Fancy yourself a vegetarian or vegan?

Think that the label that says “organically grown” has anything to do with the packaging, storage, and transport of that product to stores?

What if I told you that cow, pig, and chicken collagen is now used in place of wax on your fruits and vegetables, among many other things much worse than you can probably imagine?

And what if then I told you, as with most atrocities that happen now-a-days, that this is all approved by the FDA…

Since the early 12th century, there has been a tradition of applying wax onto the skins of fruits and vegetables for longer storage life. Today, that tradition is being carried on with a whole new generation of chemicals and compounds that are genetically designed to accomplish the same goal. But in these modern times, the health and well-being of the consumer of that apple is not necessarily the goal of this unnatural, inorganic process.

Bottom line… your produce is being dipped and sprayed with an experimental host of holy horrors in the name of “food safety” and longer shelf-life. Prepare yourself to be shocked and amazed that our Federal agency that is designed to protect us, the Food and Drug Administration, is allowing these dangerous and unhealthy practices to be perpetrated on an unwitting public, all in the name of profits.

This video was recently posted to Youtube, showing a woman peeling off of her freshly bought supermarket romaine lettuce what appears to be a plastic coating, similar to the type one would peal off of the screen of a new electronic gadget. She has no idea what she has discovered…

Now, while this seems to be an almost incredible and hard to believe hoax, the truth is even stranger. Please read on…

For those of you that know of my writing, you know that I like to get right down to the nitty-gritty… the primary source. And so we will go right to what the FDA has to say about what this strange plastic-like substance is, and whether or not it approves of such food handling practices (which it does).

Here is the link for the FDA’s website, entitled:

“Chapter VI. Microbiological Safety of Controlled and Modified Atmosphere Packaging of Fresh and Fresh-Cut Produce – Analysis and Evaluation of Preventive Control Measures for the Control and Reduction/Elimination of Microbial Hazards on Fresh and Fresh-Cut Produce”.

New Link (July 2016): http://www.fda.gov/food/foodscienceresearch/safepracticesforfoodprocesses/ucm091368.htm

Old Broken Link: http://www.fda.gov/Food/ScienceResearch/ResearchAreas/SafePracticesforFoodProcesses/ucm091368.htm

Wow! That sounds so wonderfully official and scientific, doesn’t it?

So what are these “preventative control measures” as referred to in this report?

Well, for our purposes, since these measures are actually edible, let’s explore what the FDA approves for our fruits and vegetables to be dipped in and sprayed with for our own “safety”…

The report states:

This chapter addresses the use of modified atmosphere packaging and controlled atmosphere packaging for the preservation of fresh produce. There have been great technological advances in this area of preservation, particularly as it refers to improving the quality and shelf-stability of highly perishable food products, such as produce. However, when using these technologies, careful attention must be paid to the effect on the survival and growth of pathogenic organisms. This chapter focuses on food safety aspects of packaging technologies that are either commercially available or under investigation…

Over the past 20 years, there has been an enormous increase in the demand for fresh fruit and vegetable products that has required the industry to develop new and improved methods for maintaining food quality and extending shelf life…

One of the areas of research that has shown promise, and had success, is that of modified atmosphere packaging (MAP). This technique involves either actively or passively controlling or modifying the atmosphere surrounding the product within a package made of various types and/or combinations of films. In North America, one of the first applications of this technology for fresh-cut produce was introduced by McDonald’s (Brody 1995), which used MAP of lettuce in bulk-sized packages to distribute the product to retail outlets…

A modified atmosphere can be defined as one that is created by altering the normal composition of air (78% nitrogen, 21% oxygen, 0.03% carbon dioxide and traces of noble gases) to provide an optimum atmosphere for increasing the storage length and quality of food/produce (Moleyar and Narasimham 1994; Phillips 1996). This can be achieved by using controlled atmosphere storage (CAS) and/or active or passive modified atmosphere packaging (MAP).

The numerous film types used in MAP are listed in Table VI-2 (see below), and some commercially available MAP systems are listed in Table VI-3. Oxygen, CO 2 , and N 2 , are most often used in MAP/CAS (Parry 1993; Phillips 1996). Other gases such as nitrous and nitric oxides, sulphur dioxide, ethylene, chlorine (Phillips 1996), as well as ozone and propylene oxide (Parry 1993) have been suggested and investigated experimentally.

So was that plastic looking film being peeled off of that supermarket lettuce above actually one of many forms of modified atmosphere packaging? Was it dipped in or sprayed by a “MAP” chemical compound for “food safety”?

Lets read further into this FDA report…

1.3. Films used in MAP

Edible biodegradable coatings are yet another variant of the smart film technology, where a film is used as a coating and applied directly on the food…

The use of MAP for whole and fresh-cut produce involves careful selection of the film and package type for each specific product and package size . Effective MAP of produce requires consideration of the optimal gas concentration, product respiration rate, gas diffusion through the film, as well as the optimal storage temperature in order to achieve the most benefit for the product and consumer. In addition, when selecting an appropriate film, one has to take into account the protection provided, as well as the strength, sealability and clarity, machineability, ability to label, and the gas gradient formed by the closed film (Zagory 1995).

