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| ¸ÞŸÇ÷°½º³Ý(MetaFluxNet) 1.6 |
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- ÁöÇϺΠȯ°æ ¼³Á¤ : ±Ù±Ç¿Âµµ, pH, EC
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| How Many Trees? |
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To obtain the timber value of a large remote area, estimate the number of trees from a Landsat image-a problem in statistical sampling. |
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| MSW Learning Tool |
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- Waste charaterization
- Waste collection | Waste processing
- Landfills | Recycling | Composting | Incineration
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| PROFOOD |
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Á¤È®ÇÑ »ì±Õ, ¸ê±Õ, ³Ãµ¿, °ÇÁ¶¿Í °°Àº ½ÄÇ°ÀúÀå°øÁ¤À» Á¤È®ÇÏ°Ô ÁøÇàÇϱâ À§ÇÑ °øÇаè»ê ½Ã¹Ä·¹ÀÌ¼Ç ¶Ç´Â ½ÄÇ°°¡°ø°øÁ¤¿¡¼ ¿Âµµ, ½Àµµ, ¹Ì»ý¹° ¹× ¿µ¾çµî¿¡ Á¶°Ç¼³Á¤À» À§ÇÑ ¿¹ºñ°øÁ¤ Å×½ºÆ®¸¦ À§ÇÑ ½Ã¹Ä·¹ÀÌ¼Ç Åø
- Develop a numerical tool (finite element based) for an accurate simulation of food preservation processes such as: Sterilization ,Pasteurization, Freezing, Drying
- Post-processing of results: temperature evolution, moisture evolution, microorganisms and nutrients kinetics, etc.
- Pre-defined geometry data-base for canning industry
- User friendly interface for the definition of: Process preservation parameters , Nutrients and micro-organisms kinetics parameters , Food macromolecular composition , Environment characterization: Temperature and H.R.
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| Virtual Bacterial Identification Lab |
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| Basic Steps |
- Prepare a sample from a patient and isolate whole bacterial DNA.
- Make many copies of the desired piece of DNA.
- Sequence the DNA.
- Analyze the sequence and identify the bacteria.
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| Objectives |
- What does PCR do, how does it work, and why is it useful?
- How do you separate the desired DNA from all others?
- How does an automatic DNA sequencer work?
- Why is it possible to use a DNA sequence to identify bacteria?
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| Virtual Microbiology Lab |
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- General Introduction
- Laboratory safety
- Introduction to Diagnostic Laboratory Exercise
- Specific Instructions
- Day-to-dayPlan
- Case histories
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| Virtual Transgenic Fly Lab |
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The lab will familiarize you with the science and techniques used to make transgenic flies. Transgenic organisms, which contain DNA that is inserted experimentally, are used to study many biological processes. In this lab, you will create a transgenic fly to study circadian rhythms. The fly glows only when a certain gene involved in circadian rhythms is activated. After making the glowing fly, you will use it to explore basic principles of circadian biology and genetics. |
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| Basic Steps |
Make transgenic flies
- Prepare DNA that will be incorporated into the fly genome
- Prepare fly embryos
- Inject fly embryos with DNA
- Breed flies
- Select transgenic progeny
- Examine light output from transgenic adults
Make transgenic flies
- Measure per-luc gene expression (that is, light emissions) under different light-dark conditions
- Examine different fly body parts for per-luc expression
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| WebBeePop |
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how honey bee population dynamics depends on the weather |
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| Basic Steps |
- Enter the initial settings ( colony size/ city)
- Choose a critical event (life goes on/swarm/ chalkbrood/ resource depletion/ queen superc edure/ pesticide)
- Run WebBeePop
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