Abstract: Described here is a method for increasing the transfer of a gas substrate in microbial fermentation, comprising incubating an emulsion comprising an oil phase and an aqueous phase droplet dispersed in the oil phase, and supplying the gas substrate to the oil phase, wherein the aqueous phase droplet comprises a microorganism, and wherein the emulsion is stabilized by a surfactant or an amphiphilic particle that is adsorbed to an interface of the oil phase and the aqueous phase. Also described is an emulsion for microbial fermentation, comprises an oil phase and an aqueous phase droplet dispersed in the oil phase, wherein the aqueous phase droplet comprises a microorganism, wherein the emulsion comprises a gas substrate externally-supplied to the oil phase, and wherein the emulsion is stabilized by a surfactant or an amphiphilic particle that is adsorbed to an interface of the oil phase and the aqueous phase.

Abstract: Described here is a method for increasing the transfer of a gas substrate in microbial fermentation, comprising incubating an emulsion comprising an oil phase and an aqueous phase droplet dispersed in the oil phase, and supplying the gas substrate to the oil phase, wherein the aqueous phase droplet comprises a microorganism, and wherein the emulsion is stabilized by a surfactant or an amphiphilic particle that is adsorbed to an interface of the oil phase and the aqueous phase. Also described is an emulsion for microbial fermentation, comprises an oil phase and an aqueous phase droplet dispersed in the oil phase, wherein the aqueous phase droplet comprises a microorganism, wherein the emulsion comprises a gas substrate externally-supplied to the oil phase, and wherein the emulsion is stabilized by a surfactant or an amphiphilic particle that is adsorbed to an interface of the oil phase and the aqueous phase.

Abstract: A method of producing polyhydroxyalkanoic acid (PHA)-producing biomass is provided that includes obtaining a methane-oxidizing inoculum, flushing the methane-oxidizing inoculum with natural gas and oxygen, amending the flushed methane-oxidizing inoculum with a fresh growth medium, using a non-aseptic bioreactor for growing a PHA-producing biomass, where the non-aseptic bioreactor is seeded with the amended methane-oxidizing inoculum, where a natural gas and oxygen mixture is added to the non-aseptic bioreactor, where a growth medium comprising ammonium and nutrients required for exponential growth is added to the non-aseptic bioreactor, harvesting a portion of the methane-oxidizing biomass and incubating the harvested portion in the absence of nitrogen and with the natural gas and oxygen mixture, where a PHA-enriched biomass is produced, purifying PHA from the PHA-enriched biomass, and adding the fresh growth medium and the natural gas and oxygen mixture to the bioreactor to re-grow the methane-oxidizing inoc

Abstract: A method of producing polyhydroxyalkanoic acid (PHA)-producing biomass that includes using a first bioreactor for growth of methanotrophic biomass, flushing the methanotrophic biomass with a CH4:O2 mixture and providing nutrients needed for sustained cell division, removing a portion of the flushed biomass, where the remainder is retained in the first bioreactor as starter biomass for continuous cycles of cell replication, transferring the removed biomass to a second bioreactor, incubating the removed biomass in the second bioreactor with a CH4:O2 mixture or CH3OH:O2 mixture in the absence of sufficient nutrients for cell replication and in the presence of a co-substrate, and harvesting PHA-containing cells from the second bioreactor.