Exertional Myopathies in Horses

All breeds of horses are susceptible to sporadic exertional rhabdomyolysis. The most common cause is exercise that exceeds the horse’s state of training. The incidence of muscle stiffness also has been found to increase during an outbreak of respiratory disease. Dietary deficiencies of sodium, vitamin E, selenium, or a calcium:phosphorus imbalance may also be contributory factors.

A diagnosis of sporadic exertional rhabdomyolysis is made on the basis of a horse with no previous history, or a brief history, of exertional rhabdomyolysis, signs of muscle cramping and stiffness after exercise, and moderate to marked increases in serum CK and AST. Immediately on detection of signs of exertional rhabdomyolysis, exercise should stop and the horse should be moved to a well-bedded stall with access to fresh water. The objectives of treatment are to relieve anxiety and muscle pain and to correct fluid and acid-base deficits. Tranquilizers or opioids may be given. NSAIDs can be given to a well-hydrated horse. Most horses are relatively pain free within 18–24 hr.

Severe rhabdomyolysis can lead to renal compromise due to ischemia and the combined nephrotoxic effects of myoglobinuria, dehydration, and NSAID therapy. The first priority in horses with hemoconcentration or myoglobinuria is to reestablish fluid balance and induce diuresis. In severely affected animals, regular monitoring of BUN and/or serum creatinine is advised to assess the extent of renal damage. Diuretics are contraindicated in the absence of IV fluid therapy and are indicated if the horse is in oliguric renal failure.

Horses should be stall rested on a hay diet with a dietary vitamin and mineral ration balancer supplement for a few days. For horses with sporadic forms of exertional rhabdomyolysis, rest with regular access to a paddock should continue until serum muscle enzyme concentrations are normal. Because the inciting cause is usually temporary, most horses respond to rest, a gradual increase in training, and dietary adjustment. Endurance horses should be encouraged to drink electrolyte-supplemented water during an endurance ride and monitored particularly closely during hot, humid conditions.

Some horses have recurrent episodes of rhabdomyolysis, even with light exercise. Four forms of chronic tying-up have been identified using muscle biopsies or genetic testing: type 1 polysaccharide storage myopathy (PSSM), type 2 PSSM, malignant hyperthermia, and recurrent exertional rhabdomyolysis.

Type 1 polysaccharide storage myopathy is seen frequently in Quarter horse–related breeds (especially halter and Western pleasure horses), Morgans, and draft horses but is also present in at least 20 other horse breeds. It is caused by a dominantly inherited mutation in the glycogen synthase 1 (GYS1) gene. A diagnosis can be made by genetic testing of blood or hair samples. Quarter horse–related breeds and other crossbred or light breeds of horses with type 1 PSSM often develop episodes of rhabdomyolysis at a young age with little exercise. Rest for a few days before exercise is a common triggering factor. Episodes are characterized by a tucked-up abdomen, a camped-out stance, muscle fasciculations, sweating, gait asymmetry, hindlimb stiffness, and reluctance to move. Some horses paw or roll, resembling colic. Serum CK and AST are increased during an episode (usually >1,000 U/L) and, unlike in other forms of rhabdomyolysis, subclinical episodes characterized by persistently abnormal CK levels are common. Clinical signs in draft horses may include loss of muscle mass, progressive weakness, and recumbency. CK and AST may be normal in draft horses with this syndrome. When draft horses develop rhabdomyolysis, CK and AST may be markedly increased, and horses can become myoglobinuric, weak, and reluctant to rise.

Type 2 polysaccharide storage myopathy occurs in light breeds such as Arabians, Morgans, Thoroughbreds, a variety of Warmblood breeds and some Quarter horses. A diagnosis is made by identifying an abnormal pattern of glycogen storage in muscle biopsies in a horse with a negative GYS1 genetic test. In Quarter horses <1 yr old, it may cause difficulty rising from a recumbent position and increased serum CK activity. Chronic episodes of muscle stiffness, soreness, and muscle atrophy with normal to modest increases in serum CK are common in horses with type 2 PSSM. The most common presentation of this disorder in Warmbloods is a gait abnormality, exercise intolerance, and loss of muscle mass when out of work that is not necessarily accompanied by a concomitant rise in serum CK.

