Toxicology Brief: Allium species poisoning in dogs and cats
Wild and domesticated Allium species have been used for culinary and ethnomedicinal purposes since the beginning of recorded history.
Wild and domesticated Allium species have been used for culinary and ethnomedicinal purposes since the beginning of recorded history. About 95 species of native or cultivated leeks, chives, garlic, shallots, scallions, and onions are present in North America, and more than 80 ornamental Allium species are available. All Allium species and the products derived from them can be toxic to dogs and cats1; however, relatively few Allium species are of important toxicologic interest.
The domesticated species commonly involved in toxicosis include Allium cepa (onion), Allium porrum (leek), Allium sativum (garlic), and Allium schoenoprasum (chive). The plants form solitary or clustered bulbs and are strongly aromatic, with an onion or garlic odor when crushed. The distinctive aroma distinguishes Allium species from morphologically similar poisonous plants, particularly death camas (Zigadenus species).1
Allium species contain a wide variety of organosulfoxides, particularly alk(en)ylcysteine sulfoxides. Trauma to the plants, such as chewing, converts the organosulfoxides to a complex mixture of sulfur-containing organic compounds. Many of these compounds or their metabolites are responsible for the odors, flavors, and pharmacologic effects of these plants. Many Allium species' organosulfur compounds appear to be readily absorbed through the gastrointestinal tract and are metabolized to highly reactive oxidants.2 Cooking or spoilage of Allium species does not reduce their potential toxicity.1
Mechanism of action
The primary toxicologic mechanism of Allium species-derived organosulfur compounds is oxidative hemolysis, which occurs when the concentration of oxidants in the erythrocyte exceeds the capacity of the antioxidant metabolic pathways. Catalase antioxidant activity in erythrocytes in dogs is low,3 and normal hemoglobin in cats is about two to three times more susceptible to oxidative damage than the hemoglobin in other species.4
Oxidation of the exposed beta-93 cysteine residues present in hemoglobin results in the formation of sulfhemoglobin.5 Sulfhemoglobin is less soluble than hemoglobin, so it precipitates, aggregates, and binds to the cell membrane and forms Heinz bodies. Other types of oxidation of hemoglobin globin chains result in membrane cross-linking reactions and eccentrocyte formation.6 The formation of Heinz bodies and eccentrocytes increases erythrocyte fragility and extravascular hemolysis. Direct oxidative damage to the erythrocyte cell membrane and its sodium-potassium pump or the oxidative production of hemin also contributes to cell lysis. Oxidation of the heme ion and associated methemoglobinemia results in a left shift of the hemoglobin-oxygen dissociation curve, decreased blood oxygen transportation capacity, and, ultimately, impaired delivery of oxygen to the tissues.
Thus, the result of the oxidative hemolytic process induced by Allium species consumption is the onset of anemia, methemoglobinemia, and impaired oxygen transportation. Although marked Heinz body formation may be present within a day after onions are ingested, the anemic nadir typically develops several days later.
Allicin and ajoene, pharmacologically active agents in garlic, are potent cardiac and smooth muscle relaxants, vasodilators, and hypotensive agents.7-9 Also, ajoene and other organosulfur compounds derived from onions are potent antithrombotic agents.10 Thus, hypotensive and antithrombotic effects can exacerbate the physiologic effects of anemia and impaired oxygen transportation. Garlic preparations that have not been aged cause direct damage to the gastric and ileal mucosa, resulting in pain and diarrhea.11
Exposure and susceptibility
Allium species toxicosis most commonly occurs after oral consumption. In addition to consuming fresh plant material, consuming juice, fresh and aged dietary supplements, powdered cooking preparations, dehydrated material, or food preparations derived from or containing Allium species can be potentially toxic to dogs and cats.1 Allium species toxicosis typically ensues after consumption of a single large quantity of the material or repeated small amounts. Dogs and cats are highly susceptible to onion toxicosis: Consumption of as little as 5 g/kg of onions in cats or 15 to 30 g/kg in dogs has resulted in clinically important hematologic changes. Onion toxicosis is consistently noted in animals that ingest more than 0.5% of their body weight in onions at one time.
Dogs with heritable high erythrocyte reduced glutathione and potassium concentrations are more susceptible to the hematologic effects of onions.12 This trait is relatively common in Japanese breeds. Other inborn errors in metabolism or nutritional deficiencies that result in decreased erythrocyte antioxidant defenses, such as glucose-6-phosphate dehydrogenase deficiency or zinc deficiency, could increase an animal's susceptibility to Allium species toxicity.13 Concurrent treatment with xenobiotics, drugs, or dietary factors that induce erythrocyte oxidative injury (e.g. propofol, propylene glycol, dl-methionine, sulfonamides, sulfapyridine, large doses of vitamin K3, benzocaine) or diminish erythrocyte oxidative defenses (e.g. acetaminophen) is likely to increase an animal's susceptibility to Allium species toxicosis.
Clinical signs and laboratory findings
In dogs and cats, clinical signs of Allium species toxicosis may appear within one day of consumption if large amounts of material have been ingested; however, it is more common for clinical signs to develop after a lag of several days. Clinical signs often include depression, hemoglobinuria, hemoglobin and possibly hemosiderin urinary casts, icterus, tachypnea, tachycardia, weakness, exercise intolerance, and cold sensitivity. Inappetence, abdominal pain, and diarrhea may also be present. In cases of recent ingestion, the affected dog's or cat's breath may smell of onions or garlic.
