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Related Concept Videos

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...
Bioreactor Controls-I01:28

Bioreactor Controls-I

Maintaining optimal conditions within fermenters is essential for maximizing microbial productivity and ensuring process efficiency. This lesson focuses on key parameters—temperature, foam, pH, carbon dioxide, oxygen, and pressure—and their precise measurement and control strategies in fermentation systems.Temperature ControlTemperature regulation is critical due to the exothermic nature of many fermentation processes. In small laboratory fermenters, temperature is commonly monitored using...
Fermentation01:29

Fermentation

Most eukaryotic organisms require oxygen to survive and function adequately. Such organisms produce large amounts of energy during aerobic respiration by metabolizing glucose and oxygen into carbon dioxide and water. However, most eukaryotes can generate some energy in the absence of oxygen by anaerobic metabolism.
Fermentation is a type of metabolic process that occurs in the absence of oxygen, where organic molecules such as glucose are broken down to produce energy. During this process, the...
Microbial Fermentation01:23

Microbial Fermentation

Fermentation is a crucial anaerobic metabolic process that enables microbes to derive energy from sugar without relying on oxygen or an electron transport chain. This process is fundamental to various biological and industrial applications and is classified based on the metabolic products generated.Role of Pyruvate in FermentationPyruvate and its derivatives serve as key electron acceptors in fermentative pathways. The oxidation of NADH to regenerate NAD+ is essential for the continuation of...

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Related Experiment Video

Updated: May 17, 2026

A Microfluidic Device for Studying Multiple Distinct Strains
08:15

A Microfluidic Device for Studying Multiple Distinct Strains

Published on: November 9, 2012

Yeast-powered microfluidic pump based on a four-parameter fermentation model.

Jeongmok Kim1, Kideok Kim1, Seongyeol Baeck1

  • 1School of Mechanical Engineering, College of Engineering, Chung-Ang University, Seoul, Republic of Korea.

Microsystems & Nanoengineering
|May 15, 2026
PubMed
Summary
This summary is machine-generated.

Baker's yeast fermentation powers a novel passive pump for microfluidics. This biological power source offers a cost-effective, autonomous solution for fluid control in various applications.

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Area of Science:

  • Biotechnology
  • Microfluidics
  • Biomechanical Engineering

Background:

  • Baker's yeast (Saccharomyces cerevisiae) fermentation produces carbon dioxide (CO2), increasing internal pressure.
  • Passive pumps are gaining traction in microfluidics due to their simplicity and low energy needs.
  • Integrating biological power sources into microfluidic systems remains an area of active research.

Purpose of the Study:

  • To harness yeast fermentation as a biological power source for a passive pump in microfluidic systems.
  • To develop a cost-effective and autonomous fluid control method.
  • To explore the potential of bio-driven pumps for low-power applications.

Main Methods:

  • A custom mechanical pump was designed to convert fermentation-generated gas pressure into fluid movement.
  • Experimental analysis was conducted to characterize the dynamics of gas production and pump performance over time.
  • Mathematical modeling was employed to describe gas production using six-parameter and four-parameter equations, simplified to a two-parameter model.

Main Results:

  • The yeast fermentation-powered pump successfully enabled fluid flow in microfluidic systems.
  • Experimental data on gas production dynamics were accurately captured by the developed mathematical models.
  • A simplified two-parameter model, dependent on yeast mass and sucrose concentration, was established for intuitive pump setup.

Conclusions:

  • Yeast fermentation provides a viable biological power source for passive microfluidic pumps.
  • The developed pump concept is cost-effective and extends passive pumping into biological systems.
  • This bio-driven pump has potential for autonomous microfluidic devices in space, education, and low-resource settings.