The paper does

not aim at providing a quantitative analysis on the presented feedstocks, which would be difficult at this stage of the current technological development and knowledge about those feedstocks. Rather, it has the aim of indicating potentials of little-explored feedstocks Cilengitide manufacturer that could theoretically prove to have long-term benefits for advanced biofuels production. The fundamental problem for the advanced biofuels industry is that, despite many attempts, none was successful yet with identifying a commercially viable way to produce advanced biofuels at a cost-competitive level with petroleum fuels or first generation biofuels. The main difficulty with refining second generation biofuels relates to extracting enzymes capable of breaking down lignin and cellulose in plant walls and converting biomass to fermentable sugars. The high costs of those processes determine

the final costs of the second Pictilisib nmr generation biofuels that are not competitive with traditional gasoline at this point of time. Several studies have been undertaken to address this problem and provide a viable solution. One possible solution, which would also allow for reducing costs of the second generation biofuels, has been introduced by Berka et al. [3]. The authors suggested two fungi strains (Thielavia terrestris and Myceliophthora thermophile), with their enzymes active at high temperatures between 40–75 °C, to be able to accelerate the biofuel production process. They can also contribute to improving the efficiency of biofuels production to the extent that would be sufficient for large-scale

biorefining. In addition, the fungi could be theoretically exposed to genetic manipulation in order to increase the enzyme efficiency even more than it is possible with wild types [4] and [5]. A similar solution has been investigated by the scientists from the US Department of Energy (DOE), the BioEnergy Science Center and the University of California who developed the Clostridium celluloyticum bacteria capable of breaking down cellulose and enabling the production of isobutanol in one inexpensive step [6]. Isobutanol can be burned in car engines with a heat value higher than that of ethanol (and similar Interleukin-2 receptor to gasoline). Thus, the economics of using Clostridium celluloyticum bacteria to break down cellulose is very promising in the long-term [7]. Furthermore, DOE researchers found engineered strains of the Escherichia coli bacteria (certain serotypes can be responsible for food poisoning in humans) to be able to break down cellulose and hemicellulose contained in plant cell walls, e.g., switchgrass. In this way, expensive processing steps necessary in conventional systems can be eliminated which could subsequently reduce the final biofuels price and allow a faster commercialization process for second generation biofuels.