Materials for Biomedical Engineering. Mohamed N. Rahaman

Materials for Biomedical Engineering - Mohamed N. Rahaman


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Consequently, the surface of a material can also be considered a two‐dimensional or planar defect. As the surface of a biomaterial has a strong influence on its performance in vivo, the surface characteristics of solids relevant to their use as biomaterials are discussed in detail in Chapter 5.

      The engineering properties of a material depends on its microstructure and, consequently, in the design and creation of biomaterials, we are concerned not just with the material itself but with its microstructure also. Microstructure refers to the structure of a material at a scale of approximately 0.1–100 μm, such as the nature of the phases present in the material, the quantity of each phase and its distribution. Unless specifically emphasized, structure at a nanoscale is often included within the realm of microstructure. A phase is defined as a region of material with uniform physical and chemical properties. As biomaterials are solids, we are essentially concerned with one or more solid phases, crystalline or amorphous, and, if present, porosity.

      Microstructures are commonly examined in a microscope, such as an optical microscope or an electron microscope, depending on the scale of resolution required. Often, metals and ceramics are etched using a thermal or chemical treatment to reveal the grain boundaries or the phases within the solid. The microstructures of biomaterials are numerous, varying from simple to more complex and, thus, it is not possible to describe them all. Instead, we discuss microstructural features relevant to the design and creation of biomaterials in two broad categories, namely dense biomaterials and porous biomaterials.

      3.5.1 Microstructure of Dense Biomaterials

Image described by caption.

      Source From Peters et al. (2003)

      ; (d)

      From Holand and Beall (2012).

      At a higher level of complexity, we can consider a dense solid composed of more than one phase. The Ti alloy, Ti6Al4V, for example, used as fracture fixation plates, in hip implants and as dental implants, is typically composed of two crystalline phases at ordinary temperatures, termed an alpha (α) phase and a beta (β) phase. Depending on the production method and subsequent heat treatment, this alloy can show a variety of microstructures. Figure 3.23b shows one such microstructure, composed of nearly parallel α lamellae within large β grains. ZTA femoral heads used in hip implants are composed of a matrix of Al2O3 grains and a distribution of YSZ grains (Figure 3.23c). The volume fraction of the ZrO2 is often kept within a useful range, approximately 10–15%. For this composition, the optimal mechanical properties such as strength and resistance to fracture are achieved through production methods that give a fine grain size of the Al2O3 phase, less than a few micrometers, a finer grain size of the ZrO2 phase and a homogeneous distribution of the ZrO2 grains within the Al2O3 matrix.

      In a nonporous form, semicrystalline polymers, such as PE are composed of a mixture of amorphous and crystalline phases (Figure 3.15b). The crystalline regions are referred to as crystallites. They are not called grains because they have a different structure from the grains in polycrystalline metals and ceramics. The properties of semicrystalline polymers often improve with a higher volume fraction and a homogeneous distribution of crystallites as, for example, in UHMWPE used as articulating bearings in hip and knee implants.

      As polymers are weaker than bone, one way to improve their mechanical properties is to reinforce them with a strong solid phase, commonly a ceramic biomaterial in the form of particles or fibers, to form a composite (Chapter 12). Composites composed of hydroxyapatite particles dispersed in a PE matrix have been created for use as implants in healing bone defects (Bonfield et al. 1981). The hydroxyapatite particles enhance the elastic modulus of the PE, bringing it closer to that of bone. They also provide an additional benefit by imparting some degree of bioactivity to the implant and, thus, enhance its potential to form a stronger interfacial bond and integrate with host bone.

      3.5.2 Microstructure of Porous Biomaterials

      Porous biomaterials are desirable in a variety of biomedical applications for two major reasons. First, as pores modify the properties of a solid, their incorporation into a biomaterial is often used as a strategy to bring its properties such as degradation rate, strength, and elastic modulus closer to those desired for a given application. Porosity can be


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