Pharmacology-Basic-Principles-AY-23-24-LEC.pdf

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PHARMACOLOGY
BASIC
PRINCIPLES

Vince Edward C. Araneta, MD,
FPAFP, CSPSH
Objectives
By the end of the unit, students will be expected to:

1. Define Pharmacology - its scope and its disciplines.
2. Explain the different pharmacokinetic processes such as
absorption, distribution, excretion, biotransformation, and to
identify the different factors that affect these processes.
3. Identify and explain the different molecular models of
receptors and how they work.
4. Differentiate an agonist from an antagonist.
 What Loading…
is Pharmacology?
The body of knowledge concerned with the action of chemicals on
biologic systems.
References
Basic Principles
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Part I
 Pharmacology

Medical
Toxicology
Pharmacology

Medical Pharmacology: the area of pharmacology concerned with the use of chemicals in the prevention,
diagnosis, and treatment of disease, especially in humans.

Toxicology: is the area of pharmacology concerned with the undesirable effects of chemicals on biologic
systems.
 The Nature of Drugs

Composition:
inorganic ions
nonpeptide organic molecules
small peptides and proteins
nucleic acids
lipids
carbohydrates

Source: plants or animals, but many are partially or completely synthetic
 The Nature of Drugs

Size & Molecular Weight
Most weigh between 100 and 1000
Smaller than MW 100 rarely sufficiently selective in their
actions
Larger than MW 1000 often poorly absorbed & poorly
distributed in the body
 What is the difference
between pharmacokinetics
& pharmacodynamics?
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Pharmacodynamics
Pharmacodynamics
 PHARMACODYNAMICS

The receptor concept has important practical consequences for the
development of drugs and for arriving at therapeutic decisions in clinical
practice. They may be briefly summarized as follows:

1. Receptors largely determine the quantitative relations between dose or
concentration of drug and pharmacologic effects.
2. Receptors are responsible for selectivity of drug action.
3. Receptors mediate the actions of pharmacologic agonists and
antagonists.
High-Yield Terms
Receptor A molecule to which a drug binds to bring about a
change in function of the biologic system
Inert binding A molecule to which a drug may bind without
molecule or site changing any function
Receptor site Specific region of the receptor molecule to which
the drug binds
Effector Component of a system that accomplishes the
biologic effect after the receptor is activated by an
agonist; often a channel or enzyme molecule, may
be part of the receptor molecule

Agonist A drug that activates its receptor upon binding
High-Yield Terms
Pharmacologic A drug that binds without activating its receptor
antagonist and thereby prevents activation by an agonist
Competitive A pharmacologic antagonist that can be overcome
antagonist by increasing the concentration of agonist
Irreversible A pharmacologic antagonist that cannot be
antagonist overcome by increasing agonist concentration
Physiologic A drug that counters the effects of another by
antagonist binding to a different receptor and causing
opposing effects
Chemical antagonist A drug that counters the effects of another by
binding the agonist drug (not the receptor)
High-Yield Terms
Allosteric agonist, A drug that binds to a receptor molecule without
antagonist interfering with normal agonist binding but alters the
response to the normal agonist
Partial agonist A drug that binds to its receptor but produces a smaller
effect at full dosage than a full agonist
Graded dose-response A graph of increasing response to increasing drug
curve concentration or dose
Quantal dose-response A graph of the fraction of a population that shows a
curve specified response at progressively increasing doses. The
median effective (ED50), median toxic (TD50), and (in
animals) median lethal (LD50) doses are derived from
experiments carried out in this manner.
 High-Yield Terms
Efficacy, maximal The maximal effect that can be achieved with a
efficacy particular drug, regardless of dose
Potency The amount of drug needed to produce a given
effect.
Therapeutic Index Is the ratio of the TD50 (or LD50) to the ED50.
V Safe drug : Represents an estimate of the safety of a drug. A
↑ toxic dose very safe drug might be expected to have a very
↓ effective dose
large toxic dose and a much smaller effective dose.
Therapeutic Window A more clinically useful index of safety. Describes
minimum effective to the dosage range between the minimum effective
min. toxic therapeutic concentration or dose, and the
minimum toxic concentration or dose.
Pharmacodynamic Principles: RECEPTORS
Drug-receptor binding Activation of receptor AGONIST

Drug-receptor binding Inhibition of receptor ANTAGONIST
 RELATIONSHIP BETWEEN DRUG
CONCENTRATION AND RESPONSE

The relation between dose of a drug and the clinically observed response
may be complex.

In carefully controlled in vitro systems, however, the relation between
concentration of a drug and its effect is often simple and can be described
with mathematical precision.

