Post by alankey on Nov 19, 2008 15:21:04 GMT -5
i notice an abundance of carbohydrates and plastics within the biological systems of morgellons sufferers
www.rumormillnews.com/cgi-bin/archive.cgi?noframes;read=114071
,there obviously is a link and that link is that you can form plastics from carbohydrates
www.biobasics.gc.ca/english/View.asp?x=790
"What are Biopolymers and Bioplastics?
Biopolymers and bioplastics go by many different names. They are often referred to as bio-based plastics and polymers, or as biodegradable plastics or polymers. They are defined below:
Biopolymers are polymers which are present in, or created by, living organisms. These include polymers from renewable resources that can be polymerized to create bioplastics.
Bioplastics are plastics manufactured using biopolymers, and are biodegradable.
Biopolymers and bioplastics are not new products. Henry Ford developed a method of manufacturing plastic car parts from soybeans in the mid-1900s. However, World War II side-tracked the production of bioplastic cars. Today, bioplastics are gaining popularity once again as new manufacturing techniques developed through biotechnology are being applied to their production.
Types of Biopolymers
There are two main types of biopolymers: those that come from living organisms; and, those which need to be polymerized but come from renewable resources. Both types are used in the production of bioplastics.
Biopolymers From Living Organisms
These biopolymers are present in, or created by, living organisms. These include carbohydrates and proteins. These can be used in the production of plastic for commercial purposes. Examples are listed in the table below.
Biopolymer Natural Source What is it?
Cellulose Wood, cotton, corn, wheat, and others This polymer is made up of glucose. It is the main component of plant cell walls.
Soy protein Soybeans Protein which naturally occurs in the soy plant.
Starch Corn, potatoes, wheat, tapioca, and others This polymer is one way carbohydrates are stored in plant tissue. It is a polymer made up of glucose. It is not found in animal tissues.
Polyesters Bacteria These polyesters are created through naturally occurring chemical reactions that are carried out by certain types of bacteria.
Polymerizable Molecules
These molecules come from renewable natural resources, and can be polymerized to be used in the manufacture of biodegradable plastics.
Biopolymer Natural Source What is it?
Lactic Acid Beets, corn, potatoes, and others Produced through fermentation of sugar feedstocks, such as beets, and by converting starch in corn, potatoes, or other starch sources. It is polymerized to produce polylactic acid -- a polymer that is used to produce plastic.
Triglycerides Vegetable oils These form a large part of the storage lipids found in plant and animal cells. Vegetable oils are one possible source of triglycerides that can be polymerized into plastics.
The Science – How are Biopolymers and Bioplastics Made?
There are two methods being researched and used to produce plastics from plants. The first uses fermentation, and the second relies on the plant to become the factory for plastic production. These two methods are outlined below.
Using Fermentation to Produce Plastics
Fermentation, used for hundreds of years by humans, is even more powerful when coupled with new biotechnology techniques. Fermentation is the use of microorganisms to break down organic substances in the absence of oxygen. Today, fermentation can be carried out with genetically engineered microorganisms, specially designed for the conditions under which fermentation takes place, and for the specific substance that is being broken down by the microorganism. There are two ways fermentation can be used to create biopolymers and bioplastics:
Bacterial Polyester Fermentation – Bacteria are one group of microorganisms that can be used in the fermentation process. Fermentation, in fact, is the process by which bacteria can be used to create polyesters. Bacteria called Ralstonia eutropha are used to do this. The bacteria use the sugar of harvested plants, such as corn, to fuel their cellular processes. The by-product of these cellular processes is the polymer. The polymers are then separated from the bacterial cells.
Lactic Acid Fermentation – Lactic acid is fermented from sugar, much like the process used to directly manufacture polymers by bacteria. However, in this fermentation process, the final product of fermentation is lactic acid, rather than a polymer. After the lactic acid is produced, it is converted to polylactic acid using traditional polymerization processes.
Growing Plastics in Plants
Plants are becoming factories for the production of plastics. Researchers created a Arabidopis thaliana plant through genetic engineering. The plant contains the enzymes used by bacteria to create plastics. Bacteria create the plastic through the conversion of sunlight into energy. The researchers have transferred the gene that codes for this enzyme into the plant, as a result the plant produces plastic through its cellular processes. The plant is harvested and the plastic is extracted from it using a solvent. The liquid resulting from this process is distilled to separate the solvent from the plastic.