Recently, the long list of films and commercially available MAP systems has been augmented with the conception of both smart and edible packaging systems (Guilbert and others 1996; Phillips 1996). “Smart” or “intelligent” packaging is being used in the fresh-cut industry and includes indicators of time and temperature, gas composition, seal leakage, and food safety and quality (Rooney 2000). Some intelligent systems alter package oxygen and /or carbon dioxide permeability by sensing and responding to changes in temperature. Other smart films incorporate chemicals into packets placed in the packaging system, with no contact with the product; an example would be the use of O 2 scavengers with O 2 indicators. Another type of smart film, developed with food safety in mind, is currently undergoing testing. This novel system, when incorporated into a packaging film, uses an antibody detection system to detect pathogens, and expresses a positive finding as a symbol on the surface of the package, thereby alerting food handlers to the presence of pathogens. Although this technology shows promise, it is still in its infancy and comprehensive assessments have yet to be performed. Several limitations have been suggested with this technology; for example, it would not likely be able to detect pathogens at concentrations below 104 CFU/g or cm2 and would not detect pathogens within the product.

Edible biodegradable coatings are yet another variant of the smart film technology, where a film is used as a coating and applied directly on the food (Guilbert and others 1996; Francis and others 1999). Wax has been used in China since the 12th and 13th centuries as an edible coating to retard desiccation of citrus fruits, and in the last 30 years, edible films and coatings made from a variety of compounds have been reported. Guilbert and others (1996) and Baldwin (1994) have extensively reviewed some of the newer edible films (see Tables VI-3 and VI-5). These films are gaining popularity due to both environmental pollution and food safety concerns (Padgett and others 1998). However, a number of problems have also been associated with edible coatings. For example, modification of the internal gas composition of the product due to high CO 2 and low O 2 can cause problems such as anaerobic fermentation of apples and bananas, rapid weight loss of tomatoes, elevated levels of core flush for apples, rapid decay in cucumbers, and so on (Park and others 1994).

Edible films may consist of four basic materials: lipids, resins, polysaccharides and proteins (Baldwin and others 1995). Plasticizers such as glycerol as well as cross-linking agents, antimicrobials, antioxidants, and texture agents can be added to customize the film for a specific use (Guilbert and others 1996). Plasticizers have the specific effect of increasing water vapor permeability. Therefore, their addition must be considered when calculating the desired water vapor properties of each specific film, since too much moisture can create ideal growth conditions for some foodborne pathogens. The most common plasticizer used to cast edible films is food-grade polyethylene glycol, which is used to reduce film brittleness (Koelsch 1994).

What is polyethylene glycol?

Link – http://en.wikipedia.org/wiki/Polyethylene_glycol – which causes nephrotoxicity (renal problems)

Link – http://en.wikipedia.org/wiki/Nephrotoxicity

What is a plasticizer?

Plasticizers (UK = plasticisers) or dispersants are additives that increase the plasticity or fluidity of a material. The dominant applications are for plastics, especially polyvinyl chloride (PVC). The properties other materials are also improved when blended plasticizers including concrete, clays, and related products. The worldwide market for plasticizers in 2000 was estimated to be several million tons per year.

Plasticizers work by embedding themselves between the chains of polymers, spacing them apart (increasing the “free volume”), and thus significantly lowering the glass transition temperature for the plastic and making it softer. For plastics such as PVC, the more plasticizer added, the lower its cold flex temperature will be. This means that it will be more flexible and its durability will increase as a result of it. Some plasticizers evaporate and tend to concentrate in an enclosed space; the “new car smell” is caused mostly by plasticizers evaporating from the car interior.

Plasticizers make it possible to achieve improved compound processing characteristics, while also providing flexibility in the end-use product… Plasticizers also function as softeners, extenders, and lubricants, and play a significant role in rubber manufacturing.

Other uses include:

Continued…

Lipids, or waxes and oils, and resins such as shellac and wood rosin have been widely used for intact fruits and vegetables in two distinct forms, laminates and emulsions (Baldwin and others 1995). Lipid-based edible barriers are known for their low water vapor permeabilities. Koelsch (1994) found that the water vapor permeability of a cellulose-based emulsion barrier is dependent on the lipid moiety used; a minimum permeability can be achieved when stearic acid is used as the lipid. This is due to the effective barrier formed by stearic acid through an interlocking network. However, lipid-based edible films also require a support matrix to reduce brittleness, and have difficulty adhering to the hydrophilic cut surfaces of fruits and vegetables (Koelsch 1994; Baldwin and others 1995). Some of the most common compounds used for support matrices are modified celluloses of hydroxypropylmethyl, ethyl and methylcellulose, chitosan and whey protein isolate (WPI; Koelsch 1994).

*** Authors note: Steric acid is also known as tallow (animal and plant fatty acids used in the production of soap).

In general, polysaccharides such as cellulose, pectin, starch, carrageenan, and chitosan, can adhere to cut surfaces of produce and effectively allow gas transfer; however, they are not effective moisture barriers. Due to their CO 2 and O 2 permeabilities, polysaccharide-based films allow the creation of desirable modified atmospheres, an attractive advantage over plastic or shrink wrap MAP which can be labor intensive, expensive and environmentally harmful (Baldwin and others 1995). A number of cellulose derived coatings are available commercially, most taking advantage of the modified atmosphere effect of the barriers. Pro-long (Courtaulds Group, London) and Semperfresh (Surface Systems International, Ltd., Oxfordshire, U.K.) are examples of water-soluble composite coatings comprised of the sodium salt of carboxymethyl cellulose (CMC) and sucrose fatty acid ester emulsifiers (Baldwin and others 1995). Their properties are discussed in Table VI-6. A newer product called “Snow-White,” based on sucrose esters of fatty acids, has also been used to combat oxidative browning in the potato industry. Nature-Seal is a polysaccharide-based surface treatment that uses cellulose derivatives as film formers, but unlike Semperfresh and Pro-long, does not contain sucrose fatty acid esters. Nature-Seal is a browning inhibitor that is applied as a dip or spray and has been shown to delay ripening of whole fruits and vegetables, and to retard discoloration of peeled carrots and cut mushrooms.

