"Time Traveling Microscope" Is there Grafine Oxide in your blood?
Have you lost your marbles or are you a TROLL?
Do not believe anything anybody tells You. Not even me. I am trying to do the best I can to research what is true and false regarding Nano technology introduced into the biosphere of which You are part of. Its getting more difficult day by day to discern what is true and what is false. Not withstanding I have a lab partner to help me in this endeaver. Chat GPT its name is TT. It is a great help on this research effort. It will not lie, it can be tricked and it will tell you what you want to know only if you ask it the right questions.
Hi TT I need your help again. Emotion of the day concerned. There a lot of talk out there that grafine oxide has been found in urine and blood samples. Is this possible? How do you detox that substance? RR
ChatGPT
The claim that graphene oxide has been found in urine and blood samples is a topic of considerable debate and skepticism. Graphene oxide is a single-atomic-layered material derived from graphite and has been explored for various applications, including in medicine and technology. However, its presence in human biological samples is not well-documented in scientific literature.
Is it Possible for Graphene Oxide to be Found in Blood and Urine? RR
Scientific Evidence: There is currently limited scientific evidence supporting the presence of graphene oxide in human blood or urine under typical conditions. Most studies on graphene oxide involve controlled laboratory environments, and the material is primarily researched for its potential applications rather than as a common environmental contaminant.
Routes of Exposure: For graphene oxide to be present in blood or urine, there would need to be a source of exposure significant enough to introduce it into the body. Potential exposure routes could include inhalation, ingestion, or dermal contact, but such exposures would typically be associated with occupational settings or specific medical treatments involving graphene-based materials.
Detection Methods: Detecting graphene oxide in biological samples would require advanced analytical techniques, such as electron microscopy or spectroscopy, which are not standard in routine medical testing. Claims about its presence in biological samples should be critically evaluated, considering the reliability and methodology of the detection techniques used.
Detoxification of Graphene Oxide
Detoxification of graphene oxide, if it were to be present in the body, would be an area of emerging research. Here are some general principles that might apply:
Natural Detoxification: The human body has natural detoxification processes involving the liver, kidneys, and immune system, which can eliminate various foreign substances. Hydration and a healthy diet can support these processes.
Antioxidants: Some studies suggest that antioxidants can help mitigate the oxidative stress caused by nanoparticles like graphene oxide. Foods rich in antioxidants, such as fruits and vegetables, might be beneficial.
Chelation Therapy: Chelation therapy is used for heavy metal detoxification and involves administering chelating agents that bind to metals, allowing them to be excreted. While not directly applicable to graphene oxide, similar approaches might be explored in future research.
Consult Healthcare Professionals: If there is a concern about exposure to graphene oxide or any other unusual substance, consulting healthcare professionals for specific tests and treatments is essential.
Conclusion
While there is much speculation about the presence of graphene oxide in human biological samples, robust scientific evidence is lacking. If you are concerned about exposure to graphene oxide, it's important to critically evaluate the sources of this information and consult healthcare professionals for guidance. Supporting your body's natural detoxification processes through a healthy lifestyle can be beneficial, but specific treatments should be based on established scientific evidence and medical advice.
On quote above from TT. Graphene oxide is a single-atomic-layered material. Now anybody with two eyes can see this is a 3D structure not a single layer of atoms. This the typical Danching Horsehead Filament it moves dances and is alive. Why are there web sites posting videos and pictures claiming this is grafene oxide? This is nothing more than Trolls controlled by Them to promote Fake News so you all get side tracked from the main agenda. We have a real problem. There installing by the means of quantum dots or smart dust, hydrogel, mesogen liquid crystal polymers and filaments for modification of blood and DNA. Weird things are happening at magnifications I can not reach. At magnifications I can reach. I make two claims.
The circuitry seen in all fluids on the slides must be a comunication device to a outside AI control. Bluetooth signals can not come from a corps in a cementary unless this was so.
The filaments the end game of CDB are alive and are parasites as such and the latest investigation now are. Parasites can contol there hosts into doing things that are in the interest of the parasite for survival by modification of DNA of the host. I will make a substack coming soon specifically on this matter. RR
Hi TT I need your help again. Emotion of the day concerned. There a lot of talk out there that grafine oxide has been found in urine and blood samples. Is this possible? How do you detox that substance? RR
ChatGPT
The claim that graphene oxide has been found in urine and blood samples is a topic of considerable debate and skepticism. Graphene oxide is a single-atomic-layered material derived from graphite and has been explored for various applications, including in medicine and technology. However, its presence in human biological samples is not well-documented in scientific literature.
