Atropine Totally Explained

Everything about Atropine totally explained

| PubChem=174174 | DrugBank=APRD00807 | C = 17 | H = 23 | N = 1 | O = 3 | molecular_weight = 289.369 | bioavailability= 25% | metabolism = 50% hydrolysed to tropine and tropic acid | elimination_half-life= 2 hours | excretion = 50% excreted unchanged in urine | pregnancy_US = C | legal_status = R_x only | routes_of_administration= Oral, IV, rectal }} Atropine is a tropane alkaloid extracted from the deadly nightshade (Atropa belladonna) and other plants of the family Solanaceae. It is a secondary metabolite of these plants and serves as a drug with a wide variety of effects. It is a competitive antagonist for the muscarinic acetylcholine receptor. It is classified as an anticholinergic drug. Being potentially deadly, it derives its name from Atropos, one of the three Fates who, according to Greek mythology, chose how a person was to die.

Physiological effects and uses

Generally, atropine lowers the "rest and digest" activity of all muscles and glands regulated by the parasympathetic nervous system. This occurs because atropine is a competitive antagonist of the muscarinic acetylcholine receptors (Acetylcholine is the main neurotransmitter used by the parasympathetic nervous system). Therefore, it may cause swallowing difficulties and reduced secretions.

Use as antidote against nerve agents

Atropine is used as an antidote against nerve agents, like Tabun (GA), Sarin (GB), Soman (GD) and VX which block the nervous system's "off" message to muscles, resulting in extremely painful muscle spasms and finally death due to a breakdown of the respiratory system. Atropine counters this by restoring the "off" message to the muscle systems. Usually atropine would be injected into the leg with the use of an autoinjector.

Ophthalmic use

Topical atropine is used as a cycloplegic, to temporarily paralyze the accommodation reflex; and as a mydriatic, to dilate the pupils. Atropine degrades slowly, typically wearing off in 2 to 3 days, so tropicamide (a shorter-acting cholinergic antagonist) or phenylephrine (an α-adrenergic agonist) are generally preferred as mydriatics. The effects of atropine can last up to two weeks. Atropine induces mydriasis by blocking contraction of the circular pupillary sphincter muscle, which is normally stimulated by acetylcholine release, thereby allowing the radial pupillary dilator muscle to contract and dilate the pupil. Atropine is contraindicated in patients predisposed to narrow angle glaucoma.
Atropine can be given to patients who have direct globe trauma.

Resuscitation

Injections of atropine are used in the treatment of bradycardia (an extremely low heart rate), asystole and pulseless electrical activity (PEA) in cardiac arrest. This works because the main action of the vagus nerve of the parasympathetic system on the heart is to slow it down. Atropine blocks that action and therefore may speed up the heart rate. The usual dose of atropine is 0.5 to 1 mg every three to five minutes, up to a maximum dose of 3 mg.
Atropine is also useful in treating second degree heart block Mobitz Type 1 (Wenckebach block), and also third degree heart block with a high Purkinje or AV-nodal escape rhythm. It is usually not effective in second degree heart block Mobitz type 2, and in third degree heart block with a low Purkinje or ventricular escape rhythm. Atropine is contraindicated in ischemia-induced conduction block, because the drug increases oxygen demand of the AV nodal tissue, thereby aggravating ischemia and the resulting heart block.
One of the main actions of the parasympathetic nervous system is to stimulate the M₂ muscarinic receptor in the heart, but atropine inhibits this action.

Secretions and bronchoconstriction

Atropine's actions on the parasympathetic nervous system inhibits salivary, sweat, and mucus glands. This can be useful in treating Hyperhidrosis and can prevent the death rattle of dying patients. Even though it hasn't been officially indicated for either of these purposes by the FDA, it has been used by physicians for these purposes.

Antidote for organophosphate poisoning

By blocking the action of acetylcholine at muscarinic receptors, atropine also serves as an antidote for poisoning by organophosphate insecticides and nerve gases. Troops who are likely to be attacked with chemical weapons often carry autoinjectors with atropine and obidoxime which can be quickly injected into the thigh. Atropine is often used in conjunction with Pralidoxime chloride.
Atropine is given as an antidote to SLUDGE (Salivation, Lacrimation, Urination, Diaphoresis, Gastrointestinal motility, Emesis) symptoms caused by organophosphate poisoning.
Some of the nerve gases attack and destroy acetylcholinesterase, so the action of acetylcholine becomes prolonged. Therefore, atropine can be used to reduce the effect of acetylcholine.

