does thieves essential oil kill germs

Does thieves oil kill bacteria and viruses?

Several of the oils found in thieves oil have antimicrobial properties. This means they may help kill bacteria, fungi, or viruses when people use them topically on the skin or small cuts and wounds. For example, in another older study

Will diffusing thieves oil disinfect a room?

3 Will diffusing Thieves oil disinfect a room? I have already done many experiments which suggest that essential oils like Thieves and On Guard kill germs in on a hard surface. You can see those results on this page .

Does diffusing essential oils kill germs?

Does diffusing essential oils kill germs? Answer: My experiments show that the vapor from a diffuser with Young Living Thieves oil or do Terra On Guard oil does inhibit bacterial growth, but it won't disinfect a whole room. 1 Does diffusing thieves oil kill germs? 2 Does diffusing On Guard kill germs? 3 Will diffusing Thieves oil disinfect a room?

Is thieves oil safe for children?

Some people say that Thieves oil is not safe for children. Just because something is "natural" or "organic" doesn't mean it is safe. Does diffusing thieves oil kill germs? I designed an experiment to determine if the vapor coming out of a diffuser with thieves oil kills bacteria on an agar plate.

What percentage of germs does thieves kill?

Recent studies have shown Thieves Oil, and the essential oils of clove, cinnamon, and lemon, are 99.6% effective in killing viruses and bacteria (including E. Coli, MRSA, TB) on surfaces, AS WELL AS many airborne invaders, including staph.

Where do you put thieves oil when sick?

7. Cold and Flu Protection. Put a couple drops directly on the soles of your feet to protect you from colds and flu.

Is thieves a natural disinfectant?

Thieves oil can be used as a natural disinfectant around your home.

What essential oil kills the most germs?

Essential oils of peppermint, orange or lemongrass kill most strains of fungal and bacterial infections. Posit Health News.

What does putting Thieves on your feet do?

Dilute Thieves with regular olive oil and rub it on the soles of the feet (or along the spine for particularly nasty bugs). This will help your body absorb their purifying properties and jump start your immune response to sickness.

How does Thieves help immune system?

Thieves oil contains antimicrobial properties, which can be effective against airborne microorganisms. Some of the potential benefits are boosting immune function, and fighting infections. It's been used for years as an antiviral, antiseptic to protect the body from the flu and colds.

Does Thieves oil really clean?

The mixtures of antiseptic, antibacterial, and antimicrobial properties were able to stave off the Plague and keep these merchants safe. Because of its antibacterial properties, Thieves Oil is a great all-around cleaner.

Does Thieves oil purify the air?

Thieves essential oil blends of clove, lemon, cinnamon bark, eucalyptus, and rosemary oils, creating a clean, fall-like aroma. This combination of citronella, lavandin, lemongrass, rosemary, myrtle, and tea tree oils is designed specifically to purify your air and keep your home smelling fresh.

How many drops of Thieves should I diffuse?

The Young Living site specifies for the Aromatic use of Thieves- Diffuse up 6-8 drops for up to 10 minutes 3 times daily. Using the intermittent setting along with minimal drops may be a safe way to diffuse as long as your room size is larger than the specified size for the diffuser.

Do essential oils actually disinfect?

They help deodorize surfaces. Since they have fresh scents, they also make your home smell good. Some older research has shown that essential oils might have disinfectant properties. They may be effective against viruses and bacteria.

What essential oils are sanitizing?

The lavender and tea tree essential oils both have natural disinfecting properties. Tea tree oil is also antiviral and antifungal. It's often used to treat minor skin scrapes and fungal skin infections. Tea tree oil can be a bit pungent on its own, but the lavender complements the oil's piney fragrance.

What essential oils are good for killing viruses?

Tea tree oil has been found to have antiviral and antimicrobial properties, and may be able to inactivate airborne viruses when applied to an air filter. Diffuse tea tree oil in your home or use it in a diluted cleansing formula to clean household surfaces.

Where do you put Thieves on your body?

1:013:44How to Use Thieves Vitality Essential Oil by Young Living - YouTubeYouTubeStart of suggested clipEnd of suggested clipTake it that way I my personal favorite is I add it into a veggie capsule. That's just the easiestMoreTake it that way I my personal favorite is I add it into a veggie capsule. That's just the easiest way for me to take oil internally.

Can you put thieves oil on your throat?

Cinnamon oil is one of the ingredients that makes thieves oil so beneficial for throat pain. Using thieves oil for a sore throat is a great way of supporting your immune system, while also soothing the pain and dryness that comes with a sore throat.

Can I put thieves oil in my mouth?

A: Sure you can. Just take glass of water, add few drops of Thieves essential oil and use it as a mouth wash.

