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Benzyl Alcohol
Benzyl Alcohol
Benzyl alcohol is an aromatic alcohol commonly used as a solvent, preservative, and fragrance in various products.
It has a wide range of applications in chemical synthesis, pharmaceuticals, and personal care formulations.
This compound exhibits low toxicity and is generally considered safe for human use, though, in rare cases, it may cause skin irritation or allergic reactions.
Researchers studying benzyl alcohol can leverage PubCompare.ai's AI-driven comparison tools to identify the most reproducible and accruate procedures, enhancing their research outcomes and taking their benzyl alcohol studise to the next level.
It has a wide range of applications in chemical synthesis, pharmaceuticals, and personal care formulations.
This compound exhibits low toxicity and is generally considered safe for human use, though, in rare cases, it may cause skin irritation or allergic reactions.
Researchers studying benzyl alcohol can leverage PubCompare.ai's AI-driven comparison tools to identify the most reproducible and accruate procedures, enhancing their research outcomes and taking their benzyl alcohol studise to the next level.
Most cited protocols related to «Benzyl Alcohol»
Adult
Benzyl Alcohol
benzyl benzoate
Brain
Mice, Laboratory
Optic Nerve
paraform
Phosphates
Saline Solution
Sucrose
Tissues
ST-CS NP were prepared using the innovative technique called “cold dilution of microemulsion” [25 ]. This technique involves the preparation of an O/W microemulsion (µE) using a partially water-soluble organic solvent as disperse oil phase. Following the dilution of µE with water, the solubilization of the organic solvent in water occurs, with the consequent NP precipitation. In our experimental conditions, butyl lactate (BL) was chosen as partially water-soluble organic solvent.
Different O/W µE were prepared using cholesterol (CHOL) dissolved in water-saturated BL (s-BL) as internal phase, BL-saturated water (s-water) as external phase, and various surfactants and cosurfactants. ST-CS was pre-solubilized in benzyl alcohol (BA) and then added in the dispersed phase. The resulting µE compositions are reported inTable 1 . µE were diluted with water to obtain the precipitation of ST-CS NP.
ST-CS NP suspensions were purified by gel chromatography using agarose cross-linked gel (Sepharose® CL 4B) as stationary phase. Briefly, 1 mL ST-CS NP was introduced at the head of a 10 mL-column and eluted by gravity with hypertonic PBS (8.0 g/L NaCl, 0.2 g/L KCl, 1.44 g/L Na2HPO4 2H2O, 0.24 g/L KH2PO4). Fractions of 1 mL each were collected. The opalescent fractions containing purified ST-CS NP were concentrated under nitrogen up to 1 mL final volume.
To verify the effective presence of ST-CS on NP surface, FITC-ST-CS NP were prepared introducing FITC-ST-CS in µE1.
Different O/W µE were prepared using cholesterol (CHOL) dissolved in water-saturated BL (s-BL) as internal phase, BL-saturated water (s-water) as external phase, and various surfactants and cosurfactants. ST-CS was pre-solubilized in benzyl alcohol (BA) and then added in the dispersed phase. The resulting µE compositions are reported in
ST-CS NP suspensions were purified by gel chromatography using agarose cross-linked gel (Sepharose® CL 4B) as stationary phase. Briefly, 1 mL ST-CS NP was introduced at the head of a 10 mL-column and eluted by gravity with hypertonic PBS (8.0 g/L NaCl, 0.2 g/L KCl, 1.44 g/L Na2HPO4 2H2O, 0.24 g/L KH2PO4). Fractions of 1 mL each were collected. The opalescent fractions containing purified ST-CS NP were concentrated under nitrogen up to 1 mL final volume.
To verify the effective presence of ST-CS on NP surface, FITC-ST-CS NP were prepared introducing FITC-ST-CS in µE1.
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Benzyl Alcohol
Cholesterol
Cold Temperature
Fluorescein-5-isothiocyanate
Gel Chromatography
Gravity
Head
n-butyl lactate
Nitrogen
Opalescence
Sepharose
Sepharose CL 4B
Sodium Chloride
Solvents
Surfactants
Technique, Dilution
Benzyl Alcohol
benzyl benzoate
Childbirth
Ethanol
Genotype
Ketamine
Mice, House
paraform
Perfusion
Retina
Xylazine
The flower scents were collected through dynamic headspace collection method at 12:00–14:00 p.m. Branches with full bloom flowers were clipped in distilled water, and then instantly transported to the laboratory at 25 °C for volatile collection. In each of three experimental replicates, 0.2–0.3 g whole blooming flowers was collected and placed into 100 mL injection vials, which were held for 10 min before using extraction fiber to adsorb the volatiles for 30 min at 30 °C. SPME fiber coated with divinylbenzene/carboxen/polydimenthylsiloxane (50/30 μm DVB/CAR/PDMS) was selected to collect volatiles, as reported in previous studies [31 ]. The emitted volatiles were analyzed using GC-MS, carried out by Shimadzu QP2010 (Shimadzu, Kyoto, Japan) equipped with a DB-5MS capillary column (30 × 0.25 mm, 0.25 μm thickness, Shimadzu, Kyoto, Japan). The injection temperature was held at 250 °C. Helium was the carrier gas in the split mode with the split ratio at 20 and column flow at 27.0 mL min−1. The GC oven temperature started at 40 °C, maintained 2 min, and then increased to 250 °C by 5 °C min−1, holding for 6 min. The mass spectrometer interface temperature was 250 °C and the electron potential was set to 0.9 KV with mass scan range of 30 to 300 m/z units. The solvent cut time was 3.7 min.
