Edinburgh/Yoghurt/Applications
From 2007.igem.org
(→Why Vanillin?) |
(→Why Vanillin?) |
||
| Line 6: | Line 6: | ||
====Why Vanillin?==== | ====Why Vanillin?==== | ||
| + | {| align=left | ||
| + | |- | ||
| + | | | ||
[[Image:Vanilla plant.jpg|200 px]] | [[Image:Vanilla plant.jpg|200 px]] | ||
| + | |} | ||
Vanillin is the major contributer to vanilla flavouring, which is utilised in a multitude of different products. These range from scents and fragrances, to cakes, orange juice and ice cream! | Vanillin is the major contributer to vanilla flavouring, which is utilised in a multitude of different products. These range from scents and fragrances, to cakes, orange juice and ice cream! | ||
Revision as of 11:41, 2 October 2007
Introduction | Applications | Objectives | Design | Modelling | Wet Lab | References
Contents |
Why Vanillin?
|
|
Vanillin is the major contributer to vanilla flavouring, which is utilised in a multitude of different products. These range from scents and fragrances, to cakes, orange juice and ice cream!
Vanilla flavouring is traditionally extracted from the orchid Vanilla planifolia, first discovered in Mexico, and now widely grown throughout the Americas and tropics.
The world market for natural vanilla flavouring is currently worth over $1 billion per annum, and each kilogram of vanilla extract can fetch as much as $3000!
Our project will enable the natural synthesis of vanillin (the major constituent of vanillia flavouring), as the aromatic compound will be produced by a living organism, and not chemical synthesis. Potentially, the successful and efficient production of vanillin from a natural metabolite (tyrosine) could lead to a much cheaper industrial scale method of natural vanilla flavour production.
Bonus's of Zeaxanthanin Pathway
The carotenoids produced by the zeaxanthin pathway are not just pretty pigments as they also have several world renound health benefits!
The properties of both B-carotene and lycopene have been avidly studied by scientists, a few examples of these are given below. By encorporating these carotenoids into our yoghurt, we are not only using healthy food colourings, but we are also helping to protect future consumers from diseases such as cancer, heart disease and nyctalopia (poor dark adaptation).
B-carotene
B-carotene is converted into vitamin A by the body. Vitamin A is essential for vision, immune response, epithelial cell growth and repair, bone growth, reproduction and maintenance of the surface linings of the eyes, to name a few examples.
Deficiency in vitamin A can cause:
- Abnormal dark adaptation
- dry skin, hair & broken fingernails
- decreased resistance to infections
Lycopene
Lycopene a carotenoid, with red pigmentation, is an intermediate in the zeaxanthin pathway. Several studies have reported the benifits of having a high dietry intake of lycopene, a few examples of which are given below.
Lycopene is reported to be an extremally benificial antioxident:
| "its unique structural and biologic properties enable lycopene to prevent free-radical damage to cells caused by reactive oxygen species, thus acting as a potent antioxidant" (Ansari & Ansari, 2005) |
Lycopene has also been inversely related with the risk of chronic disease, including prostate cancer and heart disease:
| "Dietary intakes of tomatoes and tomato products containing lycopene have been shown to be associated with decreased risk of chronic diseases such as cancer and cardiovascular diseases in several recent studies" (A Venket Rao, 2000) |
Introduction | Applications | Objectives | Design | Modelling | Wet Lab | References
