10238-21-8

Basic information

• Product Name: Glibenclamide
• Synonyms: LABOTEST-BB LT00244861;GLYBENCLAMIDE;GLYBENZCYCLAMIDE;GLYBURIDE;GIBENCLAMIDE;GLIBENCLAMIDE;5-CHLORO-N-[4-(CYCLOHEXYLUREIDOSULFONYL)PHENETHYL]-2-METHOXYBENZAMIDE;5-CHLORO-N-[2-[4-[[[(CYCLOHEXYLAMINO)CARBONYL]AMINO]-SULFONYL]PHENYL]ETHYL]-2-METHOXYBENZAMIDE
• CAS NO: 10238-21-8
• Molecular Formula: C23H28ClN3O5S
• Molecular Weight: 494
• EINECS: 233-570-6
• Product Categories: Aromatic Carboxylic Acids, Amides, Anilides, Anhydrides & Salts;Organics;Amino Acids & Derivatis;Isotope Labeled Compounds;API's;Potassium channel;Ion Channels;Isotope Labelled Compounds;API;GLYNASE;Diabetes Research
• Mol File: 10238-21-8.mol
• Article Data: 16

Chemical Properties

• Melting Point: 173-175°C
• Appearance: white or almost white crystalline podwer
• Density: 1.1805 (rough estimate)
• Refractive Index: 1.6100 (estimate)
• Storage Temp.: 2-8°C
• Solubility: ethanol: soluble2mg/mL
• PKA: 5.3(at 25℃)
• Water Solubility: Soluble in ethanol (5 mg/mL), DMSO (25 mg/mL), chloroform (1:36), methanol (1:250), and DMF. Insoluble in water.
• Stability: Stable for 1 year from date of purchase as supplied. Solutions in DMSO or ethanol may be stored at -20° for up to 3 months.
• Merck: 14,4478
• CAS DataBase Reference: Glibenclamide(CAS DataBase Reference)
• NIST Chemistry Reference: Glibenclamide(10238-21-8)
• EPA Substance Registry System: Glibenclamide(10238-21-8)

Safety Data

• Hazard Codes: Xn
• Statements: 20/21/22
• Safety Statements: 22-36/37/39-36-24/25
• WGK Germany: 2
• RTECS: YS4725200
• Hazardous Substances Data: 10238-21-8(Hazardous Substances Data)

Usage

Hypoglycemic agents

Glibenclamide belongs to the second generation oral sulfonylurea drugs with the mechanism of action being similar as tolbutamide and the hypoglycemic effect being strongest among sulfonylurea drugs. Its intensity of action is about 200 to 250 times of that of Tolbutamide. It can selectively act on the pancreatic β-cells, promote insulin secretion; can enhance the hypoglycemic effect of exogenous insulin and strengthen the post-receptor effect of insulin. It has fast oral absorption with high protein binding rate. It begins to take effect after 30 minutes with the effect being strongest at 1.5 hours and the duration of 16 to 24 hours. It has a distribution volume of 0.1L/kg, plasma protein binding rate of 90% to 95% and half-life of 4 to 8 hours. It is mainly consumed by the liver metabolism with six metabolites. Two of them are known as hydroxylated compounds with no hypoglycemic effect and is mainly excreted from the urine and a small amount is excreted by the stool. It is clinically mainly used for the treatment of mild to moderate non-insulin dependent diabetes mellitus. Recently, an international study found that the commonly used diabetes drug glibenclamide can help the body's immune system to fight against certain bacterial infections, e.g. in the treatment of melioidosis, the mortality rate can be reduced by about half. Melioidosis is a disease prevalent in tropical areas such as Southeast Asia and northern Australia. It is caused by Burkholderia pseudomallei with the symptoms including sepsis and pneumonia. The mortality rate is high. Diabetic patients tend to be more susceptible to melioidosis, but the mortality rate is lower compared with other patients.