The peak area of every scent compound was integrated to obtain the total ion current, with removing the peaks presented in control sample. Individual compound was tentatively identified by comparing the mass spectra with NIST11 library (the National Institute of Standards and Technology 2011, Shimadzu, Japan). Main compounds (relative amount more than 1%) were confirmed by comparing with authentic standard samples. 20 mg of standard compounds (benzaldehyde, benzyl alcohol, benzyl acetate, estragole, eugenol, methyl benzoate and propionic acid benzyl ester) were diluted using 1 mL of hexane. Then, 20 mg of standard compounds of cinnamyl alcohol, methyleugenol, cinnamyl acetate and benzyl benzoate were diluted using 1 mL of methanol. Further, 50 μL of each diluted solution was then co-added to a total volume of 1ml of hexane to make a mixed solution. Then, 5 μL of this mixed solution was placed into 100 mL capped vial for measurement. In addition, propionic acid benzyl ester as internal standard was added into capped vial in every sample. To improve the repeatability of the internal standard in every sample, 5 μL of propionic acid benzyl ester diluted solution was placed into the same position of the injection vial wall.
The peak area of every scent compound was integrated to obtain the total ion current, with removing the peaks presented in control sample. Individual compound was tentatively identified by comparing the mass spectra with NIST11 library (the National Institute of Standards and Technology 2011, Shimadzu, Japan). Main compounds (relative amount more than 1%) were confirmed by comparing with authentic standard samples. 20 mg of standard compounds (benzaldehyde, benzyl alcohol, benzyl acetate, estragole, eugenol, methyl benzoate and propionic acid benzyl ester) were diluted using 1 mL of hexane. Then, 20 mg of standard compounds of cinnamyl alcohol, methyleugenol, cinnamyl acetate and benzyl benzoate were diluted using 1 mL of methanol. Further, 50 μL of each diluted solution was then co-added to a total volume of 1ml of hexane to make a mixed solution. Then, 5 μL of this mixed solution was placed into 100 mL capped vial for measurement. In addition, propionic acid benzyl ester as internal standard was added into capped vial in every sample. To improve the repeatability of the internal standard in every sample, 5 μL of propionic acid benzyl ester diluted solution was placed into the same position of the injection vial wall.
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ARID1A protein, human
benzaldehyde
benzyl acetate
Benzyl Alcohol
benzyl benzoate
Capillaries
cDNA Library
cinnamyl acetate
cinnamyl alcohol
compound 20
divinylbenzene
Electrons
Esters
estragole
Eugenol
Fibrosis
Flowers
Gas Chromatography-Mass Spectrometry
Helium
Ion Transport
Mass Spectrometry
Methanol
methyl benzoate
methyleugenol
n-hexane
Pheromone
propionic acid
Radionuclide Imaging
Solid Phase Microextraction
Solvents
Antibodies
Benzyl Alcohol
benzyl benzoate
Equus asinus
Goat
Hair
Hair Follicle
Medulla Oblongata
Methanol
Mice, House
Microscopy, Confocal
Serum
Skin
Sulfoxide, Dimethyl
Tissues
Triton X-100
Most recents protocols related to «Benzyl Alcohol»
Example 2
A composition comprising Tretinoin as an active ingredient:
The process for the preparation of the composition was as follows:
-
- 1. Trolamine, Natrosol (HEC) and xanthan gum were added gradually to the water while stirring at high speed using mixer propeller;
- 2. The mixture of oleic acid, isopropanol, BHT, sorbic acid and tretinoin was heated to 50° C. while stirring then cooled to the room temperature;
- 3. Silica microspheres were added to the stage 2 and the resultant mixture was stirred for at least one hour;
- 4. Benzyl alcohol and Glycerin were added to stage 1
- 5. Stage 4 was added to the mixer reactor and stirred vigorously.
An opaque yellowish gel was obtained.
