Do not use in animals with known hypersensitivity to sevoflurane or other halogenated anaesthetic agents.

Do not use in animals with a known or suspected susceptibility to malignant hyperthermia.

The safety of the veterinary medicinal product has not been established during pregnancy or lactation. However, there is limited clinical experience of the use of sevoflurane, after propofol induction, in bitches and queens undergoing caesarean section, without any ill effects being detected in either the bitch or queen, or the puppies or kittens. Use only according to the benefit-risk assessment by the responsible veterinarian.

There are limited data to support the safety of sevoflurane in animals less than 12 weeks of age. Therefore, it should only be used in these animals according to a benefit-risk assessment by the responsible veterinary surgeon.

Dogs and cats:

Very common (>1 animal / 10 animals treated):	Hypotension1 Elevated alanine aminotransferase (ALT)2,3, elevated aspartate aminotransferase (AST)2,3, elevated lactate dehydrogenase (LDH)2,4, elevated total bilirubin2,4 Leucocytosis2,4 Tense muscles, fasciculation Excitation Tachypnoea, apnoea Emesis
Common (1 to 10 animals / 100 animals treated):	Respiratory depression5 Bradycardia6
Very rare (<1 animal / 10,000 animals treated, including isolated reports):	Paddling Retching, increased salivation Cyanosis Premature ventricular contractions, cardiac depression7 Respiratory depression7 Malignant hyperthermia8

1hypotension during sevoflurane anaesthesia may result in decreased renal blood flow.

2in dogs transient elevations in AST, ALT, LDH, bilirubin and white blood cell counts may occur.

3in cats transient increases in AST and ALT may occur, however hepatic enzymes tend to remain within the normal range.

4dogs only.

5respiratory depression is dose-dependent; therefore, respiration should be closely monitored during sevoflurane anaesthesia and the inspired concentration of sevoflurane adjusted accordingly.

6anaesthetic-induced bradycardia may be reversed by administration of anticholinergics.

7excessive cardiopulmonary depression.

8the possibility of sevoflurane triggering episodes of malignant hyperthermia in susceptible dogs and cats cannot be ruled out.

Reporting adverse events is important. It allows continuous safety monitoring of a veterinary medicinal product. Reports should be sent, preferably via a veterinarian, to either the marketing authorisation holder or its local representative or the national competent authority via the national reporting system. See the package leaflet for respective contact details.

Overdose of the veterinary medicinal product may result in profound respiratory depression. Therefore, respiration must be monitored closely and supported when necessary with supplementary oxygen and/or assisted ventilation.

In cases of severe cardiopulmonary depression, administration of sevoflurane should be discontinued, the existence of a patent airway ensured, and assisted or controlled ventilation with pure oxygen initiated. Cardiovascular depression should be treated with plasma expanders, pressor agents, antiarrhythmic agents or other appropriate techniques.

Due to sevoflurane's low solubility in blood, increasing the concentration may result in rapid haemodynamic changes (dose-dependent decreases in blood pressure) compared to other volatile anaesthetics. Excessive decreases in blood pressure or respiratory depression may be corrected by decreasing or discontinuing the inspired concentration of sevoflurane.

Halogenated volatile anaesthetics can react with dry carbon dioxide (CO2) absorbents to produce carbon monoxide (CO) that may result in elevated levels of carboxyhaemoglobin in some dogs. In order to minimise this reaction in rebreathing anaesthetic circuits, the veterinary medicinal product should not be passed through soda lime or barium hydroxide that has been allowed to dry out.

The exothermic reaction that occurs between inhalation agents (including sevoflurane) and CO2 absorbents is increased when the CO2 absorbent becomes desiccated, such as after an extended period of dry gas flow through the CO2 absorbent canisters. Rare cases of excessive heat production, smoke and/or fire in the anaesthetic machine have been reported during the use of a desiccated CO2 absorbent and sevoflurane. An unusual decrease in the expected depth of anaesthesia compared to the vaporiser setting may indicate excessive heating of the CO2 absorbent canister.

