Table of Contents
Volume 19, Number 7–July 2013
Volume 19, Number 7—July 2013
Letter
Human Infection with Marten Tapeworm
Article Contents
To the Editor: Cysticercosis-like human infections with the tapeworm Taenia crassiceps, which infects foxes as terminal hosts, have been reported (1,2). We report a case of a cysticercosis-like eye infection caused by the tapeworm T. martis (marten tapeworm) in a woman.
Figure
Figure. . . Cysticercosis-like eye infection caused by the tapeworm Taenia martis in a woman. A) Fundus at the patient’s initial visit, before medical therapy. The cyst lies subretinally at the temporal... Taenia martis tapeworm cyst in woman with cysticercosis–like eye infection, before and after medical therapy. Although the cyst decreased in size after medical therapy, movements of the larva persisted. Video is 100 seconds long, taken with a Heidelberg Retinal Analyzer.
Direct Video Link: http://streaming.cdc.gov/vod.php?id=eff01b6f9bbe41f1ea318db3d6e66f9220121218092846890
The patient reported no other symptoms at that time. Laboratory evaluation found no eosinophilia or elevation of total IgE. Serologic testing results were negative for antibodies against the following parasites: Taenia solium, Echinococcus multilocularis, E. granulosus, Dirofilaria immitis, Strongyloides spp., and Toxocara canis. Fecal testing results were negative for worm eggs. Images from ultrasonography of the liver and magnetic resonance imaging of the head were unremarkable. The patient’s travel history included—in addition to southern European countries—trips to Nepal and Thailand 15 years previously.
At the time of examination, the patient lived in a small village near Freiburg (im Breisgau) in southwestern Germany. She grew vegetables in the family garden, which was next to a forest. Her 3 children and husband did not report any health problems. For the past 6 years, the family had owned a dog, which received antiparasitic medications on a regular basis; recent checks for intestinal parasitic infection found no ova.
The suspected cause of the woman’s illness was cysticercosis caused by the larva of T. solium; systemic antiparasitic therapy was started (albendazole 400 mg 2×/d, dexamethasone 20 mg/d). The size of the larva diminished (Figure, panel D; Video), but the patient remained symptomatic. Therefore, after 8 days of therapy, the cyst was removed by retinotomy. A few days later, peripheral retinal detachment occurred and was treated by a second vitrectomy and intravitreal gas injection. Because of the repeated gas tamponade, a gas cataract developed, which necessitated cataract surgery. At the end of March 2011, the patient’s visual acuity had returned to 20/20 in both eyes.
The removed cyst showed the characteristic macroscopic and histologic features of a cysticercus bladder wall (Figure, panels E, F). To determine the exact species by using molecular methods, we isolated DNA from the cyst, conducted different PCRs selective for mitochondrial genes, determined the corresponding sequences, and used a BLAST search (3) to compare these sequences with publically available sequences. Sequences of the following mitochondrial genes were determined by using the given primers and later submitted to GenBank: small ribosomal subunit (primers 12S Taenia FF 5′-CACAGTGCCAGCATCYGCGGT-3′ and 12S Taenia RR 5′-GAGGGTGACGGGCGGTGTGTAC-3′, PCR product of 426 bp, GenBank accession no. JX415820); NADH dehydrogenase subunit 1 (primers: NAD1-FF 5′-ATTGGKTTATTTCAGAGTTTTTCTGATTTA-3′ and NAD1-RR 5′-CTCMCCATAATCAAATGGACTACG-3′, 394 bp, GenBank accession no. JX415819); and the cytochrome-c oxidase subunit 1 (determined by using previously published primers [4,5]; 376 bp, GenBank accession no. JX415821). All sequences showed highest identity with T. martis (99%–100%) but substantially lower identity with T. crassiceps (91%–97%) and T. solium (87%–89%) tapeworms.