What to put in a diffuser when you're sick?

Chamomile, eucalyptus, and lemon essential oils are good choices to ease muscle tension and provide relief from aches, soreness, and general cold symptoms.

What are the benefits of thieves oil?

The potential benefits of thieves oil include boosting the immune system, promoting respiratory health, and fighting microbes. Although some of these benefits are anecdotal, the individual components of thieves oil have been shown to have antimicrobial properties, promote wound healing, and may provide pain relief.

What is thieves oil?

Thieves oil is actually a blend of several essential oils, most often: Cinnamon: Made from the bark, leaves, or twigs of several species of cinnamon tree. Clove: Made from the undeveloped buds of the flowers found on the Eugenia caryophyllata species of clove tree. Eucalyptus: Obtained from the leaves of Eucalyptus plants, ...

What is the best essential oil concentration for sensitive skin?

The National Association for Holistic Aromatherapy recommends that the final essential oil concentration be 1 to 2.5 percent for normal skin and 0.5 to 1 percent for sensitive skin.

How does steam inhalation work?

Steam inhalation involves adding essential oils to a bowl of steaming water. The hot water vaporizes the oil, allowing it to be inhaled with the steam. This application may help with respiratory congestion or sinus issues.

What is the best way to diffuse oil in water?

Optional: Add a dispersing agent, such as solubol, to the solution. This helps the oil diffuse better in the water.

Is clove oil a skin irritant?

Both cinnamon and clove oil are potential skin irritants. If topical application of thieves oil causes redness, swelling, or itching, avoid using it in the future.

Can thieves oil be used as massage oil?

You can also make massage oils using essential oils. To do this, the thieves oil must be diluted in another type of oil, which is called a carrier oil. Carrier oils can include things like jojoba oil and coconut oil. Don’t apply essential oils directly on the skin unless diluted in a carrier oil.

How does ATP production occur in prokaryotes?

The production of ATP in prokaryotes occurs in both the cell wall and cytosol by glycolysis, and a correlation between the intracellular and extracellular ATP concentration has been demonstrated. EOs disrupt the cell membrane alter the intracellular and external ATP balance such that ATP is lost through the disturbed membrane [12,92,93]. The treatment of E. coli0157:H7 strain EDL 933 and Salmonella entericasubsp entericaserovar typhistrain ATCC 19430 with mustard EO resulted in the loss of intracellular ATP in S. aureus[94]. The use of oregano EO in combination with the irradiation of L. monocytogenesand S. aureusresulted in a more significant reduction of their intracellular ATP levels [95,96]. Other intracellular events may contribute to the intracellular ATP decrease; for example, inorganic phosphate may have been lost by passing through the compromised permeable membrane [93,94,95,96,97], or the proton motive force and changes in the balance of some essential ions, such as K+ and H+, may have been disrupted [36]. The treatment of some pathogens, such as E. coliand L. monocytogenes, with eugenol, cinnamaldehyde and carvacrol inhibited the generation of adenosine triphosphate from dextrose and disrupted the cell membrane. An analysis of the intracellular and extracellular ATP levels of cells treated with eugenol, cinnamaldehyde and carvacrol suggested that these compounds might inhibit the ATPase activity of bacterial cells. However, although similar concentrations of eugenol or carvacrol (5 to 10 mM) may have a bactericidal effect on E. coliand L. monocytogenes, there are large differences in response between the three organisms to cinnamaldehyde, which has bactericidal activity against E. coliand L. monocytogenes,at 10 mM and 30 mM concentrations [45]. A possible explanation for the difference in the behaviour of the three bacterial species in response to cinnamaldehyde is that there may be differences in the ability of this small hydrophobic molecule to interact with the outer surface of the cells and thus gain access to the cell membrane. Some components of the EOs, such as eugenol, carvacrol and cinnamaldehyde, are capable of inhibiting the membrane-bound ATPase activity of E. coliand L. monocytogenes. Bacterial membranes have multiple enzymes with ATPase activity, including ATP-dependent transport proteins and the F1F0 ATPase that is involved in ATP generation and cellular pH regulation [26]. Gill and Holley [64] hypothesised that ATPase inhibition could represent a secondary factor rather than a primary cause of cell death. However, they also suggested that ATPase inhibition may play a significant role in reducing the growth rate at sub-lethal concentrations. Non-specific inhibition of membrane-bound or -embedded enzymes can be caused by small hydrophobic molecules as a result of changes in the protein conformation. This mechanism may cause the inhibition of ATPase activity, as well as the inhibition of other enzymes and altered bacterial growth [13,27,47,96,98].

What is the cell wall of Gram-positive bacteria?

