Currently, growing attention is being devoted to the conversion of biomass into value-added products, such as itaconic acid (IA), which is considered as the cleanest alternative to petroleum-based acrylic acid. IA is an unsaturated dicarboxylic acid that is used as a building block chemical for the production of several value-added products such as poly-itaconic acid. IA and its derivatives have a wide range of potential applications in textile, paint, pharmaceutical and chemical industries. Presently, industries are producing IA on the large scale by fermentation from glucose. However, due to the primary utility of glucose as a food, it cannot meet the global demand for IA production in an economical way. The main challenge, so far, has been the production technology, which does not support cost-effective and competitive production of IA. This review discusses the various bottlenecks faced during each step of IA production, along with possible remedies to deal with these problems. Furthermore, it reviews the recent progress in fermentative IA production and sheds light on different microorganisms used, potential substrates and fermentation conditions. The review also covers market potential for IA, which indicates that IA can be produced cost-effectively from sustainable substrates, and it has the potential to replace petrochemicals in the near future.
Several fungi and starch-rich industrial residues were screened for itaconic acid (IA) production. Out of 15 strains, only three fungal strains were found to produce IA, which was confirmed by HPLC and GC-MS analysis. These strains were identified as strains C1 and C2, and strain C3 by sequencing of 18S rRNA gene and internal transcribed spacer regions. -aconitate decarboxylase () gene, which encodes a key enzyme in IA production in , was characterized from strains C1 and C2. C1 and C2 gene sequences showed about 96% similarity to the only available GenBank sequence of gene. 3-D structure and-aconitic acid binding pocket of Cad enzyme were predicted by structural modeling. Rice, corn and potato starch wastes were screened for IA production. These materials were enzymatically hydrolyzed under experimentally optimized conditions resulting in the highest glucose production of 230 mg/mL from 20% potato waste. On comparing the production potential of selected strains with different wastes, the best IA production was achieved with strain C1 (255.7 mg/L) using potato waste. Elemental composition as well as batch-to-batch variation in waste substrates were analyzed. The difference in IA production from two different batches of potato waste was found to inversely correlate with their phosphorus content, which indicated that produced IA under phosphate limiting condition. The potato waste hydrolysate was deionized to remove inhibitory ions like phosphate, resulting in improved IA production of 4.1 g/L by C1 strain, which is commercially competitive.
Present study used Aspergillus terreus strain C1 isolated from mangrove soil for itaconic acid (IA) production from potato starch waste. Fermentation parameters were optimized by classical one factor approach and statistical experimental designs, such as Plackett-Burman and response surface designs. Anionic deionization of potato waste was found to be a very effective, economic, and easy way of improving IA production. The increase in IA production by deionization was found to correlate with removal of phosphate. In our knowledge, this is the first report on application of deionization of potato waste to enhance IA production. Other parameters like inoculum development conditions, pH, presence of peptone and certain salts in the medium also significantly affected IA production. IA production by strain C1 increased 143-fold during optimization when compared with the starting condition. The optimized IA level (35.75 g/L) was very close to the maximum production predicted by RSM (38.88 g/L). Bench scale production of IA was further optimized in 3-L stirred tank reactor by varying parameters like agitation and aeration rate. The maximum IA production of 29.69 g/L was obtained under the agitation speed of 200 rpm and aeration rate of 0.25 vvm. To the best of our knowledge, it is the first report on IA production from potato starch waste at bioreactor level.
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