Chapter 4_ Physiologic Factors Related to Drug Absorption.pdf

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Shargel and Yu's Applied Biopharmaceutics and Pharmacokinetics, 8e

Chapter 4: Physiologic Factors Related to Drug Absorption

Phillip M. Gerk

CHAPTER OBJECTIVES
Define passive and active drug absorption.

Explain how Fick’s law of diffusion relates to passive drug absorption.

Calculate the percent of drug nonionized and ionized for a weak acid or weak­base drug using the Henderson–Hasselbalch equation and explain
how this may affect drug absorption.

Define transcellular and paracellular drug absorption and explain using drug examples.

Describe the anatomy and physiology of the GI tract and explain how stomach emptying time and GI transit time can alter the rate and extent of
drug absorption.

Explain the effect of food on GI physiology and systemic drug absorption.

Describe the various transporters and how they influence the pharmacokinetics of drug disposition in the GI tract.

Explain the pH­partition hypothesis and how gastrointestinal pH and the pKa of a drug may influence systemic drug absorption. Describe how
drug absorption may be affected by a disease that causes changes in intestinal blood flow and/or motility.

List the major factors that affect drug absorption from oral and non­oral routes of drug administration.

Describe various methods that may be used to study oral drug absorption from the GI transit.

DRUG ABSORPTION AND DESIGN OF A DRUG PRODUCT
Major considerations in the design of a drug product include the therapeutic objective, the application site, and systemic drug absorption from the
application site. If the drug is intended for systemic activity, the drug should ideally be completely and consistently absorbed from the application site.
In contrast, if the drug is intended for local activity, then systemic absorption from the application should be minimal to prevent systemic drug
exposure and possible systemic side effects. For extended­release drug products, the drug product should remain at or near the application site and
then slowly release the drug for the desired period of time. The systemic absorption of a drug is dependent on (1) the physicochemical properties of
the drug, (2) the nature of the drug product, and (3) the anatomy and physiology of the drug absorption site. Thus, the rate and extent to which a drug
gets from the site of administration to the blood will depend on its release from the dosage form into physiologic fluids, the permeability of the drug
through the tissues in the absorption site, and any degradation or metabolism of the drug that may occur before reaching the blood.

In order to develop a drug product that elicits the desired therapeutic objective, the pharmaceutical scientist must have a thorough understanding of
the biopharmaceutic properties of the drug and drug product and the physiologic and pathologic factors affecting drug absorption from the
application site. A general description of drug absorption, distribution, and elimination is shown in Fig. 4­1. Pharmacists must also understand the
relationship of drug dosage to therapeutic efficacy and adverse reactions and the potential for drug–drug and drug–nutrient interactions. This chapter
will focus on the anatomic and physiologic considerations for the systemic absorption of a drug, whereas Chapters 7 to 8 will focus on the
biopharmaceutic aspects of the drug and drug­product design, including considerations in manufacturing and performance tests. Since the major
route of drug administration is the oral route, major emphasis in this chapter will be on gastrointestinal (GI) drug absorption.

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The interrelationship of the absorption, distribution, binding, metabolism, and excretion of a drug and its concentration at its sites of action.
(Reproduced with permission from Brunton LL, Hilal­Dandan R, Knollmann BC: Goodman & Gilman’s Pharmacological Basis of Therapeutics, 13th ed.
New York, NY: McGraw Hill; 2018.)
application site. A general description of drug absorption, distribution, and elimination is shown in Fig. 4­1. Pharmacists must also understand the
relationship of drug dosage to therapeutic efficacy and adverse reactions and the potential for drug–drug and drug–nutrient interactions. This chapter
will focus on the anatomic and physiologic considerations for the systemic absorption of a drug, whereas Chapters 7 to 8 will focus on the
biopharmaceutic aspects of the drug and drug­product design, including considerations in manufacturing and performance tests. Since the major
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route of drug administration is the oral route, major emphasis in this chapter will be on gastrointestinal (GI) drug absorption.

FIGURE 4­1

The interrelationship of the absorption, distribution, binding, metabolism, and excretion of a drug and its concentration at its sites of action.
(Reproduced with permission from Brunton LL, Hilal­Dandan R, Knollmann BC: Goodman & Gilman’s Pharmacological Basis of Therapeutics, 13th ed.
New York, NY: McGraw Hill; 2018.)

ROUTE OF DRUG ADMINISTRATION
Drugs may be given by parenteral, enteral, inhalation, intranasal, transdermal (percutaneous), or intranasal route for systemic absorption. Each route
of drug administration has certain advantages and disadvantages. Characteristics of the more common routes of drug administration are listed in
Table 4­1. The systemic availability and onset of drug action are affected by blood flow at the administration site, the physicochemical characteristics of
the drug and the drug product, and any pathophysiologic condition at the absorption site. After a drug is systemically absorbed, drug distribution and
clearance follow normal physiological conditions of the body. Drug distribution and clearance are not usually altered by the drug formulation but may
be altered by pathology, genetic polymorphism, and drug–drug interactions, as discussed in other chapters.

TABLE 4­1
Common Routes of Drug Administration

Route Bioavailability Advantages Disadvantages

Parenteral Routes

Intravenous Complete (100%) Drug is given for immediate effect. Increased chance for adverse reaction.
bolus (IV) systemic drug Possible anaphylaxis.
absorption.
Instant
bioavailability.

Intravenous Complete (100%) Plasma drug levels more precisely controlled. Requires skill in insertion of infusion set.
infusion (IV inf) systemic drug May inject large fluid volumes. Tissue damage at site of injection
absorption. May use drugs with poor lipid solubility and/or irritating drugs. (infiltration, necrosis, or sterile abscess).
Rate of drug
absorption
controlled by
infusion rate.

Subcutaneous Prompt from Generally, used for insulin injection. Rate of drug absorption depends on blood
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Slow absorption from Insulin formulation can vary from short to
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repository intermediate and long acting.
formulations.
 Rate of drug
absorption
controlled by
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infusion rate.

Subcutaneous Prompt from Generally, used for insulin injection. Rate of drug absorption depends on blood
(SC) injection aqueous solution. flow and injection volume.
Slow absorption from Insulin formulation can vary from short to
repository intermediate and long acting.
formulations.

Intradermal Drug injected into Often used for allergy and other diagnostic tests, such as Some discomfort at site of injection.
injection surface area (dermal) tuberculosis.
of skin.

Intramuscular Rapid from aqueous Easier to inject than IV injection. Irritating drugs may be very painful.
(IM) injection solution. Larger volumes may be used compared to SC solutions. Different rates of absorption depending on
Slow absorption from muscle group injected and blood flow.
nonaqueous (oil)
solutions.

Intra­arterial 100% of solution is Used in chemotherapy to target drug to organ. Drug may also distribute to other tissues
injection absorbed. and organs in the body.

Intrathecal 100% of solution is Drug is directly injected into cerebrospinal fluid (CSF) for uptake Careful injection skill required.
injection absorbed. into brain.

Intraperitoneal In laboratory animals Used more in small laboratory animals. Less common injection Drug absorption via mesenteric veins to
injection (eg, rat) drug in humans. Used for renally impaired patients on peritoneal liver, may have some hepatic clearance
absorption dialysis who develop peritonitis. prior to systemic absorption.
resembles oral
absorption.

Enteral Routes

Buccal or Rapid absorption No “first­pass” effects. Buccal route may be formulated for local Some drugs may be swallowed. Not for
sublingual (SL) from lipid soluble prolonged action, eg, adhere to the buccal mucosa with some most drugs or drugs with high doses.
drugs. antifungal. Buccal is different from SL, which is usually placed
under tongue.

Oral (PO) Absorption may vary. Safest and easiest route of drug administration. Some drugs may have erratic absorption,
Generally, slower May use immediate­release and modified­release drug be unstable in the gastrointestinal tract, or
absorption rate products. be metabolized by liver prior to systemic
compared to IV bolus absorption.
or IM injection.

Rectal (PR) Absorption may vary Useful when patient cannot swallow medication. Absorption may be erratic.
from suppository. Used for local and systemic effects. Suppository may migrate to different
More reliable position.
absorption from Some patient discomfort.
enema (solution).

Other Routes

Transdermal Slow absorption, rate Transdermal delivery system (patch) is easy to use. Some irritation by patch or drug.
may vary. Used for lipid­soluble drugs with low dose and low molecular Permeability of skin variable with
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occlusive Page 3 / 51
Type of cream or ointment base affects
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Inhalation and Rapid absorption. May be used for local or systemic effects. Particle size of drug determines anatomic
 Other Routes

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Transdermal Slow absorption, rate Transdermal delivery system (patch) is easy to use. Some irritation by patch or drug.
may vary. Used for lipid­soluble drugs with low dose and low molecular Permeability of skin variable with
Increased absorption weight (MW). condition, anatomic site, age, and gender.
with occlusive Type of cream or ointment base affects
dressing. drug release and absorption.