If it is suspected that the CO2 absorbent may be desiccated, it must be replaced. The colour indicator of most CO2 absorbents does not necessarily change as a result of desiccation. Therefore, the lack of significant colour change should not be taken as an assurance of adequate hydration. CO2 absorbents should be replaced routinely regardless of the state of the colour indicator.

1,1,3,3,3-pentafluoro-2-(fluoromethoxy)propene (C4H2F6O), also known as Compound A, is produced when sevoflurane interacts with soda lime or barium hydroxide. Reaction with barium hydroxide results in a greater production of Compound A than does the reaction with soda lime. Its concentration in a circle absorber system increases with increasing sevoflurane concentrations and with decreasing fresh gas flow rates. Sevoflurane degradation in soda lime has been shown to increase with temperature. Since the reaction of carbon dioxide with absorbents is exothermic, this temperature increase will be determined by the quantities of CO2 absorbed, which in turn will depend on fresh gas flow in the anaesthetic circle system, metabolic status of the dog and ventilation. Although Compound A is a dose-dependent nephrotoxin in rats, the mechanism of this renal toxicity is unknown. Long-duration, low-flow sevoflurane anaesthesia should be avoided due to the risks of Compound A accumulation.

During maintenance of anaesthesia, increasing the concentration of sevoflurane produces a dose-dependent decrease in blood pressure. Due to sevoflurane's low solubility in blood, these haemodynamic changes may occur more rapidly than with other volatile anaesthetics. Arterial blood pressure should be monitored at frequent intervals during sevoflurane anaesthesia. Facilities for artificial ventilation, oxygen enrichment and circulatory resuscitation should be immediately available. Excessive decreases in blood pressure or respiratory depression may be related to the depth of anaesthesia and may be corrected by decreasing the inspired concentration of sevoflurane. The low solubility of sevoflurane also facilitates rapid elimination by the lungs. The nephrotoxic potential of certain NSAIDs, when used in the perioperative period, may be exacerbated by hypotensive episodes during sevoflurane anaesthesia. In order to maintain renal blood flow, prolonged episodes of hypotension (mean arterial pressure below 60 mmHg) should be avoided in dogs and cats during sevoflurane anaesthesia.

In common with all volatile agents, sevoflurane may cause hypotension in hypovolaemic animals such as those requiring surgery to repair traumatic injury, and lower doses should be administered in combination with appropriate analgesics.

Sevoflurane may trigger episodes of malignant hyperthermia in susceptible dogs and cats. If malignant hyperthermia develops, the anaesthetic supply should be interrupted immediately and 100% oxygen administered using fresh anaesthetic hoses and a rebreathing bag. Appropriate treatment should readily be instituted.

Doses of sevoflurane may need adjustment for geriatric or debilitated animals. Doses required for maintenance anaesthesia may need to be reduced by approximately 0.5% in geriatric dogs (i.e. 2.8% to 3.1% in premedicated geriatric dogs and 3.2 to 3.3% in unpremedicated geriatric dogs). There is no information on the adjustment of the maintenance dose in cats. Adjustment is, therefore, left to the discretion of the veterinarian. Limited clinical experience in administering sevoflurane to animals with renal, hepatic and cardiovascular insufficiency suggests that sevoflurane may be safely used in these conditions. However, it is recommended that such animals be monitored carefully during sevoflurane anaesthesia.

Sevoflurane may cause a small increase in intracranial pressure (ICP) under conditions of normocapnia in dogs. In dogs with head injuries or other conditions placing them at risk from increased ICP, it is recommended that hypocapnia be induced by means of controlled hyperventilation as a means of preventing changes in ICP.

In order to minimise exposure to sevoflurane vapour, the following recommendations are made:

Direct exposure to eyes may result in mild irritation. If eye exposure occurs, the eye should be flushed with plenty of water for 15 minutes. Medical attention should be sought if irritation persists.

In case of accidental contact with the skin, wash affected area with abundant water.

Symptoms of human overexposure (inhalation) to sevoflurane vapour include respiratory depression, hypotension, bradycardia, shivering, nausea and headache. If these symptoms occur, the individual should be removed from the source of exposure and medical attention sought.

Maintain a patent airway and give symptomatic and supportive treatment.