Malignant hyperthermia is caused by an autosomal dominant mutation in the skeletal muscle ryanodine receptor gene (RYR1). The mutation is responsible for both anesthesia-related and non-anesthesia-related causes of rhabdomyolysis in Quarter horses. A diagnosis can be made by genetic testing of blood or hair roots. Signs related to inhalation anesthesia include tachycardia, tachypnea, hyperthermia, muscle rigidity accompanied by a severe lactic acidosis, increased serum CK, and electrolyte derangements. Exertional rhabdomyolysis in Quarter horses with malignant hyperthermia can result in sudden death. Signs are preceded by excessive sweating, tachycardia, tachypnea, hyperthermia, and muscle rigidity. Some Quarter horses have both malignant hyperthermia and PSSM, which results in more severe signs of exertional rhabdomyolysis than those seen in horses with PSSM alone.

Recurrent exertional rhabdomyolysis is seen frequently in Thoroughbreds, Standardbreds, and Arabian horses. It is likely due to abnormal regulation of intracellular calcium in skeletal muscles. It appears there is intermittent disruption of muscle contraction, particularly when horses susceptible to the condition are fit and have a nervous temperament. In Thoroughbreds, it is likely inherited as an autosomal dominant trait.

Diagnostic tests to determine the cause of chronic tying-up include a CBC, serum chemistry panel, serum vitamin E and selenium concentrations, urinalysis to determine electrolyte balance, dietary analysis, exercise testing, muscle biopsy, and genetic testing. An exercise challenge test is useful to detect subclinical cases; serum CK is measured before and 4 hr after light exercise. In addition, quantifying the extent of exertional rhabdomyolysis during mild exercise is helpful in deciding how rapidly to reinstate training.

A diagnosis of type 1 PSSM is based on identification of the GYS1 mutation and/or the presence of muscle fibers with subsarcolemmal vacuoles, dark periodic acid-Schiff (PAS) staining for glycogen, and most notably, amylase-resistant abnormal complex polysaccharide accumulation. A diagnosis of type 2 PSSM is based on the absence of the GYS1 mutation and the presence of muscle fibers with aggregates of amylase-sensitive PAS-positive staining glycogen and occasionally small amounts of amylase-resistant PAS-positive material. A diagnosis of recurrent exertional rhabdomyolysis is based on history, clinical signs, increases in serum CK and AST, and muscle biopsy.

Horses with type 1 PSSM have constitutively active glycogen synthase that is further stimulated by increased blood insulin concentrations, resulting in high muscle glycogen concentrations. When fed a starch meal, these horses take up a higher proportion of the absorbed glucose in their muscles than healthy horses. Horses with type 2 PSSM also have abnormal glycogen storage, but the cause of this myopathy is unknown. Thus, the ideal diet for PSSM is based on feeding forage at a rate of 1.5%–2% body wt, providing >15% of digestible energy as fat and limiting starch to <10% of daily digestible energy by limiting grain or replacing it with a fat supplement. Caloric needs should be assessed first to prevent horses becoming obese on a high-fat diet. Improvement in signs of exertional rhabdomyolysis for horses with PSSM requires both dietary changes and gradual increases in the amount of daily exercise and turn-out.

Horses with malignant hyperthermia may benefit from premedication with dantrolene (4 mg/kg, PO) 60–90 min before exercise, particularly under hot conditions.

Management of recurrent exertional rhabdomyolysis is aimed at decreasing the triggering factors for excitement and pharmacologic alteration of intracellular calcium flux with contraction. Management changes that may decrease excitement include minimizing stall confinement by using turn-out or a hot walker, exercising and feeding horses with recurrent exertional rhabdomyolysis before other horses, providing compatible equine company, and the judicious use of low-dose tranquilizers during training. A high-fat, low-starch diet is beneficial, possibly by decreasing excitement. In contrast to horses with PSSM, those with recurrent exertional rhabdomyolysis often require higher caloric intakes (>24 Mcal/day). At these high caloric intakes, specialized feeds designed for exertional rhabdomyolysis are necessary, because additional vegetable oil or rice bran cannot supply enough calories for equine athletes in intense training. Hay should be fed at 1.5%–2% body wt, and high-fat, low-starch concentrates should be selected that provide ≤20% of daily digestible energy as nonstructural carbohydrate and 20%–25% of digestible energy as fat.

Dantrolene (4 mg/kg, PO) given 1 hr before exercise may decrease the release of calcium from the calcium release channel. Phenytoin (1.4–2.7 mg/kg, PO, bid) has also been advocated as a treatment for horses with recurrent exertional rhabdomyolysis. Therapeutic levels vary, so oral dosages are adjusted by monitoring serum levels to achieve 8–12 mcg/mL. However, longterm treatment with dantrolene or phenytoin is expensive.