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Benzyl Alcohol
Glycerin
Isopropyl Alcohol
Microspheres
Oleic Acid
Pharmaceutical Preparations
Silicon Dioxide
Sorbic Acid
Tretinoin
triethanolamine
xanthan gum
Example 4
A composition comprising Tretinoin as active ingredient:
The process for the preparation of the composition was as follows:
-
- 1. CMC Na (carboxymethyl cellulose sodium) and Natrosol (HEC) were dispersed in water until a clear gel was formed
- 2. Glycerin and benzyl alcohol were added to stage 1 and mixed;
- 3. Oleic acid, isopropanol, BHT, sorbic acid, Poloxamer 407 and tretinoin were heated to 50° C. while stirring until clear solution was obtained. Then the solution was cooled to the room temperature;
- 4. Silica Microspheres were added to the cooled oily phase and resultant mixture was stirred for at least one hour;
- 5. Stage 4 was added to the stage 2 and stirred for one hour under vacuum.
An opaque yellowish gel was obtained.
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Benzyl Alcohol
Ethanol
Glycerin
Isopropyl Alcohol
Microspheres
Oils
Oleic Acid
Pharmaceutical Preparations
Poloxamer 407
Silicon Dioxide
Sodium Carboxymethylcellulose
Sorbic Acid
Tretinoin
Vacuum
Example 10
EDTA was dissolved in water and added to a manufacturing vessel containing a mixture of PG and benzyl alcohol. Melphalan was added to the above solution mixture. pH was adjusted between pH 3.5-5.5 using 0.1N HCl/0.1N NaOH. Volume was made up using PG and benzyl alcohol. The obtained solution was filtered and filled in vials followed by capping and sealing. The formulation was tested for stability at 2-8° C. for a period of 22 days. Stability data is summarized in Table 10A.
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Benzyl Alcohol
Blood Vessel
Edetic Acid
Melphalan
Example 7
t-TUCB (245 mg, 0.56 mmol), benzyl alcohol (200 uL, 1.93 mmol), 1-ethyl-3-dimethylaminopropyl)carbodiimide (EDCI, 148 mg, 0.95 mmol), 4-dimethylaminopyridine (DMAP, 5 mg, 0.04 mmol) and trimethylamine (Et3N, 63 mg, 0.62 mmol) were dissolved in THF and stirred overnight. The product was extracted twice with a saturated solution of NaHCO3 and once with 1 M HCl. The product was dried over MgSO4, evaporated and purified by flash chromatography with 100% EtOAc. The final product was recrystallized in EtOAc (34 mg, 0.06 mmol, 11%). MP=186.9-189.6° C. (188.1° C.) 1H NMR (400 MHz, DMSO-d6) δ 8.47 (s, 1H), 7.87 (d, J=8.9 Hz, 2H), 7.47-7.26 (m, 6H), 7.16 (d, J=8.8 Hz, 2H), 7.02 (d, J=8.9 Hz, 1H), 6.15 (d, J=7.9 Hz, 1H), 5.26 (s, 2H), 4.41 (s, 1H), 3.47 (s, 1H), 1.99 (s, 2H), 1.88 (s, 2H), 1.45 (q, J=11.1, 10.3 Hz, 2H), 1.32 (q, J=11.2 Hz, 2H).
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1H NMR
4-dimethylaminopyridine
Benzoate
Benzyl Alcohol
Bicarbonate, Sodium
Carbodiimides
Chromatography
Sulfate, Magnesium
Sulfoxide, Dimethyl
t-TUCB
trimethylamine
EXAMPLE 2
This example shows the composition of the sealant plug covering the hole in the pipe and the pipe remains in the field of repair of.
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Aluminum
Benzyl Alcohol
bisphenol A
Corrosion
Ethanol
Ethers
ferric oxide
hydroxyethylcellulose
Hydroxyl Radical
Iron
NP 10
Oil, Rapeseed
Polyurethanes
Powder
Silicon
Silicon Dioxide
Thiamine
Top products related to «Benzyl Alcohol»
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Benzyl alcohol is a colorless organic liquid that is commonly used as a solvent and preservative in various laboratory applications. It has a mild, aromatic odor and is miscible with water, alcohol, and many organic solvents. Benzyl alcohol is a versatile chemical that serves as a key component in numerous laboratory procedures and experiments.
Sourced in United States, Germany
Benzyl benzoate is a colorless, oily liquid commonly used as a laboratory reagent. It has the chemical formula C6H5CH2OC(O)C6H5. Benzyl benzoate is a stable, low-volatility compound that can be used as a solvent or an intermediate in various chemical reactions and syntheses.
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Benzaldehyde is a clear, colorless liquid with a characteristic almond-like odor. It is a widely used organic compound that serves as a precursor and intermediate in the synthesis of various chemicals and pharmaceuticals.