This idealized relation underlies the more complex relations between dose
and effect that occur when drugs are given to patients.
Concentration-Effect Curves & Receptor Binding of
Agonists
GRADED DOSE-RESPONSE
RELATIONSHIPS

When the response of a particular receptor-effector system is
measured against increasing concentrations of a drug, the graph of
the response versus the drug concentration or dose is called a graded
dose-response curve.
GRADED DOSE-RESPONSE
RELATIONSHIPS
GRADED DOSE-BINDING RELATIONSHIP
& BINDING AFFINITY

It is possible to measure the percentage of receptors bound by a
drug, and by plotting this percentage against the log of the
concentration of the drug, a dose-binding graph similar to the dose-
response curve is obtained.
QUANTAL DOSE-RESPONSE
RELATIONSHIPS

When the minimum dose required to produce a specified response is
determined in each member of a population, the quantal dose-
response relationship is defined.

When plotted as the percentage of the population that shows this
response at each dose versus the log of the dose administered, a
cumulative quantal dose-response curve, usually sigmoid in shape,
is obtained.
QUANTAL DOSE-RESPONSE
RELATIONSHIPS
EFFICACY

Efficacy—often called maximal efficacy—is the greatest effect
(Emax) an agonist can produce if the dose is taken to the highest
tolerated level.

By definition, partial agonists have lower maximal efficacy than full
agonists
GRADED DOSE-BINDING RELATIONSHIP
& BINDING AFFINITY
POTENCY

Potency denotes the amount of drug needed to produce a given
effect. In graded dose-response measurements, the effect usually
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chosen is 50% of the maximal effect and the concentration or dose
causing this effect is called the EC50 or ED50 (Figure 2–1A and B).
QUANTAL DOSE-RESPONSE
RELATIONSHIPS
SPARE RECEPTORS

Spare receptors are said to exist if the maximal drug response
(Emax) is obtained at less than 100% occupation of the receptors
(Bmax).

In practice, the determination is usually made by comparing the
concentration for 50% of maximal effect (EC50) with the
concentration for 50% of maximal binding (Kd).
 SPARE
RECEPTORS
AGONISTS, PARTIAL AGONISTS, INVERSE
AGONISTS

Modern concepts of drug-receptor interactions consider the receptor
to have at least 2 states—active and inactive. In the absence of
ligand, a receptor might be fully active or completely inactive;

Many receptor systems exhibit some activity in the absence of
ligand, suggesting that some fraction of the receptor is always in the
activated state. Activity in the absence of ligand is called
constitutive activity.
AGONISTS, PARTIAL AGONISTS, INVERSE
AGONISTS
AGONISTS, PARTIAL AGONISTS, INVERSE
AGONISTS

A full agonist is a drug capable of fully activating the effector
system when it binds to the receptor.

A partial agonist produces less than the full effect, even when it has
saturated the receptors (Ra-Dpa +Ri-Dpa), presumably by
combining with both receptor conformations, but favoring the active
state.
AGONISTS, PARTIAL AGONISTS, INVERSE
AGONISTS

In the presence of a full agonist, a partial agonist acts as an inhibitor.
In this model, neutral antagonists bind with equal affinity to the Ri
and Ra states, preventing binding by an agonist and preventing any
deviation from the level of constitutive activity.

In contrast, inverse agonists have a higher affinity for the inactive
Ri state than for Ra and decrease or abolish any constitutive activity.
ANTAGONISTS

A. Competitive and Irreversible Pharmacologic Antagonists
Competitive antagonists are drugs that bind to, or very close to the agonist
receptor site in a reversible way without activating the effector system for
that receptor

A noncompetitive antagonist that acts at an allosteric site of the receptor
may bind reversibly or irreversibly; a noncompetitive antagonist that acts at
the receptor site binds irreversibly.
ANTAGONISTS
SIGNALING MECHANISMS

Once an agonist drug has bound to its receptor, some effector
mechanism is activated.

The receptor-effector system may be an enzyme in the intracellular
space (eg, cyclooxygenase, a target of nonsteroidal anti-
inflammatory drugs) or in the membrane or extracellular space (eg,
acetylcholinesterase).
ANTAGONISTS

B. Physiologic Antagonists
A physiologic antagonist binds to a different receptor molecule, producing
an effect opposite to that produced by the drug it antagonizes.

C. Chemical Antagonists
interacts directly with the drug being antagonized to remove it or to prevent
it from binding to its target
THERAPEUTIC INDEX AND THERAPEUTIC
WINDOW

The therapeutic index is the ratio of the TD50 (or LD50) to the
ED50, determined from quantal dose-response curves. Represents
an estimate of the safety of a drug.

The therapeutic window, a more clinically useful index of safety,
describes the dosage range between the minimum effective
therapeutic concentration or dose, and the minimum toxic
concentration or dose.
SIGNALING MECHANISMS

Once an agonist drug has bound to its receptor, some effector
mechanism is activated.

