10191-41-0

Basic information

• Product Name: Vitamin E
• Synonyms: ALL-RAC-ALPHA-TOCOPHEROL;(+/-)-ALPHA-TOCOPHEROL;(+/-)-ALPHA-TOCOFEROL;ALPHA-TOCOPHEROLUM;ALPHA-DL-TOCOPHEROL;5,7,8-TRIMETHYLTOCOL;A-TOCOPHEROL;IRGANOX E 201
• CAS NO: 10191-41-0
• Molecular Formula: C₂₉H₅₀O₂
• Molecular Weight: 430.71
• EINECS: 233-466-0
• Product Categories: Organics;Antioxidant;Biochemistry;Vitamins;Other APIs
• Mol File: 10191-41-0.mol

Chemical Properties

• Melting Point: 2-4°C
• Boiling Point: 200-220°C 0,1mm
• Flash Point: 240°C
• Appearance: low yellow powder
• Density: 0.950 g/mL at 20 °C(lit.)
• Vapor Pressure: 4.59E-10mmHg at 25°C
• Refractive Index: n20/D 1.506
• Storage Temp.: 2-8°C
• Solubility: H2O: insoluble
• PKA: 11.40±0.40(Predicted)
• Water Solubility: Miscible with chloroform, vegetable oils, ether, acetone and alcohol. Immiscible with water.
• Sensitive: Light Sensitive
• Merck: 14,9495
• BRN: 94012
• CAS DataBase Reference: Vitamin E(CAS DataBase Reference)
• NIST Chemistry Reference: Vitamin E(10191-41-0)
• EPA Substance Registry System: Vitamin E(10191-41-0)

Safety Data

• Hazard Codes: Xi,T,F
• Statements: 36/37/38-39/23/24/25-23/24/25-11
• Safety Statements: 26-37/39-45-36/37-16-7
• RIDADR: UN1230 - class 3 - PG 2 - Methanol, solution
• WGK Germany: 1
• RTECS: GA8746000
• F: 8-10-23
• TSCA: Yes
• Hazardous Substances Data: 10191-41-0(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical Industry:
Vitamin E is used as an antioxidant in the pharmaceutical industry to protect cell membrane lipids from oxidative damage. It is also used as a secondary standard for several analytical applications, including but not limited to pharma release testing, pharma method development for qualitative and quantitative analyses, and other calibration requirements.
Used in Food and Beverage Industry:
Vitamin E is used as an antioxidant in the food and beverage industry to maintain the quality and freshness of products. It helps to prevent the oxidation of fats and oils, which can lead to rancidity and spoilage.
Used in Cosmetics Industry:
Vitamin E is used in cosmetics and personal care products for its antioxidant properties, which help to protect the skin from environmental damage and promote skin health.
Used in Dietary Supplements:
Vitamin E is used in dietary supplements to support overall health and well-being. It is known to have various health benefits, including supporting immune function, promoting healthy skin and eyes, and reducing the risk of chronic diseases.

Production Methods

Naturally occurring tocopherols are obtained by the extraction or molecular distillation of steam distillates of vegetable oils; for example, alpha tocopherol occurs in concentrations of 0.1–0.3% in corn, rapeseed, soybean, sunflower, and wheat germ oils.Beta and gamma tocopherol are usually found in natural sources along with alpha tocopherol. Racemic synthetic tocopherols may be prepared by the condensation of the appropriate methylated hydroquinone with racemic isophytol.

Flammability and Explosibility

Nonflammable

Pharmaceutical Applications

Alpha tocopherol is primarily recognized as a source of vitamin E, and the commercially available materials and specifications reflect this purpose. While alpha tocopherol also exhibits antioxidant properties, the beta, delta, and gamma tocopherols are considered to be more effective as antioxidants. Alpha-tocopherol is a highly lipophilic compound, and is an excellent solvent for many poorly soluble drugs.Of widespread regulatory acceptability, tocopherols are of value in oil- or fat-based pharmaceutical products and are normally used in the concentration range 0.001–0.05% v/v. There is frequently an optimum concentration; thus the autoxidation of linoleic acid and methyl linolenate is reduced at low concentrations of alpha tocopherol, and is accelerated by higher concentrations. Antioxidant effectiveness can be increased by the addition of oil-soluble synergists such as lecithin and ascorbyl palmitate. Alpha tocopherol may be used as an efficient plasticizer. It has been used in the development of deformable liposomes as topical formulations. d-Alpha-tocopherol has also been used as a non-ionic surfactant in oral and injectable formulations.