Inhalation and Rapid absorption. May be used for local or systemic effects. Particle size of drug determines anatomic
intranasal Total dose absorbed placement in respiratory tract.
is variable. May stimulate cough reflex.
Some drug may be swallowed.

Many drugs are not administered orally because of insufficient systemic absorption from the GI tract. The diminished oral drug absorption may be due
to drug instability in the GI tract, drug degradation by the digestive enzymes in the intestine, high hepatic clearance (first­pass effect), and efflux
transporters such as P­glycoprotein resulting in poor and/or erratic systemic drug availability. Some orally administered drugs, such as
cholestyramine and others (Table 4­2), are not intended for systemic absorption but may be given orally for local activity in the GI tract. However, some
oral drugs such as mesalamine and balsalazide that are intended for local activity in the GI tract may also have a significant amount of systemic drug
absorption. Small, highly lipid­soluble drugs such as nitroglycerin and fentanyl that are subject to high first­pass effects if swallowed may be given by
buccal or sublingual routes to bypass degradation in the GI tract and/or first­pass effects. Insulin is an example of protein peptide drug generally not
given orally due to degradation and inadequate absorption in the GI tract.

TABLE 4­2
Drugs Given Orally for Local Drug Activity in the Gastrointestinal Tract

Drug Example Comment

Cholestyramine Questran Cholestyramine resin is the chloride salt of a basic anion exchange resin, a cholesterol­lowering agent. Cholestyramine
resin is hydrophilic but insoluble in water and not absorbed from the digestive tract.

Balsalazide Colazal Balsalazide disodium is a prodrug that is enzymatically cleaved in the colon to produce mesalamine, an anti­inflammatory
disodium drug. Balsalazide disodium is intended for local action in the treatment of mildly to moderately active ulcerative colitis.
Balsalazide disodium and its metabolites are absorbed from the lower intestinal tract and colon.

Mesalaminea Asacol Asacol HD delayed­release tablets have an outer protective coat and an inner coat, which dissolves at pH 7 or greater,

delayed­release HD tablet releasing mesalamine in the terminal ileum for topical anti­inflammatory action in the colon.

tablet

Mesalamine Pentasa Pentasa capsule is an ethylcellulose­coated, controlled­release capsule formulation of mesalamine designed to release
controlled­ capsule therapeutic quantities of mesalamine throughout the gastrointestinal tract.
release capsule

aAlso referred to as 5­aminosalicylic acid or 5­ASA. Although mesalamine is indicated for local anti­inflammatory activity in the lower GI tract, mesalamine is

systemically absorbed from the GI tract.

Biotechnology­derived drugs (see Chapter 10) are usually given by the parenteral route because they are too labile in the GI tract to be administered
orally. For example, erythropoietin and human growth hormone (somatropin) are administered intramuscularly, and insulin is given subcutaneously
or intramuscularly. Subcutaneous injection results in relatively slow absorption from the site of administration compared to intravenous injection,
which provides immediate delivery to the plasma. Pathophysiologic conditions such as burns will increase the permeability of drugs across the skin
compared with normal intact skin. Currently, pharmaceutical research is being directed to devise approaches for the oral absorption of various protein
drugs such as insulin (Dhawan et al, 2009). Recently, inhaled insulin was approved for use by the FDA but the product was discontinued by the
manufacturer because of poor patient and physician acceptance of this new route of administration. Biotechnology­derived drugs are discussed more
fully in Chapter
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When
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drug is administered by Reserved.
Hill. All Rights an extravascular
Termsroute of administration
of Use (eg,
Privacy Policy oral, topical,
Notice intranasal, inhalation, rectal), the drug must first be
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absorbed into the systemic circulation and then diffuse or be transported to the site of action before eliciting biological and therapeutic activity. The
general principles and kinetics of absorption from these extravascular sites follow the same principles as oral dosing, although the physiology of the
or intramuscularly. Subcutaneous injection results in relatively slow absorption from the site of administration compared to intravenous injection,
which provides immediate delivery to the plasma. Pathophysiologic conditions such as burns will increase the permeability of drugs across the skin
compared with normal intact skin. Currently, pharmaceutical research is being directed to devise approaches for the oral absorption of various protein
drugs such as insulin (Dhawan et al, 2009). Recently, inhaled insulin was approved for use by the FDA but the product was discontinued byAccess
the Provided by:
manufacturer because of poor patient and physician acceptance of this new route of administration. Biotechnology­derived drugs are discussed more
fully in Chapter 10.

When a drug is administered by an extravascular route of administration (eg, oral, topical, intranasal, inhalation, rectal), the drug must first be
absorbed into the systemic circulation and then diffuse or be transported to the site of action before eliciting biological and therapeutic activity. The
general principles and kinetics of absorption from these extravascular sites follow the same principles as oral dosing, although the physiology of the
site of administration differs.

NATURE OF CELL MEMBRANES
Many drugs administered by extravascular routes are intended for local effect. Other drugs are designed to be absorbed from the site of
administration into the systemic circulation. For systemic drug absorption, the drug may cross cellular membranes. After oral administration, drug
molecules must cross the intestinal epithelium by going either through or between the epithelial cells to reach the systemic circulation. The
permeability of a drug at the absorption site into the systemic circulation is intimately related to the molecular structure and properties of the drug and
to the physical and biochemical properties of the cell membranes. Once in the plasma, the drug may act directly or may have to cross biological
membranes to reach the site of action. Therefore, biological membranes potentially pose a significant barrier to drug delivery.

Transcellular absorption is the process of drug movement across a cell. Some polar molecules may not be able to traverse the cell membrane but
instead go through gaps or tight junctions between cells, a process known as paracellular drug diffusion. Figure 4­2 shows the difference between the
two processes. Some drugs are probably absorbed by a mixed mechanism involving multiple processes.

FIGURE 4­2

Summary of intestinal epithelial transporters. Transporters shown by square and oval shapes demonstrate active and facilitated transporters,
respectively. Names of cloned transporters are shown with square or oval shapes. In the case of active transporters, arrows in the same direction
represent symport of substance and the driving force. Arrows going in the reverse direction mean the antiport. (Reproduced with permission from
Tsuji A, Tamai I. Carrier­mediated intestinal transport of drugs, Pharm Res 1996 Jul;13(7):963­977.) Note that BCRP and MRP2 are positioned similarly
to MDR1 (P­glycoprotein).

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respectively. Names of cloned transporters are shown with square or oval shapes. In the case of active transporters, arrows in the same direction
represent symport of substance and the driving force. Arrows going in the reverse direction mean the antiport. (Reproduced with permission from
Tsuji A, Tamai I. Carrier­mediated intestinal transport of drugs, Pharm Res 1996 Jul;13(7):963­977.) Note that BCRP and MRP2 are positioned similarly
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to MDR1 (P­glycoprotein).

Membranes are major structures in cells, surrounding the entire cell (plasma membrane) and acting as a boundary between the cell and the interstitial
fluid. In addition, membranes enclose most of the cell organelles (eg, the mitochondrion membrane). Functionally, cell membranes are
semipermeable partitions that act as selective barriers to the passage of molecules. Water, some selected small molecules, and lipid­soluble molecules
pass readily through such membranes, whereas highly charged molecules and large molecules, such as proteins and protein­bound drugs, do not.

The transmembrane movement of drugs is influenced by the composition and structure of the plasma membranes. Cell membranes are generally thin,
approximately 70–100 Å in thickness. Cell membranes are composed primarily of phospholipids in the form of a bilayer interdispersed with
carbohydrates and protein groups. There are several theories as to the structure of the cell membrane. The lipid bilayer or unit membrane theory,
originally proposed by Davson and Danielli (1952), considers the plasma membrane to be composed of two layers of phospholipid between two
surface layers of proteins, with the hydrophilic “head” groups of the phospholipids facing the protein layers and the hydrophobic “tail” groups of the
phospholipids aligned in the interior. The lipid bilayer theory explains the observation that lipid­soluble drugs tend to penetrate cell membranes more
easily than polar molecules. However, the bilayer cell membrane structure does not account for the diffusion of water, small­molecular­weight
molecules such as urea, and certain charged ions.

