights suggest that the osteochondral interface plays a central role in maintaining healthy articulating joints. Uncovering the underlying transport mechanisms is key to the understanding of the cross-talk between articular cartilage and subchondral bone. Here, we describe the mechanisms that facilitate transport at the osteochondral interface. Using scanning electron microscopy (SEM), we found a continuous transition of mineralization architecture from the non-calcified cartilage towards the calcified cartilage. This refurbishes the classical picture of the so-called tidemark; a well-defined discontinuity at the osteochondral interface. Using focused-ion-beam SEM (FIB-SEM) on one osteochondral plug derived from a human cadaveric knee, we elucidated that the pore structure gradually varies from the calcified cartilage towards the subchondral bone plate. We identified nano-pores with radius of 10.71 ± 6.45 nm in calcified cartilage to 39.1 ± 26.17 nm in the subchondral bone plate. The extracted pore sizes were used to construct 3D pore-scale numerical models to explore the effect of pore sizes and connectivity among different pores. Results indicated that connectivity of nano-pores in calcified cartilage is highly compromised compared to the subchondral bone plate. Flow simulations showed a permeability decrease by about 2000-fold and solute transport simulations using a tracer (iodixanol, 1.5 kDa with a free diffusivity of 2.5 × 10−10 m2/s) showed diffusivity decrease by a factor of 1.5. Taken together, architecture of the nano-pores and the complex mineralization pattern in the osteochondral interface considerably impacts the cross-talk between cartilage and bone.

Keywords

Nanopore architecture, Osteochondral junction, Permeability, Pore -scale modelling, Solute transport, Biophysics, Biomedical Engineering, Orthopedics and Sports Medicine, Rehabilitation

Citation

Pouran, B, Raoof, A, de Winter, D A M, Arbabi, V, Bleys, R L A W, Beekman, F J, Zadpoor, A A, Malda, J & Weinans, H 2021, 'Topographic features of nano-pores within the osteochondral interface and their effects on transport properties –a 3D imaging and modeling study', Journal of Biomechanics, vol. 123, 110504. https://doi.org/10.1016/j.jbiomech.2021.110504