The Chemistry of Fungi & Silicone


Fungal-bacterial multispecies biofilms play a major role in failure of medical silicone devices, such as voice prostheses in laryngectomiy. In this study, we determined the effect of Lactobacilli supernatant (cell free) on mixed biofilm formation of fungi and bacteria on silicone in vitro. Lactobacilli supernatant inhibited the adhesion (90 min) of mixed fungi and bacteria species with an efficiency of >90%. Mixed biofilm formation and the metabolic activity of the biofilms were inhibited by 72.23% and 58.36% by Lactobacilli supernatant. The examination using confocal laser scanning microscopy and scanning electron microscopy confirmed that Lactobacilli supernatant inhibited the growth of mixed biofilm and damaged the cells. Moreover, Lactobacilli supernatant also inhibited Candida yeast-to-hyphal transition. Therefore, Lactobacilli supernatant may serve as a possible antibiofilm agent to limit biofilm formation on voice prostheses.


Mixed fungal-bacterial biofilm; Probiotic; Silicone voice prostheses

PMID: 29111321 DOI: 10.1016/j.micpath.2017.10.051


Degradation of Polymers in Nature

Environmental Information - Update


Polymers are a broad class of materials which are made from repeating units of smaller molecules called monomers. Polymers can be natural in origin, such as the lignin of tree branches, the starches of homemade bread, or the chitin of lobster shells. Other polymers are called synthetic, because they are made by humans from naturally-occurring materials. Examples include polyesters used in clothing, polystyrene used in home insulation, and silicones used in personal care and other products. Polymers are useful because of their strength and durability in many applications. However, after the useful life of a polymer is over, society desires that it degrade in the environment back to natural materials. This fact sheet first reviews the natural degradation of a wide variety of polymers, and then shows how the degradation of silicone polymers follows the same pattern.

Natural Degradation of Polymers

Degradation of all polymers follows a sequence in which the polymer is first converted to its monomers, after which the monomers are mineralized. Most polymers are too large to pass through cellular membranes, so they must first be depolymerized to small monomers before they can be absorbed and biodegraded within microbial cells. The initial breakdown of a polymer can result from a variety of physical, chemical, and biological forces [1], with chemical hydrolysis probably being the most important [2].

Health Environment & Regulatory Affairs (HERA)

Physical forces, such as heating/cooling, freezing/ thawing, or wetting/drying, can cause mechanical damage such as the cracking of polymeric materials [3]. The growth of many fungi can also cause small-scale swelling and bursting, as the fungi penetrate the polymer solids [4]. These physical forces deteriorate the polymer surfaces and create new surfaces for reacting with chemical and biochemical agents, a critical phenomenon in the degradation of solid polymers. For fluid polymers, the chemical and biological forces are more important.

Soil microbes can initiate the depolymerization of many natural polymers such as starch, cellulose, and hemicellulose [5, 6]. They secrete a variety of enzymes into the soil water, and these enzymes then begin the breakdown of the polymers. Other natural polymers such as lignin are quite resistant to breakdown, and nature has developed a system in which certain fungi secrete hydrogen peroxide and a specific enzyme, which act together to slowly initiate degradation [7, 8]. These reactions can also decompose synthetic polymers, such as polyacrylic acid and polyacrylamide [9, 10].

In addition, microbial exudates (other than enzymes) can create a micro-environment in which certain polymers become chemically unstable. For example, sulfur bacteria produce sulfuric acid from sulfide or sulfur [5]. Many fungi secrete organic acids while decomposing plant materials [5, 11], while plant roots secrete both H+ and HCO - during the uptake of

3 nutrients [12]. If these processes occur in the vicinity

of acid - or base - susceptible polymers, they may increase the degradation rates of the polymers.

Ref. n° 01-1112-01 1/4 © Copyright Dow Corning Corp., 1997. All rights reserved. Last Revision 07/98

Testing polymer degradation

The fact that polymers degrade in a sequence of abiotic and biological steps means that the standardized tests for measuring biodegradation of many small molecules do not realistically address what actually happens to a polymer in nature. For example, the OECD’s regulatory test, “Inherent Biodegradability in Soil,” tracks CO release over a

2 64 day period as a measure of biodegradation [29].

This test would only be relevant when the entire abiotic/biotic degradation sequence of a polymer occurs under the specific conditions of the test. In the case of silicones, this test would have completely missed the clay-catalyzed hydrolysis of the polymer and the identification of the monomer hydrolysis product. Subsequent reactions of the monomer, such as its biodegradation and volatilization/ atmospheric degradation, would probably have gone undetected, as well. In situations where a polymer’s monomeric units are not mineralized but are incorporated into growing cells, a simple C02 evolution test would again miss the point. The net effect of trying to force-fit the complex mechanisms of polymer degradation into a simple, standardized regulatory test means that misleading information about a polymer’s fate in the environment will be generated. For this reason, Dow Corning has published an extensive series of research studies designed to investigate the complete sequence of abiotic/biotic degradation of silicones in nature.

Ref. n° 01-1112-01 2/4 © Copyright Dow Corning Corp., 1997. All rights reserved. Last Revision 07/98




MORE RESEARCH ON TYPES OF INMPLANTS DEVELOPING FUNGAL OVERGROWTH? Importance of fungus colonization in failure of silicone rubber percutaneous gastrostomy tubes (PEGs).

Iber FL1, Livak A, Patel M.


Silicone rubber PEG tubes or replacements were recovered from 111 patients and examined for blockage, dilatations, tears, breaks, or loss of elasticity. All irregularities were stained and examined for fungus using lactophenol cotton blue stain. The intraabdominal portion of the PEG failed from obstructions, loss of elasticity, or tears related to fungus colonies in 36% of cases. An additional 34% were colonized with fungi but did not fail. On frozen section, the fungus invaded the wall of the tubing. The extraabdominal PEG tubing failed from fungi in 12, and 10 additional tubes had colonizations. Nine tubes had distal clogging with crystalline material that is believed to arise from medication. Fungus tube failure occurred in 37% of the tubes in place 250 days and in 70% of tubes in place 450 days. Fungus is an important cause of PEG failure; recommendations are provided to maintain tube patency.

PMID: 8565761

We already knew this, but it is always good when a doctor that is trained in this very process realizes it and scientific evidence supports the hypothesis. The whole protocol for breast implant illness is based on this premise. You must:

1. Starve the fungi with a diet low in mycotoxins that feed them. Phase 1 diet.

2. Take herbal antifungals that will kill the fungi.

3. Get hair mineral testing done to uncover what metals and toxins are allowing the fungi to grow. Fungi also cause a severe imbalance of important minerals for health and will compromise adrenal function. By restoring the body’s healthy state we allow for natural safe detox of the metals and toxins the implants have left behind.

#explant #biotoxinillness #autoimmune #breastimplantillness #breastimplantillnesssymptoms #detox #dougKaufmann

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