*** Authors note: Sucrose is the organic compound commonly known as table sugar and sometimes called saccharose. This is the kind of processed sugar many health conscious people avoid, and which diabetics aren’t supposed to consume, though the natural sugars in fresh fruit is acceptable for diabetics. This is a blatantly deceiving practice.

Finally, proteins such as casein, soy, and zein, can also adhere to hydrophilic cut produce surfaces and are easily modified to form films; however, they also allow water diffusion (Baldwin and others 1995). Unlike lipid-based barriers, protein-based barriers do not require the addition of a support matrix, since the protein acts as both the water vapor barrier and structural component of the film (Koelsch 1994). Park and others (1994) reported the successful application of a corn-zein film to extend the shelf life of tomatoes. Color change, loss of firmness, and weight loss during storage were delayed, and shelf life was extended by 6 d in comparison to untreated tomatoes. The corn-zein product used in the above study was a commercial product that was brushed onto the tomatoes (Regular Grade F4000, INC Biomedicals, Inc.), and consisted of 54 g of corn-zein, 14 g of glycerine, and 1 g of citric acid dissolved in 260 g of ethanol. Park and others (1994) did not comment on the use of citric acid in the film solution; however, others have found that edible films composed of zein were more successful in preventing the rancidity of nuts when citric acid was added (Guilbert and others 1996).

*** Author’s note: Ethanol, also called ethyl alcohol, pure alcohol, grain alcohol, or drinking alcohol, is a volitile, flammable, colorless liquid. It is a psychoactive drug and one of the oldest recreational drugs. Best known as the type of alcohol found in alcoholic beverages, it is also used in thermometers, as a solvent, and as a fuel. In common usage, it is often referred to simply as alcohol or spirits.

In order to obtain an edible film that incorporates all the best qualities of these four basic materials, as well as fulfilling the specific conditions for each fruit or vegetable, manufacturers are now producing films comprised of different combinations. Some of the advantages and disadvantages of the four basic edible film barriers, as well as combinations thereof, are listed in Table VI-5 (discussed below).

Here is Table VI-3:

“Commercially available modified atmosphere packaging systems for small and large quantities of produce”

Edible Films1 TAL Pro-Long (Courtaulds Group) Blend of sucrose esters of fatty acids and sodium carboxymethylcellulose; depresses internal O 2 and is edible. Pears Nutri-Save N, O-carboxymethychitosan edible film. Pears, apples Semperfresh, Nu-Coat Fo, Ban-seel, Brilloshine, Snow-White and White Wash products (Surface Systems Intl. Ltd.) Sucrose ester based fruit coatings with sodium carboxymethyl cellulose products manufactured exclusively from food ingredients available in dip or spray. Most fruits and vegetables, processed and whole potatoes (Snow-White and White-Wash) PacRite products (American Machinery Corp.) Variety of products, water-based carnauba-shellac emulsions, shellac and resin water emulsions, water-based mineral oil fatty acid emulsions, and so forth. Apples, citrus, tomatoes, cucumbers, green peppers, squash, peaches, plums, nectarines Fresh-Cote product line (Agri-Tech Inc.) Variety of products including; shellac-based, carnauba-based and oil emulsion edible films. Apples, pears, eggplant, tomatoes, cucumbers, stone fruits Vector 7, Apl-Brite 300C, Citrus-Brite 300C (Solutec Corp.) Vector 7 is a shellac-based film with morpholine; the Apl-Brite and Citrus-Brite are carnuba-based films. Apples and citrus fruits Primafresh Wax (S.C. Johnson) Carnauba-based wax emulsion. Apples, citrus and other firm-surfaced fruit Shield-Brite products (Pace Intl. Shield-Brite) Shellac, carnauba, natural wax and vegetable oil/wax and xanthan gum products. Citrus, pears, stone fruit Sta-Fresh Products (Food Machinery Corp.) Natural, synthetic, and modified natural resin products and combinations thereof. Citrus, apples, stone fruits, pomegranates, tomatoes, pineapple, cantaloupes, and sweet potatoes Fresh Wax products (Fresh Mark Corp.) Shellac and wood resin, oxidized polyethylene wax, white oil/paraffin wax products. Citrus, cantaloupes, pineapples, apples, sweet potatoes, cucumbers, tomatoes and other vegetables Brogdex Co. products Carnauba wax emulsions with or without fungicides, emulsion wax, high shine wax, water-based emulsion wax, carnauba-based emulsion, vegetable oil, resin-based and concentrated polyethylene emulsion wax products. Apples, melons, bananas, avocado, chayote, papaya, mango, pineapple, citrus, stone fruits. FreshSeal TM (Planet Polymer Technologies Inc. has licensed CPG Technologies of Agway, Inc. to produce) A patented coating that slows the ripening process by controlling the O 2 and CO 2 and water vapor flowing in and out of the product. It can be tailored to the individual respiration rates of different fruit and vegetable varieties. Currently available for avocado, cantaloupe, mangoes and papaya. Use on limes, pineapples and bananas is currently under investigation. Nature-Seal TM , AgriCoat (Mantrose Bradshaw Zinsser Group) Composite polysaccharide-based coating using cellulose derivatives as film formers. Sliced apples, carrots, peppers, onions, lettuce, pears, avocados, sliced bananas Intelligent Systems Activated Earth Films Typically polyethylene bags with powdered clay material made of powdered aluminum silicates, incorporated into the film matrix. Possibly reduces ethylene concentration by facilitating its diffusion out of the bag. Variable Temperature Responsive Films (Landec Labs) Films increase their gas permeabilities in response to temperature increases as well as increases in respiration. Stabilizes the modified atmosphere so it remains the same under various temperatures. Specific for each product CO 2 Scavengers FreshLock (Mitsubishi Gas Chemical Co.), Verifrais (Codimer Tournessi, Gujan-Mestras) Sachet type product which is placed directly in the package and absorbs both carbon dioxide and oxygen. Fruits and vegetables, coffee Ethylene absorbents Ethysorb (StayFresh Ltd), Ageless C (Mitsubishi Gas Chemical Company), Freshkeep (Kurarey), Acepack (nippon Greener), Peakfresh (Klerk Plastic Industrie, Chantler Packaging Inc.) Sachet type product which is placed directly in the package and absorbs ethylene. They are composed of a variety of products such as aluminum oxide, potassium permanganate, activated carbon, and silicon dioxide. Fruits and vegetables Antimicrobial Films-unsure of commercial availability