Their effect depends on the amount of the compound present; at low concentrations, they can interfere with enzymes involved in the production of energy, and at higher concentrations, they can denature proteins [7]. The cell wall of Gram-negative bacteria is more complex. It has a peptidoglycan layer that is 2–3 nm thick, which is thinner than in the cell wall of Gram-positive bacteria , and composes approximately 20% of the dry weight of the cell. An outer membrane (OM) lies outside of the thin peptidoglycan layer. The peptidoglycan and OM are firmly linked by Braun’s lipoprotein; this protein is covalently bound to the peptidoglycan and is embedded in the OM. The presence of an OM is one of the features that differentiate Gram-negative from Gram-positive bacteria. It is composed of a double layer of phospholipids that is linked to inner membrane by lipopolysaccharides (LPS). The peptidoglycan layer is covered by an OM that contains various proteins as well as LPS. LPS consists of lipid A, the core polysaccharide, and the O-side chain, which provides the “quid” that allows Gram-negative bacteria to be more resistant to EOs and other natural extracts with antimicrobial activity. Small hydrophilic solutes are able to pass through the OM via abundant porin proteins that serve as hydrophilic transmembrane channels, and this is one reason that Gram-negative bacteria are relatively resistant to hydrophobic antibiotics and toxic drugs [8,9]. The OM is, however, almost but not totally impermeable to hydrophobic molecules, some of which can slowly traverse through porins [10,11]. The mechanisms of action of EOs and/or their components are dependent on their chemical composition. For instance, thymol and carvacrol have similar antimicrobial effects but have different mechanisms of action against Gram-positive and Gram-negative bacteria. The location of one or more functional groups on these molecules can affect their antimicrobial activity. Thymol is structurally analogous to carvacrol, but the locations of the hydroxyl groups differ between the two molecules. However, these differences do not affect the activity of either antimicrobial agent. The antimicrobial activity of other molecules, such as limonene and p-cymene, depends on the alkyl group. Thus, in some cases, limonene can be considered to be more effective than p-cymene [12]. EOs and/or their constituents can have a single target or multiple targets of their activity. For instance, trans-cinnamaldehyde can inhibit the growth of E. coliand S. typhimiriumwithout disintegrating the OM or depleting intracellular ATP. Similar to thymol and carvacrol, trans-cinnamaldehyde likely gains access to the periplasm and deeper portions of the cell. Carvone is also ineffective against the OM and does not affect the cellular ATP pool [13,14]. It is difficult to predict the susceptibility not only of a certain species but also a certain strain within the same species to the EOs. De Martino et al.[5,15] observed that two strains of Bacillus cereusbehaved differently when exposed to the same EOs and their singular components. Identifying the mode of action of EOs requires much study of the raw material until the singular components are identified, and the mode of action should also be studied in multiple strains and species of microorganisms. Expanding our basic knowledge of the molecules present in the EOs will support future studies into the comprehensive modes of antimicrobial action of EOs.

How does EO affect bacterial cells?

