* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Adrenergic_antagonis..
Pharmaceutical marketing wikipedia , lookup
5-HT3 antagonist wikipedia , lookup
Polysubstance dependence wikipedia , lookup
Psychedelic therapy wikipedia , lookup
Drug discovery wikipedia , lookup
Specialty drugs in the United States wikipedia , lookup
Cannabinoid receptor antagonist wikipedia , lookup
Discovery and development of angiotensin receptor blockers wikipedia , lookup
Orphan drug wikipedia , lookup
Norepinephrine wikipedia , lookup
Pharmacogenomics wikipedia , lookup
Pharmaceutical industry wikipedia , lookup
Prescription drug prices in the United States wikipedia , lookup
Prescription costs wikipedia , lookup
Pharmacognosy wikipedia , lookup
Discovery and development of beta-blockers wikipedia , lookup
Neuropharmacology wikipedia , lookup
Drug interaction wikipedia , lookup
Classification of Adrenoreceptor Antagonists α– blockers β– blockers Non selective Relatively selective Selective Non selective Relatively selective Selective Both α and β adrenergic antagonists Adrenergics & Antiadrenergic drugs 1 α– Adrenoceptor Antagonists (α– blockers) يؤثر على واحدة واذا زدنا الجرعة فانه يؤثر على األخرى Non selective Relatively selective selective phenoxybenzamine prazosin tamsolusin phentolamine terazosin alfuzosin tolazoline doxazosin Adrenergics & Antiadrenergic drugs 2 Non selective α– blockers (act on α1 and α2 receptors) Phentolamine and Tolazoline (Reversible) Induce reversible competitive blockade for α1 – adrenoreceptors which can be overcome by increase of NE T1/2 = 3 – 5 hours Phenoxybenzamine (Irreversible) it produces irreversible α– blockade. t1/2 = 14 – 48 hours Adrenergics & Antiadrenergic drugs 3 Pharmacological effects of α– blockers I. Effects Mediated by blocking α– receptors A. Cardiovascular Effects: 1) They block α1 causing VD. So, decrease TVR The pressor effect of α– agonists So, they decrease BP (hypotension) But they are of limited clinical use in treating hypertension because they may cause: Tachycardia (Reflex Type) Cardiac arrhythmia Angina pectoris Peptic ulcer Sexual dysfunction 4 B. Non-cardiac Effects of α– blockers A) Miosis b) Nasal stuffness c)decrease resistance to the flow of urine d) They decrease adrenergic sweating. So they produce dry skin e) Inhibit ejaculation II. Effects mediated by non- α–adrenergic blocking effects: They induce weak blockade for: • H 1 receptors (Histamine) (Sedation; antinausea) • Serotonin receptors • Muscarinic receptors (dry mouth) Side effects of Phenoxybenzamine Fatigue Nausea (because it enters CNS) Diarrhea Postural hypotension. Tachycardia. Adrenergics & Antiadrenergic drugs 6 α– blockers Relatively selective Prazosin Terazosin Doxazosin Adrenergics & Antiadrenergic drugs 7 1. Prazosin Mechanism of action It is a relatively selective α1 – adrenoceptor competitive antagonist reversible T1/2 = 3 hours Adrenergics & Antiadrenergic drugs 8 Prazosin Actions: It produces arterial & venous dilation. So it decreases BP, so it is used for the treatment of hypertension It causes less tachycardia than non–selective vasodilators (because it doesn’t act on α2 receptors) It precipitates less angina & cardiac arrhythmia It may increase HDL / cholesterol ratio. HDL protects against ischemic heart disease There is tolerance to it’s action Dose 2 – 3 times daily for Hypertension and congestive heart failure (CHF). Adrenergics & Antiadrenergic drugs 9 Side effect of prazosin 1st dose produce hypotension & syncope, but this disappears after continuous treatment(we prevent this effect by decreasing the 1st dose and giving it at bedtime) Infrequent postural hypotension (rare and less than the non selective) Nasal stiffness due to VD & congestion Dizziness, headache & faintness . These are caused by hypotension Sexual dysfunction but less than the nonselective. α– blockers Relatively selective 2. Terazosin & Doxazosin: They are relatively α1 – selective blockers, with higher selectivity than prazosin T1/2 = Terazosin 12 hours; Doxazosin 22 hrs They produce VD with less tachycardia than prazosin Like prazosin they produce postural hypotension They produce relaxation of smooth muscle of the