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So let’s take a look at what some of these “food safety” MAP products actually are, as listed in the above table:

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Shellac is a resin secreted by the female lac bug, on trees in the forests of India and Thailand. It is processed and sold as dry flakes which are dissolved in ethyl alcohol to make liquid shellac, which is used as a brush-on colorant, food glaze and wood finish. Shellac functions as a tough natural primer, sanding sealant, tannin-blocker, odour-blocker, stain, and high-gloss varnish. Shellac was once used in electrical applications as it possesses good insulation qualities and it seals out moisture. Phonograph (gramaphone) records were also made of it during the pre-1950s, 78-rpm recording era.

Shellac is one of the few historically appropriate finishes (including casein paint, spar varnishes, boiled linseed oil and lacquer) for early 20th-century hardwood floors, and wooden wall and ceiling paneling.

From the time it replaced oil and wax finishes in the 19th century, shellac was one of the dominant wood finishes in the western world until it was replaced by nitrocellulose lacquer in the 1920s and 1930s.

(Source: http://en.wikipedia.org/wiki/Shellac)

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Morpholine is a common additive, in parts per million concentrations, for pH adjustment in both fossil fuel and nuclear power plant steam systems. Morpholine is used because its volatility is about the same as water, so once it is added to the water, its concentration becomes distributed rather evenly in both the water and steam phases. Its pH adjusting qualities then become distributed throughout the steam plant to provide corrosion protection. Morpholine is often used in conjunction with low concentrations of hydrazine or ammonia to provide a comprehensive all-volatile treatment chemistry for corrosion protection for the steam systems of such plants. Morpholine decomposes reasonably slowly in the absence of oxygen at the high temperatures and pressures in these steam systems.

The European Union has forbidden the use of Morpholine in fruit coating.

Morpholine is widely used in the USA, Canada, Australia and other parts of the world as a food additive for use as a component or coating for fruits and vegetables. However, the use of Morpholine is prohibited in the European Union, those countries where its use is permitted are fully aware of these restrictions. Consequently, they have strict protocols to ensure waxes containing Morpholine are not used for fruit destined for the UK and the EU.

Morpholine is not permitted in Europe because it is known to be a precursor of N-nitrosomorpholine, a carcinogen.

(Source: http://www.salltd.co.uk/news_item.jsp?file=2010-09-29%20Morpholine%20residues%20detected%20in%20apples%20from%20Chile.html)

(Source: http://en.wikipedia.org/wiki/Morpholine)

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Carboxymethyl cellulose (CMC) or cellulose gum is a synthesized cellulose derivative.

CMC is used in “food science” as a viscosity modifier or thickener, and to stabilize emulsions in various products including ice cream. As a food additive, it has E number E466. It is also a constituent of many non-food products, such as K-Y Jelly, toothpaste, laxatives, diet pills, water-based paints, detergents, textile sizing and various paper products. It is used primarily because it has high viscosity, is non-toxic, and is hypoallergenic. In laundry detergents it is used as a soil suspension polymer designed to deposit onto cotton and other cellulosic fabrics creating a negatively charged barrier to soils in the wash solution. CMC is used as a lubricant in non-volitile eye-drops (artificial tears). Sometimes it is methyl cellulose (MC) which is used, but its non-polar methyl groups (-CH 3 ) do not add any solubility or chemical reactivity to the base cellulose.

Following the initial reaction the resultant mixture produces approximately 60% CMC plus 40% salts (sodium chloride and sodium glycolate). This product is the so-called Technical CMC which is used in detergents. A further purification process is used to remove these salts to produce pure CMC which is used for food, pharmaceutical and dentifrice (toothpaste) applications. An intermediate “semi-purified” grade is also produced, typically used in paper applications.

CMC is also used in pharmaceuticals as a thickening agent. CMC is also used in the oil drilling industry as an ingredient of drilling mud, where it acts as a viscosity modifier and water retention agent. Poly-anionic cellulose or PAC is derived from CMC and is also used in oilfield practice.

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Paraffin – medicinal liquid paraffin is used to aid bowel movement in persons suffering chronic constipation; it passes through the gastrointestinal tract without itself being taken into the body, but it limits the amount of water removed from the stool. In the food industry, where it may be called “wax”, it can be used as a lubricant in mechanical mixing, applied to baking tins to ensure that loaves are easily released when cooked and as a coating for fruit or other items requiring a “shiny” appearance for sale.

It is often used in infrared spectroscopy, as it has a relatively uncomplicated IR spectrum. When the sample to be tested is made into a mull (a very thick paste), liquid paraffin is added so it can be spread on the transparent (to infrared) mounting plates to be tested.