The receptor-effector system may be an enzyme in the intracellular
space (eg, cyclooxygenase, a target of nonsteroidal anti-
inflammatory drugs) or in the membrane or extracellular space (eg,
acetylcholinesterase).
SIGNALING MECHANISMS
SIGNALING MECHANISMS
RECEPTOR REGULATION

Receptors are dynamically regulated in number, location, and
interaction with other molecules. Changes can occur over short
times (minutes) and longer periods (days).

Frequent or continuous exposure to agonists often results in short
term diminution of the receptor response, sometimes called
tachyphylaxis.
RECEPTOR REGULATION

Long-term reductions in receptor number (downregulation) may
occur in response to continuous exposure to agonists.

The opposite change (upregulation) occurs when receptor activation
is blocked for prolonged periods (usually several days) by
pharmacologic antagonists or by denervation.
Inert Binding Sites

Drugs bind to these nonregulatory molecules in the body no
discernible effect

Albumin: an important plasma protein with significant drug-
binding capacity
Pharmacokinetics
Pharmacokinetics
High-Yield Terms
Volume of distribution The ratio of the amount of drug in the body to the drug
(apparent) concentration in the plasma or blood
Half-life The time required for the amount of drug in the body or
blood to fall by 50%.
For drugs eliminated by first-order kinetics, this
number is a constant regardless of the concentration
Bioavailability The fraction (or percentage) of the administered dose of
drug that reaches the systemic circulation
Peak and trough The maximum and minimum drug concentrations
concentrations achieved during repeated dosing cycles
High-Yield Terms
Minimum effective The plasma drug concentration below which a patient’s
concentration response is too small for clinical benefit
(MEC)
First-pass effect, The elimination of drug that occurs after administration
presystemic but before it enters the systemic circulation (eg, during
elimination passage through the gut wall, portal circulation, or
liver for an orally administered drug)
Steady state In pharmacokinetics, the condition in which the average
total amount of drug in the body does not change over
multiple dosing cycles (ie, the condition in which the rate
of drug elimination equals the rate of administration)
Effective Drug Concentration
the concentration of a drug at the receptor site.

If the rate of input is known, the remaining processes are well
described by 2 primary parameters: apparent volume of distribution
(Vd) and clearance (CL).

These parameters are unique for a particular drug and a particular
patient but have average values in large populations that can be used to
predict drug concentrations.
Volume of Distribution
relates the amount of drug in the body to the plasma concentration
according to the following equation:
Volume of Distribution
Volume of Distribution
The Vd of drugs that are normally bound to plasma proteins such as
albumin can be altered by liver disease (through reduced protein
synthesis) and kidney disease (through urinary protein loss).

On the other hand, if a drug is avidly bound in peripheral tissues, the
drug’s concentration in plasma may drop to very low values even
though the total amount in the body is large.
Clearance
Clearance (CL) relates the rate of elimination to the plasma
concentration:

For a drug eliminated with first-order kinetics, clearance is a constant;
that is, the ratio of rate of elimination to plasma concentration is the
same over a broad range of plasma concentration
Clearance
As in the case of Vd, clearance is sometimes expressed as CL per kg of
body weight.

Clearance depends on the drug, blood flow, and the condition of the
organs of elimination in the patient.
Clearance
Half-Life
Half-life (t1/2) is a derived parameter, completely determined by Vd
and CL. Like clearance, half-life is a constant for drugs that follow
first-order kinetics. Half-life can be determined graphically from a plot
of the blood level versus time or from the following relationship:
Half-Life
 What is the half-life of drug X?
A. 8 am: 100 mg

B. 10 am: 75 mg

C. 12 pm: 50 mg

D. 2 pm: 25 mg
Half-life: 4 hours
Bioavailability
The bioavailability of a drug is the fraction (F) of the administered
dose that reaches the systemic circulation. Bioavailability is defined as
unity (or 100%) in the case of intravenous administration.

After administration by other routes, bioavailability is generally
reduced by incomplete absorption (and in the intestine, expulsion of
drug by intestinal transporters), first-pass metabolism, and any
distribution into other tissues that occurs before the drug enters the
systemic circulation.
Bioavailability
Extraction
Removal of a drug by an organ can be specified as the extraction ratio,
that is, the fraction or percentage of the drug removed from the
perfusing blood during its passage through the organ.

Drugs that have a high hepatic extraction ratio have a large first-pass
effect and the bioavailability of these drugs after oral administration is
low.
Extraction
Dosage Regimens
A dosage regimen is a plan for drug administration over a period of
time.

An optimal dosage regimen results in the achievement of therapeutic
levels of the drug in the blood without exceeding the minimum toxic
concentration.

