Anesthetics epinephrine

Isoflurane is a respiratory depressant (71). At concentrations which are associated with surgical levels of anesthesia, there is Htde or no depression of myocardial function. In experimental animals, isoflurane is the safest of the oral clinical agents (72). Cardiac output is maintained despite a decrease in stroke volume. This is usually because of an increase in heart rate. The decrease in blood pressure can be used to produce "deHberate hypotension" necessary for some intracranial procedures (73). This agent produces less sensitization of the human heart to epinephrine relative to the other inhaled anesthetics. Isoflurane potentiates the action of neuromuscular blockers and when used alone can produce sufficient muscle relaxation (74). Of all the inhaled agents currently in use, isoflurane is metabolized to the least extent (75). Unlike halothane, isoflurane does not appear to produce Hver injury and unlike methoxyflurane, isoflurane is not associated with renal toxicity. 

Desflurane is less potent than the other fluorinated anesthetics having MAC values of 5.7 to 8.9% in animals (76,85), and 6% to 7.25% in surgical patients. The respiratory effects are similar to isoflurane. Heart rate is somewhat increased and blood pressure decreased with increasing concentrations. Cardiac output remains fairly stable. Desflurane does not sensitize the myocardium to epinephrine relative to isoflurane (86). EEG effects are similar to isoflurane and muscle relaxation is satisfactory (87). Desflurane is not metabolized to any significant extent (88,89) as levels of fluoride ion in the semm and urine are not increased even after prolonged exposure. Desflurane appears to offer advantages over sevoflurane and other inhaled anesthetics because of its limited solubiHty in blood and other tissues. It is the least metabolized of current agents. 

Lidocaine hydrochloride [73-78-9] (Xylocaine), is the most versatile local anesthetic agent because of its moderate potency and duration of action, rapid onset, topical activity, and low toxicity. Its main indications are for infiltration, peripheral nerve blocks, extradural anesthesia, and in spinal anesthesia where a duration of 30 to 60 min is desirable. Because of its vasodilator activity, addition of the vasoconstrictor, epinephrine, increases the duration of action of Hdocaine markedly. It is also available in ointment or aerosol preparations for a variety of topical appHcations. 

These agents are often combined with a vasoconstrictant such as epinephrine [51-43-4]. By using such a combination, the local anesthetic is held in the area for a longer period of time and its effect extended hemorrhage is minimized, blood loss prevented, and a better surgical repair obtained. 

Stoelting RK Systemic circulation in Stoetting RK (ed) Pharmacology and Physiology in Anesthetic Practice. Philadelphia, Lippincott, 2006, pp 661-678. Sullivan TJ Cardiac disorders in penicillin-induced anaphylaxis association with intravenous epinephrine therapy. JAMA 1982 248 2161-2162. 

In an anesthetized, ventilated canine model of anaphylactic shock defined as hypotension with blood pressure maintained at 50% of baseline, epinephrine infusion produces an improvement in blood pressure, associated with positive inotropy [21]. 

Epinephrine may be mixed with certain anesthetics, such as procaine, in order to... 

The answer is d. (Hardman, p T36J The addition of a vasoconstrictor, such as epinephrine or phenylephrine, to certain short-acting, local anesthetics is a common practice in order to prevent the rapid systemic absorption of the local anesthetics, to prolong the local action, and to decrease the potential systemic reactions. Some local anesthetics cause vasodilation, which allows more compound to escape the tissue and enter the blood. Procaine is an ester-type local anesthetic with a short duration of action due to rather rapid biotransformation in the plasma by cholinesterases. The duration of action of the drug during infiltration anesthesia is greatly increased by the addition of epinephrine, which reduces the vasodilation caused by procaine. 