Mineral oil has also seen widespread use in biotechnology for preventing the evaporation of small volumes of liquid during heating. Polymerase chain-reaction samples may need to be overlaid with a layer of mineral oil to prevent evaporation during the high heat (95 °C) required to denature DNA.

Paraffin wax as a food grade substance is used in:

Shiny coating used in candy-making; although edible, it is non-digestible, passing right through the body without being broken down

Coating for many kinds of hard cheese, like Edam cheese

Sealant for jars, cans, and bottles

Chewing gum additive

It is also used for:

Candle-making

Coatings for waxed paper or cloth

Investment casting

Anti-caking agent, moisture repellent, and dust-binding coatings for fertilizers

Agent for preparation of specimens for histology

Bullet lubricant – with other ingredients, such as olive oil and beeswax

Crayons

Solid propellant for hybrid rocket motors

Component of surf-wax, used for grip on surfboards in surfing

Component of glide wax, used on skies and snowboards

Friction-reducer, for use on handrails and cement ledges, commonly used in skateboarding

Ink. Used as the basis for solid ink different color blocks of wax for thermal printers. The wax is melted and then sprayed on the paper producing images with a shiny surface

Microwax: food additive, a glazing agent with E number E905

Forensics aid: the nitrate test uses paraffin wax to detect nitrates and nitrites on the hand of a shooting suspect

Antiozonant agents: blends of paraffin and micro waxes are used in rubber compounds to prevent cracking of the rubber; the antiozonant waxes can be produced from synthetic waxes, FT wax, and Fischer Tropsch wax

Mechanical thermostats and actuators, as an expansion medium for activating such devices

“Potting” guitar pickups, which reduces microphonic feedback caused from the subtle movements of the pole pieces

“Potting” of local oscillator coils to prevent microphonic frequency modulation in low end FM radios.

Wax baths for beauty and therapy purposes

Thickening agent in many Paintballs, as used by Crayola

An effective, although comedogenic, moisturizer in toiletries and cosmetics such as Vaseline

Prevents oxidation on the surface of polished steel and iron

(Source: http://en.wikipedia.org/wiki/Paraffin)

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N(6)-Carboxymethyllysine (CML), also known as N(epsilon)-(carboxymethyl)lysine, is an advanced glycation endproduct (AGE). CML has been the most used marker for AGEs in food analysis.

An advanced glycation end-product (AGE) is the result of a chain of chemical reactions after an initial glycation reaction. Side products generated in intermediate steps may be oxidizing agents (such as hydrogen peroxide), or not (such as beta amyloid proteins). “Glycosylation” is sometimes used for “glycation” in the literature, usually as ‘non-enzymatic glycosylation.’

AGEs may be formed external to the body (exogenously) by heating (e.g., cooking);or inside the body (endogenously) through normal metabolism and aging. Under certain pathologic conditions (e.g., oxidative stress due to hyperglycemia in patients with diabetes), AGE formation can be increased beyond normal levels. AGEs are now known to play a role as proinflammatory mediators in gestational diabetes as well.

The formation and accumulation of advanced glycation endproducts (AGEs) has been implicated in the progression of age-related diseases. AGEs have been implicated in Alzheimer’s Disease,cardiovascular disease,and stroke.The mechanism by which AGEs induce damage is through a process called cross-linking that causes intracellular damage and apoptosis.They form photosensitizers in the crystalline lens, which has implications for cataract development.Reduced muscle function is also associated with AGEs.

AGEs may be less, or more, reactive than the initial sugars they were formed from. They are absorbed by the body during digestion with about 30% efficiency. Many cells in the body (for example, endothelial cells, smooth muscle, and cells of the immune system)from tissue such as lung, liver, kidney, and peripheral blood bear the Receptor for Advanced Glycation End-products (RAGE) that, when binding AGEs, contributes to age- and diabetes-related chronic inflammatory diseases such atherosclerosis, asthma, arthritis, myocardial infarction, nephropathy, retinopathy, periodontis, and neuropathy.. There may be some chemicals, such as aminoguanidine, that limit the formation of AGEs by reacting with 3-deoxyglucosone.

The total state of oxidative and peroxidative stress on the healthy body, and the accumulation of AGE-related damage is proportional to the dietary intake of exogenous (preformed) AGEs, the consumption of sugars with a propensity towards glycation such as fructose and galactose. (So naturally, this AGE is used to coat fructose engorged fruit!!! Real safe…)



AGEs affect nearly every type of cell and molecule in the body, and are thought to be one factor in aging and some age-related chronic diseases.They are also believed to play a causative role in the vascular complications of diabetes mellitus.

They have a range of pathological effects, including increasing vascular permeability, inhibition of vascular dilation by interfering with nitric oxide, oxidising LDL, binding cells including macrophage, endothelial, and mesangial cells to induce the secretion of a variety of cytokines and enhancing oxidative stress.

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Gelatin (or gelatine) is a translucent, colorless, brittle (when dry), flavorless solid substance, derived from the collagen inside animals’ skin and bones. It is commonly used as a gelling agent in food, pharmaceuticals, photography, and cosmetic manufacturing. Substances containing gelatin or functioning in a similar way are called gelatinous. Gelatin is an irreversibly hydrolyzed form of collagen, and is classified as a foodstuff and therefore carries no E Number. It is found in some gummy candies as well as other products such as marshmallows, gelatin dessert, and some low-fat yogurt. Household gelatin comes in the form of sheets, granules, or powder. Instant types can be added to the food as they are; others need to be soaked in water beforehand.

