TITANIUM DIOXIDE AND GRAPHENE OXIDE IN THE HUMAN BODY THROUGH CONSUMER PRODUCTS

Titanium Dioxide is considered Nanoparticles and nano material as Titanium Dioxide Nanoparticles (TiO) NPs) are indeed a type of nanomaterial.

They are used in many products,

including:

- sunscreen

- paint

- plastics

- and paper

Titanium Dioxide Applications

Personal products you may use daily and think are harmless:

- cosmetics

- suntan lotion

- socks

- and sports clothes

....... most all may contain atom-sized nanotech particles, some of which have been shown to sicken and kill workers in plants using nanotechnology.

Known human health risks include severe and permanent lung damage.

Cell studies indicate genetic DNA damage. Extremely toxic to aquatic wildlife, nanoparticles pose clear risks to many species and threaten the global food chain.

Nanotech particles have been embraced by industry as the wonder ingredient in personal hygiene products, food packaging, paints, medical procedures and pharmaceuticals;

....... even tires and auto parts, among burgeoning numbers of other consumer products.

Cosmetic companies add titanium dioxide nanoparticles to sun creams to make them transparent on the skin.

Sports clothing firms have introduced odor-free garments containing nanosilver particles that are twice as toxic to bacteria than bleach.

Auto industry companies have added carbon nanofibers to tires and body panels to strengthen them.

https://www.bibliotecapleyades.net/ciencia/ciencia_nanotechnology07.htm

List of Foods with Titanium Dioxide

Titanium dioxide is a common additive in various food products, known for its role as a coloring agent. Below is a comprehensive list of foods that often contain titanium dioxide.

Bakery Products

Frostings and Icing:

- Used to achieve a bright white color and smooth texture.

- Cakes: Some commercial cakes, especially those with white or colored icing.

- Donuts: Often found in glazed donuts to enhance appearance.

- Dairy Products

- Cheese: Processed cheese may contain titanium dioxide to improve color consistency.

- Yogurt: Certain flavored yogurts use it for a uniform appearance.

- Ice Cream: Particularly in novelty ice cream products and white or pastel-colored varieties.

Confectionery

- Candies: Many colorful or white candies and gum contain titanium dioxide.

- Chewing Gum: Used to achieve a bright, uniform color.

Processed Foods

- Sauces: Some sauces, particularly white sauces or gravies, may include titanium dioxide.

- Soup Mixes: Instant soup powders and mixes can contain this additive.

- Ready Meals: Certain packaged ready meals use titanium dioxide to enhance visual appeal.

Snacks

- Potato Chips: Some brands add it to achieve a consistent color.

- Snack Bars: Certain snack bars, particularly those with white coatings or fillings.

Beverages

- Drink Mixes: Some powdered drink mixes and beverages use titanium dioxide for color uniformity.

- Energy Drinks: Specific brands may use it in their formulations.

Miscellaneous

- Canned Foods: Some canned foods, especially those with sauces or coatings, may include titanium dioxide.

- Processed Fruits: In certain processed or preserved fruit products.

- Over the Counter Pain Medications: medication such as Exedrine and other headache relievers contain Titanium Dioxide Nanoparticles

This list covers a variety of food products that commonly contain titanium dioxide. For specific brands or products, always check ingredient labels for detailed information;

....... and always look for Bioengineered food in the ingredients list; ....... if its not in the food ingredients list they hide the Bioengineered information under a QR Code called "Smart Label";

....... then scan the QR Code "Smart Label" to reveal where that particular products Bioengineered Warning was hiding.

Titanium Dioxide in other uses

Biomedical uses for Titanium Dioxide

Biomedical uses for Titanium Dioxide include:

- Used in drug delivery

- cancer treatment

- imaging

- and biosensors

Environmental:

- Used to remove

pollution from water and air

Agricultural:

- Used as nano-fertilizers to

improve plant physiology

Industrial:

- Used to adsorb heavy metals

from wastewater

Personal care:

- Used in sunscreen and other products

Properties

• Low toxicity

Antibacterial properties

Resistant to body fluids and corrosion

Photocatalytic properties, such as

inactivating bacteria and killing cancer

cells

Safety:

- Evidence suggests that Tid, NPs [titanium dioxide] can accumulate in the body over time and cause genetic damage

Titanium Dioxide are Nanoparticles

Nanoparticles are tiny particles that

are less than 100 nanometers in

diameter. They are so small that they

are invisible to the human eye.

