Module 7
7.1: Introduction to Gastroenterology
The organs of the upper gastrointestinal tract (mouth, pharynx, esophagus, stomach, and duodenum) work
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conjunction to first digest food and then absorb the nutrients obtained from the digested food. Both the stomach and
the upper part of the small intestines (duodenum) release hormones and enzymes that help in this process. When food
enters the body, the stomach is triggered to begin releasing gastric juices such as hydrochloric acid (HCl) and an enzyme
called pepsin.
HCl is released by parietal cells located in the stomach. Due to its acidic nature, HCl aids in the breakdown of food
entering the stomach.
Pepsin is the primary digestive enzyme found in the stomach. Pepsin is responsible for the catabolism (breaking down) of
proteins into polypeptides.
There are three major stimulators that affect the release of gastric juices: Acetylcholine (ACh), gastrin, and histamine.
First, the ingestion of food stimulates ACh to bind to its target receptors, stimulating the release of pepsin, gastrin,
histamine, and HCl from chief cells, G cells, enterochromaffin like (ECL) cells, and parietal cells respectively. Gastrin then
binds to its target receptors on ECL and parietal cells which stimulates the release of more histamine and more HCl. The
histamine then binds to the H2 receptors on the parietal cells which, in turn, increases the amount of HCl or gastric acid
released.
Figure 7.1 Stimulation of Gastric Juices. The figure above depicts the different cells involved in the release of the different gastric
juices. The process is started by ACH being released when food is ingested. The release of the initial gastrin and histamine go on to
stimulate the release of more histamine and HCL.
Peptic Ulcers and Gastrointestinal Esophageal Reflux Disease (GERD)
Peptic ulcers are defined as open sores in the mucous membranes of the mucosal lining of the stomach or duodenum.
Pathophysiology: The cause of peptic ulcers is not always the same. The majority of GI ulcers are caused by the
bacterium Helicobacter Pylori (H. Pylori). The bacterium is believed to enter the body through contaminated food or
water. Reacting to the bacteria, an inflammatory response is initiated, which is often associated with an increase in
stomach acid secretions.
The long-term use of non-steroidal anti-inflammatory drugs (NSAIDs) is also closely related to the incidence of peptic
ulcers. NSAIDs block prostaglandins which play a role in inhibiting gastric acid secretion.
In both cases, the resulting increase in stomach acid secretions places a strain on the inner lining of the stomach until an
ulcer (break or tear) appears.
Symptoms of a peptic ulcer include pain, nausea, and loss of appetite. The pain is typically described as a dull, gnawing,
burning sensation similar to heartburn. Interestingly, if the ulcer is in the duodenum, food often relieves the pain,
whereas if the ulcer is in the stomach, food often worsens the pain.
GERD stands for gastrointestinal esophageal reflux disease and is characterized primarily by the presence of heartburn.
Heartburn (acid indigestion) is defined as a painful burning feeling behind the sternum that occurs when stomach acid
backs up into the esophagus.
Pathophysiology of GERD involves the lower esophageal sphincter (LES) or valve at the bottom of the esophagus going
into the stomach. This valve loosens such that the gastric acid is able to go back up (reflux) into the esophagus.
Symptoms of GERD go beyond occasional heartburn. In GERD, heartburn is part of an ongoing problem, often occurring
after meals and upon lying down. In severe cases, there can even be blood loss from chronic injury to the esophagus.
Treatment Overview
Peptic Ulcers
If the patient has a peptic ulcer that is caused by H. Pylori, they will need to be treated with antibiotics. It is generally
recommended to use at least two antibiotics in combination with bismuth salts (Pepto-Bismol or Kaopectate), a regimen
referred to as “triple therapy.” When a proton pump inhibitor (PPI) is added to the regimen it is then referred to as
“quadruple therapy.” PPIs will be discussed further below.
The recommended antibiotics to treat H. pylori include amoxicillin, tetracycline, metronidazole, and clarithromycin. The
purpose of the Pepto-Bismol is that bismuth is thought to disrupt the bacterial cell wall and prevent further binding to
the mucosa. Treatment typically lasts for 8 weeks leading to the eradication of the bacteria.