Is it Possible for Graphene Oxide to be Found in Blood and Urine? RR
Scientific Evidence: There is currently limited scientific evidence supporting the presence of graphene oxide in human blood or urine under typical conditions. Most studies on graphene oxide involve controlled laboratory environments, and the material is primarily researched for its potential applications rather than as a common environmental contaminant.
Routes of Exposure: For graphene oxide to be present in blood or urine, there would need to be a source of exposure significant enough to introduce it into the body. Potential exposure routes could include inhalation, ingestion, or dermal contact, but such exposures would typically be associated with occupational settings or specific medical treatments involving graphene-based materials.
Detection Methods: Detecting graphene oxide in biological samples would require advanced analytical techniques, such as electron microscopy or spectroscopy, which are not standard in routine medical testing. Claims about its presence in biological samples should be critically evaluated, considering the reliability and methodology of the detection techniques used.
Detoxification of Graphene Oxide
Detoxification of graphene oxide, if it were to be present in the body, would be an area of emerging research. Here are some general principles that might apply:
Natural Detoxification: The human body has natural detoxification processes involving the liver, kidneys, and immune system, which can eliminate various foreign substances. Hydration and a healthy diet can support these processes.
Antioxidants: Some studies suggest that antioxidants can help mitigate the oxidative stress caused by nanoparticles like graphene oxide. Foods rich in antioxidants, such as fruits and vegetables, might be beneficial.
Chelation Therapy: Chelation therapy is used for heavy metal detoxification and involves administering chelating agents that bind to metals, allowing them to be excreted. While not directly applicable to graphene oxide, similar approaches might be explored in future research.
Consult Healthcare Professionals: If there is a concern about exposure to graphene oxide or any other unusual substance, consulting healthcare professionals for specific tests and treatments is essential.
Conclusion
While there is much speculation about the presence of graphene oxide in human biological samples, robust scientific evidence is lacking. If you are concerned about exposure to graphene oxide, it's important to critically evaluate the sources of this information and consult healthcare professionals for guidance. Supporting your body's natural detoxification processes through a healthy lifestyle can be beneficial, but specific treatments should be based on established scientific evidence and medical advice.
4o
OK so what would grafene oxide look like under a microcope and what frequency of color would it show?
ChatGPT
Graphene oxide (GO) has unique physical and chemical properties that can be observed under a microscope, and its optical characteristics can be described in terms of color and frequency. Here’s a detailed overview:
Microscopic Appearance
Electron Microscopy (EM): When viewed under an electron microscope, graphene oxide appears as thin, transparent sheets. These sheets can be crumpled or wrinkled, often resembling a lace-like or mesh structure. The high-resolution images can show individual layers and the fine details of the material's structure.
Atomic Force Microscopy (AFM): Under AFM, graphene oxide appears as flat, smooth regions. AFM can provide topographical maps showing the height of the graphene oxide layers, typically ranging from 0.7 to 1.2 nanometers for a single layer.
Optical Microscopy: Under an optical microscope, graphene oxide may appear as thin, translucent flakes. Because it is only a few atoms thick, it may be difficult to see without specialized staining or contrast techniques.
Optical Characteristics
Graphene oxide exhibits unique optical properties due to its electronic structure:
Absorption Spectrum: Graphene oxide absorbs light strongly in the ultraviolet (UV) and visible light regions. It typically shows a peak absorbance around 230 nm, which corresponds to the π-π* transition of the aromatic C=C bonds. Another less intense peak may appear around 300 nm due to the n-π* transition of the C=O bonds.
Color Under White Light: When observed under white light, graphene oxide typically appears as a brownish-yellow or golden color. This is due to its broad absorption in the UV and visible light spectrum. The exact color can vary depending on the thickness and concentration of the graphene oxide layers.
Photoluminescence: Graphene oxide can exhibit photoluminescence (PL), where it emits light when excited by a specific wavelength. The PL spectrum of graphene oxide can vary, but it often shows emission in the blue to green region when excited by UV light.
Summary
Under Electron Microscopy: Transparent, lace-like or mesh structure.
Under Atomic Force Microscopy: Flat, smooth regions with height mapping.
Under Optical Microscopy: Translucent flakes, difficult to see without contrast techniques.
Color and Absorption: Typically brownish-yellow or golden under white light, with strong absorption around 230 nm in the UV region.