The fluid mosaic model, proposed by Singer and Nicolson (1972), explains the transcellular diffusion of polar molecules (Lodish, 1979). According to
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this model, the 12:33 consists
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is 49.151.13.23
proteins embedded in a dynamic fluid, lipid bilayer matrix (Fig. 4­3). These proteins provide a
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 6 / 51
pathway for the selective transfer of certain polar molecules and charged ions through the lipid barrier. As shown in Fig. 4­3, transmembrane proteins
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are interdispersed throughout the membrane. Two types of pores of about 10 nm and 50–70 nm were inferred to be present in membranes based on
capillary membrane transport studies (Pratt and Taylor, 1990). These small pores provide a channel through which water, ions, and dissolved solutes
surface layers of proteins, with the hydrophilic “head” groups of the phospholipids facing the protein layers and the hydrophobic “tail” groups of the
phospholipids aligned in the interior. The lipid bilayer theory explains the observation that lipid­soluble drugs tend to penetrate cell membranes more
easily than polar molecules. However, the bilayer cell membrane structure does not account for the diffusion of water, small­molecular­weight
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molecules such as urea, and certain charged ions.

The fluid mosaic model, proposed by Singer and Nicolson (1972), explains the transcellular diffusion of polar molecules (Lodish, 1979). According to
this model, the cell membrane consists of globular proteins embedded in a dynamic fluid, lipid bilayer matrix (Fig. 4­3). These proteins provide a
pathway for the selective transfer of certain polar molecules and charged ions through the lipid barrier. As shown in Fig. 4­3, transmembrane proteins
are interdispersed throughout the membrane. Two types of pores of about 10 nm and 50–70 nm were inferred to be present in membranes based on
capillary membrane transport studies (Pratt and Taylor, 1990). These small pores provide a channel through which water, ions, and dissolved solutes
such as urea may move across the membrane.

FIGURE 4­3

Model of the plasma membrane including proteins and carbohydrates as well as lipids. Integral proteins are embedded in the lipid bilayer; peripheral
proteins are merely associated with the membrane surface. The carbohydrate consists of monosaccharides, or simple sugars, strung together in
chains attached to proteins (forming glycoproteins) or to lipids (forming glycolipids). The asymmetry of the membrane is manifested in several ways.
Carbohydrates are always on the exterior surface and peripheral proteins are almost always on the cytoplasmic, or inner, surface. The two lipid
monolayers include different proportions of the various kinds of lipid molecules. Most important, each species of integral protein has a definite
orientation, which is the same for every molecule of that species. (© George V. Kelvin.)

Membrane proteins embedded in the bilayer serve special purposes. These membrane proteins function as structural anchors, receptors, ion
channels, or transporters to transduce electrical or chemical signaling pathways that facilitate or prevent selective actions. In contrast to simple bilayer
structure, membranes are highly ordered and compartmented (Brunton, 2011). Indeed, many early experiments on drug absorption or permeability
using isolated gut studies were proven not valid because the membrane proteins and electrical properties of the membrane were compromised in
many epithelial cell membranes, including those of the GI tract.

PASSAGE OF DRUGS ACROSS CELL MEMBRANES
There are several mechanisms by which drugs may pass through cell membranes. Passive (simple) diffusion does not involve any energy or transporter
protein. Carrier­mediated transport involves a protein which facilitates the movement of the drug across the membrane, either with or without an
energy source. Active transport is a special case of carrier­mediated transport, in which an energy source is used to drive the transport process. These
different types of transport will each be discussed further in the following sections.

Passive Diffusion

Theoretically, a lipophilic drug may pass through the cell or go around it. If the drug has a low molecular weight and is lipophilic, the lipid cell
membrane is not a barrier to drug diffusion and absorption. Passive diffusion is the process by which molecules spontaneously diffuse from a region
of higher concentration to a region of lower concentration. This process is passive because no external energy is expended. In Fig. 4­4, drug molecules
move forward and back across a membrane. If the two sides have the same drug concentration, forward­moving drug molecules are balanced by
molecules moving back, resulting in no net transfer of drug. When one side is higher in drug concentration at any given time, the number of forward­
moving drug molecules will be higher than the number of backward­moving molecules; the net result will be a transfer of molecules to the alternate
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side downstream
Chapter from the
4: Physiologic concentration
Factors gradient,
Related to as indicated
Drug Absorption, in theM.
Phillip Gerkby the big arrow. The rate of transfer is called flux and is represented
figure Page 7 by a
/ 51
vector to show its direction in space. The tendency of molecules to move in all directions
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constantly collide with one another in space. Only left and right molecule movements are shown in Fig. 4­4, because movement of molecules in other
directions will not result in concentration changes due to the limitation of the container wall.
Theoretically, a lipophilic drug may pass through the cell or go around it. If the drug has a low molecular weight and is lipophilic, the lipid cell
membrane is not a barrier to drug diffusion and absorption. Passive diffusion is the process by which molecules spontaneously diffuse from a region
of higher concentration to a region of lower concentration. This process is passive because no external energy is expended. In Fig. 4­4, drug molecules
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move forward and back across a membrane. If the two sides have the same drug concentration, forward­moving drug molecules are balanced by
molecules moving back, resulting in no net transfer of drug. When one side is higher in drug concentration at any given time, the number of forward­
moving drug molecules will be higher than the number of backward­moving molecules; the net result will be a transfer of molecules to the alternate
side downstream from the concentration gradient, as indicated in the figure by the big arrow. The rate of transfer is called flux and is represented by a
vector to show its direction in space. The tendency of molecules to move in all directions is natural because molecules possess kinetic energy and
constantly collide with one another in space. Only left and right molecule movements are shown in Fig. 4­4, because movement of molecules in other
directions will not result in concentration changes due to the limitation of the container wall.

FIGURE 4­4

Passive diffusion of molecules. Molecules in solution diffuse randomly in all directions. As molecules diffuse from left to right and vice versa (small
arrows), a net diffusion from the high­concentration side to the low­concentration side results. This results in a net flux (J) to the right side. Flux is
measured in mass per unit time (eg, ng/min).

Passive diffusion is the major absorption process for most drugs. The driving force for passive diffusion is higher drug concentrations, typically on the
mucosal side compared to the blood (serosal) side as in the case of oral drug absorption. According to Fick’s law of diffusion, drug molecules diffuse
from a region of high drug concentration to a region of low drug concentration.

(4.1)

where dQ/dt = rate of diffusion, D = diffusion coefficient, A = surface area of membrane, K = lipid–water partition coefficient of drug in the biologic
membrane that controls drug permeation, h = membrane thickness, and CGI − Cp = difference between the concentrations of drug in the GI tract and in
the plasma.

Because the drug distributes rapidly into a large volume after entering the blood, the concentration of drug in the blood initially is quite low with
respect to the concentration at the site of drug absorption. For example, a drug is usually given in milligram doses so that the drug concentration at the
absorption site maybe in mg/mL, whereas plasma drug concentrations are often in the microgram­per­milliliter or nanogram­per­milliliter range. If the
drug is given orally, then CGI >> Cp. A large concentration gradient is maintained until most of the drug is absorbed, thus driving drug molecules from
the GI tract into the plasma.

Given Fick’s law of diffusion, several other factors may influence the rate of passive diffusion of drugs. For example, the degree of lipid solubility of the
drug influences the rate of drug absorption. The partition coefficient, K, represents the lipid–water partitioning of a drug across a membrane such as
the mucosa. Drugs that are more lipid soluble have a larger K value. The surface area, A, of the membrane also influences the rate of absorption. Drugs
may be absorbed from most areas of the GI tract. However, the duodenal area of the small intestine shows the most rapid drug absorption, due to such
anatomic features as villi and microvilli, which provide a large surface area. These villi are less abundant in other areas of the GI tract.

The thickness of the membrane, h, is generally a constant1 for any particular absorption site. Drugs usually diffuse very rapidly through capillary
plasma membranes in the vascular compartments, in contrast to diffusion through plasma membranes of capillaries in the brain. In the brain, the
capillaries are densely lined with glial cells, so a drug diffuses slowly into the brain as if a thick lipid membrane exists. The term blood–brain barrier is
used to describe the slow diffusion of water­soluble molecules across capillary plasma membranes into the brain. However, in certain disease states
such as meningitis, these membranes may be disrupted or become more permeable to drug diffusion.

The diffusion coefficient, D, is a constant for each drug and is defined as the amount of a drug that diffuses across a membrane of a given unit area per
unit time when the concentration gradient is unity. The dimensions of D are area per unit time—for example, cm2/sec.

Because D, A, K, and h are constants under usual conditions for absorption, a combined constant P or permeability coefficient may be defined.

(4.2)
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Furthermore, in Equation 4.1 the drug concentration in the plasma, Cp, is extremely small compared to the drug concentration in the GI tract, CGI. If Cp
is negligible and P is substituted into Equation 4.1, the following relationship for Fick’s law is obtained:
The diffusion coefficient, D, is a constant for each drug and is defined as the amount of a drug that diffuses across a membrane of a given unit area per
unit time when the concentration gradient is unity. The dimensions of D are area per unit time—for example, cm2/sec.
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Because D, A, K, and h are constants under usual conditions for absorption, a combined constant P or permeability coefficient may be defined.