Hypoglycemic effect

Glibenclamide is currently one of the most commonly used drugs for the treatment of type 2 diabetes. Because this product has fast and strong effect, so the effect after the application remarkable, being able to have good control of blood sugar; being applicable for patients of high blood sugar who get bad efficacy when treated with other sulfonyl Urea hypoglycemic agents. Two commonly sulfonylurea oral hypoglycemic agents are glibenclamide and glimepiride, the comparison of hypoglycemic effect of them two are as follow: (1) The effect on glucose transport and metabolism: Glibenclamide and glimepiride can stimulate the key enzymes in the glucose metabolism and improve the glucose transporter (GLUT4) translocation/dephosphorylation to promote the glucose uptake of the surrounding tissue, specifically exhibited in glycogen synthesis and increased fat formation. Glycogen synthase and 3-phosphoglycerol fatty acyltransferase are the key enzymes in glycogen and fat synthesis, and glimepiride is more active than glibenclamide in activating these key enzymes, such as for activating glycogen synthase activity, glimepiride is 2.5 times that of glibenclamide; for the capability to activate lipase, glimepiride is 1.9 times that of glibenclamide. Glimepiride increased the expression of GLUT4 on the cell membrane by inducing dephosphorylation of GLUT4. ?(2) Effect on glycosylated-phosphatidylinositol-specific phospholipase (GPI-PLC): GPI is located in the outer layer of the cell membrane and participates in insulin signal transduction, which can interfere with glucose metabolism of muscle and adipocytes. GPI-PLC can shed the GPI, thereby improving the cell phosphorylation status. Insulin and sulfonylureas can activate GPI-PLC, helping muscle, adipose tissue for the uptake and transport of glucose. However, in the presence of insulin resistance, insulin itself is very difficult to activate GPI-PLC, but glimepiride can still activate the enzyme. In vitro and in vivo studies have shown that, glimepiride has the strongest pancreatic effect in sulfonylurea drugs, which can increase glucose synthesis by 2.5 times and fat synthesis by 4 times. The ratio of glimepiride to glibenclamide was 2: 1. Therefore, glimepiride has a lower secondary failure incidence than other sulfonylurea drugs.

Precautions

Glibenclamide should be started at low doses. During treatment, it should be regularly checked of the urine sugar, urine ketone body, urine protein and blood sugar, blood routine examination, liver and kidney function, vision, retinal blood vessels. (1) Patients of liver and kidney dysfunction, leukopenia, sulfa allergy, pregnant women and diabetes complicated by acidosis and acute infection should be disabled. (2) It can cause abdominal distension, abdominal pain, anorexia, nausea and other gastrointestinal reactions. It can also appear as allergy (skin erythema or urticaria), leukopenia, granulocyte deficiency, thrombocytopenia, hypoglycemia, etc., should be immediately discontinued and treated. Among them, hypoglycemia reaction is more common. (3) Glibenclamide and other sulfonylurea hypoglycemic agents can’t be combined with thiazide diuretics or glucocorticoids. (4) It should be avoided to taken together with anticoagulant drugs such as dicoumaroline. (5) When combined with phenylbutazone, the hypoglycemic effect can be enhanced, causing acute hypoglycemia. (6) Combination with sulfonamides can enhance both the effect and toxicity of glibenclamide, not suitable for use. (7) Combination with chloramphenicol can also enhance the effect and toxicity of this product; combination of two drugs demands dose adjustment according to the patient's blood sugar levels, otherwise can cause hypoglycemic shock. (8) Sulfonylurea drugs can enhance the toxicity of alcohol; alcohol should be avoided during treatment.

Chemical properties

It appears as white crystalline powder. M.p. 168-173 ° C. It is insoluble in water, slightly soluble in ethanol, acetone and chloroform.

Uses

Different sources of media describe the Uses of 10238-21-8 differently. You can refer to the following data:
1. Hypoglycemic agents with stronger effect than toluene sulfonylurea; used for the treatment of mild, non-insulin-dependent diabetes;
2. Glyburide (Glibenclamide) is a sulfonylurea compound that modulates insulin production. Sulfonylureas bind to ATP-dependent K+ channels in beta cells of the pancreas, depolarizing them and stimulating the release of Ca2+, which in turn stimulates insulin production. Glyburide (Glibenclamide) is an ATP-dependent K+ channel (KIR6, KATP) and CFTR Cl- channel blocker. This compound inhibits recombinant CFTR Cl- channels (IC50 = 20 ?M).
3. antihyperglycemic
4. Glyburide is a second generation sulfonylurea with hypoglycemic activity. Glyburide is an antidiabetic.
5. An ATP-dependent KIR6 and CFTR Cl- channel blocker

