PHYSOSTIGMINE Property

Melting point:

102-104 °C(lit.)

alpha 

D17 -76° (c = 1.3 in chloroform); D25 -120° (benzene)

Boiling point:

418.29°C (rough estimate)

Density 

1.166±0.06 g/cm3 (20 ºC 760 Torr)

refractive index 

1.5600 (estimate)

Flash point:

>100℃

storage temp. 

2-8°C

solubility 

Chloroform (Slightly, Sonicated), DMSO (Slightly), Ethanol (Slightly), Methanol

form 

Powder

pka

6.12, 12.24(at 25℃)

color 

Off-white

optical activity

-12025 (CHCl3)

Water Solubility 

Soluble in water (1:75), alcohol (1:10), chloroform (1:1), ether (1:30), and DMSO.

Sensitive 

Air & Light Sensitive

Merck 

7384

CAS DataBase Reference

57-47-6(CAS DataBase Reference)

EPA Substance Registry System

Physostigmine (57-47-6)

Safety

Hazard Codes 

T+

Risk Statements 

26/28

Safety Statements 

23-45-25

RIDADR 

UN 1544 6.1/PG 1

WGK Germany 

3

RTECS 

TJ2100000

F 

8-10

TSCA 

Yes

HazardClass 

6.1(a)

PackingGroup 

II

Hazardous Substances Data

57-47-6(Hazardous Substances Data)

Toxicity

LD50 orally in mice: 4.5 mg/kg (Lynch, Coon)

Hazard and Precautionary Statements (GHS)

Symbol(GHS)

Signal word

Danger

Hazard statements

H300Fatal if swallowed

H330Fatal if inhaled

Precautionary statements

P260Do not breathe dust/fume/gas/mist/vapours/spray.

P284Wear respiratory protection.

P304+P340IF INHALED: Remove victim to fresh air and Keep at rest in a position comfortable for breathing.

P320Specific treatment is urgent (see … on this label).

P330Rinse mouth.

P403+P233Store in a well-ventilated place. Keep container tightly closed.

P405Store locked up.

PHYSOSTIGMINE Chemical Properties,Usage,Production

Description

The classic AChEI, physostigmine, is an alkaloid obtained from seeds of the Calabar bean (Physostigma venenosum). Its parasympathomimetic effects were recognized long before its structure was elucidated in 1923. In 1929, Stedman found that the mechanism of the parasympathomimetic effects of physostigmine was inhibition of AChE; it inhibits AChE by acting as a substrate and carbamylating the enzyme. Acetylcholinesterase is carbamylated at a slow rate, but physostigmine has exceptionally high affinity (Ki ~ 10-9 M) for the catalytic site of the enzyme. By comparison, the Ks for acetylcholine is on the order of 10-4 M. Thus, physostigmine is classified as a reversible AChEI that carbamylates the enzyme at a slow rate; the carbamylated AChE also is regenerated quite slowly. Because physostigmine is a tertiary amine with a pKa of 8.2 (+BH) rather than a quaternary ammonium salt, it is more lipophilic than many other AChEIs and can diffuse across the blood-brain barrier. The tertiary amine also imparts pH dependence to its ability to inhibit AChE, because its affinity for AChE is greater when the amine is protonated.

Chemical Properties

Physostigmine is a white crystalline solid. Odorless.

Physical properties

Appearance: flaky crystal. Solubility: slightly soluble in water; soluble in ethanol, benzene, and fatty oil. Melting point: 102–104 °C. Specific optical rotation: ?120° in benzene and ?76° in chloroform, respectively

History

Eserine was first discovered as a reversible AChE inhibitor, and it is also a tertiary amine and easily crosses the blood-brain barrier. In 1846, Robert Christison observed that the extract from Calabar bean caused cardiac arrest and death; he personally ate a certain amount of the extract and felt extremely feeble but luckily survived. In 1855, Christison reported that some kind of substances in the Calabar bean possessed strong biological activity.
In 1864, chemists afforded crystal pure extract which was named as eserine. After that, Thomas Richard Fraser and Douglas Argyll Robertson cooperated to employ eserine in experimental ophthalmology, and the results showed that the antagonistic effect of eserine on mydriasis is induced by atropine. In 1875, Ludwig Laqueur declared that eserine could also be employed to depress intraocular pressure and first used as a treatment for glaucoma. In 1925, Edgar Stedman and George Barger determined the structure of eserine, which belongs to a natural product whose structure is characterized with hexahydropyrroloindole. In 1935, Percy Lavon Julian completed the chemical synthesis of its racemate for the first time .

Uses

Physostigmine base (Eserine-Base) is used as bulk pharmaceuticals (parasympathomimetic, cholinergic, ophthalmic, anti-Alzheimer). Product Data Sheet

Uses

It is a parasympathomimetic, specifically, a reversible cholinesterase inhibitor obtained from the Calabar bean, used to treat glaucoma and delayed gastric emptying.