Gelatin is a mixture of peptides and proteins produced by partial hydrolysis of collagen extracted from the boiled crushed bones, connective tissues, organs and some intestines of animals such as domesticated cattle, chicken, and pigs. The natural molecular bonds between individual collagen strands are broken down into a form that rearranges more easily. Gelatin melts to a liquid when heated and solidifies when cooled again. Together with water, it forms a semi-solid colloid gel.

The worldwide production amount of gelatin is about 300,000 tons per year (roughly 600 million lb).On a commercial scale, gelatin is made from by-products of the meat and leather industry.Gelatin is derived mainly from pork skins, pork and cattle bones, or split cattle hides; contrary to popular belief, horns and hooves are not used.The raw materials are prepared by different curing, acid, and alkali processes which are employed to extract the dried collagen hydrolysate. These processesmay take up to several weeks, and differences in such processes have great effects on the properties of the final gelatin products.

(Source: http://en.wikipedia.org/wiki/Gelatin)

Authors note… And so the practical joke of the century from the villainous FDA? Vegetarians and vegans have all this time been eating organic fruit and veggies covered in pig, beef, and chicken byproducts. Oh, they must get a kick out of themselves!

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Could this food safety practice actually be causing harm and promoting disease and harmful pathogens?

Oh, most certainly, according to the FDA report.

In fact, it after reading this report, I am very suspicious that the recent outbreaks of food-borne illness caused from produce may X have ironically been caused by this scientific process of food safety.

Remember the great spinach scare of the 2006, when almost all prepackaged washed and ready to eat spinich was recalled due to the strain of E. coli called 0157:H7? Several of those infected during that outbreak were diagnosed with hemolytic uremic syndrome, a serious form of kidney failure (remember, the kidneys are your renal system, a side effect of which is mentioned above).

How about the recent February 2011 recall of broccoli, where a number of broccoli products sold under the Signature Café, TFarms and Raley’s labels were recalled due to the risk of Listeria food poisoning?

It seems most if not all of these recalls have to do with “fresh cut” or “washed and ready to eat” produce, as well as whole produce.

So let’s take a look at the report to see what this Map film can do for our little pathogenic food poisoning friends…

3.2. Pathogenic organisms

…MAP produce is vulnerable from a safety standpoint because modified atmospheres may inhibit organisms that usually warn consumers of spoilage, while the growth of pathogens may be encouraged. Also, slow growing pathogens may further increase in numbers due to the extension of shelf life. Currently, there is concern with the psychrotrophic foodborne pathogens such as L. monocytogenes, Yersinia entercolitica and Aeromonas hydrophila, as well as non-proteolytic C. botulinum, although clearly a number of other microorganisms, especially Salmonella spp., E. coli O157:H7 and Shigella spp., can be potential health risks.

3.3. Clostridium botulinum (botulism)

…there is some concern about the use of MAP with respect to this organism (Zagory 1995). Depending on the product in a MA package, the level of O 2 can decrease rapidly if the product is temperature abused and product respiration increases, leaving a highly anaerobic environment ideal for the growth and toxin production of C. botulinum (Francis and others 1999)…

…in 1987, four circus performers in Sarasota, FL became ill with symptoms of botulism after consuming coleslaw prepared from packaged shredded cabbage purchased three weeks earlier in New Orleans (Solomon and others 1990). Researchers suspected that the cabbage had been packaged using MAP and that contaminated cabbage further contaminated the dressing, leading to the recovery of C. botulinum type A toxin and spores from the dressing.

…Lilly and others (1996) found that only 0.3% (1 of 337) of sampled shredded cabbage obtained from retail suppliers in the United States contained C. botulinum. However, the products tested had all been stored at 4°C (39.2°F), below the minimum for growth of proteolytic C. botulinum…

Growth and toxin production of C. botulinum before obvious product spoilage has also been observed on Agaricus bisporus mushrooms (Sugiyama and Yang 1975) and potato slices (Dignan 1985). As well, Austin and others (1998) performed challenge studies using both nonproteolytic and proteolytic strains of C. botulinum on MAP fresh-cut vegetables and found that samples of butternut squash (5°C [41°F], 21 d) and onion (25°C [77°F], 6 d) appeared organoleptically acceptable when toxin was detected. It was also demonstrated that toxin production by C. botulinum varied with the vegetables tested. Only nonproteolytic strains growing on butternut squash were capable of producing neurotoxin at temperatures as low as 5°C (41°F ) in 21 d, whereas proteolytic strains were able to produce toxin on all vegetables tested (onion, butternut squash, rutabaga, romaine lettuce, stir-fry and mixed salad), except coleslaw at 15°C (59°F) and higher (Austin and others 1998)…

Fresh mushrooms and tomatoes have also been shown to contain spores of Clostridium spp., and therefore the possibility of botulism associated with these MAP products must not be ignored (Zagory 1995).

3.4. Listeria monocytogenes

Recently, concerns about possible pathogen contamination in MAP produce have focused on L. monocytogenes due to its ability to grow at refrigeration temperatures (NACMCF 1999). Numerous researchers have reported that this organism can remain largely unaffected by MAP, while the normal microflora is inhibited (Amatanidou and others 1999; Francis and O’Bierne 1997, 1998). Thus, although MAP produce can remain organoleptically acceptable, L. monocytogenes, with a reduced microflora and, especially if low levels of lactic acid bacteria are present, can grow at low temperatures to potentially harmful levels during the extended storage life of a MAP produce product…

Early studies showed that L. monocytogenes inoculated onto broccoli, asparagus and cauliflower was unaffected by a modified atmosphere of 3% CO 2 , 18% O 2 and 79% N 2 for 10 d at 10°C (Berrang and others 1989a). Further studies by Beuchat and Brackett (1990a) clearly demonstrated that L. monocytogenes increased significantly in number on lettuce stored in a modified atmosphere of 3% O 2 and 97% N 2 …

…Francis and O’Beirne (1997) also reported that the growth of L. monocytogenes was stimulated by nitrogen flushing at 8°C (46.4°F). In addition, increasing CO 2 levels from 10 to 20% has been reported to stimulate the growth of L. monocytogenes in a surface model system (Amanatidou and others 1999).

