Due to their harpoon shape and forward-only motion, setae might migrate deeper, potentially even to the optic nerve.11 Because migration might take years and the barbed shape of setae does not always allow removal, some patients require lifetime monitoring with slit-lamp examination.Chronic problems, such as cataracts and persistent posterior uveitis, have been reported.10,11
Lonomism—One of the most serious (though rarest) reactions to caterpillars is lonomism, a condition caused by the caterpillars of Lonomia achelous and Lonomia obliqua moths. These caterpillars have a unique combination of toxins filling their branched spines, which ultimately leads to the same outcome: a hemorrhagic diathesis.
The toxin of L achelous comprises several proteases that degrade fibrin, fibrinogen, and factor XIII while activating prothrombin. In contrast, L obliqua poison causes a hemorrhagic diathesis by promoting a consumptive coagulopathy through enzymes that activate factor X and prothrombin.
With initial contact with either of these Lonomia caterpillars, the patient experiences severe pain accompanied by systemic symptoms, including headache, nausea, and vomiting. Shortly afterward, symptoms of a hemorrhagic diathesis manifest, including bleeding gums, hematuria, bleeding from prior wounds, and epistaxis.5 Serious complications of the hemorrhagic diathesis, such as hemorrhage of major organs, leads to death in 4% of patients.5 A reported case of a patient whose Lonomia caterpillar sting went unrecognized until a week after the accident ended with progression to stage V chronic renal disease.12
Recent research has focused on the specific mechanism of injury caused by Lonomia species. A study found that the venom of L obliqua causes cytoskeleton rearrangement and migration in vascular smooth muscle cells (VSMCs) by inducing formation of reactive oxygen species through activation of nicotinamide adenine dinucleotide phosphate oxidase.13 Thus, the venom directly contributes to the proinflammatory phenotype of endothelial cells seen following envenomation. The same study also demonstrated that elevated reactive oxygen species trigger extracellular signal-regulated kinase pathway activation in VSMCs, leading to cell proliferation, re-stenosis, and ischemia.13 This finding was confirmed by another study,14 which demonstrated an increase in Rac1, a signaling protein involved in the extracellular signal-regulated kinase pathway, in VSMCs upon exposure to L obliqua venom. These studies propose potential new targets for treatment to prevent vascular damage.