Side effects and overdose

Adverse reactions to atropine include ventricular fibrillation, supraventricular or ventricular tachycardia, dizziness, nausea, blurred vision, loss of balance, dilated pupils, photophobia, and possibly, notably in the elderly, extreme confusion, extreme dissociative hallucinations, and excitation. These latter effects are due to the fact that atropine is able to cross the blood-brain barrier. Because of the hallucinogenic properties, some have used the drug recreationally, though this is very dangerous and often unpleasant.
   In overdoses, atropine is poisonous. Atropine is sometimes added to other potentially addictive drugs, particularly anti-diahorrea opioid drugs such as diphenoxylate or difenoxin where the secretion-reducing effects of the atropine can also aid the anti-diahorrea effects. This is supposed to prevent abuse of these drugs, however while the unpleasant side effects produced by the atropine may discourage abuse they certainly don't prevent it entirely, and these combination products can be significantly more dangerous than if the opioid was administered by itself.
   Although atropine treats bradycardia (slow heart rate) in emergency settings, it can cause paradoxical heart rate slowing when given at very low doses, presumably as a result of central action in the CNS.
   The antidote to atropine is physostigmine or pilocarpine.
   A common mnemonic used to describe the physiologic manifestations of atropine overdose is: "hot as a hare, blind as a bat, dry as a bone, red as a beet, and mad as a hatter". This set of symptoms is known as anticholinergic toxidrome, and may also be caused by other drugs with anticholinergic effects, such as diphenhydramine, phenothiazine antipsychotics and benztropine.

Chemistry and pharmacology

Atropine is a racemic mixture of D-hyoscyamine and L-hyoscyamine, with most of its physiological effects due to L-hyoscyamine. Its pharmacological effects are due to binding to muscarinic acetylcholine receptors. It is an antimuscarinic agent.
The most common atropine compound used in medicine is atropine sulfate (C₁₇H₂₃N O₃)₂·H₂SO₄·H₂O, the full chemical name is 1α H, 5α H-Tropan-3-α ol (±)-tropate(ester), sulfate monohydrate.

History

Mandragora (mandrake) was described by Theophrastus in the fourth century B.C. for treatment of wounds, gout, and sleeplessness, and as a love potion. By the first century A.D. Dioscorides recognized wine of mandrake as an anaesthetic for treatment of pain or sleeplessness, to be given prior to surgery or cautery. The use of Solanaceae containing tropane alkaloids for anesthesia, often in combination with opium, persisted throughout the Roman and Islamic Empires and continued in Europe until superseded by the use of ether, chloroform, and other modern anesthetics.
   Atropine extracts from the Egyptian henbane were used by Cleopatra in the last century B.C. to dilate her pupils, in the hope that she'd appear more alluring. In the Renaissance, women used the juice of the berries of Atropa belladonna to enlarge the pupils of their eyes, for cosmetic reasons; "bella donna" is Italian for "beautiful lady".
   The mydriatic effects of atropine were studied among others by the German chemist Friedrich Ferdinand Runge (1795–1867). In 1831 the pharmacist Mein succeeded the pure crystalline isolation of atropine. The substance was first synthesized by German chemist Richard Willstätter in 1901.
   Atropinic shock therapy, also known as atropinic coma therapy, is an old and rarely used method. It consists of induction of atropinic coma by rapid intravenous infusion of atropine. Atropinic shock treatment is considered safe, but it entails prolonged coma (between four and five hours), with careful monitoring and preparation, and it has many unpleasant side effects, such as blurred vision.

Natural sources

Atropine is found in many members of the Solanaceae family. The most commonly found sources are Atropa belladonna, Datura inoxia, D. metel, and D. stramonium. Other sources include members of the Brugmansia and Hyoscyamus genera. The Nicotiana genus (including the tobacco plant, N. tabacum) is also found in the Solanaceae family, but these plants don't contain atropine or other tropane alkaloids.

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