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Linalool is a naturally occurring terpene alcohol found in various plant species. It is a colorless to pale yellow liquid with a floral, citrus-like aroma. Linalool is commonly used as a fragrance ingredient in personal care products and as a flavoring agent in food and beverages. Its core function is as a chemical precursor and intermediate in the synthesis of other compounds.
Sourced in United Kingdom, Germany, United States, Belgium
Benzyl alcohol is a clear, colorless liquid with a characteristic mild aromatic odor. It is a commonly used solvent and preservative in various industries, including pharmaceuticals, cosmetics, and personal care products. Benzyl alcohol serves as a key ingredient in the formulation of various products, providing specific functional properties.
Sourced in Germany, United States, United Kingdom, Italy, India, France, China, Australia, Spain, Canada, Switzerland, Japan, Brazil, Poland, Sao Tome and Principe, Singapore, Chile, Malaysia, Belgium, Macao, Mexico, Ireland, Sweden, Indonesia, Pakistan, Romania, Czechia, Denmark, Hungary, Egypt, Israel, Portugal, Taiwan, Province of China, Austria, Thailand
Ethanol is a clear, colorless liquid chemical compound commonly used in laboratory settings. It is a key component in various scientific applications, serving as a solvent, disinfectant, and fuel source. Ethanol has a molecular formula of C2H6O and a range of industrial and research uses.
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Geraniol is a naturally occurring alcohol compound commonly found in the essential oils of various plant species, such as geraniums, lemongrass, and citronella. It is a colorless or pale yellow liquid with a floral, rose-like aroma. Geraniol is used as a fragrance component in personal care products and as a flavoring agent in food and beverage applications.
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Methanol is a clear, colorless, and flammable liquid that is widely used in various industrial and laboratory applications. It serves as a solvent, fuel, and chemical intermediate. Methanol has a simple chemical formula of CH3OH and a boiling point of 64.7°C. It is a versatile compound that is widely used in the production of other chemicals, as well as in the fuel industry.
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Ethyl acetate is a clear, colorless liquid solvent commonly used in laboratory applications. It has a characteristic sweet, fruity odor. Ethyl acetate is known for its ability to dissolve a variety of organic compounds, making it a versatile tool in chemical research and analysis.
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1-hexanol is a clear, colorless liquid chemical compound with the molecular formula C6H14O. It is a primary alcohol with a linear carbon chain. 1-hexanol is used as a solvent and as an intermediate in the production of various chemicals.
More about "Benzyl Alcohol"
Benzyl alcohol is a versatile aromatic alcohol with a wide range of applications.
As a solvent, preservative, and fragrance, it is commonly used in various products, including pharmaceuticals, personal care formulations, and chemical synthesis.
This compound exhibits low toxicity and is generally considered safe for human use, though in rare cases it may cause skin irritation or allergic reactions.
Researchers studying benzyl alcohol can leverage powerful AI-driven comparison tools, such as those offered by PubCompare.ai, to identify the most reproducible and accurate procedures, enhancing their research outcomes and taking their benzyl alcohol studies to the next level.
These tools can help researchers compare different protocols and identify the best practices, leading to more reliable and impactful findings.
In addition to benzyl alcohol, related compounds like benzyl benzoate, benzaldehyde, linalool, ethanol, geraniol, methanol, ethyl acetate, and 1-hexanol also have important applications in various industries.
Understanding the properties and uses of these related substances can provide valuable insights and broaden the scope of benzyl alcohol research.
By utilizing the advanced features and AI-powered capabilities of platforms like PubCompare.ai, researchers can streamline their benzyl alcohol studies, optimize their experimental procedures, and ultimately drive their research to new heights of success.
Explore the wealth of resources and tools available to take your benzyl alcohol research to the next level.
As a solvent, preservative, and fragrance, it is commonly used in various products, including pharmaceuticals, personal care formulations, and chemical synthesis.
This compound exhibits low toxicity and is generally considered safe for human use, though in rare cases it may cause skin irritation or allergic reactions.
Researchers studying benzyl alcohol can leverage powerful AI-driven comparison tools, such as those offered by PubCompare.ai, to identify the most reproducible and accurate procedures, enhancing their research outcomes and taking their benzyl alcohol studies to the next level.
These tools can help researchers compare different protocols and identify the best practices, leading to more reliable and impactful findings.
In addition to benzyl alcohol, related compounds like benzyl benzoate, benzaldehyde, linalool, ethanol, geraniol, methanol, ethyl acetate, and 1-hexanol also have important applications in various industries.
Understanding the properties and uses of these related substances can provide valuable insights and broaden the scope of benzyl alcohol research.
By utilizing the advanced features and AI-powered capabilities of platforms like PubCompare.ai, researchers can streamline their benzyl alcohol studies, optimize their experimental procedures, and ultimately drive their research to new heights of success.
Explore the wealth of resources and tools available to take your benzyl alcohol research to the next level.