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Bioreactor Design and Operational System01:29

Bioreactor Design and Operational System

200
Bioreactors are engineered vessels designed to cultivate microorganisms under controlled conditions for industrial bioprocessing. They maintain sterility and allow precise regulation of pH, temperature, oxygen, and nutrient levels to optimize microbial growth and metabolite production. Bioreactors range from small laboratory units of 1 liter to industrial systems holding up to 500,000 liters, though only about 75% of their volume is actively used for fermentation. The remaining headspace...
200
Bioreactor Controls-I01:28

Bioreactor Controls-I

94
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...
94
Bioreactor Controls-II01:18

Bioreactor Controls-II

76
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...
76
Bioreactor Controls-III01:22

Bioreactor Controls-III

67
Strain improvement is a foundational strategy in industrial microbiology aimed at maximizing microbial productivity, particularly because natural isolates typically yield commercially valuable products in very low concentrations. Although optimizing the culture medium and environmental conditions can improve yields, these adjustments are inherently limited by the organism’s genetic potential. As a result, the focus shifts toward genetic modifications to enhance biosynthetic capacity. The...
67
Designing Growth Media for Bioreactors01:30

Designing Growth Media for Bioreactors

78
Growth media provide essential nutrients that support cell growth and metabolism, thereby enhancing the yield of valuable products such as enzymes, antibiotics, and biomass. Designing an effective growth medium involves balancing all components to prevent nutrient limitations or toxic excesses, both of which can impair growth and reduce product yields.Composition of a Typical Growth MediumA typical growth medium contains carbon and nitrogen sources, salts, vitamins, trace elements, and...
78
Upstream Processing01:27

Upstream Processing

97
Upstream processing represents a critical phase in biomanufacturing, wherein biological systems such as microorganisms, mammalian cells, or insect cells are cultivated to produce therapeutic proteins, vaccines, enzymes, or other biologically derived products. This phase encompasses all steps from the selection and genetic manipulation of the production organism to the cultivation of cells in bioreactors under tightly controlled environmental conditions.Host Selection and Genetic OptimizationThe...
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Related Experiment Video

Updated: May 5, 2026

A Novel Bioreactor for High Density Cultivation of Diverse Microbial Communities
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Bioreactors as Additive Manufacturing Environments.

Orkan Telhan1

  • 1Stuart Weitzman School of Design, University of Pennsylvania, Philadelphia, Pennsylvania, USA.

3D Printing and Additive Manufacturing
|May 1, 2025
PubMed
Summary
This summary is machine-generated.

Bioreactors are expanding beyond life sciences into design fields like architecture and fashion for additive fabrication. These systems uniquely handle living materials, enabling novel manufacturing workflows with live cells.

Keywords:
biodesignbiological designbiomanufacturingbioreactorsclosed-loop manufacturing

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Area of Science:

  • Bioengineering
  • Design
  • Additive Manufacturing

Background:

  • Bioreactors traditionally serve life sciences and bioengineering.
  • Emerging applications span architecture, fashion, and product design.
  • Additive fabrication with bioreactors differs from conventional digital manufacturing.

Purpose of the Study:

  • To explore the expanding role of bioreactors in additive fabrication.
  • To differentiate bioreactor use for living versus nonliving matter.
  • To present novel biofabrication platforms and case studies.

Main Methods:

  • Discussion of bioreactor characteristics in additive fabrication.
  • Comparison with traditional digital manufacturing tools.
  • Presentation of Microbial Design Studio and B | reactor platforms.

Main Results:

  • Bioreactors enable materialization of biologically-active matter.
  • Closed-loop fabrication environments are required for living ingredients.
  • Case studies demonstrate manufacturing workflows with live cells.

Conclusions:

  • Bioreactors offer unique capabilities for engaging with living matter.
  • They facilitate complex interactions between biological, algorithmic, and mechanical systems.
  • Bioreactors represent a novel frontier in additive manufacturing.