Biochem/physiol Actions

TGF-β3 (transforming growth factor-β3) regulates lymphocyte proliferation, apoptosis, hematopoiesis and embryogenesis to maintain immune homeostasis. TGF-β plays an important role in cell growth, differentiation, and survival. TGF-β3 specifically promotes chondrogenic differentiation.TGF-β3 is a strong growth inhibitor for normal and transformed epithelial, lymphoid, fibroblast, and keratinocyte cells. TGF-2 inhibits antitumor action of NK (natural killer) cells, T-cells, macrophages, monocytes and neutrophils. TGF-β3 is a tumor suppressor in the early stages of carcinogenesis, but in the later stages acts as a tumor promoter by inducing epithelial-mesenchymal transition and stimulating angiogenesis. TGF-β isoforms is known to participate in wound healing and tissue fibrosis. TGF-β3 is crucial for tissue restoration and scarless tissue repair. Mutation in the TGFβ3 gene is associated with development of non-syndromic cleft palate only (NS CPO), a rare congenital disease.

Safety

Tocopherols (vitamin E) occur in many food substances that are consumed as part of the normal diet. The daily nutritional requirement has not been clearly defined but is estimated to be 3.0–20.0 mg. Absorption from the gastrointestinal tract is dependent upon normal pancreatic function and the presence of bile. Tocopherols are widely distributed throughout the body, with some ingested tocopherol metabolized in the liver; excretion of metabolites is via the urine or bile. Individuals with vitamin E deficiency are usually treated by oral administration of tocopherols, although intramuscular and intravenous administration may sometimes be used. Tocopherols are well tolerated, although excessive oral intake may cause headache, fatigue, weakness, digestive disturbance, and nausea. Prolonged and intensive skin contact may lead to erythema and contact dermatitis. The use of tocopherols as antioxidants in pharmaceuticals and food products is unlikely to pose any hazard to human health since the daily intake from such uses is small compared with the intake of naturally occurring tocopherols in the diet. The WHO has set an acceptable daily intake of tocopherol used as an antioxidant at 0.15–2.0 mg/kg body-weight.

storage

Tocopherols are oxidized slowly by atmospheric oxygen and rapidly by ferric and silver salts. Oxidation products include tocopheroxide, tocopherylquinone, and tocopherylhydroquinone, as well as dimers and trimers. Tocopherol esters are more stable to oxidation than the free tocopherols but are in consequence less effective antioxidants. Tocopherols should be stored under an inert gas, in an airtight container in a cool, dry place and protected from light.

Purification Methods

Dissolve dl--tocopherol in anhydrous MeOH (15mL/g) cool to -6o for 1hour, then chill in a Dry-ice/acetone bath; crystallisation is induced by scratching with a glass rod. The dl--acetate [52225-20-4] (see DL-vitamin E actetate below) is a viscous yellow liquid with m -7o, b 184o/0.01mm, 224o/0.3mm, d 4 20 0.953, n D 20 1.496. It is used as a standard for Vitamin E activity where the unit of activity is attained with 1mg of pure dl--acetate. [Friedrich “Vitamins” Water de Guyter Publ, Berlin 1988, Beilstein 17/4 V 168.]

Incompatibilities

Tocopherols are incompatible with peroxides and metal ions, especially iron, copper, and silver. Tocopherols may be absorbed into plastic.

Regulatory Status

GRAS listed. Accepted in Europe as a food additive. Included in the FDA Inactive Ingredients Database (IV injections, powder, lyophilized powder for liposomal suspension; oral capsules, tablets, and topical preparations). Included in the Canadian List of Acceptable Non-medicinal Ingredients. Included in nonparenteral medicines licensed in the UK.