If the ulcer was not caused by H. Pylori, treatment does not involve antibiotics but rather anti-secretory drugs. Antisecretory
drugs are defined as drugs that inhibit the secretion of digestive enzymes, hormones, or acids. Such drugs
include H2 receptor antagonists, prostaglandins, and proton pump inhibitors. Treatment should last 4-8 weeks.
Prostaglandins are only useful in the treatment or prevention of NSAID-induced ulcers. Prostaglandins inhibit histamine
which counteracts the NSAIDs inhibition of prostaglandin synthesis. There is only one synthetic prostaglandin available,
misoprostol. It is limited in its use, primarily being used for patients at high risk of developing an ulcer that must be on
an NSAID for a limited time. Misoprostol has not been shown to be effective at preventing ulcers in patients on chronic
NSAID therapy. Misoprostol is also known to cause uterine contractions and is, therefore, contraindicated in pregnancy
due to the risk of miscarriage.
GERD
Depending on the severity of the disease, the recommended treatment may differ. In mild-moderate GERD, the H2
antagonists are a great option. They have a longer duration of action than alternatives such as an OTC antacid and
provide good relief. However, in severe GERD or in cases where there is ulcerative damage, PPIs are considered first line
therapy.
Lifestyle modifications are a critical part of the management of peptic ulcers and GERD. Recommendations include
smoking cessation, avoiding caffeine and alcohol, as well as reducing stress. If possible, NSAIDs should be avoided. If the
patient is overweight, weight loss can help. If the patient has symptoms at night, it is recommended to elevate their bed.
Drug Therapy
H2 receptor antagonists were introduced in Module 2. We will go into more detail in this module.
Mechanism of action: Work by competitively inhibiting the interaction of histamine with H2 receptors within the GI
mucosa. This blockade significantly reduces the secretion of acid and pepsin from the stomach.
Uses: Recommended for the short-term use (up to 8 weeks) of benign gastric ulcers and duodenal ulcers, GERD, stress
ulcers and gastric irritation in patients that need to remain on NSAIDs.
Adverse Events: Headache or constipation. Cimetidine specifically has been associated with reversible CNS effects such
as confusion and disorientation, usually in critically ill patients.
Drug Interactions: Cimetidine has been reported to increase the drug levels of many medications by altering
metabolism. Select examples include calcium channel blockers, beta blockers, sulfonylureas, and theophylline.
Famotidine and nizatidine have no effect on the metabolic pathway and are therefore preferred. They do not appear to
interact with food and therefore can be taken at mealtime.
Example Drugs: Cimetidine, ranitidine, famotidine, and nizatidine
PPIs are superior in their effectiveness in acid reduction and ulcer healing compared to H2 receptor antagonists.
Mechanism of action: The exchange of hydrogen and potassium via the ATPase exchange is essential to the production
of HCl. PPIs work by inhibiting this exchange, therefore, preventing the formation of acid.
Uses: First line along with antibiotics to treat H. Pylori related ulcers, benign gastric ulcers, active duodenal ulcers, and
GERD. They promote better healing over H2 blockers and therefore are the drug of choice for healing ulcers.
Adverse Events: Headache, abdominal pain, diarrhea, nausea, and constipation. New concerns have arisen that longterm
use could lead to the development of osteoporosis. Overprescription of PPIs could lead to an increase in GI
infections because of the reduction of normal acid-mediated microbial protection.
Drug Interactions: Omeprazole can increase levels of warfarin and some seizure medications (diazepam, phenytoin). It
can also affect the absorption of drugs that require an acidic environment such as iron. Omeprazole has also been shown
to decrease the antiplatelet effects of clopidogrel. Lansoprazole, pantoprazole, and rabeprazole have no clinically
relevant drug interactions.
Example Drugs: Omeprazole, esomeprazole, lansoprazole, dexlansoprazole, pantoprazole, and rabeprazole.
See Table 7.1 below for a summary chart of the H2 receptor antagonists and the PPIs.
Antacids
Mechanism of Action: They work by neutralizing the gastric acidity by reacting with HCl to form water and salts. Antacids
are typically taken orally in a tablet or liquid formulation. They are known to have a quick onset of action but a short
duration of action, making them a good choice for mild symptoms but not appropriate for maintenance or more severe
disease.