bladder neck and prostate capsule. So, they facilitate micturition. For this action, they can be used in case of urine retention associated with benign prostatic hyperplasia(BPH). Adrenergics & Antiadrenergic drugs 11 α– blockers Selective Tamsolusin & Alfuzosine It is selective for α1A – adrenoreceptors in the sphincter of urinary bladder α1A blockade leads to relaxation of the sphincter. So, it facilitates micturition Tamsolusin is used clinically in treating urine retention associated with BPH. It is better here than prazosin, Terazosin and Doxazosin It causes less hypotension than prazosin or terazosin. Because: It has low potency in inhibiting receptors in vascular smooth muscle 12 Tamsolusin Adverse affects: Retrograde ejaculation 15% Hypersensitivity reaction: skin rash & urticaria Nausea and vomiting Nasal stiffness Over dose will cause hypotension, tachycardia and fatigue Note: Similar to prazosin but with less magnitude. Adrenergics & Antiadrenergic drugs 13 Tamsolusin Contraindications: Renal impairment Tamsolusin is metabolized in the liver to an active metablite which is entirely excreted via the renal tubules, therefore, In case of renal impairment, Tamsolusin will accumulate in blood & lead to toxicity Adrenergics & Antiadrenergic drugs 14 Clinical Uses of adrenergic aantagonists: 1) Pheochromocytoma (phenoxybenzamine, phentolamine) with β blockers to reduce cardiac effect from increased catecholamines 2) Hypretensive Crisis (Labetalol) 3) Essential Hypertension (Prazosin, Terazosin) 4) Peripheral Vascular Occlusion Diseases (Raynaud’s phenomenon) e.g: Prazosin (but Calcium Channel Blockers are better choice) 5) Urinary Obstruction associated with BPH (Tamsolusin) Name of antagonist Act on T1/2 treatment Phentolamine & tolazoline Alpha 1 , 2 3-5 hours Hypertension pheochromocytoma phenoxybenzamine Alpha 1 , 2 14-48 same prazosin Alpha 1 3 Hypertension Congestive heart Failure Protect against ischemic disease Raynaud phenomenon terazosin Alpha 1 12 Hypertension Urinary retention doxazosin Alpha 1 22 same Tamsolusin & Alfuzosin Alpha 1A Adrenergics & Antiadrenergic drugs Urinary retention 16 Adrenoreceptor Antagonists β– blockers: Non selective Relatively selective Alpha and beta blockers Propranolol Atenolol Labetalol Timolol Esmolol carvedilol Nadolol Metoprolol Labetalol Practolol pindolol Acebutol bisoprolol More potent than atenolol Adrenergics & Antiadrenergic drugs 17 How could you distinguish between b-adrenergic Blockers? b-adrenergic antagonists (blockers) differ from each others in the following: Selectivity for b1 as compared to b2. or by the following: metabolism Has anesthetic action In liver (they cross BBB): Propranolol Pindolol In kidney: Atenolol nadolol timolol propranolol Has partial agonistic activity pindolol acebutolol labetolol esmolol esmolol timolol pindolol acebutolol β– blockers Pharmacological actions: CVS Angiotensin normally induces the release of NE from postganglionic sympathetic fibers BP = CO * TVR. Clinically β blockers lower BP By these mechanisms: Blockade of β1 in the heart will cause decreased HR and CO Blockade β1 in the kidney will cause decreased rennin leading to decreased angiotensin 2. this will lead to بالعربي يطلع يلقىNE الريسيبتور مقفلة يضطر انه يروح 2α لـ VD and ultimately decreased BP decrease aldosterone. This will lead to decerased salt and water retention and finally decreased BP decrease release of NE that will cause VD and decreased BP Blockade of central β adrenergic in adrenergic nerve terminals. This will makes NE acts at a2-adrenergic agonist leading to a decrease in its own release and decrease sympathetic tone to blood vessels, leading to VD and decreased BP Which one of the above mechanism is more important for treating hypertension? Decreasing renin secretion Cont…. The respiratory system Blockade of β2 receptors in bronchi will cause bronchoconstriction Non–selective β blocker (are contraindicated in the bronchial asthma (propranolol) The β1 selective blockers (e.g: Atenolol; Bisoprolol) are also should be avoided in the acute bronchial asthma because their selectivity is relative and they may have antagonistic affects on the β2 receptors at