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Batch vs Continuous Culture01:14

Batch vs Continuous Culture

Fermentation is a foundational biotechnological process used to produce pharmaceuticals, biofuels, enzymes, and food additives. Among industrial strategies, batch and continuous fermentation are the two most widely applied. Although both rely on microbial conversion of substrates into desired products, they differ markedly in operation, productivity, and suitability for specific applications.Batch fermentation occurs in a closed system in which nutrient media and inoculum are added at the...
Microbial Growth Measurement: Indirect Methods01:27

Microbial Growth Measurement: Indirect Methods

Estimating microbial growth is essential for understanding population dynamics and environmental adaptations. Indirect methods provide valuable insights by measuring parameters such as turbidity, metabolic activity, and biomass, enabling efficient and reproducible assessments.During exponential growth, microbial cells scatter light proportionally to their biomass, a principle used in turbidity measurements. About one million cells per milliliter produce detectable scattering, which a...
Microbial Growth Measurement: Direct Methods01:23

Microbial Growth Measurement: Direct Methods

Direct methods for measuring microbial populations in a culture are essential tools in microbiology, providing quantitative data for various applications. Among these, microscopic counts, plate counts, and serial dilution are widely used techniques, each with unique principles and applications.Microscopic CountsMicroscopic counting involves the use of a Petroff-Hausser chamber, a specialized microscope slide with a grid and defined depth. By observing a liquid culture under a microscope,...
Fed-Batch Culture01:23

Fed-Batch Culture

Fed-batch culture is a widely used bioprocessing strategy combining aspects of batch culture with controlled substrate feeding to optimize cell growth and product formation. In this semi-closed system, nutrients are strategically added during fermentation, while the accumulated products and biomass remain within the bioreactor until the end of the operation. This controlled addition of substrates allows for better management of growth kinetics, nutrient limitation, and metabolite...
Bioreactor Controls-II01:18

Bioreactor Controls-II

In aerobic fermentations, oxygen is vital for microbial growth and metabolite production. Since air comprises only about 20% oxygen and the gas is poorly soluble in water—just 9 ppm at 20°C—supplying sufficient oxygen becomes a critical challenge, especially in high-demand processes like yeast growth or citric acid production. Even a fully saturated broth may offer only a few seconds of oxygen availability.To address this, sterile or scrubbed air is introduced into the fermentor via a sparger...

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Biotechnology and bioengineering·1983
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Related Experiment Video

Updated: Jul 4, 2026

Microfluidic Picoliter Bioreactor for Microbial Single-cell Analysis: Fabrication, System Setup, and Operation
12:04

Microfluidic Picoliter Bioreactor for Microbial Single-cell Analysis: Fabrication, System Setup, and Operation

Published on: December 6, 2013

The continuously fed batch reactor for measuring microbial growth rates.

I A Webster1

  • 1Department of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139.

Biotechnology and Bioengineering
|December 1, 1983
PubMed
Summary

The continuously fed batch reactor (CFBR) offers a novel method for measuring microbial growth rates, overcoming limitations of traditional techniques. This approach accurately determines growth kinetics, especially at low substrate concentrations where chemostats struggle.

More Related Videos

Design and Use of Multiplexed Chemostat Arrays
19:40

Design and Use of Multiplexed Chemostat Arrays

Published on: February 23, 2013

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Last Updated: Jul 4, 2026

Microfluidic Picoliter Bioreactor for Microbial Single-cell Analysis: Fabrication, System Setup, and Operation
12:04

Microfluidic Picoliter Bioreactor for Microbial Single-cell Analysis: Fabrication, System Setup, and Operation

Published on: December 6, 2013

Design and Use of Multiplexed Chemostat Arrays
19:40

Design and Use of Multiplexed Chemostat Arrays

Published on: February 23, 2013

Area of Science:

  • Biotechnology
  • Microbial Physiology
  • Chemical Engineering

Background:

  • Traditional methods like chemostat and batch cultures have limitations for measuring microbial growth rates.
  • Accurate measurement of microbial growth kinetics is crucial for optimizing bioprocesses.
  • Existing techniques face challenges, particularly at low substrate concentrations.

Purpose of the Study:

  • To introduce the continuously fed batch reactor (CFBR) as an improved method for measuring microbial growth rates.
  • To detail the operational methodology of the CFBR for generating specific growth-rate versus substrate-concentration data.
  • To highlight the CFBR's advantage in measuring microbial growth at low rates and concentrations.

Main Methods:

  • Operating a continuously fed batch reactor (CFBR) under specific conditions.
  • Analyzing transient states where biomass and substrate concentrations exhibit temporal extrema.
  • Extracting specific growth-rate versus substrate-concentration data from these transient profiles.

Main Results:

  • The CFBR successfully generates microbial growth rate data.
  • The method is particularly effective for measuring growth at low substrate concentrations.
  • Identified extrema in biomass and substrate concentrations are key data points.

Conclusions:

  • The continuously fed batch reactor (CFBR) is a viable alternative to conventional methods for microbial growth rate determination.
  • CFBR excels in measuring microbial kinetics at low substrate levels, addressing a key limitation of chemostats.
  • This technique enhances the ability to characterize microbial physiology under challenging conditions.