Uses: Antacids are often used for mild symptoms of heartburn or to treat breakthrough symptoms in patients already on
one of the maintenance therapies above. Antacids are available OTC and most contain Magnesium, Aluminum, or
Calcium ions.
Adverse Events: Most adverse events are related to the ion component of the antacid. For example, magnesium
containing antacids are known to cause diarrhea. Aluminum and calcium containing antacids can cause constipation.
However, such side effects are only seen with chronic use.
Drug Interactions: Antacids alter the absorption of some drugs. For example, oral tetracyclines may be inhibited by
antacids.
Example Antacids: Aluminum hydroxide; magnesium hydroxide (Gaviscon, Maalox), Magnesium hydroxide (Milk of
magnesia), and Calcium carbonate (Tums)
7.2: Bowel Disorders (Diarrhea, Constipation, IBS)
Digestion continues beyond the stomach and small intestines. Peristalsis, which is defined as wavelike movements of the
intestines in which circular contraction and relaxation of the muscle propel the contents toward the rectum. Upon
reaching the colon, water and minerals are removed from the contents. The remaining waste product is then
compressed into feces for elimination through the rectum. This module will cover three conditions related to the bowel:
(1) Diarrhea, (2) Constipation, and (3) Irritable Bowel Syndrome.
Diarrhea is defined as an abnormal looseness of the stool or watery stool, which may be accompanied by a change in
stool volume or frequency.
Constipation is a condition where the frequency of defecation occurs less often than usual, or the consistency of the
feces makes it difficult to defecate.
IBS (Irritable Bowel Syndrome) is a functional disorder of the colon associated with abdominal pain, cramping, bloating,
diarrhea and/or constipation.
Diarrhea
Diarrhea can be acute (lasting less than 14 days) or chronic (lasting longer 30 days) in nature. Acute diarrhea is often selflimiting
and resolves without complications. Chronic diarrhea, however, can result in large quantities of water and
electrolytes being lost, leading to dehydration and electrolyte imbalances. Accurate diagnosis of the cause of a person’s
diarrhea is critical to selecting the appropriate drug therapy.
Pathophysiology: There are a few common causes of diarrhea. For example, microorganisms can invade the GI tract and
cause inflammation and irritation. This, in turn, causes the bowel to increase motility as a means of eliminating the
microorganism. Treatment, in this case, is often centered around treating the infection.
A second common cause of diarrhea is a side effect of another drug therapy the patient may be taking. When this is the
case, it is recommended to reduce or discontinue the causative drug if possible.
The third cause to consider is diarrhea associated with other medical problems. Examples include anemia, cancer,
diabetes, nerve damage, IBS, and Crohn’s disease. In these instances, antidiarrheal drugs are typically the treatment of
choice.
Drug Therapy used to treat diarrhea is called antidiarrheal drugs. They are divided into different groups based on how
they exert their effect: (1) adsorbents, (2) antimotility (anticholinergic and opiates), and (3) probiotics.
Adsorbents (are typically used in milder cases of diarrhea.)
Mechanism of Action: Act by coating the wall of the GI tract. They bind the causative substance to their adsorbent
surface for elimination from the body.
Adverse Events: Bismuth subsalicylate can cause increased bleeding, constipation, dark stools, confusion, ringing in ears,
and metallic taste.
Drug Interactions: These drugs are known to decrease the effectiveness of other drugs by decreasing their absorption.
Examples include digoxin and hypoglycemic drugs. Warfarin effects increase leading to increased risk of bleeds.
Example Drug: Activated charcoal, bismuth subsalicylate, and cholestyramine
Antimotility drugs are typically used in more severe cases of diarrhea.
Anticholinergic
Mechanism of Action: Work by slowing peristalsis by reducing the contractions and smooth muscle tone in the GI tract.
They also work by drying gastric secretions.
Adverse Events: Urinary retention, impotence, headache, dizziness, anxiety, drowsiness, drop-in heart rate, drop in blood
pressure, dry skin, and blurred vision.
Drug Interactions: Antacids decrease their effect.
