Developing microbial biofilm as a robust biocatalyst and its challenges

Biocatalysts, such as bacteria, yeast, fungi and the enzymes they produce, have been used for many industrial applications since they function as effective and environmentally friendly tools. Whole cells have also been used in many sophisticated bioprocesses since a number of sequential reactions can be catalyzed within the cells. However, the use of whole cells in suspension in batch, fed-batch and continuous processes has some limitations. For instance, the cultures are non-reusable, they are sometimes sensitive to the toxicity of substrates or products, there can be issues with short-term stability, and each of these issues can impede biocatalyst regeneration, perturbing the downstream process and causing complexity in running large scale continuous culture. Recently, biofilms have emerged as a new generation of biocatalysts to solve these limitations in the production of many bio-based materials, including chemicals, antibiotics, enzymes, bioethanol, biohydrogen, and electricity production via microbial fuel cells. The establishment of industrial processes using biofilms has the potential for high benefit in terms of low-cost cell immobilization without the necessity of added polymers or chemicals. Many small-scale biofilm reactors have been developed for the production of value-added products, and it may be challenging to establish it on an industrial scale.