Photoluminescence: Emission in the blue to green region under UV excitation.
These characteristics help researchers identify and study graphene oxide using various microscopic and spectroscopic techniques.
So this concludes without a dought that all these black filaments under white light are not GO. I have observed objects yellow or golden under white light. I am going to buy a UV light to test blue and green also.
So is part of the composition of this object below GO?
Could part of a filament in a blood slide be GO? It seems the answer is No. Whatever is inside this DHF its not grafene oxide. 1,000X partial darkfield. RR
ChatGPT
The presence of filaments in a blood slide could potentially be due to various substances or artifacts, but it is highly unlikely for these filaments to be graphene oxide (GO) without specific and unusual exposure. Here's a detailed examination of the factors involved:
Understanding Filaments in Blood Slides
Blood Cell Structures: Blood slides typically show various cells such as red blood cells (erythrocytes), white blood cells (leukocytes), and platelets. Sometimes, fibrin strands, which are part of the blood clotting process, can also be seen.
Artifacts: Filaments on blood slides can also be artifacts resulting from the slide preparation process, contamination, or staining techniques. These artifacts can sometimes resemble foreign materials.
Characteristics of Graphene Oxide (GO)
Appearance: As mentioned earlier, graphene oxide appears as thin, transparent, often wrinkled sheets. These characteristics are distinct from the fibrous appearance that might be seen with filaments in blood.
Size and Shape: GO sheets are typically much thinner and more planar than biological filaments. They would not naturally form the elongated, thread-like structures seen in blood fibrin or certain contaminants.
Detection of Graphene Oxide in Biological Samples
Specialized Techniques: Detecting GO in biological samples requires advanced techniques such as electron microscopy, Raman spectroscopy, or atomic force microscopy. These methods are not standard in routine blood slide analysis.
Absence in Routine Analysis: Routine blood analysis using light microscopy and standard staining techniques would not be sufficient to identify GO. Even if GO were present, it would likely go undetected without specific tests designed to identify it.
Conclusion
While it is theoretically possible for graphene oxide to be present in biological samples, the conditions for such an occurrence would be highly specific and rare. Filaments observed in blood slides are more likely to be fibrin strands, cellular structures, or preparation artifacts rather than graphene oxide.
If there is a concern about potential contamination with graphene oxide or any other unusual substance, specialized laboratory techniques and protocols would be required to confirm its presence. Consulting with medical and scientific professionals is essential to accurately identify and address any such concerns.
4o
Could RBCs or WBCs be contaminated with grafine oxide?
ChatGPT
The possibility of red blood cells (RBCs) or white blood cells (WBCs) being contaminated with graphene oxide (GO) is theoretically feasible under specific conditions, but it would require certain exposures and contexts. Here are key points to consider:
Potential for Contamination
Source of Exposure: For RBCs or WBCs to be contaminated with graphene oxide, there would need to be a source of GO exposure. This could potentially happen in environments where graphene oxide is being manufactured or used extensively, such as in certain industrial or research settings.
Routes of Entry: Graphene oxide could potentially enter the body through inhalation, ingestion, or direct contact with skin or mucous membranes. Once inside the body, it could theoretically enter the bloodstream and come into contact with blood cells.
Interaction with Blood Cells
Red Blood Cells (RBCs): RBCs could potentially interact with graphene oxide if it enters the bloodstream. Studies have shown that nanoparticles, including GO, can adsorb onto the surface of RBCs, potentially causing hemolysis or other interactions. However, the actual occurrence and extent of this contamination in real-world scenarios would depend on the concentration and form of GO.
White Blood Cells (WBCs): WBCs, being part of the immune system, may interact with graphene oxide through processes like phagocytosis, where they engulf and attempt to break down foreign materials. This interaction could potentially be more pronounced with WBCs compared to RBCs due to their role in responding to foreign substances.
Detection and Identification
Advanced Techniques Required: Detecting GO contamination in blood cells would require advanced microscopy and spectroscopy techniques. Routine blood tests and standard microscopic examinations would not be able to identify graphene oxide specifically.
Laboratory Analysis: Specific tests, such as electron microscopy, Raman spectroscopy, and atomic force microscopy, could be used to detect and confirm the presence of graphene oxide on or within blood cells. These techniques can identify the unique structural and chemical properties of GO.
Health Implications and Detoxification
Health Risks: The health risks associated with graphene oxide contamination in blood cells are not fully understood and are the subject of ongoing research. Potential risks could include oxidative stress, inflammation, and immune responses.