Diverse mechanisms have been described to explain the activity of an EO on bacterial cells. The activity of an EO can affect both the external envelope of the cell and the cytoplasm. The hydrophobicity that is typical of EOs is responsible for the disruption of bacterial structures that leads to increased permeability due to an inability to separate the EOs from the bacterial cell membrane. The permeability barrier provided by cell membranes is indispensable to many cellular functions, including maintaining the energy status of the cell, membrane-coupled energy-transducing processes, solute transport and metabolic regulation. The cell membrane is also essential for controlling the turgor pressure [59,60]. Toxic effects on membrane structure and function are generally used to explain the antimicrobial activity of EOs [61,62,63]. In fact, the mechanisms of action of the EOs include the degradation of the cell wall [13,64], damaging the cytoplasmic membrane, cytoplasm coagulation [18,33,65], damaging the membrane proteins, increased permeability leading to leakage of the cell contents [20,30], reducing the proton motive force [66], reducing the intracellular ATP pool via decreased ATP synthesis and augmented hydrolysis that is separate from the increased membrane permeability and reducing the membrane potential via increased membrane permeability [57]. Helander et al.[13] described the effects of different EO components on the OM permeability. Tea tree oil induced damage to the cell membrane structures that was accompanied by decreased viability for all three microorganisms included in their study, and the membrane damage was confirmed as the most likely cause of cell death. Thus, the hydrophobic nature of EOs allows them to penetrate microbial cells and cause alterations in its structure and functionality. This could explain why EOs are generally most effective, with some exceptions [67], against Gram-positive microorganisms. The external capsule of some Gram-negative bacteria limits or prevents the penetration of EOs into the microbial cell. The compounds present in the EOs are also capable of interfering with proteins in the wall that are often involved in the transport of essential molecules into the cell. Other authors have proposed that the components of the EO act in different manners to result in the loss of microbial viability. The effects of EOs usually lead to the destabilisation of the phospholipid bilayer, the destruction of the plasma membrane function and composition, the loss of vital intracellular components and the inactivation of enzymatic mechanisms. In some cases, essential oils also alter membrane permeability by destroying the electron transport system [68], and a number of components of the EOs, such as carvon, thymol and carvacrol, lead to an increase in the intracellular concentration of ATP, an event that is linked to the destruction of the microbial membrane [13]. Inhibiting electron transport for energy production and disrupting the proton motive force, protein translocation and synthesis of cellular components are all physiological changes that can result in cell lysis and death [19,29]. The integrity of the cell membrane is essential for the survival of bacteria because it is a key element for the fundamental biological activities taking place within the cells. The membrane represents an effective barrier between the cytoplasm and the external environment; the import and export of the metabolites and ions essential for all activities occurring in the microbial cell occur through the cell membrane. When antimicrobial compounds are present in the environment surrounding microorganisms, the bacteria may react by altering the synthesis of fatty acids and membrane proteins to modify the fluidity of the membrane [69]. The hydrophobicity of the EOs and their components allow them to diffuse through the double lipid layer of the membrane. The EOs can alter both the permeability and function of membrane proteins. Some EOs, particularly oils that are rich in phenolics, are able to insert into the phospholipids bilayer of bacterial cell walls, where they bind to proteins and prevent them from performing their normal functions [30]. This phenomenon indicates that the membrane is the first target of EOs. As previously reported, the mechanism of action of the EO is not isolated but instead involves a series of events both on the cell surface and within the cytoplasm. The alteration of membrane permeability and the defects in the transport of molecules and ions result in a “disbalance” within the microbial cell. This subsequently leads to cytoplasm coagulation, the denaturation of several enzymes and of cellular proteins and the loss of metabolites and ions [4]. In many conditions, such as in the presence of sub-lethal concentrations of EOs or other antimicrobial compounds, microorganisms react by increasing their expression of the stress-response proteins [25] to repair the damaged proteins [20]. However, when the concentration of EOs or other natural antimicrobials is higher, this response is unable to prevent cell death. This effect is more evident for Gram-positive bacteria. The cell wall of Gram-negative bacteria is more resistant to the activity of EOs and their components. The Gram-negative cell wall does not allow for the entrance of hydrophobic molecules as readily as Gram-positive bacteria; thus, EOs are less able to affect the cell growth of the Gram-negative bacteria [4]. Because of the wide variety of molecules present in the natural extracts, the antimicrobial activity of the EOs cannot be attributed to a single mechanism. Instead, different biochemical and structural mechanisms are involved [70] at multiple sites within the cell and on the cell surface. These mechanisms include chemical modifications of the cell membrane, cytoplasm, enzymes and proteins, and they can completely change the conformation of the microbial cell. Furthermore, the sustained loss of ions or metabolites due to exposure to an EO can compromise the microbial metabolism and lead to cell death [4,57]. For example, tea tree oil can cause E. colito die without lysing the cell [65]. Figure 2describes some potential mechanisms of action of the EOs and/or their components and shows the potential cell targets of their antimicrobial activity. However, each of these actions cannot be considered separate events but instead may be a consequence of the other activities.

How do bacteria interact with each other?