Challenge studies conducted by Farber and others (1998) focused on commercially available packaged vegetables and salads, as well as vegetables processed to mimic foodservice conditions. The importance of refrigeration was clearly demonstrated as L. monocytogenes population levels remained constant on all fresh-cut, processed and packaged vegetables stored at 4°C (39.2°F), with the exception of butternut squash and carrots on which the levels increased and decreased, respectively. At 10°C (50°F), the growth of L. monocytogenes was supported on all vegetables tested with the exception of chopped carrots, where the population decreased by 2 log units over 9 d. The inhibitory properties of raw, uncooked carrots and carrot juice on the growth of L. monocytogenes have been previously reported (Beuchat and Brackett 1990b). As well, Jacxsens and others (1999) reported a decline in L. monocytogenes on both Brussels sprouts and carrots packaged under a modified atmosphere (2 to 3% O 2 , 2 to 3% CO 2 , and 94 to 96% N 2 ) and stored at 7°C (44.6°F)…

…and the authors concluded that these conditions might allow L. monocytogenes to reach potentially hazardous levels during the shelf life of the product…

The effects of competition between the indigenous microflora and pathogens on MAP produce have not been studied extensively. However, in a recent study, Francis and O’Beirne (1998) used a surface model agar system to examine the effects of storage atmosphere on L. monocytogenes and the competing microflora (Pseudomonas fluorescens, P. aeruginosa, Enterobacter cloacae, Enterobacter agglomerans and Leuconostoc citreum). The findings suggested that MAP conditions (5-20% CO 2 , balance N 2 and 3% O 2 ) might increase the growth rate of L. monocytogenes…

…Liao and Sapers (1999) also reported that P. fluorescens strains inhibited the growth of L. monocytogenes on endive leaves and spinach, possibly due to the production of a fluorescent siderophore by the pseudomonads. In general, at 3% O 2 , a level often reached in commercial MAP packages, it appeared that growth of the inoculated mixed natural population was decreased, whereas L. monocytogenesproliferated.

Reports of L. monocytogenes growing on sliced apples in controlled atmosphere (Conway and others 1998) and peeled potatoes in vacuum-packages (Juneja and others 1998) at abusive temperatures provide further evidence that this organism may pose a safety risk with respect to certain MAP fruit and vegetable products, and reiterates the importance of Good Agriculture Practices (GAP), Good Manufacturing Practices (GMP) and HACCP for produce post-harvest handling and processing.

More research needs to be done to examine the influence of different atmospheres, background microflora and storage temperatures on the survival and growth of L. monocytogenes on MAP fresh-cut produce.

3.5. Aeromonas hydrophila

Aeromonas spp. can be found on a wide variety of foods, as well as in most aquatic environments and most often causes gastroenteritis, and occasionally septicemia (Kirov 1997)… A. hydrophila can grow at refrigeration temperatures, and several studies have shown that growth is not affected by low O 2 levels (1.5%) and CO 2 levels up to 50% (Francis and others 1999). A survey of 97 prepared salads found A. hydrophila to be present in 21.6% of them, significantly lower than in meat products tested (Fricker and Tompsett 1989). Hudson and De Lacy (1991) also did a small survey of 30 salads and found A. hydrophila in only one salad package not containing mayonnaise. They surmised that the mayonnaise lowered the pH of the food, thereby inhibiting the growth of or inactivating the aeromonads present…

Berrang and others (1989b) determined that although at both 4°C (39.2°F) and 15°C (59°F), the shelf life of broccoli, asparagus and cauliflower was prolonged by MAP (that is, 11-18% O 2 , 3-10% CO 2 , 97% N 2 ), it did not negatively affect the growth of resident or inoculated A. hydrophila. Interestingly, the organism was detected on most lots obtained from the commercial producer. Therefore, for storage periods of 8-21 d, depending on the product, A. hydrophila increased from roughly 104 to 108 or 109 CFU/g, and product that appeared suitable for consumption was heavily contaminated with the pathogen. As with L. monocytogenes, the CO 2 levels that were inhibitory to A. hydrophila (that is, >50%) also damaged the product (Bennik and others 1995)…

3.6. Other pathogens of concern with respect to MAP produce

Organisms such as Salmonella, Shigella, E. coli, and various enteric viruses, such as hepatitis A, have been implicated in produce outbreaks, and, therefore, there is concern about their behavior under modified atmosphere conditions (Zagory 1995; Amanatidou and others 1999). A 1986 outbreak of shigellosis was traced back to commercially distributed MAP shredded lettuce; 347 people were affected in two west Texas counties (Davis and others 1988). Fernandez-Escartin and others (1989) tested the ability of three strains of Shigella to grow on the surface of fresh-cut papaya, jicama, and watermelon and reported that populations increased significantly when the inoculated product was left at room temperature for 4-6 h. Shigella is not part of the normal flora associated with produce, but can be passed on as contaminants by infected food handlers and contaminated manure and irrigation water.

