Materials for Biomedical Engineering. Mohamed N. Rahaman

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Название Materials for Biomedical Engineering
Автор произведения Mohamed N. Rahaman
Жанр Химия
Серия
Издательство Химия
Год выпуска 0
isbn 9781119551096



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upon introduction of the solid into an aqueous solution, shown for a solid that develops a negatively charged surface. The vertical dashed line corresponds approximately to the plane of the zeta potential."/>

      5.4.2 Measurement of Surface Charge and Potential

Schematic illustration of zeta potential as a function of pH, as measured by the streaming potential method, for silicon nitride (Si3N4) as fabricated, and machined surfaces of Ti6Al4V and polyether ether ketone (PEEK).

      Source: From Bock et al.(2017) / with permission of John Wiley & Sons,

      5.4.3 Effect of Surface Charge

      As the surface of a biomaterial rapidly develops an electrostatic surface charge and an associated electrical double layer upon implantation in the physiological environment, it is realistic to assume that this surface charge system should influence subsequent interactions with the physiological environment. Depending on their composition, the components of the physiological fluid such as ions, amino acids, and proteins can be positively charged, negatively charged, polar or nonpolar (Chapter 3). Consequently, we might expect varying degrees of electrostatic interaction between these components and the charged surface. This interaction should influence, for example, the type of ions and molecules adsorbed at the surface and the conformation of adsorbed proteins, which, in turn, should influence the response of cells. In practice, a correlation between the surface charge of a biomaterial and its interaction with the physiological environment has been difficult to establish. While this is due to a variety of reasons, a major factor is the difficulty in separating the true effect of surface charge from the contributions of other surface properties such as wettability (contact angle) and surface topography.

      

Schematic illustration of examples of surface topography accidentally introduced (a, b) or deliberately introduced (c–e) in biomaterials. (a) Machined surface of polyether ether ketone (PEEK); (b) machined surface of Ti6Al4V; (c) sand-blasted surface of Ti6Al4V. (a–c)

      Source: From Bock et al. (2017).

      (d) Hemispherical depressions in titanium formed by photolithography. (e) Micro‐pillars on polyurethane produced by lithography. Source: From Xu and Siedlecki (2012).