Bacteria coordinate both bacterium-bacterium interactions and associations with higher organisms through intercellular communication systems known as quorum sensing (QS) systems. QS-controlled behaviours occur only when bacteria reach a specific cell density. These behaviours are unproductive if undertaken by a singular bacterium but become effective when the action is simultaneously performed by a group of bacteria. QS can regulate a number of activities, such as virulence factor expression, bioluminescence, sporulation, biofilm formation and mating. The expression of the QS genes results in the production of chemical signalling molecules that are known as autoinducers or bacterial pheromones. These molecules are produced as the bacterial population grows until a threshold concentration perceived by the bacteria is reached, resulting in the activation or repression of specific genes. The accumulation of a stimulatory amount of the QS molecules can occur only when a specific number of cells, referred to as a quorum, are present [121]. Researchers are increasingly investigating herbal products in the quest for new therapeutic and anti-pathogenic agents that might act as nontoxic inhibitors of QS, thus controlling infections without encouraging the appearance of resistant bacterial strains [122]. EOs may represent the richest available reservoir of novel therapeutics [122,123,124]. Bacterial QS may be inhibited through different mechanisms, including (1) the inhibition of AHL synthesis, (2) the inhibition of AHL transport and/or secretion, (3) the sequestration of AHLs, (4) the antagonistic action and (5) the inhibition of targets downstream of AHL receptor binding [125]. Different EOs from ornamental plants have been observed to be effective against biofilms formed by Salmonella, Listeria, Pseudomonas, Staphylococcusand Lactobacillusspp. Volatile organic compounds, such as those produced by the rhizospheric bacteria Pseudomonas fluorescensB-4117 and Serratia plymuthicaIC1270, may inhibit the cell-cell communication QS network mediated by AHL signalling molecules produced by various bacteria, such as Agrobacterium, Chromobacterium, Pectobacteriumand Pseudomonas. The EOs of lavender, roses, geraniums, cloves and rosemary are also able to inhibit QS, whereas orange and juniper EOs appear to have no anti-QS properties [126,127,128,129,130,131]. Investigations into the effects of different EO components are in progress. One of the most well-studied EO components is cinnamaldehyde. Its effects have been investigated from diverse points of view, and multiple mechanisms of action have been examined. Niu and Afre [132] observed that the exposure of V. harveyiBB886 (the bioluminescence of this strain is induced by 3-hydroxy-C4-HSL) to a concentration of 60 μΜ cinnamaldehyde resulted in a 55% reduction of microbial bioluminescence, and 60% of the bioluminescence of V. harveyiBB170 (mediated by AI-2) was reduced at 100 μΜ, again demonstrating that the activity of plant extracts can be strain-specific and may depend on the QS molecule involved. Using the nematode model Caenorhabditis elegans, Brackman and colleagues [133,134] demonstrated the ability of 3,4-dichlorocinnamaldehyde to decrease the virulence of V. anguillarum, V. harveyiand V. vulnificusby affecting the DNA-binding ability of LuxR.

Which compounds are most studied as phenylpropenes?

These compounds represent a relatively small portion of EOs. Eugenol, isoeugenol, vanillin, safrole and cinnamaldehyde are the most studied phenylpropenes. Most antimicrobial activity of these molecules is conferred by their free hydroxyl groups [39].

What is the peptidoglycan layer?

The peptidoglycan layer is covered by an OM that contains various proteins as well as LPS. LPS consists of lipid A, the core polysaccharide, and the O-side chain, which provides the “quid” that allows Gram-negative bacteria to be more resistant to EOs and other natural extracts with antimicrobial activity.

What are the secondary metabolites of EOs?

EOs contain a wide series of secondary metabolites that can inhibit or slow the growth of bacteria, yeasts and moulds [3,4,5]. The EOs and their components have a variety of targets, particularly the membrane and cytoplasm, and in certain situations, they completely alter the morphology of the cells.

How long does it take for sanitizer to kill bacteria?

His own study only tested 3 types of bacteria and stated, “…44% reduction in the S. aureus bioaerosol following 10 min of exposure.” In the United States, sanitizers are agents that destroy 99.999% of bacteria in 30 seconds during the Official Detergent Sanitizer Test (a public health test) and disinfectants are products that destroy all organisms in 10 minutes during the AOAC Use Dilution Test, a test regulated by the EPA to determine the efficiency of disinfectants. As a matter of fact, these studies actually all prove that none of the oils even came close to this level of kill rates, some even after 24 hours! https://home.howstuffworks.com/home-improvement/household-hints-tips/cleaning-organizing/disinfecting-vs-sanitizing.htm

What essential oils are good for MRSA?

Warnke et al (2009)looked at the effect of several essential oils (Eucalyptus, Tea Tree, Thyme white, Lavender, Lemon, Lemongrass, Cinnamon, Grapefruit, Clove Bud, Sandalwood, Peppermint, Kunzea, and Sage) on antibiotic-resistant strains of bacteria (people get infected often through hospital stays). (I can say for a fact that MRSA which was tested in this study, has been running rampant in our local hospitals for several years.) They found that the strongest oils for inhibiting the bacteria were Thyme white, Lemon, Lemongrass, and Cinnamon. They also found that the other oils also demonstrated considerable efficacy and state that “essential oils represent a cheap and effective antiseptic topical treatment option even for antibiotic-resistant strains as MRSA and antimycotic-resistant Candida species“. (This article comes from a sound peer-reviewed journal I’m familiar with, the Journal of Cranio-Maxillofacial Surgery.) Warnke did another studyshowing the same results with a focus on Lemongrass, Eucalyptusand Tea Tree oils (2013).

Why did thieves rub essential oils on themselves?

The legend is that 15thcentury thieves rubbed these oils on themselves during the plague so as not to contract disease while robbing the dead and dying. There are many essential oil companies out there with their own Thieves-type formulations.

What is the ingredient in Thieves hand sanitizer?

