Materials for Biomedical Engineering. Mohamed N. RahamanЧитать онлайн книгу.
glass (25–40 μm) used in rad...Figure 7.16 Illustration of distinctive characteristics of bioactive glasses...Figure 7.17 (a) Optical micrograph of a 45S5 bioactive glass implant (BG) bo...Figure 7.18 Effect of composition on (a) reactivity of bioactive glasses as ...Figure 7.19 Effect of microstructure on the mechanical response of porous bi...Figure 7.20 Bioactive borate glass (13–93B3) composed of microfibers used in...Figure 7.21 Concentration of copper (Cu2+) ions released from copper‐doped b...Figure 7.22 Illustration of the production of a glass‐ceramic by controlled ...Figure 7.23 Typical processing cycle for the production of glass‐ceramics.Figure 7.24 Illustration of relative nucleation and crystallization rates as...Figure 7.25 Formation of crystalline phases in lithium disilicate glass‐cera...Figure 7.26 Illustration of the mechanism of phase formation in lithium disi...Figure 7.27 SEM images showing the difference in microstructure between lith...
8 Chapter 8Figure 8.1 Types of synthetic polymers relevant to biomaterials.Figure 8.2 Arrangement of monomer units in (a) random copolymer, (b) alterna...Figure 8.3 Arrangement of monomer units in polymers composed of (a) linear c...Figure 8.4 Stereoregularity of molecules in a vinyl polymer such as polyprop...Figure 8.5 (a) Illustration of polymer composed of molecules having many dif...Figure 8.6 Illustration of the conformation of a molecular chain in a molten...Figure 8.7 Schematic plot of the specific volume of a polymer as a function ...Figure 8.8 Effect of chain backbone composition on the glass transition temp...Figure 8.9 Effect of side chains on the glass transition temperature Tg. (a...Figure 8.10 Illustration of stages in nucleation and crystal growth in polym...Figure 8.11 Illustration of the structure of a spherulite growing within a m...Figure 8.12 Molecular orientation in amorphous polymers. Extending an amorph...Figure 8.13 Stages of molecular orientation in semicrystalline polymers. Ext...Figure 8.14 (a) Representation of the synthesis of polymethyl methacrylate (...Figure 8.15 Representation of the synthesis of polyethylene terephthalate (P...Figure 8.16 Illustration of the shear modulus as a function of temperature f...Figure 8.17 Chemical structures of three fluorinated hydrocarbon polymers: p...Figure 8.18 Scanning electron microscope image of the microstructure of a po...Figure 8.19 Chemical structure of polyether ether ketone (PEEK).Figure 8.20 Chemical structures of polycarbonate (PC), polyether sulfone (PE...Figure 8.21 (a) Representation of the synthesis of nylon 6.6 by a condensati...Figure 8.22 Chemical structure of polydimethylsiloxane (PDMS).Figure 8.23 Illustration of the synthesis of a polyurethane alternating copo...Figure 8.24 Synthesis of a polyurethane segmental block copolymer by a two‐s...Figure 8.25 Chemical structures of common diisocyanates, polyols, and chain ...Figure 8.26 Schematic representation of the effect of hard segment content (...Figure 8.27 Chemical structures of common water‐soluble polymers. (a) Polyvi...
