Acute Vomiting in Cats

Metoclopramide

Metoclopramide is a prokinetic and central antiemetic drug (Fig 1). It exerts its prokinetic effects through the release of acetylcholine in gastric and small intestinal smooth muscle,^1,2 leading to increased gastric emptying and net ‘downstream’ intestinal motility. In humans, it also increases tone in the lower esophageal sphincter, reducing reflux. ³

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Fig 1

In cats, metoclopramide is a prokinetic drug, but it may not have direct central antiemetic effects. The dosage should be reduced (eg, by 50% or more) for cats in renal failure. Tremors are a possible side effect, especially in combination with phenothiazine antiemetics

Metoclopramide's central antiemetic action is due to antagonism of dopamine receptors at the chemoreceptor trigger zone. In cats, however, metoclopramide is not an effective antagonist of the emetic effects of dopamine. ⁴ Emesis from dopamine appears to be mediated through α₂-adrenergic receptors rather than dopamine receptors in cats. ⁴ This is consistent with the finding that cats are sensitive to emesis from xylazine (an α₂-agonist). ⁵

Despite this, metoclopramide appears to be clinically effective as an antiemetic in cats, perhaps via its prokinetic effects that increase gastric emptying and decrease gastric atony.^6,7 Metoclopramide may also be useful to reduce reflux esophagitis in cats with megaesophagus, although its effects on lower esophageal sphincter tone appear to be weak in cats (study performed in kittens). ⁶ It is unclear whether metoclopramide is effective as a central antiemetic for cats with uremia, intoxications or pancreatitis, or for those undergoing chemotherapy. Other central antiemetics may be more effective in such cases.

Because metoclopramide is a prokinetic drug, intestinal obstruction should be ruled out, based on physical examination and abdominal radiography (Fig 2), before therapy is instituted. Metoclopramide is dosed empirically in cats at 0.2–0.4 mg/kg SC or PO qid. Because of a short elimination half-life in other species, metoclopramide may be most effective when given by continuous rate infusion (CRI) at 1–2 mg/kg/day. The dosage should be reduced (eg, by 50% or more) in cats with renal failure, as clearance of the drug is impaired in renal failure, at least in humans. ⁸

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Fig 2

This radiograph of a 2-year-old female spayed cat, which presented with a 3-week history of vomiting and inappetence, shows linear foreign bodies in the stomach. Multiple hair elastics were removed by endoscopy, and the cat recovered uneventfully. Courtesy of the Section of Radiology, University of Wisconsin-Madison, School of Veterinary Medicine

High plasma concentrations of metoclopramide can lead to frenzied behavior or tremors (Parkinson's-like). If either occur, the drug should be discontinued until signs resolve. If signs were mild, the infusion can then be started again at half of the previous dosage.

Ondansetron and dolasetron

Ondansetron (Zofran; GlaxoSmithKline) and dolasetron (Anzemet; Sanofi Aventis) are antiemetics with 5-HT₃ receptor antagonist activity, both in the central nervous system (CNS) and gastrointestinal (GI) tract. These drugs are effective anecdotally for prophylaxis of vomiting associated with chemotherapy in cats and dogs. ⁹ They also appear to be useful for refractory vomiting in hospitalized cats with pancreatitis, hepatic lipidosis, severe inflammatory bowel disease, GI neoplasia and cholangitis.

Ondansetron is available as a 2 mg/ml injectable, 4 mg tablets and an oral solution (4 mg per 5 ml). The empirical dosage in cats is 0.5 mg/kg bid. Dolasetron is supplied as an injectable and as 50 mg tablets, which must be reformulated for use in cats. The empirical dosage is 0.6–1.0 mg/kg IV or PO sid. Oral dolasteron is approximately twice as expensive per mg as ondansetron, excluding reformulation costs.