For instance, their Hand Sanitizer’s main ingredient is “Denatured alcohol” which is the same ingredient in nearly all hand sanitizers. They just add some essential oils so it smells prettier but it’s the alcohol that’s killing the germs so instead of paying $0.99 they charge you $6.58 for a 1 oz. bottle! They have to put something in their product that makes it work because they are not allowed to call it a “sanitizer” unless it does. Here’s the link, just click on the Ingredients tab because there isn’t a direct link to the ingredients or scroll down to the list but don’t stop at Key Ingredients, be sure to go to the actual ingredients list. https://www.youngliving.com/en_US/products/thieves-waterless-hand-purifier

What is Young Living's Thieves blend?

Young Living’s Thieves blendis registered in Canada as a Natural Health Product, shown to help relieve cold s and coughs.

Why do I diffuse thieves essential oil?

Due to Bill’s weakened immune system, I diffused thieves essential oil everyday to prevent the spread of airborne illness from all the visitors and hospice workers. We were confined to our home. Everyone had to wash their hands upon entering. I made a foaming hand soap with thieves oil to kill surface germs too.

What are NHPs made of?

They are often made from plants, but can also be made from animals, microorganisms and marine sources. They come in a wide variety of forms like tablets, capsules, tinctures, solutions, creams, ointments and drops.”. A description of what products are now classified as NHPs can be found here: ...

Does diffusing thieves oil kill germs?

I designed an experiment to determine if the vapor coming out of a diffuser with thieves oil kills bacteria on an agar plate. I purchased a new bottle of Thieves oil from http://www.striveforhealthy.com/. Then, I borrowed a Young Living diffuser from a friend. I also purchased these ready-made agar plates. Next, I borrowed some of my children's Megablocks and built an apparatus to hold the agar plate upside down over the diffuser. The plate is 9.5 inches above the opening of the diffuser.

Will diffusing Thieves oil disinfect a room?

Many people have asked me to test and see if the vapor from a diffuser with thieves oil will kill germs further around a room. To test this, I decided to start in the smallest room in my house, the bathroom. The bathroom is an 11 feet by 5 feet rectangle. I got 3 agar plates really dirty by swabbing the floor, the sink, the bottom of a shoe, and the dog's mouth. I tried to get them as equally germy as possible. I put one agar plate next to the diffuser on the bathroom countertop. I put another plate 5 feet away on the edge of the bathtub. The plates did not have their lids on.

How long did the thieves plate run?

Then I put 1/2 cup of distilled water and 12 drops of Thieves into the diffuser and put the plate on top of my apparatus. It ran for 3 hours.

What did Luke do with a clean swab?

Lastly, with a clean swab, I swabbed the dog's mouth and collected some of his drool and rubbed that swab all over the same agar plate. Luke was not happy about that, but I gave him a piece of cheese afterwards. I scribbled and rubbed the swabs all around the plates so they should have had bacteria all over them.

How much Young Living Thieves oil should I put in a diffuser?

I put 12 drops of Young Living Thieves oil in the diffuser with 1/2 cup distilled water. The Young Living website says to use 8-12 drops of oil in the diffuser so I thought I'd try 12. I got those directions from this page of the Young Living website.

What do the dots on agar plates mean?

In case you are new to looking at agar plates, the whitish or yellowish dots you see are colonies (or piles) of millions of bacteria. Not every kind of bacteria can grow on these agar plates and viruses do not grow on these plates. So, just because a plate looks clean, doesn't mean that no germs whatsoever were present. Fungus can grow on these plates, so we are looking at bacteria and fungus.

Is thieves oil safe for children?

So, just because I'm doing these experiments where I'm diffusing oils, doesn't mean it is safe for you. Some people say that Thieves oil is not safe for children. Just because something is "natural" or "organic" doesn't mean it is safe.

How many drops of clove oil are in a recipe?

The amounts of each oil may vary, but the most popular combination of oils in anecdotal recipes is, as follows: 40 drops of clove oil. 35 drops of lemon or orange oil. 20 drops of cinnamon oil. 15 drops of eucalyptus oil. 10 drops of rosemary oil. Typically, a person uses a topical solution or ointment of thieves oil.

What is thieves oil?

Thieves oil is a combination of several essential oils. Some users and manufacturers claim thieves oil can help with a variety of health issues and conditions. However, few of the claims have research to support them. Keep reading to find out more about the potential benefits of thieves oil, how to make it, and how to use it.

Why do people use thieves oil?

People use thieves oil for a variety of different ailments. In many cases, they use thieves oil as a natural alternative to help with a health condition. Other individuals may turn to thieves oil when they have been unsuccessful with conventional treatments. Some potential uses of thieves oil that some people have tried include:

Is thieves oil good for you?

Thieves oil has only a few benefits that research supports. However, the supporting studies look at the component oils of thieves oil, not thieves oil directly.

Can thieves oil be used on mice?