(4.2)

Furthermore, in Equation 4.1 the drug concentration in the plasma, Cp, is extremely small compared to the drug concentration in the GI tract, CGI. If Cp
is negligible and P is substituted into Equation 4.1, the following relationship for Fick’s law is obtained:

(4.3)

Equation 4.3 is an expression for a first­order process. In practice, the extravascular absorption of most drugs tends to be a first­order absorption
process. Moreover, because of the large concentration gradient between CGI and Cp, the rate of drug absorption is usually more rapid than the rate of
drug elimination.

Many drugs have both lipophilic and hydrophilic chemical substituents. Those drugs that are more lipid soluble tend to traverse cell membranes more
easily than less lipid­soluble or more water­soluble molecules. For drugs that act as weak electrolytes, such as weak acids and bases, the extent of
ionization influences the drug’s diffusional permeability. The ionized species of the drug contains a charge and is more water soluble than the
nonionized species of the drug, which is more lipid soluble. The extent of ionization of a weak electrolyte will depend on both the pKa of the drug and
the pH of the medium in which the drug is dissolved. Henderson and Hasselbalch used the following expressions pertaining to weak acids and weak
bases to describe the relationship between pKa and pH:

For weak acids,

(4.4)

For weak bases,

(4.5)

With Equations 4.4 and 4.5, the proportion of free acid or free base existing as the nonionized species may be determined at any given pH, assuming
the pKa for the drug is known. For example, at a plasma pH of 7.4, salicylic acid (pKa = 3.0) exists mostly in its ionized or water­soluble form, as shown
below:

In a simple system, the total drug concentration on either side of a membrane should be the same at equilibrium, assuming Fick’s law of diffusion is
the only distribution factor involved. For diffusible drugs, such as nonelectrolyte drugs or drugs that do not ionize, the drug concentrations on either
side of the membrane are the same at equilibrium. However, for electrolyte drugs or drugs that ionize, the total drug concentrations on either side of
the membrane are not equal at equilibrium if the pH of the medium differs on respective sides of the membrane. For example, consider the
concentration of salicylic acid (pKa = 3.0) in the stomach (pH 1.2) as opposed to its concentration in the plasma (pH 7.4) (Fig. 4­5). According to the
Henderson–Hasselbalch equation (Equation 4.4) for weak acids, at pH 7.4 and at pH 1.2, salicylic acid exists in the ratios that follow.

FIGURE 4­5

Model for the distribution of an orally administered weak electrolyte drug such as salicylic acid.

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Henderson–Hasselbalch equation (Equation 4.4) for weak acids, at pH 7.4 and at pH 1.2, salicylic acid exists in the ratios that follow.

FIGURE 4­5

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Model for the distribution of an orally administered weak electrolyte drug such as salicylic acid.

In the plasma, at pH 7.4

In gastric juice, at pH 1.2

The total drug concentration on either side of the membrane is determined as shown in Table 4­3.

TABLE 4­3
Relative Concentrations of Salicylic Acid as Affected by pH

Drug Gastric Juice (pH 1.2) Plasma (pH 7.4)

RCOOH 1.0000 1

RCOO− 0.0158 25,100

Total drug concentration 1.0158 25,101

Thus, the pH affects distribution of salicylic acid (RCOOH) and its salt (RCOO−) across cell membranes. It is assumed that the acid, RCOOH, is freely
permeable and the salt, RCOO−, is not permeable across the cell membrane. In this example, the total concentration of salicylic acid at equilibrium is
approximately 25,000 times greater in the plasma than in the stomach (see Table 4­3). These calculations can also be applied to weak bases, using
Equation 4.5.

According to the pH­partition hypothesis, if the pH on one side of a cell membrane differs from the pH on the other side of the membrane, then (1) the
drug (weak acid or base) will ionize to different degrees on respective sides of the membrane; (2) the total drug concentrations (ionized plus
nonionized drug) on either side of the membrane will be unequal; and (3) the compartment in which the drug is more highly ionized will contain the
greater total drug concentration. For these reasons, a weak acid (such as salicylic acid) will be more rapidly absorbed from the stomach (pH 1.2) than a
weak base (such as quinidine).

Another factor that can influence drug concentrations on either side of a membrane is a particular affinity of the drug for a tissue component, which
prevents the drug from moving freely back across the cell membrane. For example, a drug such as dicumarol binds to plasma protein, and digoxin
binds to tissue protein. In each case, the protein­bound drug does not move freely across the cell membrane. Drugs such as chlordane are very lipid
soluble and will partition into adipose (fat) tissue. In addition, a drug such as tetracycline might form a complex with calcium in the bones and teeth.
Finally, a drug may concentrate in a tissue due to a specific uptake or active transport process. Such processes have been demonstrated for iodide in
thyroid tissue, potassium in the intracellular water, and certain catecholamines into adrenergic storage sites. Such drugs may have a higher total drug
concentration on the side where binding occurs, yet the free drug concentration that diffuses across cell membranes will be the same on both sides of
the membrane.

Instead of diffusing into the cell, drugs can also diffuse into the spaces around the cell as an absorption mechanism. In paracellular drug absorption,
drug molecules smaller than 500 MW diffuse through the tight junctions, or spaces between intestinal epithelial cells. Generally, paracellular drug
absorption is very
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tight junctions between cells. For example, if mannitol is dosed orally, it would be absorbed minimally through
is 49.151.13.23
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk
this route; mannitol has very, very low oral bioavailability. Page 10 / 51
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Carrier­Mediated Transport
thyroid tissue, potassium in the intracellular water, and certain catecholamines into adrenergic storage sites. Such drugs may have a higher total drug
concentration on the side where binding occurs, yet the free drug concentration that diffuses across cell membranes will be the same on both sides of
the membrane.
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Instead of diffusing into the cell, drugs can also diffuse into the spaces around the cell as an absorption mechanism. In paracellular drug absorption,
drug molecules smaller than 500 MW diffuse through the tight junctions, or spaces between intestinal epithelial cells. Generally, paracellular drug
absorption is very slow, being limited by tight junctions between cells. For example, if mannitol is dosed orally, it would be absorbed minimally through
this route; mannitol has very, very low oral bioavailability.

Carrier­Mediated Transport

Enterocytes are simple columnar epithelial cells that line the intestinal walls in the small intestine and colon. They express various drug transporters,
are connected by tight junctions, and often play an important role in determining the rate and extent of drug absorption. Uptake transporters move
drug molecules into the blood and increase plasma drug concentration, whereas efflux transporters move drug molecules back into the gut lumen and
reduce systemic drug absorption. These cells also express some drug­metabolizing enzymes, and can contribute to presystemic drug metabolism
(Doherty and Charman, 2002).

Theoretically, a lipophilic drug may either pass through the cell or go around it. If the drug has a low molecular weight and is lipophilic, the lipid cell
membrane is not a barrier to drug diffusion and absorption. In the intestine, drugs and other molecules can go through the intestinal epithelial cells by
either diffusion or a carrier­mediated mechanism. Numerous specialized carrier­mediated transport systems are present in the body, especially in the
intestine for the absorption of ions and nutrients required by the body.

Active Transport

Active transport is a carrier­mediated transmembrane process that plays an important role in the GI absorption and in urinary and biliary secretion of
many drugs and metabolites. A few lipid­insoluble drugs that resemble natural physiologic metabolites (such as 5­fluorouracil) are absorbed from the
GI tract by this process. Active transport is characterized by the ability to transport drug against a concentration gradient—that is, from regions of low
drug concentrations to regions of high drug concentrations. Therefore, this is an energy­consuming system. In addition, active transport is a
specialized process requiring a carrier that binds the drug to form a carrier–drug complex that shuttles the drug across the membrane and then
dissociates the drug on the other side of the membrane (Fig. 4­6).

FIGURE 4­6

Hypothetical carrier­mediated transport process.

The carrier molecule may be highly selective for the drug molecule. If the drug structurally resembles a natural substrate that is actively transported,
then it is likely to be actively transported by the same carrier mechanism. Therefore, drugs of similar structure may compete for sites of adsorption on
the carrier. Furthermore, because only a fixed number of carrier molecules are available, all the binding sites on the carrier may become saturated if
the drug concentration gets very high. A comparison between the rate of drug absorption and the concentration of drug at the absorption site is shown
in Fig. 4­7. Notice that for a drug absorbed by passive diffusion, the rate of absorption increases in a linear relationship to drug concentration (first­
order rate). In contrast, for drugs that are absorbed by a carrier­mediated process, the rate of drug absorption increases with drug concentration until
the carrier molecules are completely saturated. At higher drug concentrations, the rate of drug absorption remains constant, or zero order, as
expected in Michaelis­Menten kinetics.

