General Principles of Pharmacology


General Principles of Pharmacology



HOW DO DRUGS ACT?


Drugs produce their effects on biological systems by several mechanisms; these include physicochemical action, activity at receptors and inhibition of reactions mediated by enzymes.



Physicochemical Properties


Sodium citrate is an alkali and neutralizes acid; it is often administered orally to reduce the likelihood of pneumonitis after regurgitation of gastric contents. Chelating agents (chel is the Greek word for a crab’s claw) combine chemically with metal ions, reducing their toxicity and enhancing elimination, usually in the urine. Such drugs include desferrioxamine (chelates iron and aluminium), dicobalt edetate (cyanide toxicity), sodium calcium edetate (lead) and penicillamine (copper and lead). Stored blood contains a citrate-based anticoagulant which prevents clotting; this chelates calcium ions and may cause hypocalcaemia after massive blood transfusion. Phenol and alcohol denature proteins; they are used occasionally to produce prolonged or permanent nerve blockade.



Action on Receptors


A receptor is a complex structure on the cell membrane which can bind selectively with endogenous compounds or drugs, resulting in changes within the cell which modify its function. These include changes in selective ion channel permeability (e.g. acetylcholine, glutamate, GABA receptors), cyclic adenosine monophosphate (e.g. opioid, β, α2 and dopamine receptors), cyclic guanosine monophosphate (e.g. atrial natriuretic peptide receptor), inositol phosphate and diacylglycerol (e.g. α1, angiotensin AT1, endothelin, histamine H1 and vasopressin V1 receptors) and nitric oxide (e.g. muscarinic M3 receptor).


A compound which binds to a receptor and changes intracellular function is termed an agonist. The classic dose–response relationship of an agonist is shown in Figure 1.1. As the concentration of the agonist increases, a maximum effect is reached as the receptors in the system become saturated (Fig. 1.1A). Conventionally, log dose is plotted against effect, resulting in a sigmoid curve which is approximately linear between 20 and 80% of maximum effect (Fig. 1.1B). Three agonists are shown in Figure 1.2. Agonist A produces 100% effect at a lower concentration than agonist B. Therefore, compared with A, agonist B is less potent but has similar efficacy. Drug C is termed a partial agonist as the maximum effect is less than that of A or B. Buprenorphine is a partial agonist (at the μ-opioid receptor), as are some of the β-blockers with intrinsic activity, e.g. oxprenolol, pindolol, acebutalol, celiprolol.




Antagonists combine selectively with the receptor but produce no effect. They may interact with the receptor in a competitive (reversible) or non-competitive (irreversible) fashion. In the presence of a competitive antagonist, the dose–response curve of an agonist is shifted to the right but the maximum effect remains unaltered (Fig. 1.3A). Examples of this effect include the displacement of morphine by naloxone and endogenous catecholamines by β-blockers.



A non-competitive (irreversible) antagonist also shifts the dose–response curve to the right but, with increasing concentrations, reduces the maximum effect (Fig. 1.3B). For example, the α1-antagonist phenoxybenzamine, used in the preoperative preparation of patients with phaeochromocytoma, has a long duration of action because of the formation of stable chemical bonds between drug and receptor.


The relationship between drug dose and response is often described by a Hill plot (Fig. 1.4). A typical agonist such as that shown in Figure 1.1 produces a straight line with a slope (i.e. Hill coefficient) of + 1.




Action on Enzymes


Drugs may act by inhibiting the action of an enzyme or competing for its endogenous substrate. Reversible inhibition is the mechanism of action of edrophonium (acetylcholinesterase), aminophylline (phosphodiesterase) and captopril (angiotensin-converting enzyme). Irreversible enzyme inhibition occurs when a stable chemical bond is formed between drug and enzyme, resulting in prolonged or permanent inactivity e.g. omeprazole (gastric hydrogen-potassium ATPase), aspirin (cyclo-oxygenase) and organophosphorus compounds (acetylcholinesterase).


However, the interaction between drug and enzyme may be more complex than this simple classification implies. For example, neostigmine inhibits acetylcholinesterase in a reversible manner, but the mechanism of action is more akin to that of an irreversible drug because neostigmine forms covalent chemical bonds with the enzyme.



THE BLOOD–BRAIN BARRIER AND PLACENTA


Many drugs used in anaesthetic practice must cross the blood–brain barrier in order to reach their site of action. The brain is protected from most potentially toxic agents by tightly overlapping endothelial cells which surround the capillaries and interfere with passive diffusion. In addition, enzyme systems are present in the endothelium which break down many potential toxins. Consequently, only relatively small, highly lipid-soluble molecules (e.g. intravenous and volatile anaesthetic agents, opioids, local anaesthetics) have access to the central nervous system (CNS). Compared with most opioids, morphine takes some time to reach its site of action because it has a relatively low lipid solubility. Highly ionized drugs (e.g. muscle relaxants, glycopyrronium) do not cross the blood–brain barrier.


The chemoreceptor trigger zone is situated in the area postrema near the base of the fourth ventricle (see Ch 42). It is not protected by the blood–brain barrier because the capillary endothelial cells are not bound tightly in this area and allow relatively free passage of large molecules. This is an important afferent limb of the vomiting reflex and stimulation of this area by toxins or drugs in the blood or cerebrospinal fluid often leads to vomiting. Many antiemetics act at this site.


The transfer of drugs across the placenta is of considerable importance in obstetric anaesthesia (see Ch 35). In general, all drugs which affect the CNS cross the placenta and affect the fetus. Highly ionized drugs (e.g. muscle relaxants) pass across less readily.



PLASMA PROTEIN BINDING


Many drugs are bound to proteins in the plasma. This is important because only the unbound portion of the drug is available for diffusion to its site of action. Changes in protein binding may have significant effects on the active unbound concentration of a drug, and therefore its actions.