Clinical pathology findings are consistent with intravascular and extravascular hemolysis, Heinz body anemia, eccentrocytosis, hemoglobinemia, hemoglobinuria, hyperbilirubinemia, methemoglobinemia, and, if the animal survives long enough, an accompanying regenerative response.1
Necropsy and histologic findings typically indicate hemolytic anemia. Because of the common lag of several days between ingestion and the development of clinical signs, gastrointestinal erosion or Allium species in the gut content may not be seen. Histopathologic findings, although consistent with hemolytic anemia, are not specific for Allium species toxicosis and may include deposition of hemosiderin in the phagocytic cells of the liver, spleen, and renal tubular epithelium; renal tubular pigment necrosis; and nephrotubular casts and hemoglobin casts in the renal tubules.1
Differential diagnoses include other common toxicoses: brassicaceous vegetables, propylene glycol, acetaminophen, benzocaine, vitamin K3, dl-methionine, naphthalene, zinc, and copper. Common feline disorders associated with Heinz body formation include diabetes mellitus, particularly if ketoacidosis is present; hepatic lipidosis; hyperthyroidism; and lymphoma and other neoplasms.
Diagnosis and treatment
Allium species toxicosis is typically diagnosed through a combination of history, clinical signs, and microscopic confirmation of a Heinz body-type hemolytic anemia.
No specific antidote is available for Allium species toxicosis. Treatment involves gastrointestinal decontamination and removing the Allium species source, treating the anemia, and providing general supportive care. Inducing emesis can be valuable in asymptomatic dogs and cats provided no complicating factors are present and ingestion was within the last one or two hours. Consider administering activated charcoal after emesis. In severely affected animals, a blood transfusion and supplemental oxygen therapy may be required. Administering intravenous crystalloids is indicated if extensive vomiting and diarrhea have occurred or if hemoglobinuria or hypotension is evident.
Carefully monitor the patient's erythron for several days after ingestion since that is when the anemic nadir usually occurs. Antioxidants, such as sodium ascorbate, vitamin E, and N-acetylcysteine, have minimal overt protective effects in onion powder toxicosis in cats.14 Diets low in potential oxidants are recommended; semimoist foods that contain propylene glycol should be avoided, particularly in cats.15
A patient's prognosis depends on the species of plant involved, the severity of the anemia, and the institution of supportive care. In companion animals, avoiding exposure is the best preventive strategy. Feeding pets onions or other Allium species or their derivatives should be stopped.
"Toxicology Brief" was contributed by R.B. Cope, BSc, BVSc, PhD, Department of Biomedical Sciences, College of Veterinary Medicine, Oregon State University, Corvallis, OR 97331. The department editor is Petra Volmer, DVM, MS, DABVT, DABT, College of Veterinary Medicine, University of Illinois, Urbana, IL 61802.
1. Burrows GE, Tyrl RJ. Liliaceae Juss. Toxic plants of North America. Ames: Iowa State Press, 2001;751-805.
2. Amagase H, Petesch BL, Matsuura H, et al. Intake of garlic and its bioactive components. J Nutr 2001;131:955S-962S.
3. Nakamura K, Watanabe M, Sawai-Tanimoto S, et al. A low catalase activity in dog erythrocytes is due to a very low content of catalase protein despite having a normal specific activity. Int J Biochem Cell Biol 1998;30:823-831.
4. Harvey JW, Kaneko JJ. Oxidation of human and animal haemoglobins with ascorbate, acetylphenylhydrazine, nitrite, and hydrogen peroxide. Br J Haematol 1976;32:193-203.
5. Bloom JC, Brandt JT. Toxic responses of the blood. In: Klaassen CD, ed. Casarett & Doull's toxicology: the basic science of poisons. New York, NY: McGraw-Hill Book Co, 2001;389-411.
6. Lee KW, Yamato O, Tajima M, et al. Hematologic changes associated with the appearance of eccentrocytes after intragastric administration of garlic extract to dogs. Am J Vet Res 2000;61:1446-1450.
7. Mayeux PR, Agrawal KC, Tou JS, et al. The pharmacological effects of allicin, a constituent of garlic oil. Agents Actions 1988;25:182-190.
8. Martin N, Bardisa L, Pantoja C, et al. Experimental cardiovascular depressant effects of garlic (Allium sativum) dialysate. J Ethnopharmacol 1992;37:145-149.
9. Malik ZA, Siddiqui S. Hypotensive effect of freeze-dried garlic (Allium sativum) sap in dog. J Pak Med Assoc 1981;31:12-13.
10. Apitz-Castro R, Badimon JJ, Badimon L. Effect of ajoene, the major antiplatelet compound from garlic, on platelet thrombus formation. Thromb Res 1992;68:145-155.
11. Hoshino T, Kashimoto N, Kasuga S. Effects of garlic preparations on the gastrointestinal mucosa. J Nutr 2001;131:1109S-1113S.
12. Yamoto O, Maede Y. Susceptibility to onion-induced hemolysis in dogs with hereditary high erythrocyte reduced glutathione and potassium concentrations. Am J Vet Res 1992;53:134-137.
13. Smith JE, Ryer K, Wallace L. Glucose-6-phosphate dehydrogenase deficiency in a dog. Enzyme 1976;21:379-382.
14. Hill AS, O'Neill S, Rogers QR, et al. Antioxidant prevention of Heinz body formation and oxidative injury in cats. Am J Vet Res 2001;62:370-374.
15. Christopher MM, Perman V, Eaton JW. Contribution of propylene glycol-induced Heinz body formation to anemia in cats. J Am Vet Med Assoc 1989;194:1045-1056.