FIGURE 4­7

Comparison of the rates of drug absorption of a drug absorbed by passive diffusion (line A) and a drug absorbed by a carrier­mediated system (line B).

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Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 11 / 51
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expected in Michaelis­Menten kinetics.

FIGURE 4­7

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Comparison of the rates of drug absorption of a drug absorbed by passive diffusion (line A) and a drug absorbed by a carrier­mediated system (line B).

Several transport proteins are expressed in the intestinal epithelial cells (Suzuki and Sugiyama, 2000; Takano et al, 2006) (Fig. 4­8). Although some
transporters facilitate absorption, other transporters such as P­gp may effectively inhibit drug absorption. P­gp (also known as MDR1), an energy­
dependent, membrane­bound protein, is an efflux transporter that mediates the secretion of compounds from inside the cell back out into the
intestinal lumen, thereby limiting overall absorption (see Chapter 21). Thus, drug absorption may be reduced or increased by the presence or absence
of efflux proteins. The role of efflux proteins is generally believed to be a defense mechanism for the body to excrete and reduce drug accumulation.

FIGURE 4­8

Localization of efflux transporters and PEPT1 in intestinal epithelial cell. (Reproduced with permission from Takano M, Yumoto R, Murakami T.
Expression and function of efflux drug transporters in the intestine. Pharmacol Ther 2006 Jan;109(1­2):137–161.)

P­gp is expressed also in other tissues such as the blood–brain barrier, liver, and kidney, where it limits drug penetration into the brain, mediates
biliary drug secretion, and mediates renal tubular drug secretion, respectively. Efflux pumps are present throughout the body and are involved in
transport of a diverse group of hydrophobic drugs, natural products, and peptides. Many drugs and chemotherapeutic agents, such as cyclosporin A,
verapamil, terfenadine, fexofenadine, and most HIV­1 protease inhibitors, are substrates of P­gp (see Chapter 21). In addition, individual genetic
differences in intestinal absorption may be the result of genetic differences in P­gp and other transporters.

Facilitated Diffusion

Facilitated diffusion is also a carrier­mediated transport system, differing from active transport in that the drug moves along a concentration gradient
(ie, moves from a region of high drug concentration to a region of low drug concentration). Therefore, this system does not require energy input.
However, because this system is carrier mediated, it is saturable and structurally selective for the drug and shows competition kinetics for drugs of
similar structure. In terms of drug absorption, facilitated diffusion seems to play a very minor role.

Transporters and Carrier­Mediated Intestinal Absorption
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Various carrier­mediated
Chapter systems
4: Physiologic Factors (transporters)
Related to Drugare present atPhillip
Absorption, the intestinal
M. Gerkbrush border and basolateral membrane for the absorption Pageof specific
12 / 51
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ions andMcGraw Hill.
nutrients All Rights
essential for Reserved. Terms
the body (Tsuji and of Use 1996).
Tamai, Privacy Policy
Both Notice
influx Accessibility
and efflux transporters are present in the brush border and basolateral
membrane that will increase drug absorption (influx transporter) or decrease drug absorption (efflux transporter).
Facilitated diffusion is also a carrier­mediated transport system, differing from active transport in that the drug moves along a concentration gradient
(ie, moves from a region of high drug concentration to a region of low drug concentration). Therefore, this system does not require energy input.
However, because this system is carrier mediated, it is saturable and structurally selective for the drug and shows competition kinetics for drugs of
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similar structure. In terms of drug absorption, facilitated diffusion seems to play a very minor role.

Transporters and Carrier­Mediated Intestinal Absorption

Various carrier­mediated systems (transporters) are present at the intestinal brush border and basolateral membrane for the absorption of specific
ions and nutrients essential for the body (Tsuji and Tamai, 1996). Both influx and efflux transporters are present in the brush border and basolateral
membrane that will increase drug absorption (influx transporter) or decrease drug absorption (efflux transporter).

Uptake transporters

For convenience, influx transporters were referred to as those that enhance absorption as uptake transporters and those that cause drug outflow as
efflux transporters. However, this concept is too simple and inadequate to describe the roles of many transporters that have bidirectional efflux and
other functions related to their location in the membrane. Recent progress has been made in understanding the genetic role of membrane
transporters in drug safety and efficacy. In particular, more than 400 membrane transporters in two major superfamilies—ATP­binding cassette (ABC)
and solute carrier (SLC)—have been annotated in the human genome. Many of these transporters have been cloned, characterized, and localized in the
human body including the GI tract. The subject was reviewed by The International Transporter Consortium (ITC) (Giacomini, 2010).

Many drugs are absorbed by carrier systems because of the structural similarity to natural substrates or simply because they encounter the
transporters located in specific part of the GI tract (Table 4­4). The small intestine expresses a variety of uptake transporters (see Fig. 4­2) for amino
acids, peptides, hexoses, organic anions, organic cations, nucleosides, and other nutrients (Tsuji and Tamai, 1996; Giacomini, 2010). Among these
uptake (absorptive) transporters are the intestinal oligopeptide transporter, or di­/tripeptide transporter, PEPT1 has potential for enhancing intestinal
absorption of peptide drugs. The expression and function of PEPT1 (gene symbol SLC15A1) are now well analyzed for this application. Proteins given
orally are digested in the GI tract to produce a variety of short­chain peptides; these di­ and tripeptides could be taken up by enterocytes and the
proton/peptide cotransporter (PepT1) localized on the brush­border membrane. These uptake transporters are located at the brush border as well as
in the basolateral membrane to allow efficient absorption of essential nutrients into the body. Uptake transporters such as those for hexoses and
amino acids also favor absorption (see arrows as shown in Fig. 4­7).

TABLE 4­4
Intestine Transporters and Examples of Drugs Transported

Transporter Examples

Amino acid transporter Gabapentin D­Cycloserine

Methyldopa Baclofen

L­dopa

Oligopeptide transporter Cefadroxil Cephradine

Cefixime Ceftibuten

Cephalexin Captopril

Lisinopril Thrombin inhibitor

Phosphate transporter Fostomycin Foscarnet

Bile acid transporter S3744

Glucose transporter p­Nitrophenyl­β­d­glucopyranoside

P­glycoprotein efflux Etoposide Vinblastine

Downloaded 2024­9­11 12:33 A Your IP is 49.151.13.23Cyclosporin A
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 13 / 51
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Monocarboxylic acid transporter Salicylic acid Benzoic acid

Pravastatin
orally are digested in the GI tract to produce a variety of short­chain peptides; these di­ and tripeptides could be taken up by enterocytes and the
proton/peptide cotransporter (PepT1) localized on the brush­border membrane. These uptake transporters are located at the brush border as well as
in the basolateral membrane to allow efficient absorption of essential nutrients into the body. Uptake transporters such as those for hexoses and
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amino acids also favor absorption (see arrows as shown in Fig. 4­7).

TABLE 4­4
Intestine Transporters and Examples of Drugs Transported

Transporter Examples

Amino acid transporter Gabapentin D­Cycloserine

Methyldopa Baclofen

L­dopa

Oligopeptide transporter Cefadroxil Cephradine

Cefixime Ceftibuten

Cephalexin Captopril

Lisinopril Thrombin inhibitor

Phosphate transporter Fostomycin Foscarnet

Bile acid transporter S3744

Glucose transporter p­Nitrophenyl­β­d­glucopyranoside

P­glycoprotein efflux Etoposide Vinblastine

Cyclosporin A

Monocarboxylic acid transporter Salicylic acid Benzoic acid

Pravastatin

Data from Tsuji A, Tamai I. Carrier­mediated intestinal transport of drugs, Pharm Res 1996 Jul;13(7):963–977.

Efflux transporters

Many of the efflux transporters in the GI tract are membrane proteins located strategically in membranes to protect the body from influx of undesirable
compounds. A common example is MDR1 or P­gp (alias), which has the gene symbol ABCB1. P­gp is an example of the ABC subfamily. MDR1 is one of
the many proteins known as multidrug­resistance­associated protein. It is important in pumping drugs out of cells and causing treatment resistance in
some cell lines (see Chapter 21).