InChI:InChI=1/C29H50O2/c1-20(2)12-9-13-21(3)14-10-15-22(4)16-11-18-29(8)19-17-26-25(7)27(30)23(5)24(6)28(26)31-29/h20-22,30H,9-19H2,1-8H3/t21-,22+,29+/m0/s1

Synthetic route

isophytol (505-32-8) + Trimethylhydroquinone (700-13-0) → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
methanetrisulfonic acid In Ethylene carbonate; n-heptane; water at 50 - 140℃; for 1 - 1.66667h;	92.4%
methanetrisulfonic acid In 1,2-propylene cyclic carbonate; n-heptane; water at 50 - 140℃; for 1h;	91.2%
SnTf(51)-MCM-41 In hexane at 100℃; for 1h;

4-((3R,7R,11R)-3-Hydroxy-3,7,11,15-tetramethyl-hexadecyl)-5,7,8-trimethyl-1-oxa-spiro[2.5]octa-4,7-dien-6-one (129658-43-1) → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
With boron trifluoride diethyl etherate In diethyl ether for 4h;	60%

5-nitromethyl-γ-tocopherol acetate → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
With lithium aluminium tetrahydride; aluminium trichloride Reduction;	17%

(RS)-isophytol (505-32-8, 60046-87-9, 80736-12-5) + Trimethylhydroquinone (700-13-0) → (+/-)-α-tocopherol (10191-41-0) + (S)-2,3,4,6,7-Pentamethyl-2-((4S,8S)-4,8,12-trimethyl-tridecyl)-2,3-dihydro-benzofuran-5-ol

Conditions	Yield
With 1-(bis-CF3SO2-methyl)-2,3,4,5,6-pentafluoro-benzene In carbon dioxide at 100℃; under 187515 Torr; for 16h; Product distribution; Further Variations:; Pressures; Catalysts; Solvents;	A 79 % Chromat. B 3.4 % Chromat.

DL-α-tocopherol acetate → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
Multi-step reaction with 2 steps 1: 75 percent / nitric acid / acetic acid / 0.5 h / 20 °C 2: 17 percent / LiAlH4; AlCl3

α-tocopherolquinone (7559-04-8, 27696-11-3, 72657-56-8, 78419-32-6, 84368-81-0) → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
Multi-step reaction with 2 steps 1: 75 percent / silica gel / diethyl ether / 5 h / 0 - 5 °C 2: 60 percent / BF3*Et2O / diethyl ether / 4 h

α-tocopheroxyl radical → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
With (E)-5-[2-4-(hydroxyphenyl)ethenyl]-1,3-benzenediol; sodium dodecyl-sulfate at 20℃; pH=7.4; Kinetics; Reagent/catalyst; aq. buffer; Micellar solution;

Trimethylhydroquinone (700-13-0) + isophytol → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
Stage #1: Trimethylhydroquinone With acid treated bentonite at 120 - 125℃; for 0.25h; Friedel-Crafts Alkylation; Stage #2: isophytol at 120 - 125℃; for 10h; Catalytic behavior; Reagent/catalyst; Temperature; Friedel-Crafts Alkylation;
Stage #1: Trimethylhydroquinone With acid treated bentonite at 120 - 125℃; for 0.25h; Friedel-Crafts Alkylation; Stage #2: isophytol at 120 - 125℃; for 10h; Catalytic behavior; Temperature; Reagent/catalyst; Friedel-Crafts Alkylation;

2,3,5-Trimethyl-1,4-benzoquinone (935-92-2) → (+/-)-α-tocopherol (10191-41-0)

Conditions	Yield
Multi-step reaction with 2 steps 1.1: palladium 10% on activated carbon; hydrogen / 23 h / 64 °C / 6000.6 Torr 2.1: acid treated bentonite / 0.25 h / 120 - 125 °C 2.2: 10 h / 120 - 125 °C

(+/-)-α-tocopherol (10191-41-0) + epichlorohydrin (106-89-8) → 2,5,7,8-tetramethyl-6-(oxiran-2-ylmethoxy)-2-(4,8,12-trimethyltridecyl)chroman (153821-44-4)