therapeutic doses. Adrenergics & Antiadrenergic drugs 20 Cont…. The eye β–blockers are used in treatment of glaucoma (Timolol). They act by: Blocking β2 in ciliary epithelium. This will decrease production of aqueous humor. Block β2 in ciliary muscle. This will cause of contraction of the ciliary muscle leading to Decreased IOP Adrenergics & Antiadrenergic drugs 21 Cont…. Metabolic and endocrine effects β blocker inhibit lipolysis In type 1 diabetes The patient depends on catecholamines to increase blood glucose if he took overdose of insulin. If he took β blockers, they will impair the recovery from hypoglycemia β1 blockers are advised in the case of diabetic patients β – blockers cause increase VLDL & triglycerides (TG) and decrease HDL / Cholesterol ratio. Adrenergics & Antiadrenergic drugs 22 Cont…. Intrinsic sympathomimetic activity (ISA ) Some of the β antagonist produce some action of β agonist e.g. Pindolol & Labetalol…, so, they are less dangerous when given to patients with bronchial asthma or excessive bradycardia Membrane Stabilizing Action (MSA) Some β blockers stabilize the cell membrane by blocking Na+ channels. Therefore, produce “local anesthetic action” e.g. Propranolol & Pindolol … Adrenergics & Antiadrenergic drugs 23 β– blockers Side effects of β blockers Rash & fever Worsening of asthma CNS include Sedation and Depression and sleep disturbances These are more sever in Lipid – soluble β blockers (e.g. Propranolol) than in water soluble β blocker (e.g. Atenolol) Heart failure Adrenergics & Antiadrenergic drugs 24 β– blockers Contraindications of β-blockers: Bronchial asthma Peripheral vascular disease Heart failure (in severe cases only) (acute) Adrenergics & Antiadrenergic drugs 25 β– blockers Drug interactions: Verapamil (Ca++ ) channel blocker If it is combined with β – blockers, this can cause : Congestive heart failure Severe bradycardia Severe hypotension Adrenergics & Antiadrenergic drugs 26 β– blockers Withdrawal of β blockers: On chronic use, abrupt withdrawal of β – blockers causes the β receptors to become supersensitive and even the circulating catecholamine can stimulate them & cause severe arrhythmia. So, withdrawal should be very gradual over weeks Adrenergics & Antiadrenergic drugs 27 β– blockers Propranolol It is non – selective β blocker T1/2 = 2 – 5 h It is Lipid soluble Can be given orally or I.V It undergoes extensive 1st pass metabolism (90% of the drug) Adrenergics & Antiadrenergic drugs 28 Cont…. It’s duration of action is increased in Hepatic disease Decreased hepatic BF Metabolic inhibition e.g. when giving Cimetidine It has no ISA It has MSA . SO, It is used as antiarrhythmic drug but not in hypertension. It stabilize the cardiac cell membrane & decrease the activity of ectopic foci Adrenergics & Antiadrenergic drugs 29 Side effect of propranolol Bradycardia Cold extremities Fatigue Sedation Mental depression Sleep disturbances Heart failure A – V block Bronchospasm Impotence 30 β– blockers Timolol: It is a non – selective β blocker T1/2 = 4 – 5 h No ISA Low MSA so not good for arrethmia. Lipid – soluble Pass via the cornea. So, it is used as eye – drops to treat glaucoma Adrenergics & Antiadrenergic drugs 31 β– blockers Labetalol: It is a non-selective β blocker & selective α1 blocker T1/2 = 4 – 6 h Weak lipid – soluble It has ISA Has MSA It differs from other β blockers in that it produce less bradycardia. It is used in Pheochromocytoma and hypertension of pregnancy Adrenergics & Antiadrenergic drugs 32 Cont…. Adverse effects include: Nausea skin rash tiredness Aching limbs Bronchospasm Heart failure Sleep disturbance & nightmares Sexual dysfunction (more than other β blockers) Postural hypotension (because it is selective α1 blocker) Raynaud syndrome (peripheral vasospasm) Adrenergics & Antiadrenergic drugs 33 β– blockers Pindolol: It is a non-selective β blocker T1/2 = 3 – 4 h Has ISA (very important) lead to bradycardia. Weak lipid soluble Has MSA but less than Propranolol Adrenergics & Antiadrenergic drugs 34 β– blockers Carvedilol : like labitolol It is non – selective β blocker and non – selective α blocker It can be used in patients with heart failure due to: It is a