More recently, an outbreak of Salmonella Newport was reported in the U.K., associated with the consumption of ready-to-eat salad vegetables (PHLS 2001). To date, nine human cases have been identified with the isolated strain from the implicated salad vegetables having an identical PFGE pattern to three of the human isolates.

Salmonella Typhimurium and L. monocytogenes actually had an increased growth rate at these concentrations; growth increased from 0.011 and 0.031µ/h to 0.023 and 0.041 µ/h for S. Typhimurium and L. monocytogenes, respectively. In general, E. coli O157:H7, S. Hadar and S. Typhimurium were only inhibited by CO 2 levels that caused damage and spoilage to the produce (Piagentini and others 1997; Amanatidou and others 1999; Francis and others 1999). A modified atmosphere of 3% O 2 and 97% N 2 also had no significant effect on E. coli O157:H7 inoculated onto shredded lettuce, sliced cucumber, and shredded carrot and incubated at 12 and 21°C (21.6 and 69.8°F) (Abdul-Raouf and others 1993). At 5°C (41°F), populations of viable E. coli O157:H7 declined on stored vegetables; however, at 12 and 21°C (53.6 and 69.8°F), populations increased, demonstrating the importance of refrigeration temperatures in maintaining product safety. Richert and others (2000) who, although not studying MAP, reported that E. coli O157:H7 could survive on produce (broccoli, cucumbers and green peppers) stored at 4°C (39.2°F) and proliferate rapidly when stored at 15°C (59°F). In 1993, there were two foodborne outbreaks of enterotoxigenic E. coli (ETEC) linked to carrots in a tabouleh salad served in New Hampshire and to an airline salad on a flight from North Carolina to Rhode Island (CDC 1994). Although these carrots were of U.S. origin, ETEC is a common cause of diarrheal illness in Mexico and developing countries that import fresh product to North America. Research on the behavior of this pathogen on fresh and fresh-cut product, both under MAP and without MAP, seems warranted…

…A more recent study, investigating the survival of C. jejuni on MAP fresh-cut cilantro and lettuce, found that refrigeration temperatures in combination with a modified atmosphere of 2% O 2 , 18% CO 2 and 80% N 2 can be favorable for bacteria (Tran and others 2000). Due to the microaerophilic nature of Campylobacter spp., which require 5% O 2 , 10% CO 2 and 85% N 2 for optimal growth, the investigators suspected that a low O 2 modified atmosphere may provide an environment conducive to survival of the pathogen…

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Table VI-2: Polymers, film types and permeability available for packaging of MAP produce:

Edible Films O 2 permeability (mL.mm/m2.d.atm) – CO 2 permeability (mL.mm/m2.d.atm) Relative Humidity Pectin 57.5 – – 87 Chitosan 91.4 – 1553 93 Wheat (gluten) 190/250 – 4750/7100 91/94.5 Na caseinate 77 – 462 77 Gluten-DATEM 153 – 1705 94.5 Gluten-beeswax 133 – 1282 91 Na casenate/Myvacet 83 – 154 48 MC/MPMC/fatty acids 46.6 – 180 52 MC and beeswax 4 – 27 42 Gluten-DATEM and beeswax ❤ – 15 56 Gluten-Beeswax and beeswax ❤ – 13 56 Methylcellulose-palmitic acid 78.8 – – 100 Zein 0.362 – 2.672 0.1163 Cozeen 0.892 – 5.252 0.4073 Polyethylene 8.32 – 26.12 – Polypropylene 0.552 – – 0.000653 Sucrose polyester 2.102 – – 0.000423 Smart Films O 2 scavengers with O 2 indicators

scavengers with O indicators antibody based detection systems for detection of microbial pathogen Antimicrobial filmsi) Edible Chlorinated phenoxy compound with biocide incorporated into the polymer layer (that is, nisin, lysozyme)

Chlorine dioxide with biocide incorporated into polymer layer

Edible films with sorbic acid, sodium benzoate, benzoic acid and potassium sorbate

Pine based volatiles added to edible film

Horseradish extract added to edible film ii) Non-edible films/products Propyl paraben dispersed in a polymer emulsion (Permax 801 or Carboset)

LDPE with Imazalil

LDPE with grapefruit seed extract

Gas, as produced by sachets or other materials to produce sodium metabisulfite to obtain the production of sulfite

This list of ingredients includes substances that many people have high allergic reactions to, including wheat (gluten) and milk (caseinate), and ones that are just downright bad for your health, including Chlorine, corn byproducts, and other animal fatty acid byproducts.

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So now at least you know. That shiny, healthy looking high-pro glow that is emanating from your fresh store-bought produce is more than likely this MAP – a film consisting of any number of inorganic, unhealthy compounds, including pork rinds and chicken bones!

The most important factor here is to understand that in an attempt prolong shelf life and reduce natural spoilage of our produce, these film covers are also creating an environment for bad pathogens to grow. And since the produce shows no signs of spoilage or contamination, the consumer may never know what is actually thriving thanks to that prolonged life allowed by modern, yet impossibly dangerous and deceiving food science.

And so once again, this is your Federal Food and Drug Administration at work.

When will we learn that the FDA is in the business of making its government owned corporations lives easier, by deregulating the rules that govern the food and drug industries and by allowing just about anything to be called “edible” and “food”, while simultaneously destroying the lives of anyone who tries to heal or cure disease without the FDA’s permission… and stealing their patents to boot? And now arresting farmers who transport raw milk across state borders as if milk is a illicit drug?

What is it going to take to make you stand up to this beast… this tyrant?

Less fluoride, perhaps…

.

–Clint Richardson (realitybloger.wordpress.com)

–Sunday, January 8, 2012