Significant side effects have not to date been reported in cats for either ondansetron or dolasteron. In humans, headache and diarrhea are reported most commonly. ¹⁰ Ondansteron, more so than dolasteron, may cause CNS side effects such as dizziness in humans. ¹⁰ If this is also true in cats, then ondansetron may not be the best choice in patients with vomiting due to vestibular disease. Dolasetron has been associated with prolongation of the QT interval in humans, with hypokalemia as a risk factor. ¹¹ This electrocardiographical change may lead to life-threatening arrhythmias, and has also been reported in humans receiving cisapride.

Prochlorperazine and chlorpromazine

Prochlorperazine (Compazine; GlaxoSmith-Kline) and chlorpromazine are phenothiazine central antiemetics with multiple mechanisms of action, including antagonism of dopamine, histamine type 1, α₂-adrenergic and mus carinic receptors. These drugs inhibit vomiting at the chemoreceptor trigger zone and directly at the emetic center.

Cats appear to be more sensitive than dogs to the emetic effects of α₂-agonists, such as xylazine; ¹² they may, therefore, respond well to α₂-antagonist antiemetics such as pheno-thiazines. Phenothiazines are useful for refractory vomiting in patients with diagnosed underlying disease (eg, pancreatitis, GI neoplasia, chemotherapy), in which intravenous fluid support can be provided. The empirical dosage of either prochlorperazine or chlorpromazine in cats is 0.1–0.5 mg/kg SC tid. Due to their antihistamine effects, these drugs can cause sedation. Therefore, despite requiring frequent dosing, either drug may be useful as a first-line antiemetic in hospitalized cats that also require mild sedation to be handled.

As well as their sedative effects, phenothiazine antiemetics can also cause hypotension (due to α-adrenergic blockade). They are not, therefore, recommended for empirical outpatient use or in dehydrated animals.

Adjunctive fluid support is strongly recommended. There is additionally a risk of tremors due to dopamine antagonism; this may be more likely to occur if the drug is used in combination with metoclopramide, ¹³ and it may be wise, therefore, to avoid concurrent use of metoclopramide and phenothiazine antiemetics. Formulations containing anticholinergics such as isopropamide should be avoided, as they will lead to ileus.

Maropitant

Maropitant (Cerenia; Pfizer) is a neurokinin-1 (NK-1) receptor antagonist that was recently approved as an antiemetic in dogs in the US. Together with its related drugs it inhibits substance P binding to NK-1 receptors, which are located in the emetic center, chemoreceptor trigger zone and the enteric plexus of the gut, ¹⁴ and otherwise lead to vomiting when stimulated.

NK-1 receptor antagonists are gaining popularity for prevention of chemotherapy-associated vomiting in humans. ¹⁵ In dogs, maropitant is effective in preventing chemotherapy-induced vomiting, motion sickness and non-specific vomiting.^16,17 In cats, maropitant has been proven effective for both xylazine-induced emesis and motion sickness. ¹⁸ Anecdotally, it also appears to be effective in cats for a variety of other causes of nausea and vomiting, as shown in dogs.

An initial dosage estimate in cats is 1 mg/kg IV, SC or PO sid, based on preliminary studies and a long elimination half-life (13–17 h) in this species. ¹⁸ Experience with maropitant is still emerging in cats, so any common side effects remain to be clearly defined. Pain at the injection site has been reported anecdotally. NK-1 receptor antagonists do not interact with dopaminergic or serotonergic receptors, ¹⁴ and should not cause cumulative side effects in combination with metoclopramide or 5-HT₃ antagonists.

Adjunctive drugs for specific indications

Famotidine

Famotidine (Pepcid; Merck Pharmaceuticals) is an H₂ blocker that reduces gastric acid secretion. It is more potent than ranitidine in cats, but has a similar duration of action. ¹⁹ Unlike cimetidine, famotidine does not inhibit cytochrome P450-mediated clearance of other drugs; therefore, in humans it causes relatively few drug interactions. ²⁰

Famotidine is not an antiemetic, and appears to be overused in vomiting animals, as hyperacidity is probably a relatively uncommon cause of vomiting in cats. It may be useful in cases of severe or persistent vomiting, where secondary reflux and esophagitis are of concern (Fig 3), and is indicated for vomiting due to hyperacidity caused by high gastrin levels in renal failure ²¹ or by histamine released from mast cell tumors.