Properties:

- Size: Nanoparticles are one billionth of a meter in size.

Properties:

- Nanoparticles have different physical and chemical properties than bulk materials of the same composition.

Reactivity:

- Nanoparticles have different chemical reactivity, energy absorption, and biological mobility than bulk materials.

Uses

Medicine:

- Nanoparticles are used in medical imaging

- drug delivery

- and biosensors

Electronics:

- Nanoparticles are used in electronics.

Energy:

- Nanoparticles are used in energy.

Environmental science:

- Nanoparticles

are used in environmental science.

Toxicity:

- Inhalation, Inhaled nanoparticles can cause inflammation, asthma, and other lung diseases

Neurotoxicity:

- Inhaled nanoparticles can deposit in the central nervous system and cause neurotoxicity

Examples:

- Titanium oxide: A mineral nanoparticle used in sunscreen

Titanium Dioxide is considered a nano material. Nanomaterials are a class of materials where the individual units have at least one dimension below 100 nanometers. They can be made of any element and

are commonly classed into organic,

inorganic, and hybrid materials.

Nanomaterials are usually considered to be materials with at least one external

dimension that measures 100 nanometres

or less or with internal structures

measuring 100 nm or less. They may be in

the form of particles, tubes, rods or fibres.

Titanium Oxide is used in Microchip Implantation

Titanium dioxide (Tio2,) is used in

microchips and other electronic

devices. Tio2, is a transition metal oxide that has many applications in the

electronics industry.

How is titanium dioxide used in

microchips:

Adhesive:

- A thin layer of Tio2, can act as an adhesive between different materials in a chip. This allows engineers to use copper, gold, or silver wiring instead of aluminum wires

Microreactor:

- A microchip can contain a microreactor covered with TiO.

Electrodes:

- Tio2, can be used to make flexible, low-cost electrodes for medical devices. These electrodes can detect biosignals and stimulate muscles.

Other applications of titanium dioxide

Solar energy:

- Tio2, is a semiconductor that can be used in solar cells to convert solar energy into electricity or fuel.

Photocatalysis:

- Tio2, can be used to

decompose pollutants and in the

photodynamic treatment of cancer and bacterial infections

UV protection:

- Tio2, nanomaterials are used in UV protection products

Food:

- Tio2, nanoparticles are used in food products.

Personal hygiene:

- Tio2, nanoparticles

are used in personal hygiene products

Building materials:

- Tio2, nanoparticles

are used in paints, plasters, and tiles.

Is titanium dioxide a

nanotechnology?

Ultrafine Tio2 is believed to be one of the three most produced nanomaterials,

along with silicon dioxide

nanoparticles and zinc oxide

nanoparticles. It is the second most

advertised nanomaterial in consumer

products, behind silver nanoparticles.

Do Oreos contain titanium dioxide?

Did you know the bright white filling in your favorite Oreo cookies contains a secret ingredient tied to billion- dollar corporate espionage? ) ....... That additive is is known as titanium dioxide (Tio2) - a white pigment used in countless products from paint to plastics.

Why is titanium dioxide in tampons!?

Titanium dioxide is used as a pigment in the thread attached to tampons.

What are the side effects of titanium

dioxide?

The following acute (short-term) health

effects may occur immediately or shortly

after exposure to Titanium Dioxide: Exposure can irritate the eyes, nose and

throat. since it has been shown to cause

lung cancer in animals. a carcinogen.

So why is Titanium Dioxide in Tampons......?

STERILITY Thats Why they place Titanium Dioxide in Tampons, aka POPULATION CONTROL.

PVS: [Back in the 90s Wal-Mart induced RFID-Tags on certain inventory products.

RFID = Radio-Frequency Identification

Radio-frequency identification uses electromagnetic fields [gwen/EMF/cell towers] to automatically identify and track tags attached to objects. RFID is a specific application of RF technology used for identifying and tracking people as well. RFID systems consist of tags, readers, and antennas.

