The synthesis of certain products is defined as chemical or enzymatic production based on the catalysts involved in the process. The drawbacks of high energy consumption, unexpected byproducts, and potential environmental pollution and safety issues resulted from chemical synthesis led to the development of enzymatic conversions. The enzymes, derived from an organism or cell culture that catalyzes substrate conversions, are used for the synthesis of target products in a mild temperature, pH, substrate specificity under suitable reaction. Therefore, it is highly important to explore and improve the highly active enzymes for increased productivity. Besides, the enzyme-based processing technologies with the advantages of high efficiency, energy-saving, clean, and sustainability shed light on its huge potential in green technology. For instance, the enzymatical conversion of waste-based stocks into value-added products is becoming a hot topic in environmental protection.
Enzymes have great industrial potential as biocatalysts, which have attracted much attention on their extensive applications. This research topic aims to publish novel research contributions on the exploration, modification, and application of high-active enzymes. In detail, the research topic intends to include research contributions dealing with the development of enzyme immobilization, enhancement of enzymatic stability and bioactivity, optimization of enzymatic conversion systems, synthetic biology through engineered enzymes, enzymatic-based productions for high value-added food additives, daily chemicals, fine chemicals, and other products are welcome. Alternatively, the utilization of enzymatic technologies to convert waste-based feedstocks into valuable products, to develop a cleaner, safer, and more energy-efficient process is encouraged.
1. Exploration and directional modification of highly active enzymes
2. Enzyme immobilization with enhanced stability and bioactivity
3. Novel enzymatic technology: construction and optimization for a green and efficient conversion system
4. Enzymatic preparation and production: high value-added food additives, daily chemicals, fine chemicals, and other products
5. Enzymatic processing technology: from waste feedstocks to high value-added products
6. Synthetic biology through newly engineered enzymes
The synthesis of certain products is defined as chemical or enzymatic production based on the catalysts involved in the process. The drawbacks of high energy consumption, unexpected byproducts, and potential environmental pollution and safety issues resulted from chemical synthesis led to the development of enzymatic conversions. The enzymes, derived from an organism or cell culture that catalyzes substrate conversions, are used for the synthesis of target products in a mild temperature, pH, substrate specificity under suitable reaction. Therefore, it is highly important to explore and improve the highly active enzymes for increased productivity. Besides, the enzyme-based processing technologies with the advantages of high efficiency, energy-saving, clean, and sustainability shed light on its huge potential in green technology. For instance, the enzymatical conversion of waste-based stocks into value-added products is becoming a hot topic in environmental protection.
Enzymes have great industrial potential as biocatalysts, which have attracted much attention on their extensive applications. This research topic aims to publish novel research contributions on the exploration, modification, and application of high-active enzymes. In detail, the research topic intends to include research contributions dealing with the development of enzyme immobilization, enhancement of enzymatic stability and bioactivity, optimization of enzymatic conversion systems, synthetic biology through engineered enzymes, enzymatic-based productions for high value-added food additives, daily chemicals, fine chemicals, and other products are welcome. Alternatively, the utilization of enzymatic technologies to convert waste-based feedstocks into valuable products, to develop a cleaner, safer, and more energy-efficient process is encouraged.
1. Exploration and directional modification of highly active enzymes
2. Enzyme immobilization with enhanced stability and bioactivity
3. Novel enzymatic technology: construction and optimization for a green and efficient conversion system
4. Enzymatic preparation and production: high value-added food additives, daily chemicals, fine chemicals, and other products
5. Enzymatic processing technology: from waste feedstocks to high value-added products
6. Synthetic biology through newly engineered enzymes