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In Conjunction With: National Science Foundation Community College Innovation Challenge 2015 “Optimizing Genetic Engineering Technology for Increased Lipid.

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Presentation on theme: "In Conjunction With: National Science Foundation Community College Innovation Challenge 2015 “Optimizing Genetic Engineering Technology for Increased Lipid."— Presentation transcript:

1 Studying Culture Media for Improving Growth of Green Algae Botryococcus braunii

2 In Conjunction With: National Science Foundation Community College Innovation Challenge 2015 “Optimizing Genetic Engineering Technology for Increased Lipid Production in Green Algae (Botryococcus braunii)” Top ten finalists will present in Washington D.C. June 2015

3 Not Just Pond Scum Grows Fast High Biofuel Yields
High photosynthetic efficiency Consumes atmospheric and waste CO2 Does not compete with agriculture Purifies wastewater (Phytoremediation)

4 Botryococcus braunii Green Colonial Microalga
Promising candidate for biofuel production Accumulates a dry weight of 30% - 70% of hydrocarbons The slow growth rate of this particular species creates a barrier for its commercial development.

5 Research Question Hypothesis
What levels of nutrient concentrations in liquid medium will result in higher biomass yields? Hypothesis BG-11 will result in higher biomass yields based on its higher nutrient concentrations.

6 Medium Candidates Differences of significant levels of nutrient concentrations Specific purpose of each medium Most are designed for Blue-green algae Chu No.10, Chu No.13, Jaworski’s Medium (JM), and BG-11 Increasing efficiency increases the potential to become commercially developed as a biofuel resource This investigation will use specific green algae medium, non-specific medium, and blue-green algae specific medium

7 Preparation Stock algal cultures were grown in sealed 125 ml flasks using Chu No.10 medium as the nutrient supply Stock cultures were grown for 13 weeks on an orbital shaker ranging from rpm under 16:8 light: dark photoperiod Every 1-2 weeks, the cultures were transferred to fresh medium.

8

9 Procedure Three replicates of each medium Using Optical Density (OD)-
Initial OD was measured Twice a week OD was measured again Visual results were also recorded Homogenized Clumping Film Physiological changes

10 Data Red circles mark beginning of clumping

11 Chu No.10 Chu No. 13 BG-11 Jaworski’s Medium

12 Results Chu No. 13 remained the most homogenized
Chu No.13 had the greatest growth spike BG-11 continues to grow Chu No. 10 is first start showing physiological distress (yellow/orange)

13 What is the next step? Hydrocarbon analysis Physiological differences
Nile Red Stain HPLC UV Physiological differences Continue growing algae!

14 QUESTIONS?

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