posted on 2021-02-23, 12:53authored byPhilip Poillot, Christine L. Le Maitre, Jacques M. Huyghe
The strain-generated potential (SGP) is a well-established mechanism in cartilaginous tissues whereby mechanical forces generate electrical potentials. In articular cartilage (AC) and the intervertebral disc (IVD), studies on the SGP have focused on fluidand ionic-driven effects, namely Donnan, diffusion and streaming potentials. However, recent evidence has indicated a direct
coupling between strain and electrical potential. Piezoelectricity is one such mechanism whereby deformation of most biological
structures, like collagen, can directly generate an electrical potential. In this review, the SGP in AC and the IVD will be revisited
in light of piezoelectricity and mechanotransduction. While the evidence base for physiologically significant piezoelectric
responses in tissue is lacking, difficulties in quantifying the physiological response and imperfect measurement techniques
may have underestimated the property. Hindering our understanding of the SGP further, numerical models to-date have negated
ferroelectric effects in the SGP and have utilised classic Donnan theory that, as evidence argues, may be oversimplified.
Moreover, changes in the SGP with degeneration due to an altered extracellular matrix (ECM) indicate that the significance of
ionic-driven mechanisms may diminish relative to the piezoelectric response. The SGP, and these mechanisms behind it, are
finally discussed in relation to the cell response.
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