An RFID system consists of a tiny radio transponder called a tag, a radio receiver, and a transmitter. Radiofrequency identification (RFID) microchips are used to remotely identify objects, e.g. an animal in which a chip is implanted.

A passive RFID microchip absorbs energy from an external source and emits a radiofrequency identification signal which is then decoded by a detector.

The RFID censors I delt with at Wal-Mart in the 90s were like microchips the size of a small grain of rice; ....... and guess which products it was covertly attached to and where exactly it was applied with absolutely no disclaimers what so ever to the General Public?

The RFID Tags were placed in Women's Underware Panties/Knickers; .......The RFID Microchips were sewn into the inner crotch area of all the Panties Knickers and underware, right where the opening of the Vagina would be;

.......The RFID Microchip would be pressing againt that fertile energy zone.

Again; I feel that was and is all about STERILITY aka POPULATION CONTROL aka AGENDA 21 and AGENDA 2030

Titanium Dioxide can contain Graphene Oxide

Yes, titanium dioxide (Tio2,) can contain

graphene oxide!(GO).

The combination

of Tio2, and Go is called a

nanocomposite!

How is Tio2 combined with GO?

Electrostatic

Attraction:

- GO and Tio2,

particles can form heteroaggregates

through electrostatic attraction

- Hydrothermal process: Tio2,

nanoparticles can be grown on GO

platelets through a hydrothermal

process.

Electrospinning:

- Tio2, and rGO can be combined to form nanofibers through electrospinning

What are the sources of graphene

oxide?

Graphene is found in charred roasted meat and also in plant charcoal, which is present

in the infant's gripe water. Graphene as

graphene oxide (GO) is produced on

charring the surface of meat on a barbecue forming nitrogen doped GO originating from the pyrolysis of protein in air.

What does graphene oxide do to

blood cells?

...... structure results in peculiar

interactions with blood proteins,

potentially causing serious repercussions

such as thrombogenicity and immune

cell activation. Our findings revealed reduced cell viability and proliferation, and increased oxidative stress and DNA damage, even

with low graphene oxide concentrations.

How do you activate graphene oxide?

Constant magnetic field [5g cell towers] may be used to activate graphene oxide layers. Level of graphene oxide activation depends on constant magnetic field strength. Activation of graphene oxide is stable in time.

What would graphene oxide do to

the human body?

....... oxide induces cytotoxicity by

increasing LDH leakage in a variety of cancer cells, including ovarian cancer, neuroblastoma, and human lung cancer

cells. Blood exposure to graphene oxide may

cause anaphylactic death in non-human

primates.

How do you reduce graphene oxide?

Reduced graphene oxide (GO) consists of a few sheets of carbon that are usually derived from GO powders prepared by

Hummers' method and then reduced to

lower the oxygen content. This reduction

process can occur using chemicals such as hydrazine hydrate, strong acids (HNO3 or

H2S04), or heating [124,138,139].

What are the symptoms of graphene

in the body?

One of the more common symptoms of graphene oxide contact with the blood is clotting, also known as thrombogenicity. Toxicity studies in animals also show an

increase in immunoglobulin E, lung damage,

and signs of an anaphylactic response when

graphene oxide contacts lung tissue.

What dissolves graphene oxide?

The solubility of GO in water is limited only by the formation of a nematic phase and by the associated viscosity of solutions at high

GO concentrations.

It was also reported that GO is soluble in organic solvents such as:

- DMF

- N-methyl-2-pyrrolidone

- and ethylene glycol

What is the antidote of graphene

oxide?

Humic Acid Acts as a Natural Antidote of

Graphene by Regulating Nanomaterial

Translocation and Metabolic Fluxes in Vivo.

What dissolves graphene?

By far the most widely used solvent for dispersing graphene is NMP, where sonication of graphite can yield stable G dispersions in the range of 0.01-2 mg.

Does hydrogen peroxide break down

graphene oxide?

Graphene oxide breaks down in the

presence of hydrogen peroxide, in a reaction catalysed by the myeloperoxidase

enzyme. The degree of degradation

depends on the colloidal stability of the suspension, which indicates that the hydrophilic nature of graphene oxide is a key factor in its breakdown by enzymes.

Can graphene oxide cross the blood

brain barrier?