Uses

Because of its ability to diffuse into the CNS, it is used as an antidote for toxic concentrations in the organism of drugs with anticholinergic properties such as atropine, antihistamines, phenothiazines, and tricyclic antidepressants. Its action on the organism is basically similar to that of acetylcholine, and it is used for the same indications in ophthalmology for constricting the pupil and lowering ocular pressure in glaucoma.

Definition

ChEBI: Physostigmine is a carbamate ester and an indole alkaloid. It has a role as a miotic, an EC 3.1.1.8 (cholinesterase) inhibitor and an antidote to curare poisoning.

brand name

Eserine Sulfate (Ciba Vision, US Ophthalmics).

General Description

White, odorless, microcrystalline powder. Used as a cholinergic (anticholinesterase) agent and as a veterinary medication.

General Description

Physostigmine is an alkaloidobtained from the dried ripe seed of Physostigma venenosum.It occurs as a white, odorless, microcrystalline powderthat is slightly soluble in water and freely soluble inalcohol, chloroform, and the fixed oils. The alkaloid, asthe free base, is quite sensitive to heat, light, moisture,and bases, undergoing rapid decomposition. In solution,it is hydrolyzed to methyl carbamic acid and eseroline,neither of which inhibits AChE. Eseroline is oxidized toa red compound, rubreserine,and then further decomposedto eserine blue and eserine brown. Addition of sulfiteor ascorbic acid prevents oxidation of the phenol, eseroline,to rubreserine. Hydrolysis does take place,however, and the physostigmine is inactivated. Solutionsare most stable at pH 6 and should never be sterilizedby heat.
Physostigmine is a relatively poor carbamylating agentof AChE and is often considered a reversible inhibitor ofthe enzyme. Its cholinesterase-inhibiting properties varywith the pH of the medium . The conjugateacid of physostigmine has a pKa of about 8, and as the pHof the solution is lowered, more is present in the protonatedform. Inhibition of cholinesterase is greater in acidmedia, suggesting that the protonated form makes a contributionto the inhibitory activity well as its carbamylationof the enzyme.

Health Hazard

Super toxic. Probable oral lethal dose is less than 5 mg/kg for a 70 kg (150 lb.) person. Material is a cholinesterase inhibitor. Effects of exposure may involve the respiratory, gastrointestinal, cardiovascular and central nervous systems. Death occurs due to respiratory paralysis or impaired cardiac function. Time to death may vary from 5 minutes to 24 hours, in severely poisoned patients, depending on factors such as the dose and route. Persons with asthma and/or persons that require drugs containing choline esters are at risk.

Fire Hazard

PHYSOSTIGMINE is a slight fire hazard. When heated to decomposition PHYSOSTIGMINE emits toxic fumes of nitrogen oxides. Keep from light and heat.

Mechanism of action

Physostigmine is easily absorbed from the gastrointestinal tract and other mucous membranes. Upon entering the bloodstream, it easily permeates the blood–brain barrier. It is inactivated by cholinesterase of the plasma. Physostigmine has a minimal direct effect on cholinesterase receptors.

Pharmacology

Eserine was first discovered as one of AChE inhibitors. AChE inhibitor is the same as ACh, which can combine with cholinesterase, while AChE inhibitor will combine more tightly with cholinesterase, which leads to slow hydrolysis, inactive enzyme, cumulative ACh, and emergent biological activities . Although eserine does not directly activate M and N receptor, it can cross the central nervous system and strongly militate the central and peripheral nervous systems .
When locally using eserine in the eyes, the effect is similar to pilocarpine but more powerful and durable. It can activate AChR of iridis sphincter, representing that the pupil is narrowed and the intraocular pressure is depressed, which is more obvious when being used to treat glaucoma patients. When being absorbed, the effect of eserine is similar to neostigmine, which is called as M- and N-like effects, representing that smooth muscle is activated strongly. After crossing the central nervous system, eserine can inhibit the activities induced by AChE, and it is presented as “activate previously, inhibit later.” It is noted that the effect of eserine is dependent on the status of the central nervous system .

Clinical Use

Physostigmine was used first as a topical application inthe treatment of glaucoma. Its lipid solubility properties permitadequate absorption from ointment bases. It is used systemicallyas an antidote for atropine poisoning and otheranticholinergic drugs by increasing the duration of actionof ACh at cholinergic sites through inhibition of AChE.Physostigmine, along with other cholinomimetic drugs actingin the CNS, has been studied for use in the treatment ofAlzheimer disease. Cholinomimetics that are currentlyused or which have been recently evaluated in the treatmentof Alzheimer disease include donepezil, galantamine, metrifonate,rivastigmine, and tacrine. It is anticipated that thislist will continue to grow as the etiology of this disease becomesbetter understood.