Hazards & Safety Information

Category : Toxic substances Toxic classification:? poisoning Acute toxicity:? Intraperitoneal-rat LD50: 3750 mg/kg; Oral-mouse LD50: 3250 mg/kg Flammability Hazardous characteristics : Thermal decomposition releases toxic nitrogen oxides, sulfur oxides, chloride fumes Storage and transport characteristics:? Treasury: low temperature, ventilated and dry Extinguishing agent : water, carbon dioxide, foam, dry powder

Description

Glyburide (10238-21-8) is a second generation oral hypoglycemic agent. Acts via ATP-dependent K+ channel (Kir6, KATP) block.1?Inhibits Kir6 currents in the pancreas, causing an increase in intracellular Ca2+ and insulin secretion. Glyburide also inhibits recombinant CFTR Cl- channels with an IC50 of 20 μM.2?Cell permeable.

Chemical Properties

White or almost white, crystalline powder

Originator

Daonil,Hoechst,Germany

Definition

ChEBI: An N-sulfonylurea that is acetohexamide in which the acetyl group is replaced by a 2-(5-chloro-2-methoxybenzamido)ethyl group.

Manufacturing Process

To a solution of 10.2 g of 4-(β-(2-ethoxy-5-chlorobenzamido)ethyl)- benzenesulfonamide in 12.5 ml of 2 N sodium hydroxide solution and 30 ml acetone are added dropwise, at 0-5°C, 3.3 g of cyclohexyl isocyanate. The whole is stirred for 3 hours, diluted with water and methanol, undissolved matter is separeted by filtration. The filtrate is acidified with dilute hydrochloric acid. The 4-(β-(2-ethoxy-5-chlorobenzamido)ethyl)- benzenesulfonyl)-N'-cyclohexylurea which precipitates in the form of crystals melts after recrystallization from methanol at 168-170°C.

Brand name

Micronase (Pharmacia & Upjohn).

Therapeutic Function

Oral hypoglycemic

General Description

Different sources of media describe the General Description of 10238-21-8 differently. You can refer to the following data:
1. Glyburide (glibenclamide) is 5-chloro-N-[2-[4-[[[(cyclohexylamino)carbonyl]amino]sulfonyl]phenyl]ethyl]-2-methoxybenzamide; this compound can also be named asthe urea—see preceding discussion (Diabeta, Glynase,generic). Some tablet formulations contain micronized drug(formerly Micronase, now only generic). Combinations areavailable with metformin in the United States (Glucovance,generic; tablets, mg glipizide/mg metformin as hydrochloride:1.25/250, 2.5/500, 5/500).
2. Similar to glipizide, glyburide, 1-[[p-[2-(5-chloro-o-anisamido)ethyl]-phenyl]sulfonyl]-3-cyclohexylurea(DiaBeta, Micronase, Glynase), is a second-generationoral hypoglycemic agent. The drug has a half-life eliminationof 10 hours, but its hypoglycemic effect remains for upto 24 hours.

Biological Activity

ATP-dependent K + channel (K ATP ) and CFTR Cl - channel blocker. Inhibits K ATP currents in the pancreas, causing an increase in intracellular Ca 2+ and insulin secretion. Inhibits recombinant CFTR Cl- channels with an IC 50 of 20 μ M.

Biochem/physiol Actions

Selectively blocks ATP-sensitive K+ channels; high affinity binding sites found in brain, pancreatic β cells, and cardiovascular system.

Mechanism of action

This drug belongs to the second-generation sulfonylurea derivatives. Like all of the other oral hypoglycemic drugs examined, it is a β-cell stimulant in pancreas; but on the other hand, it increases the sensitivity to insulin, the degree to which it binds with target cells. At the same time, it differs in that it is easier to tolerate. The hypoglycemic effect sets in at significantly lower doses than with first-generation drugs.