Like all other nano/micro materials,

graphene-based materials, when

administered systemically, must cross the

blood-brain barrier (BBB) in order to

access the brain. The BBB is an essential regulatory layer at the neural interface with

the brain vasculature, which acts as a selective barrier.

Which drugs use graphene oxide?

These emerging uses due to its high surface area, mechanical properties, and the

chemical structure with high number of

oxygenic functional groups. Due to this, graphene oxide has been used to absorb

many drugs, including doxorubicin and

paclitaxel.

What are the sources of graphene

oxide?

Graphene Oxide (GO) is a carbon-based

nanomaterial obtained by the chemical

oxidation of natural graphite or carbon

nanofibers.

What can break down graphene?

UV light initiates an oxidation process that fragments a water-dispersible form of graphene and eventually

decomposes the material, as

indicated by the gradual lightening of the solutions shown here: https://cen.acs.org

How do you reduce graphene oxide?

Reduced graphene oxide (rGO) refers to the graphene-like nanosheet, which is prepared by the reduction of GO via chemical reduction, electrochemical reduction, and thermal reduction. rGO has higher electrical and thermal conductivity than GO due to the reduction of oxygen groups.

What removes graphene oxide from

water?

Floc-flotation can remove up to 98% of the GO nanoparticles from water. Floc-flotation can result in a much less environmental

concern for GO in natural water bodies.

The Nano-level

The nano-level represents the overlap between traditional physics and quantum mechanics. At this scale the physical, chemical, and biological properties of materials differ in fundamental ways from the properties of either individual atoms or bulk matter.

This makes the prediction of cause and effect relationships much more difficult and introduces phenomena such as quantum tunneling, superposition, and entanglement.

As a result, material at the nanoscale can exhibit surprising characteristics that are not evident at large scales. For example:

Collections of gold particles can appear orange, purple, red, or greenish, depending upon the specific size of the particles making up the sample.

Carbon atoms in the form of a nanotube exhibit tensile strengths 100 times that of steel and can be either metallic or semiconducting depending on their configuration. Titanium dioxide and zinc oxide, common ingredients in sun screen, both appear white when made of macro particles.

But when the particles are ground to the nanoscale, they appear translucent.

The Progression of Nanotechnology

Why now?

If it seems that nanotechnology has begun to blossom in the last ten years, this is largely due to the development of new instruments that allow researchers to observe and manipulate matter at the nanolevel.

Technologies such as scanning tunneling microscopy, magnetic force microscopy, and electron microscopy allow scientists to observe events at the atomic level.

At the same time, economic pressures in the electronics industry have forced the development of new lithographic techniques that continue the steady reduction in feature size and cost.

Just as Galileo’s knowledge was limited by the technology of his day, until recently a lack of good instrumentation prevented scientists from gaining more knowledge of the nanoscale.

As better instrumentation for observing, manipulating and measuring events at this scale are developed, further advances in our understanding and ability will occur.

One leader in nanotechnology policy has identified four distinct generations in the development of nanotechnology products, to which we can add a possible fifth.

Passive Nanostructures (2000-2005)

During the first period products will take advantage of the passive properties of nanomaterials, including nanotubes and nanolayers.

For example, titanium dioxide is often used in sunscreens because it absorbs and reflects ultraviolet light.

When broken down into nanoparticles it becomes transparent to visible light, eliminating the white cream appearance associated with traditional sunscreens.

Carbon nanotubes are much stronger than steel but only a fraction of the weight. Tennis rackets containing them promise to deliver greater stiffness without additional weight.

As a third example, yarn that is coated with a nanolayer of material can be woven into stain-resistant clothing. Each of these products takes advantage of the unique property of a material when it is manufactured at a nanoscale.

However, in each case the nanomaterial itself remains static once it is encapsulated into the product.

Active Nanostructures (2005-2010)

Active nanostructures change their state during use, responding in predicable ways to the environment around them.

Nanoparticles might seek out cancer cells and then release an attached drug. A nanoelectromechancial device embedded into construction material could sense when the material is under strain and release an epoxy that repairs any rupture.

Or a layer of nanomaterial might respond to the presence of sunlight by emitting an electrical charge to power an appliance.