Thus, molecular methods unequivocally identified the larva as that of a T. martis tapeworm. T. martis tapeworms (cestodes) live and produce eggs in the intestines of definitive hosts, weasels (family Mustelidae), which also includes pine martens, stone martens, polecats, badgers, wolverines, and stoats (6). The intermediate hosts are prey animals of the definitive hosts, such as arvicoline (voles and muskrats) or murid rodents. When intermediate hosts ingest eggs, cysticerci develop in the pleural and peritoneal cavities. T. martis tapeworms probably occur worldwide wherever suitable definitive and intermediate hosts are present (6,7). A study in southwest Germany reported that 36% of stone martens were infected with T. martis tapeworms (6).
Although nearly all patients who had cysticercosis-like infections caused by T. crassiceps tapeworms were immunosuppressed (1,2), we found no signs of immunosuppression in the patient reported here. The only identified risk factor for this patient was consumption of homegrown vegetables, which could have been contaminated by marten feces.
The clinical and histologic appearance of the organism in this patient suggested cysticercosis caused by a T. solium tapeworm. However, the specific diagnosis of T. martis tapeworm infection was possible only by use of molecular methods. Thus, human infections with T. martis and other animal tapeworms might occur at times but might be misdiagnosed as T. solium cysticercosis. For therapy, the rules and considerations are probably the same as those for T. solium cysticercosis, as described (8,9). Concerning antiparasitic therapy, one must be aware of possible complications caused by intraocular immunologic reactions. As demonstrated by the case reported here, surgical removal of a subretinal larva is connected with the risk for retinal detachment and cataract formation. The identification of the responsible tapeworm is useful for epidemiologic reasons, for determining the source of infection. We therefore suggest using molecular methods to determine the exact species of parasites removed from human tissue.
Direct Video Link: http://streaming.cdc.gov/vod.php?id=eff01b6f9bbe41f1ea318db3d6e66f9220121218092846890
The patient reported no other symptoms at that time. Laboratory evaluation found no eosinophilia or elevation of total IgE. Serologic testing results were negative for antibodies against the following parasites: Taenia solium, Echinococcus multilocularis, E. granulosus, Dirofilaria immitis, Strongyloides spp., and Toxocara canis. Fecal testing results were negative for worm eggs. Images from ultrasonography of the liver and magnetic resonance imaging of the head were unremarkable. The patient’s travel history included—in addition to southern European countries—trips to Nepal and Thailand 15 years previously.
At the time of examination, the patient lived in a small village near Freiburg (im Breisgau) in southwestern Germany. She grew vegetables in the family garden, which was next to a forest. Her 3 children and husband did not report any health problems. For the past 6 years, the family had owned a dog, which received antiparasitic medications on a regular basis; recent checks for intestinal parasitic infection found no ova.
The suspected cause of the woman’s illness was cysticercosis caused by the larva of T. solium; systemic antiparasitic therapy was started (albendazole 400 mg 2×/d, dexamethasone 20 mg/d). The size of the larva diminished (Figure, panel D; Video), but the patient remained symptomatic. Therefore, after 8 days of therapy, the cyst was removed by retinotomy. A few days later, peripheral retinal detachment occurred and was treated by a second vitrectomy and intravitreal gas injection. Because of the repeated gas tamponade, a gas cataract developed, which necessitated cataract surgery. At the end of March 2011, the patient’s visual acuity had returned to 20/20 in both eyes.
The removed cyst showed the characteristic macroscopic and histologic features of a cysticercus bladder wall (Figure, panels E, F). To determine the exact species by using molecular methods, we isolated DNA from the cyst, conducted different PCRs selective for mitochondrial genes, determined the corresponding sequences, and used a BLAST search (3) to compare these sequences with publically available sequences. Sequences of the following mitochondrial genes were determined by using the given primers and later submitted to GenBank: small ribosomal subunit (primers 12S Taenia FF 5′-CACAGTGCCAGCATCYGCGGT-3′ and 12S Taenia RR 5′-GAGGGTGACGGGCGGTGTGTAC-3′, PCR product of 426 bp, GenBank accession no. JX415820); NADH dehydrogenase subunit 1 (primers: NAD1-FF 5′-ATTGGKTTATTTCAGAGTTTTTCTGATTTA-3′ and NAD1-RR 5′-CTCMCCATAATCAAATGGACTACG-3′, 394 bp, GenBank accession no. JX415819); and the cytochrome-c oxidase subunit 1 (determined by using previously published primers [4,5]; 376 bp, GenBank accession no. JX415821). All sequences showed highest identity with T. martis (99%–100%) but substantially lower identity with T. crassiceps (91%–97%) and T. solium (87%–89%) tapeworms.
