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Biochemical and Biomolecular Engineering Commons™
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- Biofuel (1)
- Biorefinery (1)
- Design of Experiment (1)
- Dissociation (1)
- Ester biosynthesis (1)
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- Fusion Protein (1)
- Genome wide association (1)
- Hydrogen Evolution (1)
- Klason Lignin (1)
- Lignin (1)
- Metabolic engineering (1)
- Microbial engineering (1)
- Modularity (1)
- Nuclear magnetic resonance (1)
- Photosystem I (1)
- Phycobilisome (1)
- Populus (1)
- Pretreatment (1)
- Protein engineering (1)
- Response Surface (1)
- Synthetic biology (1)
- Publication
Articles 1 - 4 of 4
Full-Text Articles in Biochemical and Biomolecular Engineering
Characterization Of Lignin Structural Variability And The Associated Application In Genome Wide Association Studies, Nathan D. Bryant
Characterization Of Lignin Structural Variability And The Associated Application In Genome Wide Association Studies, Nathan D. Bryant
Doctoral Dissertations
Poplar (Populus sp.) is a promising biofuel feedstock due to advantageous features such as fast growth, the ability to grow on marginal land, and relatively low lignin content. However, there is tremendous variability associated with the composition of biomass. Understanding this variability, especially in lignin, is crucial to developing and implementing financially viable, integrated biorefineries. Although lignin is typically described as being comprised of three primary monolignols (syringyl, guaiacyl, p-hydroxyphenyl), it is a highly irregular biopolymer that can incorporate non-canonical monolignols. It is also connected by a variety of interunit linkages, adding to its complexity. Secondary cell wall …
Engineering Modularity Of Ester Biosynthesis Across Biological Scales, Hyeongmin Seo
Engineering Modularity Of Ester Biosynthesis Across Biological Scales, Hyeongmin Seo
Doctoral Dissertations
Metabolic engineering and synthetic biology enable controlled manipulation of whole-cell biocatalysts to produce valuable chemicals from renewable feedstocks in a rapid and efficient manner, helping reduce our reliance on the conventional petroleum-based chemical synthesis. However, strain engineering process is costly and time-consuming that developing economically competitive bioprocess at industrial scale is still challenging. To accelerate the strain engineering process, modular cell engineering has been proposed as an innovative approach that harnesses modularity of metabolism for designing microbial cell factories. It is important to understand biological modularity and to develop design principles for effective implementation of modular cell engineering. In this …
Lignin Maximization: Analyzing The Impact Of Different Feedstocks And Feedstock Ratios Using Organosolv Fractionation, Marc Banholzer
Lignin Maximization: Analyzing The Impact Of Different Feedstocks And Feedstock Ratios Using Organosolv Fractionation, Marc Banholzer
Masters Theses
Over-exploitation of fossil fuels coupled with increasing pressure to reduce carbon emissions are prompting a transition from conventional petrochemical feedstocks to sustainable and renewable sourced carbon. The use of lignocellulosic biomass as a feedstock for integrated biorefining is of current high interest, as separation into its component parts affords process streams of cellulose, hemicellulose and lignin, each of which can serve as a starting point for the production of biobased chemicals and fuels. Given the large number of potential sources of lignocellulosic feedstocks, the biorefinery will need to adapt to the supplies available over a normal growing season. Of particular …
Capturing More Light: Phycobilisome Characterization For Increased Hydrogen Production Efficiency, Paul Abraham Willard
Capturing More Light: Phycobilisome Characterization For Increased Hydrogen Production Efficiency, Paul Abraham Willard
Masters Theses
Alternative energy and biofuels are a growing area of research. The demand for more and clean energy is ever increasing, but the current technology is inefficient, expensive, and incapable of meeting the demands of the current market. Hydrogen is a potential future fuel, as it is both clean and renewable, but its formation through conventional means is costly and inefficient. Photosynthesis can be utilized for the formation of hydrogen, which can then serve as a convenient and renewable biofuel. Photosynthetic hydrogen evolution is observed in vitro, but the current photosystem design is not very versatile and optimized to use …