Clinical Use

Non-insulin dependent diabetes mellitus

Synthesis

Glyburide, 1-[4-[2-(5-chloro-2-methoxybenzamido)ethyl]-phenylsulfonyl]-3- cyclohexylurea (26.2.11), is a second-generation drug that differs from those described above in that it has a more complex structure in the sulfonylamide region of the molecule into which an additional pharmacophore group is added. It is synthesized from 2-methoxy-5-chlorobenzoic acid chloride, which is transformed into an amide 26.2.9 by reacting it with 2-phenylethylamine. This undergoes subsequent sulfonylchlorination by chlorosulfonic acid, and then amination by ammonia, which gives sulfonamide 26.2.10. The resulting sulfonamide is reacted with cylclohexylisocyanate to give the desired glyburide (26.2.11).

Drug interactions

Potentially hazardous interactions with other drugs Analgesics: effects enhanced by NSAIDs. Antibacterials: effects enhanced by chloramphenicol, sulphonamides, tetracyclines and trimethoprim; effects possibly enhanced by ciprofloxacin and norfloxacin; effect reduced by rifamycins. Anticoagulants: effect possibly enhanced by coumarins; also possibly changes to INR. Antifungals: concentration increased by fluconazole and miconazole and possibly voriconazole. Bosentan: increased risk of hepatoxicity - avoid. Ciclosporin: may increase ciclosporin levels. Lipid-regulating drugs: absorption reduced by colesevelam; concentration possibly increased by fluvastatin; possibly additive hypoglycaemic effect with fibrates. Sulfinpyrazone: enhanced effect of sulphonylureas.

Metabolism

Glibenclamide is metabolised, almost completely, in the liver, the principal metabolite being only very weakly active. About 50% of a dose is excreted in the urine and 50% via the bile into the faeces.

References

1) Brogden et al. (1979), Glipizide: a review of its pharmacological properties and therapeutic use; Drugs, 18 329 2) Sheppard and Welsh (1992), Effect of ATP-sensitive K+ channel regulators on cystic fibrosis transmembrane conductance regulator chloride currents; J. Gen. Physiol., 100 573

InChI:InChI=1/C23H22ClN3O5S/c1-32-21-12-9-17(24)15-20(21)22(28)25-14-13-16-7-10-19(11-8-16)33(30,31)27-23(29)26-18-5-3-2-4-6-18/h2-12,15H,13-14H2,1H3,(H,25,28)(H2,26,27,29)

Synthetic route

5-chloro-2-methoxy-N-(4-sulfamoylphenethyl)benzamide (16673-34-0) + Cyclohexyl isocyanate (3173-53-3) → Glibenclamid (10238-21-8)

Conditions	Yield
With copper(l) chloride In nitromethane at 20℃; for 2h; Reagent/catalyst; Solvent; Concentration; Milling;	100 %Spectr.
With potassium carbonate In N,N-dimethyl-formamide at 80℃; for 0.166667h; Sealed tube;	81 mg
With 18-crown-6 ether; potassium tert-butylate In N,N-dimethyl-formamide at 0 - 5℃; for 6h; Reflux;	4.49 g

carbon monoxide (201230-82-2) + 4-(2-(5-chloro-2-methoxybenzamido)ethyl)benzenesulfonyl azide + cyclohexylamine (108-91-8) → Glibenclamid (10238-21-8)

Conditions	Yield
With palladium diacetate In acetonitrile at 20℃; under 15 Torr; Schlenk technique; Sealed tube;	99%

C19H21ClN2O6S*C6H13N → Glibenclamid (10238-21-8)

Conditions	Yield
In toluene at 110℃; Industrial scale;

5-chloro-2-methoxybenzoic acid (3438-16-2) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 3 steps 1: oxalyl dichloride / dichloromethane / 12 h / 20 °C / Schlenk technique 2: triethylamine / dichloromethane / 6 h / 20 °C / Schlenk technique 3: palladium diacetate / acetonitrile / 20 °C / 15 Torr / Schlenk technique; Sealed tube
Multi-step reaction with 5 steps 1: oxalyl dichloride / dichloromethane / 12 h / 20 °C / Schlenk technique 2: triethylamine / dichloromethane / 6 h / 20 °C / Schlenk technique 3: chlorosulfonic acid / 1,2-dichloro-ethane / 50 °C / Schlenk technique 4: sodium azide / acetonitrile / 50 °C / Schlenk technique 5: palladium diacetate / acetonitrile / 20 °C / 15 Torr / Schlenk technique; Sealed tube
Multi-step reaction with 4 steps 1: phosphorus trichloride / tetrahydrofuran / 0.08 h / 150 °C / Sealed tube 2: chlorosulfonic acid / chloroform / 0.17 h / 60 °C / Sealed tube 3: ammonium hydroxide / 1,4-dioxane / 0.17 h / 120 °C / Sealed tube; Cooling with ice 4: potassium carbonate / N,N-dimethyl-formamide / 0.17 h / 80 °C / Sealed tube