Example Drug: Atropine, hyoscyamine
Opiates
Mechanism of Action: Work by acting on smooth muscle cells in the GI tract inhibiting motility and excessive GI
propulsion. This results in a decrease in the number of stools and their water content.
Adverse Events: Drowsiness, dizziness, lethargy, constipation, nausea/vomiting, low blood pressure, urinary retention,
respiratory depression.
Drug Interactions: Additive CNS depressant effects when co-administered with alcohol, opioids, sedative-hypnotics,
antipsychotics, or skeletal muscle relaxants.
Example Drug: Diphenoxylate with atropine (Lomotil), loperamide (Imodium A-D)
Probiotics (are used in patients that have antibiotic induced diarrhea.)
Mechanism of Action: They work by replenishing bacteria that may have been destroyed by antibiotics. This helps
restore the normal flora and suppresses the growth of diarrhea causing bacteria.
No known adverse events or drug interactions.
Example Drug: lactobacillus acidophilus
Constipation
Constipation is a symptom, not a disease. It is a disorder of movement through the colon. Some of the more common
causes of constipation are listed in Table 7.2
Drug Therapy
Drugs used for the treatment of constipation are called laxatives. Treatment of constipation should be individualized
based on the person’s age, the duration, and severity of the constipation, and potential contributing factors.
Laxatives are some of the more commonly misused OTC medications. If they are used too long or too often, they can
cause laxative dependence, damage to the bowel, or new intestinal problems. There are five different types of laxative
medications. (1) Bulk Forming (only class safe for long term use), (2) Emollient, (3) Hyperosmotic, (4) Saline, and (5)
Stimulant.
Bulk-Forming
Mechanism of Action: Work similar to natural fiber. They absorb water into the intestines which increases bulk and
distends the bowel to initiate activity, thus promoting a bowel movement.
Use: Acute and chronic constipation, IBS
Adverse Events: Fluid disturbances, electrolyte imbalance, gas, esophageal blockage
Drug Interactions: Can decrease the absorption of antibiotics, digoxin, tetracyclines, and warfarin.
Example Drugs: Psyllium, methylcellulose
Emollient (also known as “stool softeners” and “lubricant laxatives”)
Mechanism of Action:
Stool softeners work by lowering the surface tension of the GI fluids so that more water and fat are absorbed into the
stool and the intestines.
Lubricant laxatives work by the fecal material and intestinal wall and preventing the absorption of water from the
intestines. This water then works to soften and expand the stool. This promotes bowel distention and peristalsis leading
to a bowel movement.
Uses: Acute and Chronic constipation, fecal impaction
Adverse Events: Decreased absorption of vitamins, electrolyte imbalance
Drug Interactions: Mineral oil can decrease the absorption of fat-soluble vitamins (A, D, E, And K)
Example Drugs: Docusate salts, mineral oil
Hyperosmotic
Mechanism of Action: Work by increasing fecal water content which causes distention and peristalsis and ultimately a
bowel movement.
Uses: Chronic constipation, bowel prep for surgical procedures
Adverse Events: Abdominal bloating, rectal irritation, electrolyte imbalance
Drug Interactions: Can cause increased CNS depression when combined with barbiturates, opioids, or antipsychotics.
Oral antibiotics can decrease the effects of lactulose.
Example Drugs: Polyethylene glycol, lactulose, sorbitol, and glycerin.
Saline
Mechanism of Action: Work by increasing osmotic pressure in the small intestines. This inhibits water absorption and
increases both water and electrolyte secretions from the bowel wall. This causes watery stool. The increase distention
promotes peristalsis and evacuation.
Uses: Constipation, bowel prep for surgical procedures
Adverse Events: Magnesium toxicity, electrolyte imbalances, cramping, diarrhea, increased thirst
Drug Interactions: No major drug interactions
Example Drugs: Magnesium hydroxide, magnesium sulfate, or magnesium citrate
Stimulant
Mechanism of Action: Work by stimulating the nerve within the intestine which causes peristalsis. They also increase
bulk and soften stool.
Uses: Acute constipation, bowel prep for surgical procedures.
Adverse Events: Nutrient malabsorption, gastric irritation, electrolyte imbalance, discolored urine, rectal irritation.