According to a recent study, researchers found that inject ing eucalyptus oil, which is one of the oils in thieves oil, into mice or having them inhale it helped to alleviate some pain.

Does thieves oil kill viruses?

Several of the oils found in thieves oil have antimicrobial properties. This means they may help kill bacteria, fungi, or viruses when people use them topically on the skin or small cuts and wounds .

Is thieves oil safe for breast cancer?

In a 2018 study, researchers found that thieves oil was toxic to some breast cancer cells in a petri dish. They also found that each of the component oils had some anticancer effects. The researchers checked thieves oil on its effect on two types of breast cancer cells only.

How do you use Thieves’ oil when you are sick?

With one or two drops in the palm of your hand, rub both hands together for a few seconds and you will be using Thieves oil as a disinfectant. For best application, try Thieves’ personal care line by Young Living.

Does Thieves oil kill germs?

Remember that essential oils have antimicrobial properties and Thieves oil is a blend of the best of them. That means, using this oil like others will help you kill bacteria, viruses and fungi that may be present on your skin or in the environment.

How is cajuput obtained?

The cajuput EO is obtained both from wild plants and those cultivated on plantations. It is obtained as a result of distillation with steam from fresh twigs. The cajuput EO content ranges from 1.5–3.0% [61]. The cajuput EO is yellow-green with an intense, herbal scent reminiscent of eucalyptus EO.

Where does cajuput oil come from?

Cajuput oil is obtained from leaves and small branches of the cajuput tree (Melaleuca leucadendronL.; syn of M. cajuputiPowell, syn of M. minorSmith), which belongs to the Myrtaceaefamily and is native to Southeast Asia and North East Australia [57,58]. The cajuput tree reaches a height of 25 m, and has a characteristic white and twisted trunk, similar to birch trees. Furthermore, the bark of the cajuput tree has a thick flaky texture that detaches itself from the trunk and hangs downwards [59]. The branches are arranged irregularly, covered with white bark, and in the case of young branches, slightly silvery. The leaves are thick, lanceolate, about 10 cm long, and 1.5 cm wide. Oil reservoirs are visible on the leaf surface, making the leaves highly aromatic. Their smell is associated with camphor, rosemary, and cardamom. The small, white, individual flowers are collected in spiky inflorescences. Flowers bloom in early summer or spring and developed fruits are green-brown sacks [60].

What are the components of thyme EO?

The composition of thyme EO is well known and described. The main components of thyme EO are thymol (36–55%) and p-cymene (15–28%). It should be noted that the thymol was first isolated in 1719 by Neuman. The compound is characterized by strong bactericidal, fungal, and anti-parasitic properties, with relatively low toxicity to humans and animals. The percentage of other compounds should be in the following ranges: γ-terpinene (5–10%), linalool (4–6.5%), carvacrol (1–4%), β-myrcene (1–3%), terpin-4-ol (0.2–4.0%) [33]. In addition, there are also monoterpene hydrocarbons, such as α-tujen, α-pinene, α-terpinen, camphor myrcen, as well as oxygen derivatives of monoterpenes, 1.8-cineol, linalool, terpin-4-ol, and γ-terpinol, camphor and borneol. Sesquiterpene hydrocarbons have also been identified, which include α-humulene, α-kopene, kubeben, α-gurjunen, germacren D, α- and γ-muurolen, and γ and δ-cadinene [15,16].

What is thyme EO?

The genus Thymus, consisting of over 400 species, belongs to the Lamiaceaefamily. Thyme grows as a shrub with a stumpy, raised stem, on which small, longitudinal leaves and two-lobed pink-violet, light-violet, or white flowers in pairs glow. Oblong, brown splines are obstructions This plant has a height of 10–40 cm. EO is found in glandular hairs on leaves and flowers [15,16]. Plants of this type have been used in folk medicine for thousands of years, especially in the countries of the Mediterranean region. Antimicrobial activity is the most extensively studied in the case of Thymus vulgarisL. (common thyme, German thyme) [30]. The high intraspecific polymorphism of T. vulgarisL. in the production of terpenes is noteworthy, since 6 chemotypes of this species were found [31,32]. Pharmacopeia refers to thymol chemotype. Thyme EO (Latin thymi aetheroleum) is obtained by steam distillation of fresh aerial parts of T. vulgarisL.; T. zygisLoefl (Spanish thyme, white thyme), or mixtures of both species. The highest level of EO production usually occurs during the flowering period of the plant [30].

What is lavender oil?