DK13 (33924-49-1) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 3 steps 1: chlorosulfonic acid / 1,2-dichloro-ethane / 50 °C / Schlenk technique 2: sodium azide / acetonitrile / 50 °C / Schlenk technique 3: palladium diacetate / acetonitrile / 20 °C / 15 Torr / Schlenk technique; Sealed tube
Multi-step reaction with 3 steps 1: chlorosulfonic acid / chloroform / 0.17 h / 60 °C / Sealed tube 2: ammonium hydroxide / 1,4-dioxane / 0.17 h / 120 °C / Sealed tube; Cooling with ice 3: potassium carbonate / N,N-dimethyl-formamide / 0.17 h / 80 °C / Sealed tube

phenethylamine (64-04-0) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 4 steps 1: phosphorus trichloride / tetrahydrofuran / 0.08 h / 150 °C / Sealed tube 2: chlorosulfonic acid / chloroform / 0.17 h / 60 °C / Sealed tube 3: ammonium hydroxide / 1,4-dioxane / 0.17 h / 120 °C / Sealed tube; Cooling with ice 4: potassium carbonate / N,N-dimethyl-formamide / 0.17 h / 80 °C / Sealed tube
Multi-step reaction with 5 steps 1.1: pyridine / tetrahydrofuran / 4 h / 20 °C / Cooling with ice 2.1: chlorosulfonic acid / 2 h / 20 °C / Cooling with ice 3.1: ammonium hydroxide / acetone / 20 °C 4.1: 1,1'-carbonyldiimidazole / tetrahydrofuran / 4 h / 20 °C / Inert atmosphere 4.2: 16 h / 20 °C 5.1: potassium tert-butylate; 18-crown-6 ether / N,N-dimethyl-formamide / 6 h / 0 - 5 °C / Reflux

2-methoxy-5-chlorobenzoyl chloride (29568-33-0) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 2 steps 1: triethylamine / dichloromethane / 6 h / 20 °C / Schlenk technique 2: palladium diacetate / acetonitrile / 20 °C / 15 Torr / Schlenk technique; Sealed tube
Multi-step reaction with 4 steps 1: triethylamine / dichloromethane / 6 h / 20 °C / Schlenk technique 2: chlorosulfonic acid / 1,2-dichloro-ethane / 50 °C / Schlenk technique 3: sodium azide / acetonitrile / 50 °C / Schlenk technique 4: palladium diacetate / acetonitrile / 20 °C / 15 Torr / Schlenk technique; Sealed tube

4-(2-[(5-chloro-2-methoxyphenyl)formamido]ethyl)benzene-1-sulfonyl chloride (33924-54-8) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 2 steps 1: sodium azide / acetonitrile / 50 °C / Schlenk technique 2: palladium diacetate / acetonitrile / 20 °C / 15 Torr / Schlenk technique; Sealed tube

5-chloro-2-methoxy-N-(4-sulfamoylphenethyl)benzamide (16673-34-0) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 3 steps 1.1: ammonium hydroxide / acetone / Industrial scale 2.1: pyrographite / acetone / 1.17 h / Reflux; Industrial scale 2.2: 0.5 h / 58 °C / Industrial scale 3.1: toluene / 110 °C / Industrial scale

2,2,2-trifluoro-N-(2-phenylethyl)acetamide (458-85-5) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 4 steps 1.1: chlorosulfonic acid / 2 h / 20 °C / Cooling with ice 2.1: ammonium hydroxide / acetone / 20 °C 3.1: 1,1'-carbonyldiimidazole / tetrahydrofuran / 4 h / 20 °C / Inert atmosphere 3.2: 16 h / 20 °C 4.1: potassium tert-butylate; 18-crown-6 ether / N,N-dimethyl-formamide / 6 h / 0 - 5 °C / Reflux

