Difference between revisions of "Team:Cornell/Experiments"

Oxyponics was conceived in the summer of 2017 by Cornell iGEM - a synthetic biology engineering project team composed of 36 undergraduate students. The company created a toolkit to optimize redox state by controlling the amount of reactive oxygen species in the environment. Utilizing the research conducted by the team throughout 2017, Oxyponics created a novel biosensor that couples a redox-sensitive fluorescent protein and an optogenetic circuit to a spectrometric receiver. This allows for a dual reporter-response functionality that greatly enhances versatility and sensitivity over traditional biosensor systems. With the development of an effective large-scale sensing system to monitor plants and track data, the optimal level of oxidative stress that can be determined for the plant systems. Members of the team communicated with local farmers to learn more about Through the feedback of farmers themselves, we created Oxyponics, which couples fluorescent bacteria with a camera-rail system for imaging, to provide exactly the large-scale blanket-type sensing that conventional redox probes cannot.

Oxyponics was conceived in the summer of 2017 by Cornell iGEM - a synthetic biology engineering project team composed of 36 undergraduate students. The company created a toolkit to optimize redox state by controlling the amount of reactive oxygen species in the environment. Utilizing the research conducted by the team throughout 2017, Oxyponics created a novel biosensor that couples a redox-sensitive fluorescent protein and an optogenetic circuit to a spectrometric receiver. This allows for a dual reporter-response functionality that greatly enhances versatility and sensitivity over traditional biosensor systems. With the development of an effective large-scale sensing system to monitor plants and track data, the optimal level of oxidative stress that can be determined for the plant systems. Members of the team communicated with local farmers to learn more about Through the feedback of farmers themselves, we created Oxyponics, which couples fluorescent bacteria with a camera-rail system for imaging, to provide exactly the large-scale blanket-type sensing that conventional redox probes cannot.

Oxyponics was conceived in the summer of 2017 by Cornell iGEM - a synthetic biology engineering project team composed of 36 undergraduate students. The company created a toolkit to optimize redox state by controlling the amount of reactive oxygen species in the environment. Utilizing the research conducted by the team throughout 2017, Oxyponics created a novel biosensor that couples a redox-sensitive fluorescent protein and an optogenetic circuit to a spectrometric receiver. This allows for a dual reporter-response functionality that greatly enhances versatility and sensitivity over traditional biosensor systems. With the development of an effective large-scale sensing system to monitor plants and track data, the optimal level of oxidative stress that can be determined for the plant systems. Members of the team communicated with local farmers to learn more about Through the feedback of farmers themselves, we created Oxyponics, which couples fluorescent bacteria with a camera-rail system for imaging, to provide exactly the large-scale blanket-type sensing that conventional redox probes cannot.

Oxyponics was conceived in the summer of 2017 by Cornell iGEM - a synthetic biology engineering project team composed of 36 undergraduate students. The company created a toolkit to optimize redox state by controlling the amount of reactive oxygen species in the environment. Utilizing the research conducted by the team throughout 2017, Oxyponics created a novel biosensor that couples a redox-sensitive fluorescent protein and an optogenetic circuit to a spectrometric receiver. This allows for a dual reporter-response functionality that greatly enhances versatility and sensitivity over traditional biosensor systems. With the development of an effective large-scale sensing system to monitor plants and track data, the optimal level of oxidative stress that can be determined for the plant systems. Members of the team communicated with local farmers to learn more about Through the feedback of farmers themselves, we created Oxyponics, which couples fluorescent bacteria with a camera-rail system for imaging, to provide exactly the large-scale blanket-type sensing that conventional redox probes cannot.

Oxyponics was conceived in the summer of 2017 by Cornell iGEM - a synthetic biology engineering project team composed of 36 undergraduate students. The company created a toolkit to optimize redox state by controlling the amount of reactive oxygen species in the environment. Utilizing the research conducted by the team throughout 2017, Oxyponics created a novel biosensor that couples a redox-sensitive fluorescent protein and an optogenetic circuit to a spectrometric receiver. This allows for a dual reporter-response functionality that greatly enhances versatility and sensitivity over traditional biosensor systems. With the development of an effective large-scale sensing system to monitor plants and track data, the optimal level of oxidative stress that can be determined for the plant systems. Members of the team communicated with local farmers to learn more about Through the feedback of farmers themselves, we created Oxyponics, which couples fluorescent bacteria with a camera-rail system for imaging, to provide exactly the large-scale blanket-type sensing that conventional redox probes cannot.

Oxyponics was conceived in the summer of 2017 by Cornell iGEM - a synthetic biology engineering project team composed of 36 undergraduate students. The company created a toolkit to optimize redox state by controlling the amount of reactive oxygen species in the environment. Utilizing the research conducted by the team throughout 2017, Oxyponics created a novel biosensor that couples a redox-sensitive fluorescent protein and an optogenetic circuit to a spectrometric receiver. This allows for a dual reporter-response functionality that greatly enhances versatility and sensitivity over traditional biosensor systems. With the development of an effective large-scale sensing system to monitor plants and track data, the optimal level of oxidative stress that can be determined for the plant systems. Members of the team communicated with local farmers to learn more about Through the feedback of farmers themselves, we created Oxyponics, which couples fluorescent bacteria with a camera-rail system for imaging, to provide exactly the large-scale blanket-type sensing that conventional redox probes cannot.