To maintain the plasma concentration within a specified range over
long periods of therapy, a schedule of maintenance doses is used.
A. Maintenance Dosage
Because the maintenance rate of drug administration is equal to the
rate of elimination at steady state (this is the definition of steady state),
the maintenance dosage is a function of clearance (from Equation 2).
A. Maintenance Dosage
The number of doses to be given per day is usually determined by the
half-life of the drug and the difference between the minimum
therapeutic and toxic concentrations (therapeutic window).
If the difference between the toxic and therapeutic concentrations is
small, then smaller and more frequent doses must be administered to
prevent toxicity.
B. Loading Dosage
If the therapeutic concentration must be achieved rapidly and the Vd is
large, a large loading dose may be needed at the onset of therapy. This
can be calculated from the following equation:
Therapeutic Window
The therapeutic window is the safe range between the minimum
therapeutic concentration and the minimum toxic concentration of a
drug.

These data are used to determine the acceptable range of plasma levels
when designing a dosing regimen.
Therapeutic Window
Adjustment of Dosage When
Elimination is Altered by Disease
Renal disease or reduced cardiac output often reduces the clearance of
drugs that depend on renal elimination. Alteration of clearance by liver
disease is less common but may also occur.

The most important renal variable in drug elimination is glomerular
filtration rate (GFR), and creatinine clearance (CLcr) is a convenient
approximation of GFR.
Adjustment of Dosage When
Elimination is Altered by Disease
The dosage in a patient with renal impairment may be corrected by
multiplying the average dosage for a normal person times the ratio of
the patient’s altered creatinine clearance (CLcr) to normal creatinine
clearance (approximately 100 mL/min, or 6 L/h in a young adult).
Adjustment of Dosage When
Elimination is Altered by Disease
For example, if a drug is 50% cleared by the kidney and 50% by the
liver and the normal dosage is 200 mg/d, the hepatic and renal
elimination rates are each 100 mg/d. Therefore, the corrected dosage
in a patient with a creatinine clearance of 20 mL/min will be:
Adjustment of Dosage When
Elimination is Altered by Disease
Renal function is altered by many diseases and is often decreased in
older patients.

CLcr can be measured directly, but this requires careful measurement
of both serum creatinine concentration and a timed total urine
creatinine.
Adjustment of Dosage When
Elimination is Altered by Disease
A common shortcut that requires only the serum (or plasma) creatinine
measurement (Scr) is the use of an equation. One such equation in
common use is the Cockcroft-Gault equation:

The result is multiplied by 0.85 for females.
Adjustment of Dosage When
Elimination is Altered by Disease
A similar equation for GFR is the MDRD equation:
DRUG METABOLISM
DRUG METABOLISM
Many cells in tissues that act as portals for entry of external molecules
into the body that expel unwanted molecules immediately after
absorption.

Biotransformation of drugs is one such process. It is an important
mechanism by which the body terminates the action of many drugs.

In some cases, it serves to activate prodrugs.
TYPES OF METABOLIC
REACTIONS
Phase I Reactions - include oxidation, reduction, deamination, and
hydrolysis

Phase II Reactions - synthetic reactions that involve addition
(conjugation) of subgroups to —OH, —NH2, and —SH functions on
the drug molecule
TYPES OF
METABOLIC
REACTIONS
TYPES OF
METABOLICLoading…
REACTIONS
SITES OF DRUG
METABOLISM
The most important organ for drug
metabolism is the liver.

The kidneys play an important role in the
metabolism of some drugs.

A few drugs (eg, esters) are metabolized
in many tissues (eg, liver, blood,
intestinal wall) because of the wide
distribution of their enzymes.
DETERMINANTS OF
BIOTRANSFORMATIONS RATE
The rate of biotransformation of a drug may vary markedly among
different individuals. This variation is most often due to genetic or
drug-induced differences.

For a few drugs, age or disease-related differences in drug metabolism
are significant.
DETERMINANTS OF
BIOTRANSFORMATIONS RATE
Genetic Factors

Effects of Other Drugs
Enzyme Induction
Enzyme Inhibition
Inhibitors of Intestinal P-Glycoprotein
DETERMINANTS OF
BIOTRANSFORMATIONS RATE
Genetic Factors

Effects of Other Drugs
Enzyme Induction
Enzyme Inhibition
Inhibitors of Intestinal P-Glycoprotein
DETERMINANTS OF
BIOTRANSFORMATIONS RATE
DETERMINANTS OF
BIOTRANSFORMATIONS RATE
TOXIC METABOLISM
Drug metabolism is not synonymous with drug inactivation. Some
drugs are converted to active products by metabolism.

If these products are toxic, severe injury may result under some
circumstances.

An important example is acetaminophen when taken in large
overdoses.
TOXIC METABOLISM