P­gp has been identified in the intestine and reduces apparent intestinal epithelial cell permeability from lumen to blood for various lipophilic or
cytotoxic drugs. P­gp is highly expressed on the apical surface of superficial columnar epithelial cells of the ileum and colon, and expression decreases
proximally into the jejunum, duodenum, and stomach. Takano et al (2006) reported that P­gp is present in various human tissues and ranked as
follows: (1) adrenal medulla (relative level to that in KB­3­1 cells, >500­fold); (2) adrenal (160­fold); (3) kidney medulla (75­fold); (4) kidney (50­fold); (5)
colon (31­fold); (6) liver (25­fold); (7) lung, jejunum, and rectum (20­fold); (8) brain (12­fold); (9) prostate (8­fold); and so on, including skin, esophagus,
stomach, ovary, muscle, heart, and kidney cortex. The widespread presence of P­gp in the body appears to be related to its defensive role in effluxing
drugs and other xenobiotics out of different cells and vital body organs. This transporter is sometimes called an efflux transporter while others are
better described as “influx” proteins. P­gp has the remarkable ability to efflux drug out of many types of cells including endothelial lumens of
capillaries. The
Downloaded expression
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12:33 is often
A Your IP triggered in many cancer cells making them drug resistant due to drug efflux.
is 49.151.13.23
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 14 / 51
For many
©2024 GI transporters,
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Hill. All Rights Reserved.of a Terms
drug is of
often
Usebidirectional (Fig. 4­9),
Privacy Policy and whether
Notice the transporter causes drug absorption or exsorption
Accessibility
depends on which direction the flux dominates with regard to a particular drug at a given site. An example of how P­gp affects drug absorption can be
seen with the drug digoxin. P­gp is present in the liver and the GI tract. In Caco­2 cells and other model systems, P­gp is known to efflux drug out of the
follows: (1) adrenal medulla (relative level to that in KB­3­1 cells, >500­fold); (2) adrenal (160­fold); (3) kidney medulla (75­fold); (4) kidney (50­fold); (5)
colon (31­fold); (6) liver (25­fold); (7) lung, jejunum, and rectum (20­fold); (8) brain (12­fold); (9) prostate (8­fold); and so on, including skin, esophagus,
stomach, ovary, muscle, heart, and kidney cortex. The widespread presence of P­gp in the body appears to be related to its defensive role in effluxing
Access Provided by:
drugs and other xenobiotics out of different cells and vital body organs. This transporter is sometimes called an efflux transporter while others are
better described as “influx” proteins. P­gp has the remarkable ability to efflux drug out of many types of cells including endothelial lumens of
capillaries. The expression of P­gp is often triggered in many cancer cells making them drug resistant due to drug efflux.

For many GI transporters, the transport of a drug is often bidirectional (Fig. 4­9), and whether the transporter causes drug absorption or exsorption
depends on which direction the flux dominates with regard to a particular drug at a given site. An example of how P­gp affects drug absorption can be
seen with the drug digoxin. P­gp is present in the liver and the GI tract. In Caco­2 cells and other model systems, P­gp is known to efflux drug out of the
enterocyte. Digoxin was previously known to have erratic/incomplete absorption or bioavailability problems. While reported bioavailability issues
were attributed to formulation or other factors, it is also now known that knocking out the P­gp gene in mice increases bioavailability of the drug. In
addition, human P­gp genetic polymorphisms occur. Hoffmeyer et al (2000) demonstrated that a polymorphism in exon 26 (C3435T) resulted in
reduced intestinal P­gp, leading to increased oral bioavailability of digoxin in the subject involved. However, direct determination of P­gp substrate in
vivo is not always readily possible. Most early determinations are done using in vitro cell assay methods, or in vivo studies involving a cloned animal
with the gene knocked out such as the P­gp, a knock­out (KO) mouse, for example, P­gp (−/−), which is the most sensitive method to identify P­gp
substrates. Changes in the expression of P­gp may be triggered by diseases or other drugs, contributing to variability in P­gp activity and variable
plasma drug concentrations after a given dose is administered. Results from in vitro and preclinical (animal) studies may need to be verified through
clinical drug–drug interaction studies to establish the role of P­gp in the oral bioavailability of a drug.

FIGURE 4­9

Diagram showing possible directional movement of a substrate drug by a transporter.

The breast cancer resistance protein (BCRP; gene symbol ABCG2) is like P­gp in that it is also found in many important fluid barrier layers, including the
intestine, liver, kidney, and brain. BCRP also transports many drugs out of cells, working (like P­gp) to keep various compounds out of the body (by
decreasing their absorption) or helping to eliminate them. Drugs transported by BCRP include many anticancer drugs (methotrexate, irinotecan,
mitoxantrone), statins (rosuvastatin), as well as nitrofurantoin and various sulfated metabolites of drugs and endogenous compounds. The FDA
requires all investigational new drugs to be tested for their potential activity as substrates of both P­gp and BCRP, and also recommends determining if
they are inhibitors (Huang and Zhang, 2012).

FREQUENTLY ASKED QUESTIONS

What is the effect of intestinal P­gp on the blood level of the substrate drug digoxin when a substrate inhibitor (ketoconazole) is present?

According to the diagram in Fig. 4­9, in which direction is P­gp pumping the drug? Is P­gp acting as an efflux transporter in this diagram?

Why is it too simple to classify transporters based on an “absorption” and “exsorption” concept?

Would a drug transport process involving ABC transporter be considered a passive or active transport process?

How does a transporter influence the level of drug within the cell?

P­gp affects the bioavailability of many substrate drugs listed in Table 4­5. P­gp inhibitors should be carefully evaluated before coadministration with a
P­gp substrate drug. Other transporters are also present in the intestines (Tsuji and Tamai, 1996). For example, many oral cephalosporins are
absorbed through amino acid transporters. Cefazolin, a parenteral­only cephalosporin, is not available orally because it cannot be absorbed to a
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Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 15 / 51
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Reported Substrates of P­gp—A Member of ATP­Binding Cassette (ABC) Transporters
 How does a transporter influence the level of drug within the cell?

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P­gp affects the bioavailability of many substrate drugs listed in Table 4­5. P­gp inhibitors should be carefully evaluated before coadministration with a
P­gp substrate drug. Other transporters are also present in the intestines (Tsuji and Tamai, 1996). For example, many oral cephalosporins are
absorbed through amino acid transporters. Cefazolin, a parenteral­only cephalosporin, is not available orally because it cannot be absorbed to a
significant degree through this mechanism.

TABLE 4­5
Reported Substrates of P­gp—A Member of ATP­Binding Cassette (ABC) Transporters

Acebutolol, acetaminophen, actinomycin d, h­acetyldigoxin, amitriptyline, amprenavir, apafant, asimadoline, atenolol, atorvastatin, azidopine,
azidoprocainamide methiodide, azithromycin
Benzo(a)pyrene, betamethasone, bisantrene, bromocriptine, bunitrolol, calcein­AM
Camptothecin, carbamazepine, carvedilol, celiprolol, cepharanthin, cerivastatin, chloroquine, chlorpromazine, chlorothiazide, clarithromycin, colchicine,
corticosterone, cortisol, cyclosporin A
Daunorubicin (daunomycin), debrisoquine, desoxycorticoster one, dexamethasone, digitoxin
Digoxin, diltiazem, dipyridamole, docetaxel, dolastatin 10, domperidone, doxorubicin (adriamycin)
Eletriptan, emetine, endosulfan, erythromycin, estradiol, estradiol­17h­d­glucuronide, etoposide (VP­16)
Fexofenadine, gf120918, grepafloxacin
Hoechst 33342, hydroxyrubicin, imatinib, indinavir, ivermectin
Levofloxacin, loperamide, losartan, lovastatin
Methadone, methotrexate, methylprednisolone, metoprolol, mitoxantrone, monensin
Morphine, 99mtc­sestamibi

N­desmethyltamoxifen, nadolol, nelfinavir, nicardipine, nifedipine, nitrendipine, norverapamil
Olanzapine, omeprazole
PSC­833 (valspodar), perphenazine, prazosin, prednisone, pristinamycin IA, puromycin
Quetiapine, quinidine, quinine
Ranitidine, reserpine
Rhodamine 123, risperidone, ritonavir, roxithromycin
Saquinavir, sirolimus, sparfloxacin, sumatriptan,
Tacrolimus, talinolol, tamoxifen, taxol (paclitaxel), telithromycin, terfenadine, timolol, toremifene
Tributylmethylammonium, trimethoprim
Valinomycin, vecuronium, verapamil, vinblastine
Vincristine, vindoline, vinorelbine

Adapted with permission from Takano M, Yumoto R, Murakami T. Expression and function of efflux drug transporters in the intestine. Pharmacol Ther 2006
Jan;109(1–2):137–161.

FREQUENTLY ASKED QUESTIONS

The bioavailability of an antitumor drug is provided in the package insert. Why is it important to know whether the drug is an efflux transporter
substrate or not?

Can the expression of efflux transporter in a cell change as the disease progresses?

Why is blockade of efflux transporter efflux of a drug, its glucuronide, or sulfate metabolite into the bile clinically important?