Lavender EO is a colorless or pale yellow liquid with a characteristic odor. The chemical composition is well known, with detailed data specified in the European Pharmacopoeia 9, Polish Pharmacopoeia VIII, and PNISO (Polish ISO standard) 3515: 2004. Lavender EO is obtained after distillation with water vapor of fresh or dried tips of blooming plants. The main components are Renantiomers of linalool (20–45%) and linalyl acetate (25 to 46%). The high content of these ingredients determines the quality of the oil. The content of other ingredients should be in the following ranges: limonene (>1.0%), eucalyptol (<2.5%), camphor (>1.2%), terpin-4-ol (0.1–6.0) %), lawandulol (<0.1%), lavandulyl acetate (<0.2%), and α-terpineol (>2.0%). Due to the incalculable influence on the scent, lavender oil should not contain too much ocymen, cineole, camphor, or terpin-4-ol [15,16].

Why are EOs used in medicine?

Humans have used EOs for thousands of years, not only as ingredients of perfumes or as seasonings for the aromatization of food, but also in folk medicine, because of their many different biological properties, including antimicrobial properties [6]. The antimicrobial qualities are essential in managing the rapidly growing issue of drug-resistant microorganisms. In 2016, about 6 million people died globally due to infections of the upper respiratory tract, tuberculosis, or diarrheal diseases. At the same time, the number of strains of microorganisms resistant to existing antibiotics is constantly increasing. Patients with infections caused by drug-resistant bacteria are, thus, exposed to an increased risk of worse clinical results and even death. Such patients also consume more healthcare resources than patients infected with non-resistant strains of the same bacteria. According to the WHO report on drug resistance, the most serious problems include the resistance of Klebsiella pneumoniaeto third-generation cephalosporins and carbapenem, Escherichia colito third-generation cephalosporins and fluoroquinolone, Staphylococcus aureusto methicillin, Streptococcus pneumoniaeto penicillin, and Salmonellasp. to fluoroquinolones. Among the fungal infections, the most common problem is candidiasis caused mainly by Candida albicansand less often by C. glabrataand C. parapsilosis, with more than 20 species of Candidathat can cause human infection [7]. Other examples of common fungal infections are aspergillosis, histoplasmosis, and skin mycosis (commonly known as ringworm) [8].

How are EOs obtained?

EOs are usually obtained as a result of hydrodistillation, steam distillation, dry distillation, or the mechanical cold pressing of plants. At the laboratory scale, the classical method is based on the use of the Clevenger steam distillation apparatus, discovered in 1928. Due to several disadvantages (i.e., placement of valve, fragility), this apparatus was modified by Jakub Deryng in 1951 [3] and it is widely used in Central European countries. Modifications of the simultaneous distillation-extraction (SDE) equipment were described in the manuscript of Arora et al. [4]. The effectiveness of these modifications was described in detail by Baj et al. [5]. At the laboratory scale, modern methods also include processes supported by microwaves and extraction in supercritical fluids. EOs can also be isolated using fermentation, crushing, extraction, or hydrolysis. However, depending on the chosen method, the chemical composition of the obtained EO can unfortunately be different.

What was the secret formula used by the thieves during the Black Plague?

The four thieves during the black plague in Europe used a secret formula which is now known as thieves oil.

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What is clove oil used for?

Clove oil- Clove is a very fragrant spice that is powerful against e. Coli, and is widely used to stop a toothache. It is an insect repellant, particularly for fleas.

What is the best essential oil for wounds?

Lemon oil- It has detoxifying, antiseptic, disinfectant and anti-fungal properties. You can use lemon essential oil to sanitize wound as it has anti-bacterial properties. It activates white blood cells and stimulates the immune system. It also enhances the absorption of essential oils through the skin.

What is eucalyptus oil used for?

Eucalyptus oil- It can be used to relieve fever, nasal congestion, asthma, it helps calm cough. It is a purifying agent and has anti-bacterial properties. It supports the health of the respiratory system.

What is rosemary oil good for?

It improves alertness, concentration, and mental activity. It also reduces stress and nervousness. It can be used for cramps, and is also good for digestion and bloating.

How many people died from the Bubonic Plague?

You probably heard or read of bubonic plague or black plague in world history class. It has been considered as one of the most pandemic plague that killed millions of people in Europe. It was estimated to have caused the death of 75 to 200 million people in Europe and Asia and it wiped off 30%- 60% of the population of Europe in 1300.

Overview

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  While reading about essential oils, you may have heard about something called thieves oil. Thieves oil is actually a blend of several essential oils, most often:
• Cinnamon: Made from the bark, leaves, or twigs of several species of cinnamon tree
  Clove: Made from the undeveloped buds of the flowers found on the Eugenia caryophyllata species of clove tree

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Antimicrobial properties

Wound healing

Pain relief

Effects on mood

Diffusion

Steam inhalation

Massage

Lotions and creams

Spray application

Skin reactions

Photosensitivity