Products in this phase require a greater understanding of how the structure of a nanomaterial determines its properties and a corresponding ability to design unique materials.

They also raise more advanced manufacturing and deployment challenges.

Systems of Nanosystems (2010-2015)

In this stage assemblies of nanotools work together to achieve a final goal.

A key challenge is to get the main components to work together within a network, possibly exchanging information in the process.

Proteins or viruses might assemble small batteries. Nanostructures could self-assemble into a lattice on which bone or other tissues could grow. Smart dust strewn over an area could sense the presence of human beings and communicate their location.

Small nanoelectromechancial devices could search out cancer cells and turn off their reproductive capacity.

At this stage significant advancements in robotics, biotechnology, and new generation information technology will begin to appear in products.

Molecular Nanosystems (2015-2020)

This stage involves the intelligent design of molecular and atomic devices, leading to “unprecedented understanding and control over the basic building blocks of all natural and man-made things.”

Although the line between this stage and the last blurs, what seems to distinguish products introduced here is that matter is crafted at the molecular and even atomic level to take advantage of the specific nanoscale properties of different elements.

Research will occur on the interaction between light and matter, the machine-human interface, and atomic manipulation to design molecules.

Among the examples that Dr. Roco foresees are “multifunctional molecules, catalysts for synthesis and controlling of engineered nanostructures, subcellular interventions;

....... and biomimetics for complex system dynamics and control.”

Since the path from initial discovery to product application takes 10-12 years, the initial scientific foundations for these technologies are already starting to emerge from laboratories.

At this stage a single product will integrate a wide variety of capacities including:

- independent power generation

- information processing and communication

- and mechanical operation

Its manufacture implies the ability to rearrange the basic building blocks of matter and life to accomplish specific purposes.

Nanoproducts regularly applied to a field might search out and transform hazardous materials and mix a specified amount of oxygen into the soil.

Nanodevices could roam the body, fixing the DNA of damaged cells, monitoring vital conditions and displaying data in a readable form on skin cells in a form similar to a tattoo.

Computers operate by reading the brain waves of the operator.

The Singularity (2020 and beyond)

Every exponential curve eventually reaches a point where the growth rate becomes almost infinite.

This point is often called the Singularity. If technology continues to advance at exponential rates, what happens after 2030?

Technology is likely to continue, but at this stage some observers forecast a period at which scientific advances aggressively assume their own momentum and accelerate at unprecedented levels;

....... enabling products that today seem like science fiction. Beyond the Singularity, human society is incomparably different from what it is today.

Several assumptions seem to drive predictions of a Singularity:

- The first is that continued material demands and competitive pressures will continue to drive technology forward.

- Second, at some point artificial intelligence advances to a point where computers enhance and accelerate scientific discovery and technological change. In other words, intelligent machines start to produce discoveries that are too complex for humans.

- Finally, there is an assumption that solutions to most of today’s problems including material scarcity, human health, and environmental degradation can be solved by technology, if not by us, then by the computers we eventually develop

....... Whether or not one believes in the Singularity, it is difficult to overestimate nanotechnology’s likely implications for society.

For one thing, advances in just the last five years have proceeded much faster than even the best experts had predicted.

Looking forward, science is likely to continue outrunning expectations, at least in the medium term.

Although science may advance rapidly, technology and daily life are likely to change at a much slower pace for several reasons:

- First, it takes time for scientific discoveries to become embedded into new products, especially when the market for those products is uncertain.

- Second, both individuals and institutions can exhibit a great deal of resistance to change.

....... Because new technology often requires significant organizational change and cost in order to have its full effect, this can delay the social impact of new discoveries.

PVS

And Resources:

https://www.bibliotecapleyades.net/ciencia/ciencia_nanotechnology01.htm

PFD Titanium Dioxide Nanoparticles in Food and Personal Care Products: https://www.bibliotecapleyades.net/archivos_pdf/titanium-dioxide-nanoparticles-food-personalcare-products.pdf

#ParrisVstefanow #TitaniumDioxide #GrapheneOxide #Nanotechnology #Transhuman #4IR #WEF #PopulationControl #MindControl #Agenda21 #Walmart #EMF #RFID #RFsignals #Microchip #Implants