peripheral vasodilator (unlike other β blockers) It has antioxidant activity It used in renal impairment . Adrenergics & Antiadrenergic drugs 35 β– blockers Atenolol: It is a relative β1 selective blocker Hydrophilic so it has: Longer t1/2= 12 – 18 h because it stays in tissue for a long time For this reason, the dose is once daily Less severe side effects on CNS No ISA No MSA Adverse effects include CNS : insomnia, headache & dizziness Impairment of glucose tolerance Bradycardia Bronchospasm Sexual dysfunction* Fatigue : due to decreased blood supply to the periphery* *all β blockers cause sexual dysfunction and fatigue. Adrenergics & Antiadrenergic drugs 36 β– blockers Practolol: It is a relatively β1 selective blocker It is used in intensive care unit for severe ventricular arrhythmia It is not used to treat hypertension because of it’s side effect Adrenergics & Antiadrenergic drugs 37 β– blockers Esmolol : It is a selective β1 blocker Has very short duration of action (t1/2 = 8min) Has low ISA Has MSA (good for arrhythmia ) It is given I.V when short term β blockade is required Safer to use than longer acting antagonists in critically ill patients. Adrenergics & Antiadrenergic drugs 38 Name of Drug Selectivity ISA MSA T1/2 Lipid solubility Atenolol Beta 1 No no 6-9 no Carvedilol Beta 1,2 No No 7-10 yes Esmolol Beta 1 No No 10 min no Labetalol Beta 1,2 Yes Yes 5 yes Pindolol Beta 1,2 Yes Yes 3-4 yes Propranolol Beta 1,2 No Yes 3-6 yes Timolol Beta 1,2 No No 4-5 yes Adrenergics & Antiadrenergic drugs 39 hypertension • atenolol • Labetalol • Pindolol • Esmolol • carvedilol Ischemic heart disease Arrhythmia • timolol • Propranolol • Propranolol • Esmolol • practolol Heart failure • Carvedilol • Metoprolol • Atenolol glaucoma • timolol Hyperthyroidism and anxiety • propranolol Migraine: •Propranolol Adrenergics & Antiadrenergic drugs 40 Centrally acting sympatholytic drugs Adrenergics & Antiadrenergic drugs 41 Centrally acting sympatholytic drugs These drugs have the opposite effect to those of the sympathomimetic drugs by acting on the CNS. Examples: α-methyldopa Clonidine Adrenergics & Antiadrenergic drugs 42 α– methyldopa Mechanism of action α–methyldopa is given orally then absorbed from GIT & enters the circulation It freely passes BBB & reaches CNS then it is converted to α– methylenorepinephrine which acts as an agonist at central α2 – adrenoreceptors. These α2 – adrenoreceptors are found in the medulla & pons α– methylenorepinephrine is called “false neurotransmitter” or (reactive metabolic of α– methyldopa) Action of α– methyldopa VD lead to decrease TVR without significant effects on CO or HR or renal blood flow Adrenergics & Antiadrenergic drugs 43 Cont…. Clinical uses: Treat pregnancy – associated hypertension Treat mild to moderate hypertension (not common used) Side effects include: It may cause fluid retention It may produce postural hypotension when standing from the sleeping position Sedation, insomnia, depression This not severe like α– blockers in the beginning of treatment & disappears after continuous use Serious extrapyramidal signs It interferes with neurotransmitter of extra pyramidal tract May lead to muscle incoordination Adrenergics & Antiadrenergic drugs 44 Cont…. Lactation Even in male : the breast may produce milk Hepatitis & drug fever (can be serious) Impotence A lupus – like reaction : skin rash and pustules Hemolytic anemia Leukopenia : sometimes Adrenergics & Antiadrenergic drugs 45 Clonidine: Already mentioned in α2 agonist. Alfa – methydopa Clonidine Route of administration I.V , orally I.V , orally, I.M t1/2 2–4h 5–7h Dose 800 – 1200mg total / dose/day 125 – 250 ug/day Metabolism To give alfa – methyl NE, then conjugated in urine and some of it secrete in faeces Adrenergics & Antiadrenergic drugs To give inactive form and secreted in the urine after conjugation 46 Adrenergics & Antiadrenergic drugs 47 :قواعد جوهرية •All adrenergic blockers reduce BP But : α blockers produce postural hypotension •Any α2 agonist is considered an antagonist because it inhibits the release of NE. •Relatively selective, means in high dose it may act on other receptors. (α1 blocker may act on α2 in high doses).