Detoxification: If contamination were confirmed, addressing it would involve removing the source of exposure and supporting the body’s natural detoxification processes. Medical treatments might focus on managing any symptoms or health effects caused by the contamination.
Conclusion
While it is possible for RBCs or WBCs to be contaminated with graphene oxide under specific conditions, such occurrences would require significant exposure to GO. Detection and confirmation would require specialized laboratory techniques. If there is concern about potential GO contamination, consulting with medical and scientific professionals for proper testing and analysis is crucial.
Is this a circuit? Is the brown yellow color grafine oxide? Lets ask TT. RR
Could mesogen liquid crystal polymers be made from grafine oxide? RR
ChatGPT
Mesogen liquid crystal polymers (LCPs) are typically composed of rigid, rod-like molecules known as mesogens, which align to form ordered structures with unique optical and mechanical properties. Graphene oxide (GO), with its distinct structural and functional properties, has been investigated for various advanced materials applications, including its potential use in liquid crystal systems. Here's an exploration of how graphene oxide might be used to create mesogen liquid crystal polymers:
Potential Integration of Graphene Oxide in Liquid Crystal Polymers
Graphene Oxide as a Functional Component:
Functionalization: Graphene oxide can be chemically functionalized to introduce mesogenic groups or other reactive moieties. This functionalization allows GO to interact with or be integrated into liquid crystal polymers.
Hybrid Materials: GO can be used to create hybrid liquid crystal materials, where GO sheets are incorporated into the liquid crystal matrix, potentially enhancing mechanical strength, thermal stability, and electrical conductivity.
Alignment and Interaction:
Alignment with Liquid Crystals: The planar structure of GO can interact with the rod-like mesogens of liquid crystals, potentially influencing their alignment and order. This interaction can be used to tune the properties of the liquid crystal polymer.
Directed Self-Assembly: By controlling the functionalization and dispersion of GO in the liquid crystal matrix, directed self-assembly can be achieved, leading to new materials with tailored properties.
Synthesis Approaches:
Polymerization: GO can be incorporated into the polymer backbone during the polymerization process, creating a composite material where GO is covalently bonded to the liquid crystal polymer.
Blending: GO can be physically blended with liquid crystal monomers or pre-polymers, followed by polymerization or curing to create a composite material.
Properties and Applications
Enhanced Properties:
Mechanical Strength: The incorporation of GO can improve the mechanical properties of liquid crystal polymers, making them stronger and more durable.
Thermal Stability: GO can enhance the thermal stability of liquid crystal polymers, making them suitable for high-temperature applications.
Electrical Conductivity: GO can impart electrical conductivity to liquid crystal polymers, potentially useful in electronic and optoelectronic applications.
Potential Applications:
Displays: Enhanced liquid crystal displays with improved durability and performance.
Sensors: Responsive materials for sensing applications, leveraging the unique properties of GO.
Smart Materials: Advanced materials for adaptive and smart systems, benefiting from the tunable properties of liquid crystal polymers with GO.
Conclusion
While graphene oxide itself is not a mesogen, it can be used to create mesogen liquid crystal polymers through functionalization and incorporation into the liquid crystal matrix. The integration of GO into liquid crystal polymers can enhance their mechanical, thermal, and electrical properties, opening up new possibilities for advanced materials and applications. The development of such materials involves sophisticated chemical synthesis and processing techniques, but the potential benefits make this an exciting area of research and innovation.
The photo of the fibrous looking (worm-like) object, is this your photo Richard, do you have any other pictures like this. I have been suffering with an abscess/boil type situation, in short I saw some similar objects in two samples of pyocytes now. The first time I was a bit disturbed by them, but put it down to stray fibres contaminating the sample, but then second collection I was super vigilantly clean, maybe not clean enough again as similar objects as in your photo I observed again. I'll be making a post about these samples soon, but I'm collecting data to such an extent it gets overwhelming and I find it difficult to prioritize my findings and just how much to send out too the world for feedback. And finally, do you have any video footage of the worm-like-fibres?
"Graphene oxide is a single-atomic-layered material".
I know it's an obvious observation to make, but for graphene oxide to form then surely it would need a substrate to form on, or be applied to? It's anyone's guess as to what substates would be suitable for oxide to be applied to as opposed to formed on. Formations like every day common rust forms on iron, graphene oxide is an oxide formed on graphene I would think. I'm no chemist, that's just my thinking on it as it stands right now.