Conditions	Yield
With tetra(n-butyl)ammonium hydrogensulfate; potassium hydroxide In water at 0 - 20℃; for 4h;	96%

(+/-)-α-tocopherol (10191-41-0) + epichlorohydrin (106-89-8) → C32H54O3

Conditions	Yield
With tetra(n-butyl)ammonium hydrogensulfate; potassium hydroxide In water at 0 - 20℃; for 4h;	96%

(+/-)-α-tocopherol (10191-41-0) + bromoacetic acid methyl ester (96-32-2) → methyl 2-(2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)chroman-6-yloxy)acetate (1445229-61-7)

Conditions	Yield
Stage #1: (+/-)-α-tocopherol With sodium hydride In N,N-dimethyl-formamide at 20℃; for 0.5h; Stage #2: bromoacetic acid methyl ester In N,N-dimethyl-formamide at 20℃; for 15h;	93%

trans-styrylacetic acid (2243-53-0, 59744-46-6, 1914-58-5) + (+/-)-α-tocopherol (10191-41-0) → (E)-(-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)chroman-6-yl) 4-phenyl-but-3-enoate

Conditions	Yield
With dmap; dicyclohexyl-carbodiimide In dichloromethane at 20℃; for 24h;	92%

α-L-polyglutamic acid + (+/-)-α-tocopherol (10191-41-0) → polyglutamate

Conditions	Yield
Stage #1: α-L-polyglutamic acid; (+/-)-α-tocopherol With dmap; diisopropyl-carbodiimide In N,N-dimethyl-formamide at 15℃; for 3h; Stage #2: With hydrogenchloride In water; N,N-dimethyl-formamide pH=2;	90%

(+/-)-α-tocopherol (10191-41-0) + allyl bromide (106-95-6) → DL-α-tocopherol allyl ether

Conditions	Yield
With potassium carbonate In acetone for 10h; Reflux;	90%

2,5,8,11,14,17,20,23,26,29,32,35,38,41,44,47,50-heptadecaoxadopentacontan-52-oic acid + (+/-)-α-tocopherol (10191-41-0) → C64H118O20

Conditions	Yield
With dmap; 1-ethyl-(3-(3-dimethylamino)propyl)-carbodiimide hydrochloride In dichloromethane at 40℃; for 10h; Solvent; Temperature;	88%

trans-4-[({[(1,1-dimethylethyl)oxy]carbonyl}amino)methyl]cyclohexanecarboxylic acid + (+/-)-α-tocopherol (10191-41-0) → dl-α-tocopherol BOC-tranexamate

Conditions	Yield
With dicyclohexyl-carbodiimide In pyridine at 20℃; for 24h;	85%

(+/-)-α-tocopherol (10191-41-0) + bromoacetic acid methyl ester (96-32-2) → 2-tocopheryloxy ethanol

Conditions	Yield
Stage #1: (+/-)-α-tocopherol; bromoacetic acid methyl ester With potassium carbonate; potassium iodide In acetone Inert atmosphere; Reflux; Stage #2: With lithium aluminium tetrahydride In tetrahydrofuran at 20℃; for 4h; Inert atmosphere;	85%

(+/-)-α-tocopherol (10191-41-0) + bromoacetic acid methyl ester (96-32-2) + serinol (534-03-2) → C34H59NO5

Conditions	Yield
Stage #1: (+/-)-α-tocopherol; bromoacetic acid methyl ester With potassium carbonate; potassium iodide In acetone Inert atmosphere; Reflux; Stage #2: serinol In dimethyl sulfoxide at 25℃; for 6h; Inert atmosphere;	85%

5-azidolevulinic acid (440359-99-9) + (+/-)-α-tocopherol (10191-41-0) → (+/-)-α-tocopherol-5-azidolevulinic acid ester

Conditions	Yield
With dmap; dicyclohexyl-carbodiimide In dichloromethane at 20℃; for 12h; Inert atmosphere;	83%

(+/-)-α-tocopherol (10191-41-0) + methyl iodide (74-88-4) → α-tocopheryl methyl ether

Conditions	Yield
With potassium carbonate In acetone for 36h; Methylation; Heating;	82%