4-[2-(2,2,2-trifluoroacetamido)ethyl]benzenesulfonyl chloride (223253-87-0) → Glibenclamid (10238-21-8)

Conditions	Yield
Multi-step reaction with 3 steps 1.1: ammonium hydroxide / acetone / 20 °C 2.1: 1,1'-carbonyldiimidazole / tetrahydrofuran / 4 h / 20 °C / Inert atmosphere 2.2: 16 h / 20 °C 3.1: potassium tert-butylate; 18-crown-6 ether / N,N-dimethyl-formamide / 6 h / 0 - 5 °C / Reflux

C23H28ClN3O5S*C42H70O35 (155021-30-0) → Glibenclamid (10238-21-8) + β‐cyclodextrin (7585-39-9)

Conditions	Yield
at 25℃; pH=7; aq. phosphate buffer;

Glibenclamid (10238-21-8) + tetra(n-butyl)ammonium hydroxide (2052-49-5) → glibenclamide tetrabutylammonium salt

Conditions	Yield
In methanol	100%

Glibenclamid (10238-21-8) → C23H27(2)HClN3O5S

Conditions	Yield
With [(1,5-cyclooctadiene)Ir(1,3-bis(2,4,6-trimethylphenyl)imidazol-2-ylidene)(PPh3)]PF6; deuterium In dichloromethane at 20℃; for 2h; Sealed tube;	100%
With deuterium at 100℃; Sealed tube;

Glibenclamid (10238-21-8) → C23H26(2)H2ClN3O5S

Conditions	Yield
With Kerr's catalyst; deuterium In chlorobenzene at 120℃; for 1h; Reagent/catalyst; Temperature;	90%

Glibenclamid (10238-21-8) + acetic anhydride (108-24-7) → N-<4-<2-(5-Chlor-2-methoxybenzoylamino)ethyl>benzolsulfonyl>acetamid

Conditions	Yield
With pyridine for 0.25h;	84%

diethylenetriaminepentaacetic dianhydride (23911-26-4) + Glibenclamid (10238-21-8) → DTPA-glyburide (848488-96-0)

Conditions	Yield
Stage #1: Glibenclamid With sodium amide In dimethyl sulfoxide at 20℃; for 0.166667h; Stage #2: diethylenetriaminepentaacetic dianhydride With sodium amide In dimethyl sulfoxide for 22h;	80%

2-(2-methylphenyl)pyridine (10273-89-9) + Glibenclamid (10238-21-8) → C35H38N4O5S

Conditions	Yield
With C17H24N5Ru(1+)*F6P(1-); Potassium benzoate; potassium carbonate In 1-methyl-pyrrolidin-2-one at 50℃; for 72h; Inert atmosphere;	78%
With C17H24N5Ru(1+)*F6P(1-); Potassium benzoate; potassium carbonate In 1-methyl-pyrrolidin-2-one at 50℃; for 72h; Inert atmosphere; Glovebox;	78%

copper(II) choride dihydrate + Glibenclamid (10238-21-8) → [Cu(glibenclamide)Cl2(H2O)2]*2H2O

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of CuCl2*2H2O in EtOH-H2O mixt. (1:1) to hot soln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the same solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and then with Et2O; elem. anal.;	76%

Glibenclamid (10238-21-8) + copper dichloride → C46H58Cl2CuN6O10S2

Conditions	Yield
Reflux;	76%

Glibenclamid (10238-21-8) + water (7732-18-5) + Co metal salt solution → C46H62Cl2CoN6O12S2

Conditions	Yield
Reflux;	75%

nickel(II) chloride hexahydrate + Glibenclamid (10238-21-8) → [Ni(glibenclamide)Cl2(H2O)2]*3H2O

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of NiCl2*6H2O in EtOH-H2O mixt. (1:1) to hot soln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the same solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and then with Et2O; elem. anal.;	74%

Glibenclamid (10238-21-8) + manganese(ll) chloride → [Mn(glibenclamide)Cl2]*H2O

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of MnCl2 in EtOH-H2O mixt. (1:1) to hotsoln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the s ame solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and then with Et2O; elem. anal.;	73%