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Fig 3

Esophagitis, such as that caused by clindamycin capsules in this 12-year-old male neutered Persian (a), may initially manifest as vomiting and then progress to regurgitation. Esophagitis should be treated aggressively to prevent progression to esophageal stricture, as occurred in this case (b). The cat was treated successfully with balloon dilation of the esophageal stricture, and was discharged on a short course of famotidine and sucralfate treatment

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Table 1

Recommended drugs for specific indications in vomiting cats

Underlying disease	Clinical approach to vomiting
Renal failure	Famotidine or ranitidine for hyperacidity Hydration; treat hypokalemia if present Maropitant if still vomiting
Cholangitis Hepatic lipidosis	Famotidine or ranitidine for hyperacidity Treat encephalopathy (lactulose, hydration) Treat hypokalemia
Avoid metronidazole if GI upset already present, or use metronidazole benzoate Maropitant if still vomiting
Inflammatory bowel disease	Treat underlying inflammation (novel protein diet, glucocorticoids) If no response, metoclopramide or cisapride if gastroparesis suspected Famotidine or ranitidine if gastric reflux suspected
Pancreatitis	Metoclopramide, maropitant, ondansetron, or prochlorperazine (if mild sedation desired) If abdominal pain present, buprenorphine or fentanyl CRI
Intoxication	Gastric lavage; then consider ondansetron or maropitant Prokinetics may enhance intestinal absorption of toxin, so not recommended
Hairballs	Petrolatum products If no response, cisapride, metoclopramide or ranitidine
Motion sickness	Maropitant (dimenhydrinate or maropitant in dogs)
Megacolon with vomiting	Ranitidine or cisapride

CRI = constant rate infusion

The empirical dosage of famotidine in cats is 0.5–1.0 mg/kg sid to bid. The drug is generally well tolerated. Prior anecdotal reports of hemolysis after intravenous administration were unsupported in a recent study, which showed that famotidine did not cause hemolysis in any of 56 hospitalized cats when given by slow bolus injection over 5 mins. ²² In humans, a dose reduction is recommended in renal failure patients, ²⁰ as high plasma famotidine concentrations can lead to mental status abnormalities such as confusion or delirium. ²³

Ranitidine

Ranitidine (Zantac; GlaxoSmithKline) is also an H₂ blocker and has been shown to decrease gastric hydrochloric acid secretion in cats. ²⁴ In addition, ranitidine has prokinetic effects on the GI tract, including the colon, as a result of its weak acetylcholinesterase activity.^25,26 As with famotidine, ranitidine may be useful for severe persistent vomiting where esophageal reflux or esophagitis is a concern, as well as for vomiting due to hyperacidity (renal failure, mast cell disease). Ranitidine may be preferable to famotidine in cats with both suspected hyperacidity or reflux, and gastric atony or megacolon.

Ranitidine is available without prescription in the USA as 75 mg tablets. The recommended dosage, based on pharmacokinetic data in cats, is 2.5 mg/kg IV bid or 3.5 mg/kg PO bid. ²⁷ Similar to famotidine, a dose reduction of ranitidine is recommended in human renal failure patients. No clinically significant cytochrome P450 enzyme inhibition is seen with ranitidine at therapeutic concentrations. ²⁸ Ranitidine by intravenous bolus may cause transient hypotension in cats.^2,3

Omeprazole

Omeprazole (Prilosec; AstraZeneca) and related proton pump blockers inhibit the H⁺/K⁺ ATPase pump at the luminal surface of gastric parietal cells. This prevents the final step in gastric hydrochloric acid secretion, and these drugs are more potent antacids than H₂ blockers. Omeprazole has been shown to reduce gastric acid secretion in cats. ²⁴

Omeprazole is useful for significant or refractory gastroduodenal ulceration or erosive esophagitis. It has no direct antiemetic effects. Although there is a delay of 1–3 days before omeprazole exerts its maximal effect, adding H₂ blockers for the first few days of treatment provides little or no improvement in efficacy in humans, and is not necessary.