Clinical Examples of Transporter Impact

Multidrug resistance (MDR) to cancer cells has been linked to efflux transporter proteins such as P­gp that can efflux or pump out chemotherapeutic
agents from the cells (Sauna et al, 2001). Paclitaxel (Taxol) is an example of coordinated metabolism, efflux, and triggering of hormone nuclear
receptor to induce efflux protein (Fig. 4­10). P­gp (see MDR1 in Fig. 4­2) is responsible for 85% of paclitaxel excretion back into the GI tract (Synold et al,
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2001). Paclitaxel activates12:33 A Your IP
the pregnane is 49.151.13.23
X receptor (also known as PXR, or alternatively as steroid X receptor [SXR]), which in turn induces MDR1
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 16 / 51
transcription
©2024 McGraw Hill. All Rights Reserved. Terms offurther
and P­gp expression, resulting in even Use excretion of paclitaxel
Privacy Policy Noticeinto the intestinal fluid. Paclitaxel also induces CYP3A4 and CYP2C8
Accessibility
transcription, resulting in increased paclitaxel metabolism. Thus, in response to a xenobiotic challenge, PXR can induce both a first line of defense
(intestinal excretion) and a backup system (hepatic drug inactivation) that limits exposure to potentially toxic compounds. In contrast to paclitaxel,
Clinical Examples of Transporter Impact
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Multidrug resistance (MDR) to cancer cells has been linked to efflux transporter proteins such as P­gp that can efflux or pump out chemotherapeutic
agents from the cells (Sauna et al, 2001). Paclitaxel (Taxol) is an example of coordinated metabolism, efflux, and triggering of hormone nuclear
receptor to induce efflux protein (Fig. 4­10). P­gp (see MDR1 in Fig. 4­2) is responsible for 85% of paclitaxel excretion back into the GI tract (Synold et al,
2001). Paclitaxel activates the pregnane X receptor (also known as PXR, or alternatively as steroid X receptor [SXR]), which in turn induces MDR1
transcription and P­gp expression, resulting in even further excretion of paclitaxel into the intestinal fluid. Paclitaxel also induces CYP3A4 and CYP2C8
transcription, resulting in increased paclitaxel metabolism. Thus, in response to a xenobiotic challenge, PXR can induce both a first line of defense
(intestinal excretion) and a backup system (hepatic drug inactivation) that limits exposure to potentially toxic compounds. In contrast to paclitaxel,
docetaxel is a closely related antineoplastic agent that does not activate PXR but has a much better absorption profile.

FIGURE 4­10

Mechanism of coordinated efflux and metabolism of paclitaxel by PXR (SXR). (Reproduced with permission from Synold TW, Dussault I, Forman BM.
The orphan nuclear receptor SXR coordinately regulates drug metabolism and efflux. Nat Med 2001 May;7(5):584–590.)

Mutations of other transporters, particularly those involved in reuptake of serotonin, dopamine, and gamma­aminobutyric acid (GABA), are presently
being studied with regard to clinically relevant changes in drug response. Pharmacogenetic variability in these transporters is an important
consideration in patient dosing. When therapeutic failures occur, the following questions should be asked: (1) Is the drug a substrate for P­gp and/or
CYP3A4? (2) Is the drug being coadministered with anything that inhibits P­gp and/or CYP3A4? For example, grapefruit juice and many drugs can affect
drug metabolism and oral absorption.

Vesicular Transport

Vesicular transport is the process of engulfing particles or dissolved materials by the cell. Pinocytosis and phagocytosis are forms of vesicular
transport that differ by the type of material ingested. Pinocytosis refers to the engulfment of small solutes or fluid, whereas phagocytosis refers to the
engulfment of larger particles or macromolecules, generally by macrophages. Endocytosis and exocytosis are the processes of moving specific
macromolecules into and out of a cell, respectively.

During pinocytosis, phagocytosis, or transcytosis, the cell membrane invaginates to surround the material and then engulfs the material, incorporating
it inside the cell (Fig. 4­11). Subsequently, the cell membrane containing the material forms a vesicle or vacuole within the cell. Transcytosis is the
process by which various macromolecules are transported across the interior of a cell. In transcytosis, the vesicle fuses with the plasma membrane to
release the encapsulated material to another side of the cell. Vesicles are employed to intake the macromolecules on one side of the cell, draw them
across the cell, and eject them on the other side. Transcytosis (sometimes referred to as vesicular transport) is the proposed process for the
absorption of 2024­9­11
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12:33 A Sabin polio
Your IP vaccine and various large proteins.
is 49.151.13.23
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 17 / 51
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FIGURE McGraw Hill. All Rights Reserved. Terms of Use Privacy Policy Notice Accessibility

Diagram showing exocytosis and endocytosis.
During pinocytosis, phagocytosis, or transcytosis, the cell membrane invaginates to surround the material and then engulfs the material, incorporating
it inside the cell (Fig. 4­11). Subsequently, the cell membrane containing the material forms a vesicle or vacuole within the cell. Transcytosis is the
process by which various macromolecules are transported across the interior of a cell. In transcytosis, the vesicle fuses with the plasma membrane to
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release the encapsulated material to another side of the cell. Vesicles are employed to intake the macromolecules on one side of the cell, draw them
across the cell, and eject them on the other side. Transcytosis (sometimes referred to as vesicular transport) is the proposed process for the
absorption of orally administered Sabin polio vaccine and various large proteins.

FIGURE 4­11

Diagram showing exocytosis and endocytosis.

Pinocytosis is a cellular process that permits the active transport of fluid from outside the cell through the membrane surrounding the cell into the
inside of the cell. In pinocytosis, tiny incuppings called caveolae (little caves) in the surface of the cell close and then pinch off to form pinosomes, little
fluid­filled bubbles, that are free within the cytoplasm of the cell.

An example of exocytosis is the transport of a protein such as insulin from insulin­producing cells of the pancreas into the extracellular space. The
insulin molecules are first packaged into intracellular vesicles, which then fuse with the plasma membrane to release the insulin outside the cell.

Pore (Convective) Transport

Very small molecules (such as urea, water, and sugars) are able to cross cell membranes rapidly, as if the membrane contained channels or pores.
Although such pores have never been directly observed by microscopy, the model of drug permeation through aqueous pores is used to explain renal
excretion of drugs and the uptake of drugs into the liver.

A certain type of protein called a transport protein may form an open channel across the lipid membrane of the cell (see Fig. 4­2). Small molecules
including drugs move through the channel by diffusion more rapidly than at other parts of the membrane.

Ion­Pair Formation

Strong electrolyte drugs are highly ionized or charged molecules, such as quaternary nitrogen compounds with extreme pKa values. Strong electrolyte
drugs maintain their charge at all physiologic pH values and penetrate membranes poorly. When the ionized drug is linked with an oppositely charged
ion, an ion pair is formed in which the overall charge of the pair is neutral. This neutral drug complex diffuses more easily across the membrane. For
example, the formation of ion pairs to facilitate drug absorption has been demonstrated for propranolol, a basic drug that forms an ion pair with oleic
acid, and quinine, which forms ion pairs with hexylsalicylate (Nienbert, 1989).

An interesting application of ion pairs is the complexation of amphotericin B and DSPG (distearoylphosphatidylglycerol) in some amphotericin
B/liposome products. Ion pairing may transiently alter distribution, reduce high plasma free drug concentration, and reduce renal toxicity.

1 The thickness of the membrane is generally a constant. However, under certain pathological conditions such as meningitis, drugs penetrate into the
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Chapter 4: Physiologic
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DRUG INTERACTIONS IN THE GASTROINTESTINAL TRACT
example, the formation of ion pairs to facilitate drug absorption has been demonstrated for propranolol, a basic drug that forms an ion pair with oleic
acid, and quinine, which forms ion pairs with hexylsalicylate (Nienbert, 1989).

An interesting application of ion pairs is the complexation of amphotericin B and DSPG (distearoylphosphatidylglycerol) in some amphotericin
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B/liposome products. Ion pairing may transiently alter distribution, reduce high plasma free drug concentration, and reduce renal toxicity.

1 The thickness of the membrane is generally a constant. However, under certain pathological conditions such as meningitis, drugs penetrate into the

brain more quickly or in the case of burns, drugs can permeate through the skin more easily.

DRUG INTERACTIONS IN THE GASTROINTESTINAL TRACT
Many agents (drug or chemical substances) may have dual roles as substrate and/or inhibitor between CYP3A4 and P­glycoprotein, P­gp. Simultaneous
administration of these agents results in an increase in the oral drug bioavailability of one or both of the drugs. Various drug–drug and drug–nutrient
interactions involving oral bioavailability have been reported in human subjects (Thummel and Wilkinson, 1998; Di Marco et al, 2002; von Richter et al,
2004).