(+/-)-α-tocopherol (10191-41-0) + 5-((tert-butoxycarbonyl)amino)-4-oxopentanoic acid (72072-06-1) → (+/-)-α-tocopherol-Boc-ALA ester

Conditions	Yield
With dmap; dicyclohexyl-carbodiimide In dichloromethane at 20℃; for 12h; Inert atmosphere;	78%

4-(bromomethyl)-1-methyl-2,6,7-trioxabicyclo[2.2.2]-octane (60028-14-0) + (+/-)-α-tocopherol (10191-41-0) → C34H60O5

Conditions	Yield
Stage #1: (+/-)-α-tocopherol With sodium hydride In N,N-dimethyl-formamide at 20℃; for 0.25h; Stage #2: 4-(bromomethyl)-1-methyl-2,6,7-trioxabicyclo[2.2.2]-octane In tetrahydrofuran at 100℃; for 24h; Inert atmosphere; Stage #3: With hydrogenchloride In methanol; dichloromethane at 50℃; for 4h; Inert atmosphere;	78%

methanol (67-56-1) + (+/-)-α-tocopherol (10191-41-0) → 8a-methoxy-α-tocopherone (3329-05-3, 119616-52-3, 119616-53-4)

Conditions	Yield
With potassium hydroxide; iodine at 10℃; for 0.166667h;	68%

BOC-glycine (4530-20-5) + (+/-)-α-tocopherol (10191-41-0) → tert-Butoxycarbonylamino-acetic acid (R)-2,5,7,8-tetramethyl-2-((4R,8R)-4,8,12-trimethyl-tridecyl)-chroman-6-yl ester

Conditions	Yield
Stage #1: BOC-glycine; (+/-)-α-tocopherol With dmap; dicyclohexyl-carbodiimide In dichloromethane at 20℃; Stage #2: In dichloromethane at -20℃; for 2h;	60%
With dicyclohexyl-carbodiimide In pyridine for 24h; Ambient temperature;

(+/-)-α-tocopherol (10191-41-0) + 5-fluorouracil-1-acetic acid (56059-30-4)

Conditions	Yield
With dicyclohexyl-carbodiimide In tetrahydrofuran at 50℃; for 48h; Inert atmosphere;	60%

(+/-)-α-tocopherol (10191-41-0) + ethyl bromoacetate (105-36-2) → ethyl 2-tocopheryloxy acetate

Conditions	Yield
Stage #1: (+/-)-α-tocopherol With sodium hydride In N,N-dimethyl-formamide at 0℃; for 0.25h; Inert atmosphere; Stage #2: ethyl bromoacetate In N,N-dimethyl-formamide at 20℃; for 16h; Inert atmosphere;	60%

2-Iodobenzyl bromide (40400-13-3) + (+/-)-α-tocopherol (10191-41-0) → 6-((2-iodobenzyl)oxy)-2,5,7,8-tetramethyl-2-(4,8,12-trimethyltridecyl)chromane

Conditions	Yield
With potassium carbonate In N,N-dimethyl-formamide at 80℃; for 12h;	38%

phthalic anhydride (85-44-9) + (+/-)-α-tocopherol (10191-41-0) → mono-tocopherol phthalate (850655-12-8)

Conditions	Yield
With stannous octoate In N,N-dimethyl acetamide at 140℃; for 24h;	31.1%

terephthalic acid (100-21-0) + (+/-)-α-tocopherol (10191-41-0) → mono-tocopherol terephthalate (850655-10-6)

Conditions	Yield
With dmap; 2-chloro-1-methyl-pyridinium iodide In N,N-dimethyl acetamide at 50℃; for 4h;	27.6%

C45H92N2O2 + (+/-)-α-tocopherol (10191-41-0) → C74H140N2O3

Conditions	Yield
With Medroxyprogesterone acetate; 1-ethyl-(3-(3-dimethylamino)propyl)-carbodiimide hydrochloride In dichloromethane at 20℃;	26%

trimethoxysilane (2487-90-3) + (+/-)-α-tocopherol (10191-41-0) + 6-Bromo-1-hexene (2695-47-8) → (6-((DL-α-tocopheryl)oxy)hexyl)trimethoxysilane