Omeprazole is available in 10 and 20 mg capsules. An empirical dosage in cats (and dogs) is 0.5–1.0 mg/kg PO sid. The drug is enteric-coated to prevent degradation. If reformulated, enteric-coated granules can be measured and placed in a gelatin capsule. The equine preparation (Gastrogard; Merial) is much too concentrated to use safely in cats (or dogs).

Omeprazole is a cytochrome P450 enzyme inhibitor in humans, but without the wide range of enzyme inhibition seen with cimetidine. Omeprazole can decrease the clearance of diazepam in humans, ²⁹ and, depending on the drug, omeprazole can also act as a P450 inducer. Because of the potential for drug interactions, omeprazole may not be an ideal long-term antacid in cats being treated with multiple drugs.

The safety of omeprazole for long-term administration has not been established in cats. Because of effective acid suppression, pump blockers lead to a feedback increase in gastrin release, which has been associated with parietal cell hyperplasia in dogs, and, at very high doses, with gastric carcinoids in rats. ³⁰ Long term (>1 year) use of omeprazole is associated with an increased incidence of gastric polyps in humans, although dysplastic changes are rare, ³¹ and an increase in gastric cancer has not been observed in humans.

Sucralfate

Sucralfate (Carafate; Aventis Pharmaceuticals) is a disaccharide complexed to aluminium hydroxide. In the acidic environment of the stomach it becomes cross-linked and forms a gel that adheres to gastric epithelium, especially that of exposed ulcer beds. Sucralfate also binds pepsin and bile salts, which can otherwise contribute to ulcer formation. In addition, it can act as a phosphate binder. Sucralfate may speed ulcer healing by enhancing the production of cytoprotective prostaglandins by the gastric mucosa; however, this effect has not been studied in cats, and could not be demonstrated in canine gastric mucosa. ³²

Sucralfate is indicated for esophagitis, such as that caused by doxycycline or clindamycin capsules in cats,^33,34 gastric or duodenal ulceration, and uremic gastritis. It may be helpful after endoscopic retrieval of gastric or esophageal foreign bodies. Sucralfate has been shown experimentally to prevent acid-induced esophagitis in cats, ³⁵ and, therefore, may be useful prophylactically prior to surgery when reflux is anticipated (eg, a recent meal, presence of megaesophagus or a hiatal hernia). Sucralfate has been advocated for radiation mucositis, but its efficacy has been disappointing in humans. ³⁶

The empirical dosage of sucralfate is one-quarter of a 1 g tablet per cat tid to qid. Sucralfate may be crushed and suspended in water; it is stable for 14 days in the refrigerator as a 200 mg/ml suspension. ³⁷ A gel formulation of sucralfate is as effective as the suspension and can be given less frequently (twice daily in humans); ³⁸ sucralfate gel is marketed in Europe for human use.

Sucralfate can lead to constipation, and has a chalky, unpalatable taste, but is a safe drug overall. The most important complication of treatment is the potential for drug interactions. The aluminium in sucralfate binds other drugs such as doxycycline, digoxin and all fluoroquinolones, and markedly impairs their absorption. If sucralfate must be given orally with any of these drugs, it is best to give the other drug 2 h before sucralfate. Reversing the order will not prevent an interaction, as sucralfate remains in the stomach for many hours after administration. Sucralfate can be given concomitantly with H₂ blockers without affecting their overall absorption;^39,40 therefore, no separation of dosing times is necessary.