Drug Interactions: Antibiotic, digoxin, salicylates and oral anticoagulant absorption is decreased.
Example Drugs: Senna and bisacodyl
When treating constipation, one of the most important considerations is often the onset of action.
Table 7.3 below summarizes the onset of action or time to bowel movement for some of the commonly used laxatives.
Irritable Bowel Syndrome (IBS)
Patients often cope with IBS by avoiding irritating foods and/or taking OTC laxatives and antidiarrheals. IBS is more
commonly seen in women than in men. Besides self-treatment with OTC medications, there are two prescription
medications indicated specifically for IBS: (1) alosetron, (2) linaclotide. It is important to note that these medications
should be reserved for patients where conventional therapy has failed. They are not to be used first line.
Alosetron (Lotronex)
Class: Selective serotonin receptor antagonist
Mechanism of Action: By blocking the serotonin receptors in the intestines resulting in a slowing of the movement of
stool.
Use: Severe Chronic diarrhea predominant IBS for women who have failed conventional treatment. If the response is
inadequate after 4 weeks, the medication should be discontinued.
Adverse Events: Constipation, abdominal discomfort, and pain, nausea, infrequent but serious ischemic colitis (if this
occurs drug must be discontinued).
Drug Interactions: When taken with fluvoxamine (antipsychotic) alosetron levels increased.
Linaclotide (Linzess)
Class: Peptide guanylate cyclase-C agonist
Mechanism of Action: Not entirely understood. It is thought to work by increasing fluid secretion and GI motility.
Use: IBS with constipation and chronic idiopathic (of unknown cause) constipation.
Adverse Events: Diarrhea, abdominal pain, and flatulence
Drug Interactions: No known drug interactions
7.3: Nausea/Vomiting
Nausea and vomiting are two gastrointestinal disorders that can range from mild, self-limiting symptoms to extremely
unpleasant symptoms leading to more serious problems. Nausea is defined as the sensation often leading to the urge to
vomit. Emesis (vomiting) is defined as the forcible emptying or expulsion of gastric and occasionally intestinal contents
through the mouth.
Pathophysiology: There is an area within the brain called the vomiting center. The vomiting center is defined as the area
of the brain that is involved in stimulating the physiologic events that lead to nausea and vomiting. This process is
controlled through the chemoreceptor trigger zone (CTZ) or the area of the brain that is involved in the sensation of
nausea and the action of vomiting. The CTZ sends neurotransmitters to the vomiting center which then alerts the brain
of nauseating substances that need to be expelled from the body. Figure 7.2 outlines the vomiting process within the
body.
There are five main neurotransmitters involved in the vomiting process including acetylcholine (ACh), dopamine,
histamine (H1), serotonin (5-HT3), and substance P (Neurokinin 1). These become important in understanding the
mechanism of action of the drug therapies used to treat nausea and vomiting.
Figure 7.2 Pathophysiology of Nausea and Vomiting. The body sends signals via neurotransmitters to the brain’s chemoreceptor
trigger zone and vomiting center signaling the physiologic events that cause nausea and vomiting.
Drug Therapy: Medications used for the treatment of nausea and vomiting are termed antiemetics. They all work
within different sites of the vomiting pathway. For this reason, they can often be combined, and the overall effect can be
greater. Antiemetics covered in this module include (1) Anticholinergics, (2) Antihistamines, (3) Antidopaminergics, (4)
Neurokinin antagonists, (5) Prokinetics, and (6) Serotonin blockers.
Anticholinergics
Mechanism of Action: They act by binding to and blocking vestibular nuclei receptors deep within the brain. When ACh
is blocked from these receptors, the nausea inducing signals are prevented from reaching the CTZ. The drying effects of
anticholinergics help to dry GI secretions and reduce smooth muscle spasms which can also have a positive impact on
reducing the symptoms of nausea and vomiting.
Use: Motion sickness, Nausea/Vomiting
Adverse Events: Dizziness, drowsiness, disorientation, increased heart rate, blurred vision, dry mouth, difficulty with
urination, and constipation.
Drug Interactions: Additive drying effects when given with antihistamines.
