Microbial Electrophotosynthesis

Petra Fromme (Inventor), Ana Moore (Inventor), Thomas Moore (Inventor), Bruce Rittmann (Inventor), Cesar Torres (Inventor), Willem Vermaas (Inventor)

Research output: Patent

Abstract

While photosynthetic microorganisms offer a promising route to generate sustainable transportation fuels and products using solar energy, boosting their photosynthetic efficiency above normal levels (20% for converting photon energy to electricity. However, current artificial systems have yet to realize the capacity of photosynthesis to produce complex molecules, high value products and high energy-density transportation fuels. Researchers at Arizona State University (ASU) and the Biodesign Institute at ASU have modified a strain of cyanobacteria to utilize photovoltaic (PV) electricity to stimulate growth in a technology called Microbial Electro-Photosynthesis (MEPS). Specially designed chemical redox mediators shuttle electrons from a cathode directly into the photosynthetic electron transport chain. Light energy from photosynthesis is used to drive carbon fixation, yielding biomass and complex, high energy transportation fuel feedstock, which are not efficiently generated by microorganisms using electricity alone. Potential Applications MEPS technology enables numerous products of commercial interest, which are naturally occurring or engineered within photosynthetic organisms, including: High-density transportation fuels Human and animal supplements Cosmetics Agrochemicals Therapeutics Plastics Specialty Chemicals Benefits and Advantages PV captures about twice the number of photons compared to capture by photosynthetic microbes alone The integrated MEPS bio + PV system could increase solar-to-fuel and solar-to-product conversion efficiency to >25% Improves productivity of oxygen sensitive metabolic processes Improves light utilization to allow cultures to reach higher densities Reduces downstream dewatering and harvesting costs Strain facilitates genetic engineering of new metabolic pathways to produce novel products and optimize expression yields Utilizes electricity from any source, including wind, hydro, and geothermal Can be easily integrated into standard photobioreactor designs Download Original PDF For more information about the inventor(s) and their research, please see Dr. Fromme's laboratory webpage Dr. Rittmann's laboratory webpage Dr. Thomas Moore's laboratory webpage Dr. Ana Moore's laboratory webpage Dr. Vermaas' laboratory webpage
Original languageEnglish (US)
StatePublished - Jul 25 2014

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Photosynthesis
Electricity
Microorganisms
Photons
Photobioreactors
Genetic engineering
Cosmetics
Dewatering
Solar energy
Feedstocks
Conversion efficiency
Animals
Biomass
Cathodes
Productivity
Plastics
Molecules
Carbon
Oxygen
Electrons

Cite this

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title = "Microbial Electrophotosynthesis",
abstract = "While photosynthetic microorganisms offer a promising route to generate sustainable transportation fuels and products using solar energy, boosting their photosynthetic efficiency above normal levels (20{\%} for converting photon energy to electricity. However, current artificial systems have yet to realize the capacity of photosynthesis to produce complex molecules, high value products and high energy-density transportation fuels. Researchers at Arizona State University (ASU) and the Biodesign Institute at ASU have modified a strain of cyanobacteria to utilize photovoltaic (PV) electricity to stimulate growth in a technology called Microbial Electro-Photosynthesis (MEPS). Specially designed chemical redox mediators shuttle electrons from a cathode directly into the photosynthetic electron transport chain. Light energy from photosynthesis is used to drive carbon fixation, yielding biomass and complex, high energy transportation fuel feedstock, which are not efficiently generated by microorganisms using electricity alone. Potential Applications MEPS technology enables numerous products of commercial interest, which are naturally occurring or engineered within photosynthetic organisms, including: High-density transportation fuels Human and animal supplements Cosmetics Agrochemicals Therapeutics Plastics Specialty Chemicals Benefits and Advantages PV captures about twice the number of photons compared to capture by photosynthetic microbes alone The integrated MEPS bio + PV system could increase solar-to-fuel and solar-to-product conversion efficiency to >25{\%} Improves productivity of oxygen sensitive metabolic processes Improves light utilization to allow cultures to reach higher densities Reduces downstream dewatering and harvesting costs Strain facilitates genetic engineering of new metabolic pathways to produce novel products and optimize expression yields Utilizes electricity from any source, including wind, hydro, and geothermal Can be easily integrated into standard photobioreactor designs Download Original PDF For more information about the inventor(s) and their research, please see Dr. Fromme's laboratory webpage Dr. Rittmann's laboratory webpage Dr. Thomas Moore's laboratory webpage Dr. Ana Moore's laboratory webpage Dr. Vermaas' laboratory webpage",
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TY - PAT