Safety Profile

A human poison by an unspecified route. Poison experimentally by ingestion, subcutaneous, intramuscular, intravenous, and intraperitoneal routes. Human systemic effects by ingestion: nausea, dyspnea, coma, blood pressure elevation, flaccid paralysis without anesthesia, muscle weakness. Normally administered by injection. Poisoning can occur as a result of a mistake in dosage or due to hypersensitivity of the patient withm 5 to 25 minutes after administration. Death usually results from respiratory paralysis. Experimental reproductive effects. Combustible when exposed to heat or flame. When heated to decomposition it emits toxic fumes of NOx. See also CARBAMATES.

Synthesis

Physostigmine, 1,3a,8-trimethyl-2,3,3a,8a-tetrahydropyrrolo[2,3-b]- indol-5-yl-N-methylcarbamate (13.2.7), is an alkaloid isolated from the so-called grand beans?aseeds of the poisonous African plant of the familia Physostigma venenosum. Physostigmine is made synthetically in various ways [40¨C42], one of which being from pethoxymethylaniline, which is reacted with |á-bromopropionyl bromide in the presence of aluminum chloride, giving 1,3-dimethyl-5-ethoxyindolin-2-one (13.2.1). Reacting this with chloracetonitrile in the presence of sodium ethoxide gives 1,3-dimethyl-5-ethoxy- 3-cyanomethylindolin-2-one (13.2.2). The nitrile group is reduced to an amine group, which is further methoxided, giving 1,3-dimethyl-5-ethoxy-3-(|? methylaminoethyl) indolin-2-one (13.2.3). The carbonyl group of this compound is reduced, forming an aminoalcohol (13.2.4), the dehydration of which leads to formation of 1,3a,8-trimethyl- 2,3,3a,8a-tetrahydropyrrolo[2,3b]-5-ethoxyindol (13.2.5). The ethoxy-protecting group is removed by hydrogen bromide, giving a compound with a phenol hydroxyl group (13.2.6), which is reacted with methylisocyanate, giving the desired physostigmine (13.2.7).

Potential Exposure

Physostigmine, an alkaloid, originally derived from the calabar bean (Physostigma venenosum) isa potent and reversible inhibitor of cholinesterase. Material is used as a cholinergic (anticholinesterase) agent and as a veterinary medication. Although listed as a carbamate pesticide, physostigmine is not registered for use as an agricultural chemical in the United States.

Veterinary Drugs and Treatments

Physostigmine has been used for the adjunctive treatment of ivermectin toxicity in dogs, as a provocative agent for the diagnosis of narcolepsy in dogs and horses, and as a treatment for anticholinergic toxicity. Because of the potential for serious adverse effects, use of physostigmine as an antidote is generally reserved for very serious toxicity affecting the CNS. Otherwise, safer alternatives such as neostigmine or pyridostigmine are preferred.
While physostigmine has been used to antagonize the CNS depressant effects of benzodiazepines in humans, it should not be used for this purpose because of the potential toxicity and nonspecific action of physostigmine.

Metabolism

Physostigmine is the tertiary amine that are rapidly absorbed from the gastrointestinal tract, as are tacrine, donepezil, and galanthamine, whereas quaternary ammonium compounds are poorly absorbed after oral administration. Nevertheless, quaternary ammonium compounds like neostigmine and pyridostigmine are orally active if larger doses are employed. Only the quaternary ammonium inhibitors do not readily enter the CNS. Because of their high lipid solubility and low molecular weight, most of the organophosphates are absorbed by all routes of administration; even percutaneous exposure can result in the absorption of sufficient drug to permit the accumulation of toxic levels of these compounds.

Shipping

UN2811 Toxic solids, organic, n.o.s., Hazard Class: 6.1; Labels: 6.1-Poisonous materials, Technical Name Required. UN1544 Alkaloids, solid, n.o.s. or Alkaloid salts, solid, n.o.s. poisonous, Hazard Class: 6.1; Labels: 6.1-Poisonous materials, Technical Name Required.

Purification Methods

Eserine crystallises from Et2O or *C6H6 and forms an unstable low melting form m 86-87o [Harley-Mason & Jackson J Chem Soc 3651 1954, Wijnberg & Speckamp Tetrahedron 34 2399 1978]. [Beilstein 23/11 V 401.]

Incompatibilities

Light and heat.

Waste Disposal

It is not appropriate to dispose of expired or waste drugs or waste product such as lab chemicals by flushing them down the toilet or discarding them to the trash. Larger quantities shall carefully take into consideration applicable EPA, and FDA regulations. If possible return the lab chemicals to the manufacturer for proper disposal being careful to properly label and securely package the material. Alternatively, the waste lab chemicals shall be labeled, securely packaged and transported by a state licensed medical waste contractor to dispose by burial in a licensed hazardous or toxic waste landfill or incinerator. In accordance with 40CFR165, follow recommendations for the disposal of pesticides and pesticide containers. Must be disposed properly by following package label directions or by contacting your local or federal environmental control agency, or by contacting your regional EPA office.