Glibenclamid (10238-21-8) + C13H12BFO3 → C36H38FN3O6S

Conditions	Yield
With potassium phosphate monohydrate; palladium diacetate; N2Phos In water at 60℃; for 24h; Reagent/catalyst; Suzuki-Miyaura Coupling;	73%

chromium chloride hexahydrate + Glibenclamid (10238-21-8) → [Cr(glibenclamide)Cl3(H2O)]*3H2O

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of CrCl3*6H2O in EtOH-H2O mixt. (1:1) to hot soln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the same solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and with Et2O; elem. anal.;	70%

iron(III) chloride hexahydrate + Glibenclamid (10238-21-8) → [Fe(glibenclamide)Cl3(H2O)]

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of FeCl3*6H2O in EtOH-H2O mixt. (1:1) to hot soln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the same solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and then with Et2O; elem. anal.;	68%

zinc(II) chloride dihydrate + Glibenclamid (10238-21-8) → [Zn(glibenclamide)Cl2]

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of ZnCl2 in EtOH-H2O mixt. (1:1) to hotsoln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the s ame solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and then with Et2O; elem. anal.;	65%

cobalt(II) chloride hexahydrate + Glibenclamid (10238-21-8) → [Co(glibenclamide)Cl2(H2O)2]

Conditions	Yield
In ethanol; water addn. of hot soln. (60°C) of CoCl2 in EtOH-H2O mixt. (1:1) to hotsoln. (60°C) of MeOC6H3(Cl)CONHCH2CH2C6H4SO2NHCONHC6H11 in the s ame solvent; stirring under reflux for 1 h; pptn., filtration, washing several times with 1:1 EtOH:H2O mixt. and then with Et2O; elem. anal.;	65%

4-Methoxystyrene (637-69-4) + 2,2,6,6-tetramethylpiperidin-1-ol (7031-93-8) + Glibenclamid (10238-21-8) → C41H56N4O7S

Conditions	Yield
With 2,6-di(t-butyl)-4-phenylphenol; caesium carbonate In dimethyl sulfoxide at 20℃; for 20h; Irradiation; Inert atmosphere;	61%

Glibenclamid (10238-21-8) → N-[2-(4-[N-(cyclohexylcarbamoyl)-sulfamoyl]-phenyl)-ethyl]-5-hydroxy-2-methoxybenzamide (1334544-50-1)

Conditions	Yield
With sodium hydroxide In ethanol at 20℃; for 24h;	60%

Glibenclamid (10238-21-8) + N-boc-2-pyrroleboronic acid (135884-31-0) → C32H40N4O7S

Conditions	Yield
With O4P(3-)*3K(1+)*5H2O; tris(1-adamantyl)phosphine; C28H26N2O8Pd2S2 In tetrahydrofuran at 100℃; for 5h; Suzuki-Miyaura Coupling; Inert atmosphere; Schlenk technique;	37%
With 1,2,3-trimethoxybenzene; O4P(3-)*3K(1+)*5H2O; tris(1-adamantyl)phosphine; {2-[((acetyl-κO)amino)phenyl-κC](tri-1-adamantylphosphine)palladium}(p-toluenesulfonate) In tetrahydrofuran at 100℃; for 5h; Suzuki-Miyaura Coupling; Inert atmosphere;	37%

phthalic anhydride (85-44-9) + Glibenclamid (10238-21-8) → N-cyclohexylphthalimide (2133-65-5) + 5-chloro-2-methoxy-N-(4-sulfamoylphenethyl)benzamide (16673-34-0)

Conditions	Yield
With pyridine; dmap for 4h; Heating;	A 34% B 29%

Glibenclamid (10238-21-8) → N-cyclohexylphthalimide (2133-65-5) + 5-chloro-2-methoxy-N-(4-sulfamoylphenethyl)benzamide (16673-34-0)

Conditions	Yield
With pyridine; dmap; phthalic anhydride for 4h; Heating;	A 34% B 29%

Glibenclamid (10238-21-8) → C23H27ClN4O7S

Conditions	Yield
Stage #1: Glibenclamid With sulfuric acid; nitric acid In 1,4-dioxane at 0 - 20℃; for 1.5h; Cooling with ice; Stage #2: Sonication;	11%
With sulfuric acid; nitric acid In 1,4-dioxane at 0 - 20℃; for 1.5h;	11%