Conditions	Yield
Stage #1: (+/-)-α-tocopherol; 6-Bromo-1-hexene With sodium hydroxide In N,N-dimethyl-formamide at 20℃; for 12h; Inert atmosphere; Schlenk technique; Stage #2: trimethoxysilane With platinum(0)-1,3-divinyl-1,1,3,3-tetramethyldisiloxane complex In 5,5-dimethyl-1,3-cyclohexadiene; N,N-dimethyl-formamide at 50℃; for 12h; Inert atmosphere; Schlenk technique;	21%

(+/-)-α-tocopherol (10191-41-0) + β-D-galactose peracetate (4163-60-4) → α-tocopheryl 2,3,4,6-tetra-O-acetyl-β-D-galactopyranoside

Conditions	Yield
With toluene-4-sulfonic acid In nitrobenzene at 90℃; for 5h;	20%

(+/-)-α-tocopherol (10191-41-0) + β-D-glucose pentaacetate (604-69-3) → all-rac-α-tocopheryl 2,3,4,6-tetra-O-acetyl-β-D-glucopyranoside (99502-55-3)

Conditions	Yield
With toluene-4-sulfonic acid In nitrobenzene at 90℃; for 5h;	15%

(+/-)-α-tocopherol (10191-41-0) + β-D-mannopyranose pentaacetate (83-87-4, 604-68-2, 604-69-3, 2152-77-4, 4026-35-1, 4163-59-1, 4163-60-4, 4163-61-5, 4163-65-9, 4257-94-7, 4257-96-9, 16299-15-3, 19186-39-1, 19189-55-0, 25878-60-8, 25941-03-1, 32445-48-0, 32445-49-1, 32445-53-7, 32445-54-8, 34685-58-0, 34685-59-1, 43168-42-9, 43168-44-1, 43169-22-8, 43169-25-1, 66966-07-2, 70749-17-6, 80184-01-6, 93221-01-3, 93221-02-4, 99630-88-3, 109215-53-4, 115792-70-6, 115792-73-9, 139894-92-1, 139973-25-4, 144071-49-8, 147648-81-5) → dl-α-tocopheryltetraacetyl-β-mannoside

Conditions	Yield
With toluene-4-sulfonic acid In nitrobenzene at 90℃; for 5h;	14%

linoleic acid (60-33-3) + (+/-)-α-tocopherol (10191-41-0) → dl-α-Tocopheryl linoleate (36148-84-2, 51744-92-4, 146566-14-5)

Conditions	Yield
With 1,1'-carbonyldiimidazole In chloroform	98.9 % Chromat.

Upstream product

• 129658-43-1 4-((3R,7R,11R)-3-Hydroxy-3,7,11,15-tetramethyl-hexadecyl)-5,7,8-trimethyl-1-oxa-spiro[2.5]octa-4,7-dien-6-one 
• 59-02-9 vitamin E 
• 110-82-7 cyclohexane 
• 10191-41-0 (+/-)-α-tocopherol 
• 935-92-2 2,3,5-Trimethyl-1,4-benzoquinone 
• 700-13-0 Trimethylhydroquinone 
• 505-32-8 isophytol 
• 7559-04-8 α-tocopherolquinone 
• 1406-70-8 DL-α-tocopherol acetate 
• 505-32-8 (RS)-isophytol 

Downstream Products

• 766-07-4 cyclohexyl hydroperoxide 
• 59-02-9 (R)-2,5,7,8-Tetramethyl-2-((4R,8R)-4,8,12-trimethyl-tridecyl)-chroman-6-ol 
• 34562-29-3 dl-α-Tocopheryl palmitate 
• 850655-12-8 mono-tocopherol phthalate 
• 850655-10-6 mono-tocopherol terephthalate 
• 77171-97-2 α-tocopherol 
• 59-02-9 Tocopherol 
• 59-02-9 vitamin E 
• 1406-70-8 DL-α-tocopherol acetate 
• 87291-70-1 DL-α-Tocopheryl phosphate dianilide 
• 16676-75-8 DL-α-tocopherol nicotinate 