Inhalation of certain hydrocarbons, including some anesthetics, can make the mammalian heart abnormally sensitive to epinephrine, resulting in ventricular arrhythmias, which in some cases can lead to sudden death (Reinhardt et al. 1971). The mechanism of action of cardiac sensitization is not completely understood but appears to involve a disturbance in the normal conduction of the electrical impulse through the heart, probably by producing a local disturbance in the electrical potential across cell membranes. The hydrocarbons themselves do not produce arrhythmia the arrhythmia is the result of the potentiation of endogenous epinephrine (adrenalin) by the hydrocarbon. 

In an undated study, HCFC-141b was administered to male SpragueDawley rats at concentrations of 5,000, 10,000, or 20,000 ppm for 30 min (Eger, unpublished data). As exposure continued, bolus intravenous epinephrine, characterized as three times the dose that produced arrhythmias in the same rats anesthetized with halothane, was administered. The dose of epinephrine was defined as a maximum of 12 fig/kg. For this study, three or more premature ventricular contractions was considered an arrhythmic response (Table 4—5). Marked arrhythmias occurred at all concentrations. The author further compared the concentrations of halothane and HCFC-141b that produced arrhythmias with administration of various doses of exogenous epinephrine. The nominal chamber concentration for HCFC-141b did not differ from that of halothane. Furthermore, the arrhythmias were characterized as relatively mild and within acceptable limits for surgical anesthesia in humans. 

Cardiac arrhythmias were induced in rats injected with exogenous epinephrine and exposed to HCFC-141 b at 5,000 ppm. However, the intravenous dose of epinephrine required was 3-fold that which induced arrhythmias in the same rats administered halothane, a common clinical anesthetic. Furthermore, the arrhythmias were characterized as mild. The threshold for cardiac sensitization for dogs was approximately 5,200 ppm. Deaths occurred in one study at 10,000 ppm and in another study at 20,000 ppm (with no deaths between concentrations of 9,000 and 19,000 ppm). 

Changes in adrenergic function are complex. Inhibition of neuronal catecholamine reuptake gives rise to superimposed indirect sympathomimetic stimulation. Patients are supersensitive to catecholamines (e.g., epinephrine in local anesthetic injections must be avoided). On the other hand, blockade of ai-receptors may lead to orthostatic hypotension. 

Several studies have indicated that n-butane sensitizes the myocardium to epinephrine-induced cardiac arrhythmias. In anesthetized dogs, 5000 ppm caused hemodynamic changes such as decreases in cardiac output, left ventricular pressure, and stroke volume, myocardial contractility, and aortic pressure. Exposure of dogs to 1-20% butane for periods of 2 minutes to 2 hours hypersen-... 

Inhalation studies with chloropentafluoroethane in anesthetized dogs, rats, and monkeys showed that exposure to 100,000-2 5 0,000 ppm, under certain conditions, caused an increase in blood pressure, accelerated heart rate, depression of myocardial contractility and sensitized the heart to epinephrine.Compared with other chlorofluorocarbons, it is ranked among the least potent for cardiac sensitization." ... 

Cardiac arrhythmias have been provoked in a number of species. Inhalation of 3 5 00-6100 ppm by dogs for 5 minutes caused ventricular fibrillation and cardiac arrest after injection of epinephrine. The minimal concentration that elicited cardiac arrhythmias in the anesthetized monkey was 50,000ppm. ... 

The vasoconstrictor actions of epinephrine and norepinephrine have been used to prolong the action of local anesthetics by reducing local blood flow in the region of the injection. Epinephrine has been used as a topical hemostatic agent for the control of local hemorrhage. Norepinephrine is infused intravenously to combat systemic hypotension during spinal anesthesia or other hypotensive conditions in which peripheral resistance is low, but it is not used to combat the hypotension due to most types of shock. In shock, marked sympathetic activity is already present, and perfusion of organs, such as the kidneys, may be jeopardized by norepinephrine administration. 

The most commonly used vasoconstrictors, the sympathomimetic drugs, are often added to local anesthetics to delay absorption of the anesthetic from its injection site. By slowing absorption, these drugs reduce the anesthetic s systemic toxicity and keep it in contact with nerve fibers longer, thereby increasing the drug s duration of action. Administration of lidocaine 1% with epinephrine results in the same degree of blockade as that produced by lidocaine 2% without the vasoconstrictor. 

