Introduction to Biomedical EngineeringPearson/Prentice Hall, 2004 - 244 sider For freshman and limited calculus-based courses in Introduction to Biomedical Engineering or Introduction to Bioengineering. This text presents freshman-level students with a study of some of the best engineering designs provided by nature and exposes them to bioengineering practice from a variety of perspectives. Examining the living system from the molecular to the the human scale, this text covers such key issues as optimization, scaling, and design; and introduces these concepts in a sequential, layered manner. Analysis strategies, science, and technology are illustrated in each chapter. |
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Resultater 1-3 af 43
Side 35
... Glucose required = 1 kg human * 0.3 kg water - free / kg human * 0.5 kg C / kg water - free * 180 kg glucose / 72 kg C = 0.375 kg glucose ( per kg of human ) . Note the use of units and their cancellation ; explicitly writing the units ...
... Glucose required = 1 kg human * 0.3 kg water - free / kg human * 0.5 kg C / kg water - free * 180 kg glucose / 72 kg C = 0.375 kg glucose ( per kg of human ) . Note the use of units and their cancellation ; explicitly writing the units ...
Side 45
... glucose because once set up , no additional inputs of glucose from the environment are available and glucose is consumed to produce cells . Thus , by using the definition of yield ( Chapter 1 ) , the fate of glucose can be accounted for ...
... glucose because once set up , no additional inputs of glucose from the environment are available and glucose is consumed to produce cells . Thus , by using the definition of yield ( Chapter 1 ) , the fate of glucose can be accounted for ...
Side 118
... glucose is par- tially degraded to acetic acid . Thereafter , if the acid concentration is not at a toxic level , once the glucose is gone , the acetic acid can then be metabolized to sustain the growth of the microbial population ...
... glucose is par- tially degraded to acetic acid . Thereafter , if the acid concentration is not at a toxic level , once the glucose is gone , the acetic acid can then be metabolized to sustain the growth of the microbial population ...
Indhold
What is Bioengineering? | 3 |
Cellular Elemental and Molecular Building Blocks | 16 |
Mass Conservation Cycling and Kinetics | 33 |
Copyright | |
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activity amino acids analysis artificial heart Assume bacteria binding sites biochemical bioengineering biomaterials engineering Biomedical Engineering body carbon cellular Chapter chemical clotting coli constant contact angle device digestive system disease drug energy enzyme equal Equation example factor flow rate fluid fluorescent free induction free induction decay frequency function genetic glucose growth heat hormone human illustrate immune system implanted increase ingested insulin interactions iron ISBN kinetics ligand magnetic mass balance matrix mechanisms membrane metabolic engineering molecular molecules mRNA needed nutrients occurs organs Overall oxidation oxygen patient percent performed plasma platelet polymer pressure drop problem produce protein pump raw materials reaction Recall recycle red blood cells released result shear force shear stress shown in Figure signal strategy substrate sugar surface tion tissue engineering tube turnover number typical variables velocity versus voltage volume yield