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New heterogeneous catalysts for greener routes in the synthesis of fine chemicals

New strong Lewis acid SnTf-MCM-41 and SnTf-UVM-7 catalysts with unimodal and bimodal pore systems were prepared in a two-step synthesis in which the triflic acid (Tf) was incorporated to previously synthesized mesoporous tin-containing silicas. The Sn incorporation inside the pore walls was carried out through the Atrane method. The SnTf-UVM-7 catalysts were prepared by aggregating nanometric mesoporous particles defining a hierarchic textural-type additional pore system. Following these procedures, catalysts with different Si/Sn ratios-21.8 to 50.8 for SnTf-MCM-41 and 18.4 for SnTf-UVM-7-were prepared. These new materials were tested in the acylation of aromatic sulfonamides using acetic acid as the acylating agent and in the synthesis of (dl)-[α]-tocopherol through the condensation of 2,3,6-trimethylhydroquinone (TMHQ) with isophytol (IP). The activity data indicate that these heterogeneous catalysts are very active, corresponding to high yields in acylated compounds as 65.5% and very high selectivity to (dl)-[α]-tocopherol (94%, for a conversion of 98%).

Structure-activity relationship and mechanism of the tocopherol- regenerating activity of resveratrol and its analogues

The present study investigated the mechanism of the synergistic antioxidant activity of α-tocopherol with resveratrol (3,5,4′-trihydroxy-trans- stilbene, 3,5,4′-THS) and its synthetic analogues, that is, 3,4-dihydroxy-trans-stilbene (3,4-DHS), 4,4′-dihydroxy-trans-stilbene (4,4′-DHS), 4-hydroxy-trans-stilbene (4-HS), and 3,5-dihydroxy-trans- stilbene (3,5-DHS). The reaction kinetics of α-tocopheroxyl radical with resveratrol and its analogues were studied in sodium dodecyl sulfate (SDS) and cetyl trimethylammonium bromide (CTAB) micelles using the stopped-flow electron paramagnetic resonance (EPR) technique. It was found that resveratrol and its analogues could regenerate α-tocopherol with rate constants (k REG) in the order of 3,4-DHS > 4,4′-DHS > resveratrol ≥ 4-HS ≥ 3,5-DHS in SDS and CTAB micelles. It was found that the analogues bearing o-dihydroxyl groups (3,4-DHS) and p-dihydroxyl groups (4,4′-HS) exhibited remarkably higher α-tocopherol-regenerating activity than those bearing no such groups (resveratrol, 4-HS, and 3,5-DHS). In addition, the α-tocopherol-regenerating activity of resveratrol and its analogues was correlated with their electrochemical behaviors, suggesting that electron transfer might play a critical role during the regeneration reaction.

Synthesis of (all-rac)-α-tocopherol in supercritical carbon dioxide: Tuning of the product selectivity in batch and continuous-flow reactors

α-Tocopherol was synthesized using a condensation reaction of 2,3,6-trimethylhydroquinone with isophytol in supercritical CO2 using batch and continuous-flow reactors. In the batch reaction catalyzed by a fluorinated molecular catalyst bearing strong Bronsted acidity, C 6F5CHTf2 (Tf=SO2CF3), an increase in the CO2 pressure causes a marked increase in the product selectivity for α-tocopherol, albeit with a slight decrease in the product yield. The solubility measurements by extraction experiments and the supercritical fluid NMR (scNMR) indicate that the homogeneous and non-polar reaction phase in scCO2 is crucial to obtain α-tocopherol with high selectivity. A continuous flow scCO2 process for the condensation reaction can be performed with a strong acid resin, Amberlyst 15, as a solid acid catalyst to give the desired product with high selectivity.

SYNTHESIS OF CHROMANOL DERIVATIVES

The present invention relates to a process for the production of chromanol derivatives, more specifically to a process for preparing a compound of the general formula I wherein R1, R2 and R3 independently of each other are selected from hydrogen and methyl, R4 is selected from C-1-C6-alkyl, and X is selected from C1-C20-alkyl and C2-C20-alkenyl.