9 Chapter 9Figure 9.1 Schematic illustration of the cleavage of a hydrolytically unstab...Figure 9.2 Schematic illustration of (a) surface erosion, (b) bulk erosion, ...Figure 9.3 Chemical structure and degradation rate constants for various deg...Figure 9.4 Simplified illustration of (a) acid‐catalyzed and (b) base‐cataly...Figure 9.5 Effect of pH on degradation (molecular weight M relative to initi...Figure 9.6 Effect of molecular weight on (a) degradation (molecular weight MFigure 9.7 Illustration of percolation in a material composed of spherical p...Figure 9.8 Critical thickness Lc that a polymer has to exceed in order to un...Figure 9.9 Chemical structure of the most widely used poly(α‐hydroxy esters)...Figure 9.10 Chemical structure of D‐lactic acid and L‐lactic acid.Figure 9.11 Crystallinity of polylactic‐co‐glycolic acid (PLGA), synthesized...Figure 9.12 Water uptake of polylactic‐co‐glycolic acid (PLGA), synthesized ...Figure 9.13 Approximate half‐life t1/2 (time taken for the molecular weight...Figure 9.14 Chemical structures of polycaprolactone (PCL) and its monomeric ...Figure 9.15 Chemical structures of a polyanhydride synthesized from 1,3‐bis(...Figure 9.16 Erosion kinetics (mass eroded relative to the initial mass) for ...Figure 9.17 Percent crystallinity of copolymer P(CCP‐SA) composed of varying...Figure 9.18 Chemical structures of a poly(ortho ester) under investigation f...Figure 9.19 Chemical structure of polydioxanone.Figure 9.20 Chemical structures of the polyhydroxyalkanoates poly‐3‐hydroxyb...Figure 9.21 Chemical structures of poly(propylene fumarate) (PPF) and its mo...Figure 9.22 Poly(cyclohexane‐1,4‐diyl acetone dimethyl ketal) (PCADK) and ac...Figure 9.23 (a) Scanning electron microscope image of poly(cyclohexane‐1,4‐d...Figure 9.24 Synthesis of poly(glycerol sebacate) (PGS) from glycerol and seb...Figure 9.25 Comparison of the changes in mass, compressive strength, and wat...Figure 9.26 Chemical structure of poly(1,3‐trimethylene carbonate).Figure 9.27 Chemical structure of tyrosine‐derived polycarbonate.
10 Chapter 10Figure 10.1 Illustration of the hierarchical structure of collagen (type I)....Figure 10.2 Scanning electron microscope images of collagen sponge microstru...Figure 10.3 Reaction of glutaraldehyde with the free amino groups of lysine ...Figure 10.4 Denaturation temperature and primary amine group content for der...Figure 10.5 Reaction of (a) hexamethylene diisocyanate with the free amine g...Figure 10.6 Schematic of different collagen structures and their denaturatio...Figure 10.7 Illustration of the mechanical response of collagenous tissues i...Figure 10.8 Typical tensile stress versus strain curves of collagen structur...Figure 10.9 Schematic showing method for extracting gelatin from collagenous...Figure 10.10 Illustration of the hierarchical structure of silkworm silk fib...Figure 10.11 Tensile stress versus tensile strain curves for silkworm (Bombi...Figure 10.12 Illustration of elastin in (a) relaxed and (b) stretched states...Figure 10.13 Illustration of major steps in the formation of fibrin.Figure 10.14 Scanning electron microscope image of the structure of fibrin f...Figure 10.15 Two common ways to depict the chemical structure of a monosacch...Figure 10.16 Chemical structure of the repeating unit in hyaluronic acid, co...Figure 10.17 Illustration of the structure of chemically modified hyaluronic...Figure 10.18 Chemical structure of the repeating unit in chondroitin sulfate...Figure 10.19 Representative alginate structure showing (a) chain conformatio...Figure 10.20 Illustration of the formation of a three‐dimensional network of...Figure 10.21 Illustration of a possible reaction scheme for the covalent bon...Figure 10.22 Chemical structure of the repeating unit in (a) chitin, (b) chi...Figure 10.23 Illustration of the chemical modification of chitosan. (a) Ioni...Figure 10.24 Chemical structure of the repeating unit in agarose.Figure 10.25 Chemical structure of α‐glucose and β‐glucose.Figure 10.26 Chemical structure of cellulose.Figure 10.27 Hierarchical structure of cellulose fiber.Figure 10.28 Illustration of the hierarchical structure of bacterial cellulo...Figure 10.29 Scanning electron microscope image of the surface of a bacteria...
11 Chapter 11Figure 11.1 Illustration of a hydrogel in a dehydrated state and in a hydrat...Figure 11.2 Example of the chemical structure of a monomer (hydroxyethyl met...Figure 11.3 Schematic of chemical reaction between polyvinyl alcohol (PVA) c...Figure 11.4 Illustration of alginate hydrogels created by ionic crosslinking...Figure 11.5 Illustration of hydrogen bonded structure between polyacrylic ac...Figure 11.6 (a) Chemical structure of polymers (referred to as Pluronics) co...Figure 11.7 Illustration of the gelling mechanism upon warming a solution of...Figure 11.8 Illustration of gelling in polyvinyl alcohol (PVA) by a crystall...Figure 11.9 Illustration of the mesh size ξ and molecular weight betw...Figure 11.10 Illustration of the contributions to the overall Gibbs free ene...Figure 11.11 Dependence of the molecular weight between crosslinks
