Sea snake venom is extremely stable. Research has shown that boiling for 30 minutes and dissolving venom in both acidic and basic solutions to a pH range of 1 to 11, respectively, did not significantly change LD50 levels after administration in rats.[1] Therefore, hot water is not indicated for this venom and may in fact worsen outcomes by increasing blood flow to the area with the toxins.

Physical exam findings revolve around blockage of neural impulses and muscle breakdown. Paralysis, dysphagia, muscle spasm, respiratory arrest, and dysarthria can occur, and the most common cause of death in sea snake poisoning is respiratory arrest due to diaphragm paralysis or drowning secondary to skeletal muscle paralysis. Because sea snakes have small teeth, bite marks may be difficult to appreciate, and it can sometimes be difficult for the victim to realize they were bitten until symptoms occur. In general, if no symptoms occur within a few hours after the bite, including both neurologic symptoms and muscle pain from myonecrosis, it is possible that the bite was a dry bite with no envenomation.[2] Approximately 50% of bites are dry bites and only 50% of the time is there a significant envenomation.[4]

Due to the potential for myonecrosis from phospholipase A, creatine kinase levels may be elevated and myoglobinuria present in urine. No specific laboratory or radiographic tests are required for the diagnosis as clinical history including contact with a sea snake, and typical symptomatology is all that is required for diagnosis. Serum electrolytes and creatinine levels may be helpful to monitor for resultant kidney injury but are not required for diagnosis.[5]

Treatment is supportive and requires the administration of antivenin as soon as possible when symptoms of envenomation are present. Removal of the patient from the water is paramount as skeletal muscle paralysis can cause drowning. Respiratory compromise may also occur, owing to diaphragmatic paralysis, and patients may require intubation and mechanical ventilation until antivenin is administered and can neutralize the venom. Incision, drainage, and suctioning of the bite area is not indicated as little venom is likely to be removed in this manner and resultant damage to the skin and possible subsequent infection risks outweigh the benefit of any possible venom removal. A pressure-immobilization bandage can be considered to help prevent systemic circulation of venom. Monitoring urine output should also be considered to evaluate for myoglobinuria, and frequent measurement of serum creatinine and electrolytes should be evaluated, and electrolytes supplemented as needed. In the absence of antivenin, hemodialysis can be considered and, theoretically, could be helpful in refractory cases given the small protein size (6,000 to 8,000 daltons) of the neurotoxin.[1]

• Cobra Envenomation

• Copperhead and Cotton Mouth Envenomation

• Coral Snake Envenomation

• Gillian-Barre Syndrome

• Mojave Rattlesnake Envenomation

• Rattlesnake Envenomation

• Rhabdomyolysis

Due to the high LD50 of sea snake venom, morbidity and mortality rates are high without appropriate treatment. However, if supportive care, including mechanical ventilation as needed for respiratory compromise, and antivenin administration is done early, the overall prognosis is good.

Complications of sea snake envenomation can include muscle necrosis and myoglobinuria due to phospholipase A. If significant muscle breakdown occurs, the resultant myoglobinuria can lead to elevated creatinine levels and kidney damage. If antivenin is not administered promptly, significant morbidity up to and including death from drowning or respiratory failure can occur.

If available, consultation with toxicology for advice regarding the type and dose of antivenin is warranted. Intensive care unit consultation may also be required if a respiratory compromise occurs and mechanical ventilation is needed. If considering hemodialysis, consultation with nephrology is required.

Sea snakes are not aggressive but they are quite dangerous; therefore, educating patients and the public to avoid contact with sea snakes could dramatically reduce the incidence of sea snake bites. The group that could be potentially impacted the most from education focusing on prevention are fishermen. As most bites occur when fisherman are emptying or entangling their nets, educating them on identifying sea snakes in endemic areas and avoiding contact with sea snakes could be an important preventative measure. Furthermore, if a sea snake bite does occur, educating the population most at risk about potential adverse outcomes such as paralysis and respiratory arrest is important as this education would help potential victims understand that they need to get to definitive care quickly for antivenin administration.

Recognition and early treatment of a potential envenomation by a sea snake are imperative to a successful outcome.[1] Health professionals who are likely to encounter sea snake envenomation should have the skills needed to identify symptoms of sea snake envenomation and the skills needed to provide supportive care up to and including mechanical ventilation if respiratory muscle involvement occurs. (Level V)