T1 - Microbial Electrophotosynthesis

AU - Fromme, Petra

AU - Moore, Ana

AU - Moore, Thomas

AU - Rittmann, Bruce

AU - Torres, Cesar

AU - Vermaas, Willem

PY - 2014/7/25

Y1 - 2014/7/25

N2 - While photosynthetic microorganisms offer a promising route to generate sustainable transportation fuels and products using solar energy, boosting their photosynthetic efficiency above normal levels (20% for converting photon energy to electricity. However, current artificial systems have yet to realize the capacity of photosynthesis to produce complex molecules, high value products and high energy-density transportation fuels. Researchers at Arizona State University (ASU) and the Biodesign Institute at ASU have modified a strain of cyanobacteria to utilize photovoltaic (PV) electricity to stimulate growth in a technology called Microbial Electro-Photosynthesis (MEPS). Specially designed chemical redox mediators shuttle electrons from a cathode directly into the photosynthetic electron transport chain. Light energy from photosynthesis is used to drive carbon fixation, yielding biomass and complex, high energy transportation fuel feedstock, which are not efficiently generated by microorganisms using electricity alone. Potential Applications MEPS technology enables numerous products of commercial interest, which are naturally occurring or engineered within photosynthetic organisms, including: High-density transportation fuels Human and animal supplements Cosmetics Agrochemicals Therapeutics Plastics Specialty Chemicals Benefits and Advantages PV captures about twice the number of photons compared to capture by photosynthetic microbes alone The integrated MEPS bio + PV system could increase solar-to-fuel and solar-to-product conversion efficiency to >25% Improves productivity of oxygen sensitive metabolic processes Improves light utilization to allow cultures to reach higher densities Reduces downstream dewatering and harvesting costs Strain facilitates genetic engineering of new metabolic pathways to produce novel products and optimize expression yields Utilizes electricity from any source, including wind, hydro, and geothermal Can be easily integrated into standard photobioreactor designs Download Original PDF For more information about the inventor(s) and their research, please see Dr. Fromme's laboratory webpage Dr. Rittmann's laboratory webpage Dr. Thomas Moore's laboratory webpage Dr. Ana Moore's laboratory webpage Dr. Vermaas' laboratory webpage

AB - While photosynthetic microorganisms offer a promising route to generate sustainable transportation fuels and products using solar energy, boosting their photosynthetic efficiency above normal levels (20% for converting photon energy to electricity. However, current artificial systems have yet to realize the capacity of photosynthesis to produce complex molecules, high value products and high energy-density transportation fuels. Researchers at Arizona State University (ASU) and the Biodesign Institute at ASU have modified a strain of cyanobacteria to utilize photovoltaic (PV) electricity to stimulate growth in a technology called Microbial Electro-Photosynthesis (MEPS). Specially designed chemical redox mediators shuttle electrons from a cathode directly into the photosynthetic electron transport chain. Light energy from photosynthesis is used to drive carbon fixation, yielding biomass and complex, high energy transportation fuel feedstock, which are not efficiently generated by microorganisms using electricity alone. Potential Applications MEPS technology enables numerous products of commercial interest, which are naturally occurring or engineered within photosynthetic organisms, including: High-density transportation fuels Human and animal supplements Cosmetics Agrochemicals Therapeutics Plastics Specialty Chemicals Benefits and Advantages PV captures about twice the number of photons compared to capture by photosynthetic microbes alone The integrated MEPS bio + PV system could increase solar-to-fuel and solar-to-product conversion efficiency to >25% Improves productivity of oxygen sensitive metabolic processes Improves light utilization to allow cultures to reach higher densities Reduces downstream dewatering and harvesting costs Strain facilitates genetic engineering of new metabolic pathways to produce novel products and optimize expression yields Utilizes electricity from any source, including wind, hydro, and geothermal Can be easily integrated into standard photobioreactor designs Download Original PDF For more information about the inventor(s) and their research, please see Dr. Fromme's laboratory webpage Dr. Rittmann's laboratory webpage Dr. Thomas Moore's laboratory webpage Dr. Ana Moore's laboratory webpage Dr. Vermaas' laboratory webpage

M3 - Patent

ER -