Biotechnology and Biopolymers and Bioplastics
Biotechnology is driving the production of new bioplastics. Biotechnology techniques used to produce bioplastics include fermentation, and genetic engineering. For example, fermentation is used to release the cellulose from plants, so the cellulose can be used to create plastics. Also, genetic engineering can be used to create plants, such as soybean, specifically designed to be used as a raw material for the production of bioplastics.
Current Research Areas in Biopolymers and Bioplastics
Improving efficiency is a major concern for the production of plastics and bioplastics. Currently, fossil fuel is still used as an energy source during the production process. This has raised questions by some regarding how much fossil fuel is actually saved by manufacturing bioplastics. Only a few processes have emerged that actually use less energy in the production process. Therefore, researchers are still working on refining the processes used in order to make bioplastics viable alternatives to petrochemical plastics.
Energy use is not the only concern when it comes to biopolymers and bioplastics. There are also concerns about how to balance the need to grow plants for food, and the need to grow plants for use as raw materials. Agricultural space needs to be shared. Researchers are looking into creating a plant that can be used for food, but also as feedstock for plastic production. One group is attempting to genetically engineer corn to contain the bacterial enzyme responsible for plastic production. Eventually, they are hoping to create the plant in a way which would restrict the plastic production to the stem, and leaves of the plant. This would leave the edible part of the corn plastic free. The edible part of the corn would be used as food, or as livestock feed. The plastic would be removed from the remaining part of the corn plant.
Sustainable Development and Biopolymers and Bioplastics
Biopolymers and bioplastics are the main components in creating a sustainable plastics industry. These products reduce the dependence on non-renewable fossil fuels, and are easily biodegradable. Together, this greatly limits the environmental impacts of plastic use and manufacture. Also, characteristics such as being biodegradable make plastics more acceptable for long term use by society. It is likely that in the long term, these products will mean plastics will remain affordable, even as fossil fuel reserves diminish."
i like the bacterial fermentation method,since the plastics and carbohydrates are found in the stomachs of morgellons sufferers,it may by a possibility that plastics are being fermented from carbohydrates somewhere within the digestive system
whats more the polymer esk fibres seen in morgellons are easily created by the above bacterial fermentaion process.
www.rumormillnews.com/cgi-bin/archive.cgi?noframes;read=114071
,there obviously is a link and that link is that you can form plastics from carbohydrates
www.biobasics.gc.ca/english/View.asp?x=790
"What are Biopolymers and Bioplastics?
Biopolymers and bioplastics go by many different names. They are often referred to as bio-based plastics and polymers, or as biodegradable plastics or polymers. They are defined below:
Biopolymers are polymers which are present in, or created by, living organisms. These include polymers from renewable resources that can be polymerized to create bioplastics.
Bioplastics are plastics manufactured using biopolymers, and are biodegradable.
Biopolymers and bioplastics are not new products. Henry Ford developed a method of manufacturing plastic car parts from soybeans in the mid-1900s. However, World War II side-tracked the production of bioplastic cars. Today, bioplastics are gaining popularity once again as new manufacturing techniques developed through biotechnology are being applied to their production.
Types of Biopolymers
There are two main types of biopolymers: those that come from living organisms; and, those which need to be polymerized but come from renewable resources. Both types are used in the production of bioplastics.
Biopolymers From Living Organisms
These biopolymers are present in, or created by, living organisms. These include carbohydrates and proteins. These can be used in the production of plastic for commercial purposes. Examples are listed in the table below.
Biopolymer Natural Source What is it?
Cellulose Wood, cotton, corn, wheat, and others This polymer is made up of glucose. It is the main component of plant cell walls.
Soy protein Soybeans Protein which naturally occurs in the soy plant.
Starch Corn, potatoes, wheat, tapioca, and others This polymer is one way carbohydrates are stored in plant tissue. It is a polymer made up of glucose. It is not found in animal tissues.
Polyesters Bacteria These polyesters are created through naturally occurring chemical reactions that are carried out by certain types of bacteria.
Polymerizable Molecules
These molecules come from renewable natural resources, and can be polymerized to be used in the manufacture of biodegradable plastics.
Biopolymer Natural Source What is it?