Many commonly used medications (eg, dextromethorphan hydrobromide) and certain food groups (eg, grapefruit juice) are substrates both for the
efflux transporter, P­gp, and for the CYP3A enzymes involved in biotransformation of drugs (see Chapter 21). Grapefruit juice also affects drug
transport in the intestinal wall. Certain components of grapefruit juice (such as naringin and bergamottin) are responsible for the inhibition of P­gp
and CYP3A. Di Marco et al (2002) demonstrated the inhibitory effect of grapefruit and Seville orange juice on the pharmacokinetics of
dextromethorphan. Using dextromethorphan as the substrate, these investigators showed that grapefruit juice inhibits both CYP3A activity as well as
P­gp resulting in an increased bioavailability of dextromethorphan. Grapefruit juice has been shown to increase the oral bioavailability of many drugs,
such as cyclosporine or saquinavir, by inhibiting intestinal metabolism.

Esomeprazole (Nexium) and omeprazole (Prilosec®) are proton pump inhibitors that inhibit gastric acid secretion, resulting an increased stomach pH.
Esomeprazole and omeprazole may interfere with the absorption of drugs where gastric pH is an important determinant of bioavailability (eg,
ketoconazole, iron salts, and digoxin). Both esomeprazole and omeprazole are extensively metabolized in the liver by CYP2C19 and CYP3A4. The
prodrug clopidogrel (Plavix) inhibits platelet aggregation entirely due to an active metabolite. Coadministration of clopidogrel with omeprazole, an
inhibitor of CYP2C19, reduces the pharmacological activity of clopidogrel if given either concomitantly or 12 hours apart.

The dual effect of a CYP isoenzyme and a transporter on drug absorption is not always easy to determine or predict based on pharmacokinetic studies
alone. A well­studied example is the drug digoxin. Digoxin is minimally metabolized (CYP3A4), orally absorbed (Suzuki and Sugiyama, 2000), and a
substrate for P­gp based on:

1. Human polymorphism single­nucleotide polymorphism (SNP) in exon 26 (C3435T) results in a reduced intestinal expression level of P­gp, along
with increased oral bioavailability of digoxin.

2. Ketoconazole increases the oral bioavailability and shortens mean absorption time from 1.1 to 0.3 hour. Ketoconazole is a substrate and inhibitor
of P­gp; P­gp can subsequently influence bioavailability. The influence of P­gp is not always easily detected unless studies are designed to
investigate its presence.

For this analysis, a drug is given orally and intravenously before and after administration of an inhibitor drug. The AUC of the drug is calculated for
each case. For example, ketoconazole causes an increase in the oral bioavailability of the immunosuppressant tacrolimus from 0.14 to 0.30, without
affecting hepatic bioavailability (0.96–0.97) (Suzuki and Sugiyama, 2000). Since hepatic bioavailability is similar, the increase in bioavailability from 0.14
to 0.30 is the result of ketoconazole suppression on P­gp.

Mouly and Paine (2003) reported P­gp expression determined by Western blotting along the entire length of the human small intestine. They found
that relative P­gp levels increased progressively from the proximal to the distal region. von Richter et al (2004) measured P­gp as well as CYP3A4 in
paired human small intestine and liver specimens obtained from 15 patients. They reported that much higher levels of both P­gp (about seven times)
and CYP3A4 (about three times) were found in the intestine than in the liver, suggesting the critical participation of intestinal P­gp in limiting oral drug
bioavailability.

The concept of drug–drug interactions has received increased attention in recent years, as they may be responsible for many drug therapy­induced
medical problems (Johnson et al, 1999).

FREQUENTLY ASKED QUESTIONS

Animal studies are not definitive when extrapolated to humans. Why are animal studies or in vitro transport studies in human cells often
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a drug a P­gp substrate?
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk Page 19 / 51
©2024How
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youAll Rights Reserved.
demonstrate Terms
that digoxin of Use Privacy
metabolism is solelyPolicy
due to hepatic
Notice extraction
Accessibility
and not due to intestinal extraction since both CYP3A4
and P­gp are present in the intestine in larger amounts?
and CYP3A4 (about three times) were found in the intestine than in the liver, suggesting the critical participation of intestinal P­gp in limiting oral drug
bioavailability.

The concept of drug–drug interactions has received increased attention in recent years, as they may be responsible for many drug therapy­induced
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medical problems (Johnson et al, 1999).

FREQUENTLY ASKED QUESTIONS

Animal studies are not definitive when extrapolated to humans. Why are animal studies or in vitro transport studies in human cells often
performed to decide whether a drug is a P­gp substrate?

How would you demonstrate that digoxin metabolism is solely due to hepatic extraction and not due to intestinal extraction since both CYP3A4
and P­gp are present in the intestine in larger amounts?

ORAL DRUG ABSORPTION
The oral route of administration is the most common and popular route of drug dosing. The oral dosage form must be designed to account for
extreme pH ranges, the presence or absence of food, degradative enzymes, varying drug permeability in the different regions of the intestine, and
motility of the GI tract. In this chapter we will discuss intestinal variables that affect absorption; dosage­form considerations are discussed in Chapters
7–10.

Anatomic and Physiologic Considerations

The normal physiologic processes of the alimentary canal may be affected by diet, contents of the GI tract, hormones, the visceral nervous system,
disease, and drugs. Thus, drugs given by the enteral route for systemic absorption may be affected by the anatomy, physiologic functions, and
contents of the alimentary tract. Moreover, the physical, chemical, and pharmacologic properties of the drug and the formulation of the drug product
will also affect systemic drug absorption from the alimentary canal.

The enteral system consists of the alimentary canal from the mouth to the anus (Fig. 4­12). The major physiologic processes that occur in the GI system
are secretion, digestion, and absorption. Secretion includes the transport of fluid, electrolytes, peptides, and proteins into the lumen of the alimentary
canal. Enzymes in saliva and pancreatic secretions are also involved in the digestion of carbohydrates and proteins. Other secretions, such as mucus,
protect the linings of the lumen of the GI tract. Digestion is the breakdown of food constituents into smaller structures in preparation for absorption.
Food constituents are mostly absorbed in the proximal area (duodenum) of the small intestine. The process of absorption is the entry of constituents
from the lumen of the gut into the body. Absorption may be considered the net result of both lumen­to­blood and blood­to­lumen transport
movements.

FIGURE 4­12

Gastrointestinal tract.

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movements.

FIGURE 4­12

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Gastrointestinal tract.

Drugs administered orally pass through various parts of the enteral canal, including the oral cavity, esophagus, and various parts of the GI tract.
Residues eventually exit the body through the anus with the feces. The total transit time, including gastric emptying, small intestinal transit, and colonic
transit, ranges from 0.4 to 5 days (Kirwan and Smith, 1974). The small intestine, particularly the duodenum area, is the most important site for drug
absorption. Small intestine transit time (SITT) ranges from 3 to 4 hours for most healthy subjects. If absorption is not completed by the time a drug
leaves the small intestine, absorption may be erratic or incomplete.

The small intestine is normally filled with digestive juices and liquids, keeping the lumen contents fluid. In contrast, the fluid in the colon is reabsorbed,
and the lumenal content in the colon is either semisolid or solid, making further drug dissolution and absorption erratic and difficult. The lack of the
solubilizing effect of the chyme and digestive fluid contributes to a less favorable environment for drug absorption.

Oral Cavity

Saliva is the main secretion of the oral cavity, and it has a pH of about 7. Saliva contains ptyalin (salivary amylase), which digests starches. Mucin, a
glycoprotein that lubricates food, is also secreted and may interact with drugs. About 1500 mL of saliva is secreted per day.

The oral cavity can be used for the buccal absorption of lipid­soluble drugs such as fentanyl citrate (Actiq®) and nitroglycerin, also formulated for
sublingual routes. Recently, orally disintegrating tablets (ODTs) have become available. These ODTs, such as aripiprazole (Abilify Discmelt®), rapidly
disintegrate in the oral cavity in the presence of saliva. The resulting fragments, which are suspended in the saliva, are swallowed and the drug is then
absorbed from the GI tract. A major advantage for ODTs is that the drug may be taken without water. In the case of the antipsychotic drug, aripiprazole,
a nurse may give the drug in the form of an ODT (Abilify Discmelt) to a schizophrenic patient. The nurse can easily ascertain that the drug was taken and
swallowed.

Esophagus

The esophagus connects the pharynx and the cardiac orifice of the stomach. The pH of the fluids in the esophagus is between 5 and 6. The lower part
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of the esophagus ends with the esophageal sphincter, which prevents acid reflux from the stomach. Tablets or capsules may lodge in this Page
area, 21
causing
Chapter 4: Physiologic Factors Related to Drug Absorption, Phillip M. Gerk / 51
local irritation. Very little drug dissolution occurs in the esophagus.
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Stomach
a nurse may give the drug in the form of an ODT (Abilify Discmelt) to a schizophrenic patient. The nurse can easily ascertain that the drug was taken and
swallowed.
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Esophagus

The esophagus connects the pharynx and the cardiac orifice of the stomach. The pH of the fluids in the esophagus is between 5 and