Mepivacaine hydrochloride (Carbocaine) is longer acting than lidocaine and has a more rapid onset of action (3-5 minutes). Topical application is not effective. It has been widely used in obstetrics, but its use has declined recently because of the early transient neurobehavioral effects it produces. Adverse reactions associated with mepivacaine are generally similar to those produced by other local anesthetics. It can be used with epinephrine or levonordefrin (dental use only). 

TAC (tetracaine, adrenalin [epinephrine], and cocaine) is a combination topical anesthetic frequently used in pediatric emergency departments for repair of minor lacerations. The usual mixture is tetracaine 0.5%, epinephrine 1 2,000, and cocaine 11.8%. Because of potential complications (seizures), lower concentrations of cocaine and epinephrine in a tetracaine 1% solution have been suggested (TAC III). 

D. Epinephrine is by far the most commonly employed vasoconstrictor. Phenylephrine is occasionally used with procaine for dental procedures. Levonordefrin is also used rarely in dental procedures. Dopamine has no vasoconstrictor activity. Cocaine is itself a local anesthetic with some vasoconstrictor properties. However, cocaine, because of its abuse potential and toxicity, is seldom used. Its only use is topical. 

Beta-blockers interact with a large number of other medications. The combination of beta-blockers with calcium antagonists should be avoided, given the risk for hypotension and cardiac arrhythmias. Cimetidine, hydralazine, and alcohol all increase blood levels of beta-blockers, whereas rifampicin decreases their concentrations. Beta-blockers may increase blood levels of phenothiazines and other neuroleptics, clonidine, phen-ytoin, anesthetics, lidocaine, epinephrine, monoamine oxidase inhibitors and other antidepressants, benzodiazepines, and thyroxine. Beta-blockers decrease the effects of insulin and oral hypoglycemic agents. Smoking, oral contraceptives, carbamazepine, and nonsteroidal anti-inflammatory analgesics decrease the effects of beta-blockers (Coffey, 1990). 

Amphetamines Local anesthetic drags containing epinephrine or cocaine... 

Patients taking MAOIs are advised to carry identification cards that indicate that they are taking MAOIs. Before accepting any medication or anesthetic, patients should notify their physicians that they are taking MAOIs. When patients undergo dental procedures, local anesthetics without vasoconstrictors (e.g., epinephrine) must be used. 

Local anesthetics are frequently coadministered with vasoconstrictor molecules such as epinephrine. Normally, they are applied or injected locally and then taken up by local blood vessels into the systemic circulation, ultimately leading to their metabolic breakdown. The co-administration of a vasoconstrictor decreases the systemic absorption of the local anesthetic, thereby increasing its effective half-life in the area of administration and decreasing the probability of systemic toxicity (i.e., cardiac toxicity) secondary to systemic distribution. 

Effects of an -selective (phenylephrine), 13-selective (isoproterenol), and nonselective (epinephrine) sympathomimetic, given as an intravenous bolus injection to a dog. Reflexes are blunted but not eliminated in this anesthetized animal. BP, blood pressure HR, heart rate. 

Combining agonists with some local anesthetics greatly prolongs the duration of infiltration nerve block the total dose of local anesthetic (and the probability of toxicity) can therefore be reduced. Epinephrine, 1 200,000, is the favored agent for this application, but norepinephrine, phenylephrine, and other agonists have also been used. Systemic effects on the heart and peripheral vasculature may occur even with local drug administration but are usually minimal. 

Top Effects of phentolamine, an a-receptor-blocking drug, on blood pressure in an anesthetized dog. Epinephrine reversal is demonstrated by tracings showing the response to epinephrine before (middle) and after (bottom) phentolamine. All drugs given intravenously. BP, blood pressure HR, heart rate. 

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