Tren Acetate 150 mg/ml recipe

I had heard about it dissolving rubber and causing cancer in animal studies from darknet vendors as their reasoning for not using it.

ChatGPT:

Q: if ethyl oleate can deteriorate a rubber stopper, will it do the same to your muscles? Can it cause cancer?

A:

Ethyl Oleate and Rubber Stoppers​

  1. Solvent Properties:
    • Dissolves Materials: Ethyl oleate is a strong solvent that can dissolve or break down certain materials, including rubber. This is why it can deteriorate rubber stoppers over time.
    • Compatibility Issues: The chemical composition of rubber makes it susceptible to being degraded by solvents like ethyl oleate, especially when the two are in prolonged contact.
  2. Types of Rubber:
    • Varying Sensitivity: Different types of rubber have varying resistance to solvents. Natural rubber is more likely to degrade in the presence of ethyl oleate compared to synthetic rubbers designed to withstand such interactions.

Ethyl Oleate and Muscle Tissue​

  1. Biological Compatibility:
    • Different Chemistry: Human tissues are composed of cells, proteins, and other organic molecules, which have different chemical properties compared to synthetic rubber.
    • Biodegradability: Ethyl oleate is generally metabolized by the body and does not accumulate in tissues like rubber particles might. This reduces the likelihood of it causing similar deterioration in muscle tissue.
  2. Potential Effects on Tissue:
    • Localized Irritation: While ethyl oleate can cause localized irritation or inflammation at the injection site, it doesn’t chemically "dissolve" muscle tissue the way it might dissolve rubber. The irritation is typically a physical or immune response rather than a chemical breakdown of tissues.
    • Adverse Reactions: Some individuals may experience pain, swelling, or redness, which are signs of irritation or an allergic reaction rather than tissue degradation.
  3. Biological Metabolism:
    • Metabolism and Clearance: Once injected, ethyl oleate is metabolized by enzymes in the body into ethanol and oleic acid, which are further processed and used or excreted by the body. This metabolic pathway minimizes the risk of tissue damage.

Research and Regulation:​

  • Regulatory Stance: Regulatory agencies like the FDA and EMA typically evaluate the safety of substances used in pharmaceuticals, including ethyl oleate, and have not classified it as a carcinogen.
  • Animal Studies: Some studies involving high doses of ethyl oleate in animal models have shown inflammatory responses, but these findings are not directly indicative of cancer risk in humans at therapeutic doses.

Conclusion​

While ethyl oleate can deteriorate rubber stoppers due to its solvent properties, it does not have the same effect on muscle tissue. In biological systems, ethyl oleate is broken down and metabolized, reducing the risk of chemical damage to tissues. However, irritation and allergic reactions are possible, and it's important to use pharmaceutical-grade ethyl oleate in a controlled setting to minimize these risks.




You have to be careful with how you phrase GPT prompts though, the question can greatly effect the results it gives you.



Q: does the molecular size of tren make it more likely to produce tren cough?

A:

Tren cough, a sudden and often intense coughing fit experienced shortly after injecting trenbolone acetate, is a phenomenon associated with this anabolic steroid. The exact mechanism behind tren cough is not entirely understood, but several factors, including the molecular size of trenbolone and its properties, may contribute to this reaction. Let’s explore how molecular size and other factors might play a role:

Trenbolone Acetate: Molecular Properties​

  1. Molecular Size and Structure:
    • Small Molecule: Trenbolone is a relatively small molecule, with a molecular weight of approximately 270.37 g/mol for the base form and 312.4 g/mol for the acetate form.
    • Steroid Structure: It is a synthetic anabolic steroid with a structure similar to other androgens, but with modifications that increase its anabolic and androgenic potency.
  2. Lipid Solubility:
    • Lipophilicity: Trenbolone is highly lipophilic, meaning it dissolves easily in fats and oils. This characteristic helps it pass through cell membranes quickly, affecting various tissues, including muscle.
    • Carrier Solvent: The lipid-soluble nature of trenbolone acetate allows it to be suspended in oil-based carriers, which can contribute to the cough.

Factors Contributing to Tren Cough​

  1. Rapid Absorption:
    • Bloodstream Entry: When injected intramuscularly, the oil-based solution can enter the bloodstream rapidly. This may cause a sudden irritation of the lungs and airways, leading to coughing.
    • Oil Microembolism: Tiny oil droplets might enter the bloodstream and reach the pulmonary circulation, causing an acute inflammatory response in the lungs. This can lead to coughing and other respiratory symptoms.
  2. Chemical Irritation:
    • Local Irritation: The immediate release of trenbolone acetate and its rapid absorption can irritate the bronchial tissues, leading to coughing.
    • Direct Effect on Lungs: Some suggest that trenbolone itself, or its metabolites, may directly irritate lung tissue, triggering a cough reflex.
  3. Histamine Release:
    • Inflammatory Response: Trenbolone or its metabolites might trigger the release of histamine or other inflammatory mediators, which could contribute to respiratory symptoms like coughing.
    • Bronchial Constriction: Histamine release can lead to bronchoconstriction, which exacerbates coughing and respiratory discomfort.
  4. Injection Technique:
    • Improper Injection: Injecting too quickly or in the wrong site can increase the likelihood of tren cough by facilitating faster absorption into the bloodstream.
    • Needle Placement: Inadvertently injecting into a blood vessel rather than muscle tissue can lead to more direct entry of the compound into circulation, increasing the risk of pulmonary effects.

Comparison with Other Steroids​

  • Other Anabolic Steroids: Not all steroids produce a similar cough. The specific chemical properties and how they interact with lung tissues and blood vessels can vary significantly.
  • Molecular Differences: The specific modifications in the trenbolone molecule may lead to different interactions with the body's systems compared to other anabolic steroids.

Conclusion​

While the molecular size of trenbolone itself is not the direct cause of tren cough, its lipid solubility and rapid absorption into the bloodstream likely contribute to this phenomenon. The irritation of lung tissues, potential oil microembolism, and inflammatory responses are more directly linked to the occurrence of tren cough.

Those considering using trenbolone or any similar compounds should consult with a healthcare provider and consider the risks and benefits carefully. Proper injection technique and awareness of potential side effects are crucial in managing the risks associated with its use.
 
Back
Top