Succinic acid, also known as butanedioic acid, is a dicarboxylic compound that is essential to many industries, including pharmaceuticals, cosmetics, biotechnology, as well as the production of plastics, solvents, and food additives. In this article, we invite you to discover how succinic acid is produced through various processes, including traditional chemical production methods and the latest biotechnological advancements, focused on microbial fermentation.
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How is succinic acid produced?
Summary
- Succinic acid can be obtained through chemical synthesis
- A closer look at the production of succinic acid through biochemical synthesis
- What should we understand about the methods of obtaining succinic acid?
- Sources
Published November 7, 2024,
updated on November 7, 2024,
by
Jamal, PhD, Doctor of human pathology and infectious diseases
—
8 min read
Succinic acid can be obtained through chemical synthesis.
The succinic acid has long been obtained through petrochemical processes from fossil resources. Among the most common methods, we find catalytic hydrogenation, the oxidation of maleic acid or maleic anhydride, as well as electrolytic reduction. For example, the oxidation of butane or benzene allows the formation of maleic anhydride, which is then hydrogenated to obtain succinic acid, with a global production of about 30,000 tons per year.
However, the fluctuations in oil prices and the environmental issues associated with the depletion of fossil resources have led to the search for sustainable alternatives. In response to these challenges, the focus is on the production of succinic acid from renewable resources, such as biomass.
A closer look at the production of succinic acid through biochemical synthesis.
The biochemical synthesis of succinic acid relies on a fermentation process, leveraging the Krebs cycle, which is a crucial cellular mechanism. This process involves various microorganisms, including Actinobacillus succinogenes, Mannheimia succiniciproducens, as well as modified strains of Escherichia coli, to convert substrates into succinic acid.
The production of succinic acid through fermentation is influenced by several factors, such as the type of substrate used and environmental conditions, including pH and temperature, which directly affect the production yield. Notable advancements in the genetic modification of microorganisms have also significantly increased these yields. For example, Corynebacterium glutamicum S071 has demonstrated a production of 152.2 g/L of succinic acid under optimized anaerobic conditions.
A recent advancement in the biosynthesis of succinic acid is the use of yeasts, such as Saccharomyces cerevisiae. Compared to bacteria, yeasts exhibit better tolerance to low pH, utilize transporters to extract succinic acid from cells, and produce fewer undesirable byproducts. Additionally, these yeasts use cellular compartments to optimize production, particularly through the reductive pathway of the Krebs cycle.
Various metabolic pathways, such as the reductive branches of the Krebs cycle and the glyoxylate cycle, play a fundamental role in the biosynthesis of succinic acid. These pathways are mediated by key enzymes, including phosphoenolpyruvate carboxylase, pyruvate carboxylase, and acetyl-CoA carboxylase. Optimizing these processes, combined with the selection of new microbial strains and the reduction of substrate costs, represents a promising approach for the production of succinic acid that can be used in cosmetics in a more environmentally friendly manner.
What should we understand about the methods of obtaining succinic acid?
Here are the key points to remember about the production of succinic acid:
Variety of Methods: Succinic acid can be obtained either through chemical processes from fossil resources, or by microbial fermentation methods.
Traditional Chemical Processes: Although chemical synthesis is well established, it has environmental drawbacks, particularly related to fossil resources.
Biotechnological Advances: Microbial fermentation, particularly through the use of yeasts, proves to be a more sustainable and eco-friendly solution with increased yields.
Strain Optimization: Current research is focused on improving microbial strains to enhance the efficiency of processes and reduce costs.
Reduced environmental impact: The use of renewable substrates, such as biomass, contributes to a more environmentally friendly production.
Sources
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