Several organic and amino acids have found applications as specialty molecules in food, consumer goods and pharmaceutical industries. Itaconic Acid (IA) is a 5 carbon dicarboxylic acid produced through bacterial fermentation and used as an important building block for biopolymers. In case of IA production, downstream processing can account to 30-50 % of the overall cost of goods (COGs). Therefore, it requires effective and efficient operations to improve sustainability and cost competitiveness. In the current article, we will briefly discuss the role of expanded bed adsorption (EBA) and simulated moving bed (SMB) technologies in production of IA.
Figure 1: Purification of IA requires a downstream process to separate IA from suspended and dissolved impurities
The basis for selecting a specific unit-operation is defined by desired separation. Typical fermentation output stream contains 5-10 % IA, 5-10 % impurities and 80-90 % water. Impurities include both suspended solids like biomass and dissolved compounds that are produced as co-metabolites. Though precipitation is an easy method for IA purification, it results in formation of by-products and limits product purity. Therefore, instead of precipitation, adsorption using a chromatography resin is a preferred alternative. However, feed for packed bed chromatography columns need to be free of suspended solids and this require additional unit operations for clarification, resulting in yield losses and higher costs. To overcome these limitations, Expanded Bed Adsorption (EBA) can be applied. EBA is an integrated adsorption process, where the product is selectively captured by fluidized adsorbent beads from unclarified fermentation broth. Thereby, enabling removal of both suspended and soluble impurities in 1 step.
Successful EBA process can achieve desired product purity with high recovery yields using 30-60 % less number of unit-operations. In addition, it is easier to scale EBA for large-scale production processes with several kilotons annual capacity, due to no pressure drop limitations. However, it is important to note that application of EBA on large scale can lead to large side streams, which require processing before recycling or release into the environment. Additionally, fluid distribution and hydrodynamic performance of EBA may result in reduced dynamic binding capacity compared to packed bed. A prudent approach to overcome these limitations is by operating EBA in SMB mode.