Glibenclamid (10238-21-8) → C23H27(3)HClN3O5S

Conditions	Yield
With tritium; [Ir(1,5-COD)(P(C6H5)3)2]BF4 In dichloromethane for 16h; Ambient temperature;

Glibenclamid (10238-21-8) → N-{4-[β-(2-hydroxy-5-chlorobenzene carboxamido)ethyl]benzene-sulfonyl}-N'-cyclohexylurea (57334-90-4)

Conditions	Yield
With boron tribromide

Glibenclamid (10238-21-8) + 2-amino-2-hydroxymethyl-1,3-propanediol (77-86-1) → C4H11NO3*C23H28ClN3O5S (873552-77-3)

Conditions	Yield
In methanol at 5℃;

Upstream product

• 108-91-8 cyclohexylamine 
• 16673-34-0 5-chloro-2-methoxy-N-(4-sulfamoylphenethyl)benzamide 
• 56379-88-5 cyclohexylcarbamic acid phenyl ester 
• 223253-87-0 4-[2-(2,2,2-trifluoroacetamido)ethyl]benzenesulfonyl chloride 
• 458-85-5 2,2,2-trifluoro-N-(2-phenylethyl)acetamide 
• 64-04-0 phenethylamine 
• 33924-54-8 4-(2-[(5-chloro-2-methoxyphenyl)formamido]ethyl)benzene-1-sulfonyl chloride 
• 29568-33-0 2-methoxy-5-chlorobenzoyl chloride 
• 3438-16-2 5-chloro-2-methoxybenzoic acid 
• 33924-49-1 DK₁₃ 
• 201230-82-2 carbon monoxide 
• 3173-53-3 Cyclohexyl isocyanate 
• 155021-30-0 C₂₃H₂₈ClN₃O₅S*C₄₂H₇₀O₃₅ 

Downstream Products

• 2133-65-5 N-cyclohexylphthalimide 
• 16673-34-0 5-chloro-2-methoxy-N-(4-sulfamoylphenethyl)benzamide 
• 155021-30-0 C₂₃H₂₈ClN₃O₅S*C₄₂H₇₀O₃₅ 

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Relevant articles and documents

Total Synthesis of Glipizide and Glibenclamide in Continuous Flow

Glipizide and glibenclamide remain some of the widely prescribed antidiabetic sulfonylurea drugs for the treatment of type 2 diabetes mellitus. Herein the authors report on an isocyanate-free synthetic procedure towards the preparation of these on demand drugs at multigram scale using continuous flow technology. The safety concern over the use of isocyanates in most of the existing synthetic routes was dealt with in this present work by using N-carbamates synthesised in situ from activation of amines with chloroformates as safer alternatives. An overall yield of 80–85 % was obtained for the semi-telescoped steps within 10 min total residence time.

Synthesis technology of glibenclamide

The invention provides a novel synthesis technology of a glibenclamide bulk pharmaceuticals. The glibenclamide product is finally prepared by taking sulfamide as a starting raw material through the four steps of a secondary condensation reaction, a compounding reaction, a dealcoholization reaction and refining. The technology has the advantages of being high in yield, low in purity, easy and convenient to operate, suitable for industrialized production and the like.

Design and Performance Validation of a Conductively Heated Sealed-Vessel Reactor for Organic Synthesis

A newly designed robust and safe laboratory scale reactor for syntheses under sealed-vessel conditions at 250 °C maximum temperature and 20 bar maximum pressure is presented. The reactor employs conductive heating of a sealed glass vessel via a stainless steel heating jacket and implements both online temperature and pressure monitoring in addition to magnetic stirring. Reactions are performed in 10 mL borosilicate vials that are sealed with a silicone cap and Teflon septum and allow syntheses to be performed on a 2-6 mL scale. This conductively heated reactor is compared to a standard single-mode sealed-vessel microwave instrument with respect to heating and cooling performance, stirring efficiency, and temperature and pressure control. Importantly, comparison of the reaction outcome for a number of different synthetic transformations performed side by side in the new device and a standard microwave reactor suggest that results obtained using microwave conditions can be readily mimicked in the operationally much simpler and smaller conventionally heated device.