Example Antiemetic: Scopolamine
Antihistamines (specifically H1 receptors)
Mechanism of Action: They bind to and block H1 receptors which prevents ACh from binding to the receptors in the
vestibular nuclei. This mechanism gives them potent anticholinergic activity.
Use: Motion Sickness, nonproductive cough, sedation, rhinitis, allergies, nausea/vomiting.
Adverse Events: Dizziness, drowsiness, confusion, blurred vision, dry mouth, and difficulty with urination.
Drug Interactions: Additive CNS depressant effects are seen when given with opioids, hypnotics, some antidepressants,
and alcohol.
Example Antiemetic: Dimenhydrinate, diphenhydramine, meclizine
Antidopaminergic: These drugs were historically used for the antipsychotic effects but were also shown to prevent
nausea and vomiting.
Mechanism of Action: Block dopamine receptors in the CTZ of the brain.
Use: Psychotic disorders, intractable hiccups, and nausea/vomiting
Adverse Events: Orthostatic hypotension, increased heart rate, extrapyramidal symptoms (To be further covered in
Module 8- examples include: slurred speech, tremor, muscle contractions, rigidity, and muscle slowness), blurred vision,
dry eyes, urinary retention, and dry mouth.
Drug Interactions: Additive CNS depressant effect when given with opioids, hypnotics, some antidepressants, and
alcohol.
Example Antiemetic: Prochlorperazine, promethazine
Neurokinin antagonists
Mechanism of Action: Inhibit substance-P neurokinin receptors.
Use: Nausea and vomiting associated with chemotherapy
Adverse Events: Decrease in blood pressure and heart rate, fatigue, dizziness, diarrhea, and abdominal pain.
Drug Interactions: Has been shown to induce the metabolism of warfarin, thus lowering the concentration. Neurokinin
antagonists can also increase the concentration of corticosteroids (dexamethasone and methylprednisolone) and antianxiety
medications (triazolam, alprazolam, and midazolam). They can also reduce the effectiveness of oral
contraceptives.
Example Antiemetic: Aprepitant, fosaprepitant
Prokinetics
Mechanism of Action: These drugs work in two ways; primarily they work by stimulating peristalsis through ACh
receptors in the GI tract. This increases stomach emptying into the small intestines. Secondly, they also block dopamine
receptors in the CTZ.
Use: Delayed gastric emptying, GERD, nausea, and vomiting.
Adverse Events: Decreased blood pressure, increased heart rate, sedation, fatigue, restlessness, dry mouth, and
diarrhea.
Drug Interactions: Can cause CNS depression when taken with alcohol. Anticholinergics and analgesics can also block the
motility effect of metoclopramide.
Example Antiemetic: Metoclopramide
Serotonin blockers- are the newest class to treat nausea and vomiting. They have played a major role in treating
nausea and vomiting associated with cancer chemotherapy and radiation therapy.
Mechanism of Action: They work by blocking the serotonin receptors in the GI tract, CTZ and vomiting center. There are
many subtypes of serotonin receptors throughout the body. The subtype involved in nausea and vomiting is the 5-
hydroxytryptamine (5-HT3) receptor.
Use: Nausea and vomiting associated with chemotherapy and postoperative nausea and vomiting. It is also commonly
used to treat nausea associated with pregnancy. It is pregnancy category B. However, there is some concern regarding
cleft palate development in the fetus when used in the first trimester.
Adverse Events: Headache, diarrhea, bronchospasm
Drug Interactions: No major drug interactions.
Example Antiemetic: ondansetron, granisetron, dolasetron, and palonosetron.
See Table 7.4 for an overview of the antiemetic drugs covered in this section.
Problem Set
Question 1
List the two most common causes of Peptic ulcers.
1. The bacteria Helicobacter Pylori. 2. Long term use of NSAIDs.
Question 2
Describe the pathophysiology of GERD.
Pathophysiology of GERD involves the lower esophageal sphincter (LES) or valve at the bottom of the esophagus going
into the stomach. This valve loosens such that the gastric acid is able to go back up (reflux) into the esophagus
Question 3
What are the components of the quadruple therapy when referring to H. Pylori treatment regimen?
two antibiotics, Pepto-Bismol, and a PPI.
