LDR | | 04952cmm u2200505Mu 4500 |
001 | | 000000321550 |
005 | | 20230613111106 |
006 | | m d |
007 | | cr cnu---unuuu |
008 | | 201031s2020 xx o ||| 0 eng d |
019 | |
▼a 1201227716 |
020 | |
▼a 0262353970 |
020 | |
▼a 9780262353977
▼q (electronic bk.) |
020 | |
▼z 9780262042659 |
020 | |
▼z 0262042657 |
035 | |
▼a 2654327
▼b (N$T) |
040 | |
▼a EBLCP
▼b eng
▼c EBLCP
▼d RECBK
▼d OCLCO
▼d UKAHL
▼d YDX
▼d OCLCF
▼d N$T
▼d 248032 |
050 | 4 |
▼a R857.B54 |
082 | 04 |
▼a 610.284 |
100 | 1 |
▼a Wittrup, K. Dane. |
245 | 10 |
▼a Quantitative Fundamentals of Molecular and Cellular Bioengineering
▼h [electronic resource]. |
260 | |
▼a Cambridge :
▼b MIT Press,
▼c 2020. |
300 | |
▼a 1 online resource (568 p.) |
500 | |
▼a Description based upon print version of record. |
500 | |
▼a Case Study 3-1 J. D. Stone, J. R. Cochran, and L. J. Stern. T-cell activation by soluble MHC oligomers can be described by a two-parameter binding model. Biophys. J. 81: 2547-2557 (2001). |
505 | 0 |
▼a Intro -- Title Page -- Copyright -- Table of Contents -- Dedication -- Preface and Acknowledgments -- 1. Introduction to Biological Rate Processes -- 1.1. Biological Rate Processes -- 1.2. Why Develop a Model? -- 1.3. Mechanistic Model Formulation -- 1.4. Model Validation -- 1.4.1. Consistency with Experiment Is Necessary but Not Sufficient for a Model's Correctness -- 1.4.2. Comparison to Alternative Models -- 1.4.3. Prediction and Falsifiability -- 1.4.4. Parameter Sensitivity Analysis -- 1.5. Basic Themes in Rate Process Modeling -- 1.5.1. Steady State versus Equilibrium |
505 | 8 |
▼a 1.5.2. Perturbations -- 1.5.3. Rate Forms -- 1.5.4. Characteristic Time and Length Scales -- Suggestions for Further Reading -- References -- 2. Noncovalent Binding Interactions -- 2.1. Kinetic Rate Constants -- 2.1.1. Typical Ranges for kon and koff -- 2.2. Thermodynamics -- 2.2.1. State Functions -- 2.2.2. Free Energy and Standard States -- 2.3. Energetic Contributions to Binding Affinity -- 2.3.1. Electrostatics -- 2.3.2. Hydrogen Bonding -- 2.3.3. van der Waals Interactions -- 2.3.4. Hydrophobic Effect -- 2.3.5. Deformation Energy and Entropy -- 2.4. Energetics of Protein Binding Interfaces |
505 | 8 |
▼a 2.4.1. Thermodynamic Cycle Analysis -- Case Study 2-1 P. J. Carter, G. Winter, A. J. Wilkinson, and A. R. Fersht. The use of double mutants to detect structural changes in the active site of the tyrosyl-tRNA synthetase (Bacillus stearothermophilus). Cell 38: 835-840 (1984). -- Case Study 2-2 Z. S. Hendsch and B. Tidor. Do salt bridges stabilize proteins? A continuum electrostatic analysis. Protein Sci. 3: 211-226 (1994). -- 2.5. Environmental Impacts on Binding Rate -- 2.5.1. Arrhenius Relationship and Transition State Theory -- 2.5.2. Electrostatic Effects on Binding Kinetics |
505 | 8 |
▼a 2.6. Molecular Measurements: Light-Matter Interactions -- 2.6.1. Scattering -- 2.6.2. Absorbance -- 2.6.3. Fluorescence -- Case Study 2-3 L. Song, E. J. Hennink, I. T. Young, and H. J. Tanke. Photobleaching kinetics of fluorescein in quantitative fluorescence microscopy. Biophys. J. 68: 2588-2600 (1995). -- 2.7. Fluorescence Applications for Biomolecular Measurements -- 2.7.1. Biosynthetic Fluorescent Labeling -- Case Study 2-4 B. G. Reid and G. C. Flynn. Chromophore formation in green fluorescent protein. Biochemistry 36: 6786-6791 (1997). -- 2.7.2. Common Fluorophores for In Vitro Conjugation |
505 | 8 |
▼a 2.7.3. Fluorescence Instrumentation -- Suggestions for Further Reading -- Problems -- References -- 3. Binding Equilibria and Kinetics -- 3.1. Equilibrium Monovalent Protein-Ligand Binding -- 3.1.1. Monovalent Binding Isotherm -- 3.1.2. Graphical Representations -- 3.2. Binding Kinetics -- 3.3. Multiple Binding Sites -- 3.3.1. Independent Sites -- 3.3.2. Cooperativity -- 3.3.3. Avidity and Effective Concentration -- 3.3.4. Equilibrium Bivalent Binding at Cell Surfaces |
520 | |
▼a A comprehensive presentation of essential topics for biological engineers, focusing on the development and application of dynamic models of biomolecular and cellular phenomena. |
650 | 0 |
▼a Science. |
650 | 7 |
▼a SCIENCE / Life Sciences / Molecular Biology.
▼2 bisacsh |
650 | 7 |
▼a Science.
▼2 fast
▼0 (OCoLC)fst01108176 |
655 | 4 |
▼a Electronic books. |
700 | 1 |
▼a Tidor, Bruce. |
700 | 1 |
▼a Hackel, Benjamin J. |
700 | 1 |
▼a Sarkar, Casim A. |
776 | 08 |
▼i Print version:
▼a Wittrup, K. Dane
▼t Quantitative Fundamentals of Molecular and Cellular Bioengineering
▼d Cambridge : MIT Press,c2020
▼z 9780262042659 |
856 | 40 |
▼3 EBSCOhost
▼u https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=2654327 |
938 | |
▼a Askews and Holts Library Services
▼b ASKH
▼n AH37793732 |
938 | |
▼a Recorded Books, LLC
▼b RECE
▼n rbeEB00838329 |
938 | |
▼a ProQuest Ebook Central
▼b EBLB
▼n EBL6374134 |
938 | |
▼a YBP Library Services
▼b YANK
▼n 301633879 |
938 | |
▼a EBSCOhost
▼b EBSC
▼n 2654327 |
990 | |
▼a 관리자 |