Albumin is the most important protein in this regard and is responsible mainly for the binding of acidic and neutral drugs. Globulins, especially α1-glycoprotein, bind mainly basic drugs. If a drug is highly protein bound (> 80%), any change in plasma protein concentration or displacement of the drug by another with similar binding properties may have clinically significant effects. For example, most NSAIDs displace warfarin, phenytoin and lithium from plasma binding sites, leading to potential toxicity.


Plasma albumin concentration is often decreased in the elderly, in neonates and in the presence of malnutrition, liver, renal or cardiac failure and malignancy. α1-Glycoprotein concentration is decreased during pregnancy and in the neonate but may be increased in the postoperative period and other conditions such as infection, trauma, burns and malignancy.



METABOLISM


Most drugs are lipid-soluble and many are metabolized in the liver into more ionized compounds which are inactive pharmacologically and excreted by the kidneys. However, metabolites may be active (Table 1.1). The liver is not the only site of metabolism. For example, succinylcholine and mivacurium are metabolized by plasma cholinesterase, esmolol by erythrocyte esterases, remifentanil by tissue esterases and, in part, dopamine by the kidney and prilocaine by the lungs.



A substance is termed a prodrug if it is inactive in the form in which it is administered, pharmacological effects being dependent on the formation of active metabolites. Examples of this are codeine (morphine), diamorphine (6-monoacetylmorphine, morphine), chloral hydrate (trichlorethanol) and parecoxib (valdecoxib). Midazolam is ionized and dissolved in an acidic solution in the ampoule; after intravenous injection and exposure in the blood to pH 7.4, the molecule becomes lipid-soluble.


Drugs undergo two types of reactions during metabolism: phase I and phase II. Phase I reactions include reduction, oxidation and hydrolysis. Drug oxidation occurs in the smooth endoplasmic reticulum, primarily by the cytochrome P450 enzyme system. This system and other enzymes also perform reduction reactions. Hydrolysis is a common phase I reaction in the metabolism of drugs with ester groups (e.g. remifentanil, succinylcholine, atracurium, mivacurium). Amide drugs often undergo hydrolysis and oxidative N-dealkylation (e.g. lidocaine, bupivacaine).


Phase II reactions involve conjugation of a metabolite or the drug itself with an endogenous substrate. Conjugation with glucuronic acid is a major metabolic pathway, but others include acetylation, methylation and conjugation with sulphate or glycine.



Enzyme Induction and Inhibition


Some drugs may enhance the activity of enzymes responsible for drug metabolism, particularly the cytochrome P450 enzymes and glucuronyl transferase. Such drugs include phenytoin, carbamazepine, phenylbutazone, barbiturates, ethanol, steroids and some inhalational anaesthetic agents (halothane, enflurane). Cigarette smoking also induces cytochrome P450 enzymes.


Drugs with mechanisms of action other than on enzymes may also interfere significantly with enzyme systems. For example, etomidate inhibits the synthesis of cortisol and aldosterone – an effect which may explain the increased mortality in critically ill patients which occurred when it was used as a sedative in intensive care. Cimetidine is a potent enzyme inhibitor and may prolong the elimination of drugs such as diazepam, propranolol, oral anticoagulants, phenytoin and lidocaine. Troublesome interactions with enzyme systems are less of a problem with new drugs; if significant enzyme interaction is discovered in the early stages of development, the drug is usually abandoned.



DRUG EXCRETION


Ionized compounds with a low molecular weight (MW) are excreted mainly by the kidneys. Most drugs and metabolites diffuse passively into the proximal renal tubules by the process of glomerular filtration, but some are secreted actively (e.g. penicillins, aspirin, many diuretics, morphine, lidocaine and glucuronides). Ionization is a significant barrier to reabsorption at the distal tubule. Consequently, basic drugs or metabolites are excreted more efficiently in acid urine and acidic compounds in alkaline urine.


Some drugs and metabolites, particularly those with larger molecules (MW > 400 D), are excreted in the bile (e.g. glycopyrronium, vecuronium, pancuronium and the metabolites of morphine and buprenorphine). Ventilation is responsible for excretion of volatile anaesthetic agents.



PHARMACOKINETIC PRINCIPLES


Pharmacokinetics is the study of what happens to drugs after they have been administered. In contrast, pharmacodynamics is concerned with their effects on biological systems. An understanding of the basic principles of pharmacokinetics is an important aid to the safe use of drugs in anaesthesia, pain management and intensive care medicine. Pharmacokinetics is an attempt to fit observed changes in plasma concentration of drugs into mathematical equations which may then be used to predict concentrations under various circumstances.


Derived values describing volume of distribution (V), clearance (Cl) and half-life (t1/2) give an indication of the likely properties of a drug. However, even in healthy individuals of the same sex, weight and age, there is significant variability which makes precise prediction very difficult. It is important to remember that the accepted pharmacokinetic values of drugs are usually the mean of a wide range of observations.



Volume of Distribution


Volume of distribution is a good example of the abstract nature of pharmacokinetics; it is not a real volume but merely a concept which helps us to understand what we observe. Nevertheless, it is a very useful notion which enables us to predict certain properties of a drug and also calculate other pharmacokinetic values.


Imagine that a patient receiving an intravenous dose of an anaesthetic induction agent is a bucket of water and that the drug is distributed evenly throughout the water immediately after injection. The volume of water represents the initial volume of distribution (V). It may be calculated easily:


image (1)


where C0 is the initial concentration. Therefore:


image (2)


A more accurate measurement of V

May 31, 2016 | Posted by in ANESTHESIA | Comments Off on General Principles of Pharmacology

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