Lactic Acid Beets, corn, potatoes, and others Produced through fermentation of sugar feedstocks, such as beets, and by converting starch in corn, potatoes, or other starch sources. It is polymerized to produce polylactic acid -- a polymer that is used to produce plastic.
Triglycerides Vegetable oils These form a large part of the storage lipids found in plant and animal cells. Vegetable oils are one possible source of triglycerides that can be polymerized into plastics.
The Science – How are Biopolymers and Bioplastics Made?
There are two methods being researched and used to produce plastics from plants. The first uses fermentation, and the second relies on the plant to become the factory for plastic production. These two methods are outlined below.
Using Fermentation to Produce Plastics
Fermentation, used for hundreds of years by humans, is even more powerful when coupled with new biotechnology techniques. Fermentation is the use of microorganisms to break down organic substances in the absence of oxygen. Today, fermentation can be carried out with genetically engineered microorganisms, specially designed for the conditions under which fermentation takes place, and for the specific substance that is being broken down by the microorganism. There are two ways fermentation can be used to create biopolymers and bioplastics:
Bacterial Polyester Fermentation – Bacteria are one group of microorganisms that can be used in the fermentation process. Fermentation, in fact, is the process by which bacteria can be used to create polyesters. Bacteria called Ralstonia eutropha are used to do this. The bacteria use the sugar of harvested plants, such as corn, to fuel their cellular processes. The by-product of these cellular processes is the polymer. The polymers are then separated from the bacterial cells.
Lactic Acid Fermentation – Lactic acid is fermented from sugar, much like the process used to directly manufacture polymers by bacteria. However, in this fermentation process, the final product of fermentation is lactic acid, rather than a polymer. After the lactic acid is produced, it is converted to polylactic acid using traditional polymerization processes.
Growing Plastics in Plants
Plants are becoming factories for the production of plastics. Researchers created a Arabidopis thaliana plant through genetic engineering. The plant contains the enzymes used by bacteria to create plastics. Bacteria create the plastic through the conversion of sunlight into energy. The researchers have transferred the gene that codes for this enzyme into the plant, as a result the plant produces plastic through its cellular processes. The plant is harvested and the plastic is extracted from it using a solvent. The liquid resulting from this process is distilled to separate the solvent from the plastic.
Biotechnology and Biopolymers and Bioplastics
Biotechnology is driving the production of new bioplastics. Biotechnology techniques used to produce bioplastics include fermentation, and genetic engineering. For example, fermentation is used to release the cellulose from plants, so the cellulose can be used to create plastics. Also, genetic engineering can be used to create plants, such as soybean, specifically designed to be used as a raw material for the production of bioplastics.
Current Research Areas in Biopolymers and Bioplastics
Improving efficiency is a major concern for the production of plastics and bioplastics. Currently, fossil fuel is still used as an energy source during the production process. This has raised questions by some regarding how much fossil fuel is actually saved by manufacturing bioplastics. Only a few processes have emerged that actually use less energy in the production process. Therefore, researchers are still working on refining the processes used in order to make bioplastics viable alternatives to petrochemical plastics.
Energy use is not the only concern when it comes to biopolymers and bioplastics. There are also concerns about how to balance the need to grow plants for food, and the need to grow plants for use as raw materials. Agricultural space needs to be shared. Researchers are looking into creating a plant that can be used for food, but also as feedstock for plastic production. One group is attempting to genetically engineer corn to contain the bacterial enzyme responsible for plastic production. Eventually, they are hoping to create the plant in a way which would restrict the plastic production to the stem, and leaves of the plant. This would leave the edible part of the corn plastic free. The edible part of the corn would be used as food, or as livestock feed. The plastic would be removed from the remaining part of the corn plant.
Sustainable Development and Biopolymers and Bioplastics
Biopolymers and bioplastics are the main components in creating a sustainable plastics industry. These products reduce the dependence on non-renewable fossil fuels, and are easily biodegradable. Together, this greatly limits the environmental impacts of plastic use and manufacture. Also, characteristics such as being biodegradable make plastics more acceptable for long term use by society. It is likely that in the long term, these products will mean plastics will remain affordable, even as fossil fuel reserves diminish."
i like the bacterial fermentation method,since the plastics and carbohydrates are found in the stomachs of morgellons sufferers,it may by a possibility that plastics are being fermented from carbohydrates somewhere within the digestive system
whats more the polymer esk fibres seen in morgellons are easily created by the above bacterial fermentaion process.