SYNTHESIS OF CHROMANOL DERIVATIVES

The present invention relates to a process for the production of chromanol derivatives, more specifically to a process for preparing a compound of the general formula (I) wherein R1, R2 and R3 independently of each other are selected from hydrogen and methyl, R4 is selected from hydrogen and C1-C6-alkanoyl, and X is selected from C1-C20-alkyl and C2-C20-alkenyl.

Process of separating chiral isomers of chroman compounds and their derivatives and precursors

The present invention relates to a process of separating chiral isomers of chroman compounds, particularly tocopherols and tocotrienols as well as the esters and intermediates thereof. It has been found that this process allows a separation of the desired isomer with a higher yield and enables the use of the non-desired isomers in a very efficient way. Said process is particularly useful when implemented in an industrial process. Furthermore, it has been found that this process allows using isomer mixtures as they result from traditional industrial synthesis.

MANUFACTURE OF α-TOCOPHEROL

A process for the manufacture of (all- rac)-α-tocopherol by the acid-catalyzed reaction of trimethylhydroquinone with isophytol or phytol is characterized by carrying out the reaction in the presence of methane trisulphonate as the catalyst in an organic solvent. The product of the process is the most active and industrially most important member of the vitamin E group.

Preparation and reactions of 5-nitromethyl-γ-tocopherol acetate

Nitration of α-tocopherol acetate 1b yielded 5-nitromethyl-γ-tocopherol acetate 2b. The acetate 2b was converted to free phenol 2a by transesterification in methanol. Reduction of 2b by NaBH4 in ethyl acetate and methanol gave 5-(2-hydroxypropyl)-γ-tocopherol 5a and 5-methoxymethyl-γ-tocopherol 6 respectively.

Electron-transfer reactions of alkyl peroxy radicals

One-electron-transfer reactions of alkyl peroxy radicals were studied by pulse radiolysis of aqueous solutions. At pH 13, the methyl peroxy radical was found to rapidly, k = 1 × 105-4.9 × 107 s-1, and quantitatively oxidize various organic substrates with E13 = 0.13-0.76 V vs NHE. On the other hand, this radical was unreactive with compounds with E13 ≥ 0.85 V. Consequently, E13 of the methyl peroxy radical is higher than 0.76 V and lower than 0.85 V, which means that E7 is in the range 1.02-1.11 V. At pH 8, the rate constants of the oxidation of four ferrocene derivatives by the alkyl peroxy radicals ranged from 7.1 × 104 M-1 s-1 for ferrocenedicarboxylate (E8 = 0.66 V) to 2.3 × 106 M-1 s-1 for (hydroxymethyl)ferrocene (E8 = 0.42 V). These rate constants were used to evaluate the reduction potential and self-exchange rate of alkyl peroxy radicals in neutral media from the Marcus equation. The calculated E7 = 1.05 V is in excellent agreement with the estimated E7 = 1.02-1.11 V and with one of the perviously published values E7 = 1.0 V, but the value is in excellent agreement higher than the other E7 ～ 0.6 V. It is suggested that the high reorganization energy, λ = 72 kcal mol-1 redox couple originates from the requirement for solvent reorganization due to the solvation of hydroperoxide anion in the transition state. In support of this are the activation parameters of the reaction of the methyl peroxy radical with uric acid. The activation entropy is 9 eu lower at pH 7.3 than it is at pH 13.2, whereas the activation enthalpies are unchanged. The importance of entropy control was verified in the reactions of cyclohexyl peroxy radicals with α- and δ-tocopherol in aerated cyclohexane (ΔH+ ≈ 0 kcal/mol, and ΔS+ = -25 and -26 eu). The implications of these findings on the inactivation of alkyl peroxy radicals in general are discussed.

Addition of Diazomethane to α-Tocopherolquinone

The reaction of α-tocopherolquinone (3a) and its derivatives (3c,d) with diazomethane was investigated.As the result of its addition to the >C1=O group the spiroepoxycyclohexadienones 5a, b, and c were formed.By catalytic reduction (Pd/C) compound 5a was transformed into the phenol 7.In the presence of BF3*Et2O, compound 5a was cyclized to α-tocopherol (2a).