Chapter 6. How Cells Grow 6.1 INTRODUCTION (6.1) (6.2a) (6.2b) (6.3)

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Presentation transcript:

Chapter 6. How Cells Grow 6.1 INTRODUCTION (6.1) (6.2a) (6.2b) (6.3)

6.2. BATCH GROWTH 6.2.1. Quantifying Cell Concentration 6.2.1.1 Determining cell number density

6.2.1. Quantifying Cell Concentration 6.2.1.2 Determining mass concentration

6.2.1. Quantifying Cell Concentration 6.2.1.2 Determining mass concentration (6.4)

6.2.2. Growth patterns and Kinetics in Batch Culture

6.2.2. Growth patterns and Kinetics in Batch Culture

6.2.2. Growth patterns and Kinetics in Batch Culture (6.5) (6.6) (6.7) (6.8)

6.2.2. Growth patterns and Kinetics in Batch Culture (6.9) (6.10)

6.2.2. Growth patterns and Kinetics in Batch Culture (6.11) (6.12) (6.13) (6.14) (6.15)

6.2.2. Growth patterns and Kinetics in Batch Culture

6.2.2. Growth patterns and Kinetics in Batch Culture (6.16) (6.17) (6.18)

6.2.2. Growth patterns and Kinetics in Batch Culture

6.2.2. Growth patterns and Kinetics in Batch Culture

6.2.3. How Environmental Conditions Affect Growth Kinetics (6.19) (6.20)

6.2.3. How Environmental Conditions Affect Growth Kinetics

6.2.3. How Environmental Conditions Affect Growth Kinetics

6.2.3. How Environmental Conditions Affect Growth Kinetics

6.2.3. How Environmental Conditions Affect Growth Kinetics (6.21) (6.22) (6.23) (6.24)

6.2.3. How Environmental Conditions Affect Growth Kinetics (6.25) (6.26)

6.2.4. Heat Generation by Microbial Growth (6.28) (6.29)

6.2.4. Heat Generation by Microbial Growth

6.3.2. Heat Generation by Microbial Growth 6.3.2.1 Substrate-Limited growth. (6.30)

6.3.2. Heat Generation by Microbial Growth 6.3.2.1 Substrate-Limited growth.

6.3.2. Heat Generation by Microbial Growth 6.3.2.1 Substrate-Limited growth. (6.31) (6.32)

6.3.2. Heat Generation by Microbial Growth 6.3.2.1 Substrate-Limited growth. (6.33) (6.34) (6.35) (6.36)

6.3.2. Heat Generation by Microbial Growth 6.3.2.1 Substrate-Limited growth.

6.3.2. Heat Generation by Microbial Growth 6.3.2.1 Substrate-Limited growth. (6.37) (6.38)

6.3.2. Heat Generation by Microbial Growth 6.3.2.2 Models with growth inhibitors. (6.39) (6.40) (6.41)

6.3.2. Heat Generation by Microbial Growth 6.3.2.2 Models with growth inhibitors. (6.42) (6.43) (6.44) (6.45)

6.3.2. Heat Generation by Microbial Growth 6.3.2.2 Models with growth inhibitors. (6.46) (6.47) (6.48)

6.3.2. Heat Generation by Microbial Growth 6.3.2.2 Models with growth inhibitors. (6.49)

6.3.2. Heat Generation by Microbial Growth 6.3.2.3. The logistic equation. (6.50) (6.51) (6.52) (6.53)

6.3.2. Heat Generation by Microbial Growth 6.3.2.3. The logistic equation. (6.54) (6.55) (6.56)

6.3.2. Heat Generation by Microbial Growth 6.3.2.4. Growth models for filamentous organisms. (6.57) (6.58a) (6.58b) (6.59)

6.3.3. Models for Transient Behavior 6.3.3.2. Chemically structured models.

6.3.3. Models for Transient Behavior 6.3.3.2. Chemically structured models.

6.3.3. Models for Transient Behavior 6.3.3.2. Chemically structured models. (6.60)

6.3.3. Models for Transient Behavior 6.3.3.2. Chemically structured models. (6.61) (6.62a) (6.62b) (6.63)

6.4.2. Some Specific Devices for Continuous Culture

6.4.2. Some Specific Devices for Continuous Culture

6.4.3. The Ideal Chemostat

6.4.3. The Ideal Chemostat (6.64) (6.65) (6.66)

6.4.3. The Ideal Chemostat (6.67) (6.68)

6.4.3. The Ideal Chemostat (6.69) (6.70) (6.71) (6.72)

6.4.3. The Ideal Chemostat (6.73a) (6.73b) (6.73c)

6.4.3. The Ideal Chemostat (6.74) (6.75a) (6.75b) (6.76) (6.77)

6.4.3. The Ideal Chemostat (6.78) (6.79)

6.4.3. The Ideal Chemostat

6.4.3. The Ideal Chemostat (6.80) (6.81)

6.4.3. The Ideal Chemostat (6.78) (6.82) (6.83)

6.4.5. Deviations from Ideality