to the catastrophic shattering of an object into two or more pieces under sufficiently high mechanical stresses. Despite their brittleness, ceramics can be engineered to function safely and reliably over long durations under high stresses if these stresses are compressive in nature. Ceramics are not recommended for use in high‐stress applications when the applied stress has an appreciable tensile or bending component. In general, ceramics show high hardness and wear resistance.
The density of ceramics is lower than that of most metals, often by a factor of two or more, which means that for the same geometry, a ceramic implant will not be as heavy as a metal implant. Ceramics are generally poor conductors of electricity and heat, and those ceramics used in technological applications normally have a high degree of chemical inertness. On the other hand, certain compositions, such as hydroxyapatite and β‐tricalcium phosphate, composed of the same ions as the mineral constituent of bone, show some reactivity in the physiological environment.
Ceramics are generally more difficult to fabricate than metals and far more difficult to fabricate than polymers. Forming ceramics into useful objects having the requisite external shape and microstructure often requires high fabrication temperatures, approximately several hundred degrees Celsius. Due to their high hardness, ceramics are expensive and difficult to machine into the desired shape and surface smoothness after their fabrication.
Overall, major limitations of ceramics are their brittleness, and the difficulty and cost of fabricating them into useful objects. On the other hand, ceramics have high compressive strength, stiffness, hardness, and wear resistance. Consequently, ceramics generally find use in applications where the applied stress is much lower than their strength or mainly compressive in nature, and where high wear resistance and chemical inertness are required.
1.4.3 Intrinsic Properties of Polymers
Polymers are generally composed of long‐chain molecules formed by repeated bonding of a large number of small molecules. The simplest example is polyethylene (abbreviated PE) whose molecular chains consist a large number (several hundred to several thousand) of ethylene (H2C=CH2) molecules bonded together. Polymers show low strength and low elastic modulus. In contrast to metals and ceramics, they show a time‐dependent mechanical response. This means that the measured mechanical properties of polymers, such as strength and elastic modulus, are dependent on the duration or rate of the mechanical testing procedure, or on the temperature at which the test is performed (Chapter 4). A given polymer, such as PMMA, for example, can show a range of mechanical behavior, from ductile to brittle, depending on the rate or the temperature of the mechanical test. Unless they are brittle, polymers typically show good fatigue resistance. Due to their low hardness, the resistance of polymers to abrasive wear is low.
Polymers generally have low density (~1 g/cm3), low electrical conductivity, and low thermal conductivity. A clear advantage of polymers over metals and ceramics is their ease of fabrication. Polymers can be easily formed into the requisite shape and microstructure using conventional processing or additive manufacturing (3D printing) methods. Another advantage of polymers is their compositional flexibility. Polymers can not only be synthesized with the requisite composition but their composition can also be easily modified to achieve more desirable properties, such as degradation rate.
Overall, the human body, except for bone and teeth, is composed of soft tissues (and organs). When compared to metals and ceramics, polymers can be more easily designed to approximate the structure and properties of these soft tissues. Consequently, polymers find considerable use as biomaterials. Because of the ease in synthesizing compositions with a controllable degradation rate, polymers also find considerable use as biomaterials for drug delivery.
1.4.4 Properties of Composites
Composites are composed of two or more physically distinct materials or phases (Chapter 12). Synthetic composites used as biomaterials are composed of one or more of the primary classes of materials (metals, ceramics, and polymers), and consist of a continuous phase (the matrix) and a dispersed phase (the reinforcing phase). While composites are abundant in nature, synthetic composites find only limited use as biomaterials. A well‐known example of a natural composite is bone, produced by embedded cells and composed of an inorganic (ceramic) phase of fine lath‐like particles of composition approximating that of hydroxyapatite and an organic phase composed of collagen.
Synthetic composites are often of interest when a single material cannot provide the desired combination of properties. For example, polymers have an advantage of ease of fabrication but, because of their weak mechanical properties, they are not suitable as implants to heal defects in structural bone that have to support a significant physiological stress. To better approximate the mechanical properties of bone, polymers can be reinforced with a strong material, such as a ceramic in the form of particles or fibers. Use of particles composed of hydroxyapatite or bioactive glass can also enhance the functionality of the polymer matrix, such as its bioactivity.
As ceramics are brittle, they are sometimes reinforced with another phase, typically strong ceramic particles or fibers, to improve their resistance to fracture, a property quantified by a measurable parameter called the fracture toughness. For example, zirconium oxide (ZrO2 ) is incorporated into alumina (Al2O3) to form a composite, referred to as zirconia‐toughened alumina (ZTA), an improved form of which is called alumina matrix composite (AMC). Because of its better fracture resistance (higher fracture toughness) and better wear resistance, AMC has now replaced Al2O3 as a ceramic femoral head material in hip implants.
1.4.5 Representation of Properties
Charts provide a succinct way to show a direct comparison of material properties. As a mechanical function is often a major consideration in many biomedical applications, charts that compare mechanical properties can be useful at the outset of materials selection and design. Several types of mechanical properties are available and, depending on the application, some properties can be more important than others. Figure 1.5 shows one type of material property chart, which depicts the measured strength versus elastic modulus for the primary classes of synthetic materials and for selected natural materials. The properties of the synthetic materials shown in Figure 1.5 (and in most mechanical property charts) are those for the dense materials, that is, the materials have zero or near zero porosity. As the presence of porosity lowers the mechanical properties of a material, one approach to modifying the properties of strong synthetic materials in order to achieve more optimal properties for use as biomaterials is to incorporate a controlled amount of porosity into them. In comparison, incorporation of a strong phase into polymers to form a composite provides a way to improve their mechanical properties.
Figure 1.5 Strength versus elastic modulus for the three major classes of synthetic materials used as biomaterials (ceramics, metals, and polymers). The range shown for each class of material is approximate and for the dense (or almost dense) material (zero or close to zero porosity). The presence of porosity in these materials will lead to a reduction in these and other mechanical properties. The properties of some human tissues are shown for comparison.
1.5 Case Study in Materials Design and Selection: The Hip Implant
Modern implants for total hip replacement (Figure 1.1b) provide a useful example of the design and selection of biomaterials. While these implants do not reflect the aforementioned trend