Question 4
Explain the mechanism of action of the acid controlling drugs H2
work by competitively inhibit the interaction of histamine with H2 receptors within the GI mucosa. This blockade
significantly reduces the secretion of acid and pepsin from the stomach.
Question 5
Explain the mechanism of action of the acid controlling drugs, PPIs.
The exchange of hydrogen and potassium via the ATPase exchange is essential to the production of HCl. PPIs work by
inhibiting this exchange therefore preventing the formation of acid.
Question 6
List the various classes of antidiarrheals.
(1) adsorbents, (2) antimotility (anticholinergic and opiates), and (3) probiotics.
Question 7
Describe the mechanism of action of the two types of anti-motility antidiarrheals.
Anticholinergic: Mechanism of Action: Work by slowing peristalsis by reducing the contractions and smooth muscle
tone in the GI tract. They also work by drying gastric secretions.
Opiates: Mechanism of Action: works by acting on smooth muscle cells in the GI tract inhibiting motility and excessive
GI propulsion. This results in a decrease in the number of stools and their water content.
Question 8
List the medications used to treat constipation.
laxatives- bulk, emollient, hyperosmotic, saline, stimulant
Question 9
Define IBS.
IBS (irritable Bowel Syndrome) a functional disorder of the colon with abdominal pain, cramping, bloating, diarrhea
and/or constipation.
Question 10
Describe the general treatment approach for IBS.
Patients often cope with IBS by avoiding irritating foods and/or taking OTC laxatives and antidiarrheals. Besides selftreatment
with OTC medications, there are two prescription medications indicated specifically for IBS. (1) alosetron,
(2) linaclotide. It is important to note that these medications should be reserved for patients where conventional
therapy has failed. These are not to be used first line.
Question 11
Describe the pathophysiology of nausea and vomiting.
There is an area with in the brain called the vomiting center. The vomiting center is defined as the area of the brain
that is involved in stimulating the physiologic events that lead to nausea and vomiting. This process is controlled
through the chemoreceptor trigger zone (CTZ) or the area brain that is involved in the sensation of nausea and the
action of vomiting. The CTZ sends neurotransmitters to the vomiting center which then alerts the brain of nauseating
substances that need to be expelled from the body.
Question 12
List the various antiemetic drugs.
(1) Anticholinergics, (2) Antihistamines, (3) Antidopaminergics, (4) Neurokinin antagonists, (5) Prokinetics, and (6)
Serotonin blockers.
Question 13
Explain how anticholinergics and serotonin blockers work to decrease nausea.
Anticholinergics: Mechanism of Action: They act by binding to and blocking vestibular nuclei receptors deep within the
brain. When ACh is blocked from these receptors, the nausea inducing signals are prevented from reaching the CTZ.
The drying effects of anticholinergics help to dry GI secretions and reduce smooth muscle spasms which can also have
a positive impact on reducing the symptoms of nausea and vomiting.
Serotonin blockers: Mechanism of Action: They work by blocking the serotonin receptors in the GI tract, CTZ and
vomiting center. There are many subtypes of serotonin receptors throughout the body. The subtype involved in nausea
and vomiting is the 5-hydroxytryptamine (5-HT3) receptor.
Question 14
List the common side effects of the different antiemetic drugs.
Anticholinergics: Dizziness, drowsiness, disorientation, increased heart rate, blurred vison, dry mouth, difficulty with
urination and constipation.
Antihistamines: Dizziness, drowsiness, confusion, blurred vision, dry mouth, difficulty with urination.
Antidopaminergic: orthostatic hypotension, increased heart rate, extrapyramidal symptoms (will cover in module 8-
examples include: slurred speech, tremor, muscle contractions, rigidity, muscle slowness), blurred vison, dry eyes,
urinary retention, dry mouth.
Neurokinin antagonists: decrease in blood pressure and heart rate, fatigue, dizziness, diarrhea, abdominal pain.
Prokinetics: decreased blood pressure, increased heartrate, sedation, fatigue, restlessness, dry mouth, diarrhea.
Serotonin blockers: headache, diarrhea, bronchospasm [Show Less]