Thus, molecular methods unequivocally identified the larva as that of a T. martis tapeworm. T. martis tapeworms (cestodes) live and produce eggs in the intestines of definitive hosts, weasels (family Mustelidae), which also includes pine martens, stone martens, polecats, badgers, wolverines, and stoats (6). The intermediate hosts are prey animals of the definitive hosts, such as arvicoline (voles and muskrats) or murid rodents. When intermediate hosts ingest eggs, cysticerci develop in the pleural and peritoneal cavities. T. martis tapeworms probably occur worldwide wherever suitable definitive and intermediate hosts are present (6,7). A study in southwest Germany reported that 36% of stone martens were infected with T. martis tapeworms (6).
Although nearly all patients who had cysticercosis-like infections caused by T. crassiceps tapeworms were immunosuppressed (1,2), we found no signs of immunosuppression in the patient reported here. The only identified risk factor for this patient was consumption of homegrown vegetables, which could have been contaminated by marten feces.
The clinical and histologic appearance of the organism in this patient suggested cysticercosis caused by a T. solium tapeworm. However, the specific diagnosis of T. martis tapeworm infection was possible only by use of molecular methods. Thus, human infections with T. martis and other animal tapeworms might occur at times but might be misdiagnosed as T. solium cysticercosis. For therapy, the rules and considerations are probably the same as those for T. solium cysticercosis, as described (8,9). Concerning antiparasitic therapy, one must be aware of possible complications caused by intraocular immunologic reactions. As demonstrated by the case reported here, surgical removal of a subretinal larva is connected with the risk for retinal detachment and cataract formation. The identification of the responsible tapeworm is useful for epidemiologic reasons, for determining the source of infection. We therefore suggest using molecular methods to determine the exact species of parasites removed from human tissue.
Philipp Eberwein, Alexandra Haeupler, Fabian Kuepper, Dirk Wagner, Winfried V. Kern, Birgit Muntau, Paul Racz, Hansjuergen Agostini, and Sven Poppert
Acknowledgment
We gratefully acknowledge Heidrun von Thien for her technical assistance. We thank the patient for her collaboration and her approval to publish this case report, and we thank the board of directors of the Bernhard Nocht Institute for Tropical Medicine, Rolf Horstmann, Bernhard Fleischer, and Egbert Tannich for their support.
References
- Goesseringer N, Lindenblatt N, Mihic-Probst D, Grimm F, Giovanoli P. Taenia crassiceps upper limb fasciitis in a patient with untreated acquired immunodeficiency syndrome and chronic hepatitis C infection—the role of surgical debridement. J Plast Reconstr Aesthet Surg. 2011;64:e174–6 . DOI
PubMed
- Heldwein K, Biedermann HG, Hamperl WD, Bretzel G, Loscher T, Laregina D, Subcutaneous Taenia crassiceps infection in a patient with non-Hodgkin's lymphoma. Am J Trop Med Hyg. 2006;75:108–11 .PubMed
- Altschul SF, Madden TL, Schaffer AA, Zhang J, Zhang Z, Miller W, Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 1997;25:3389–402. DOI
- Bowles J, Blair D, McManus DP. Genetic variants within the genus Echinococcus identified by mitochondrial DNA sequencing. Mol Biochem Parasitol. 1992;54:165–73 . DOI
- Bowles J, McManus DP. NADH dehydrogenase 1 gene sequences compared for species and strains of the genus Echinococcus. Int J Parasitol. 1993;23:969–72 . DOI
- Loos-Frank B, Zeyhle E. The intestinal helminths of the red fox and some other carnivores in southwest Germany. Z Parasitenkd. 1982;67:99–113 . DOI
- Mathy A, Hanosset R, Adant S, Losson B. The carriage of larval Echinococcus multilocularis and other cestodes by the musk rat (Ondatra zibethicus) along the Ourthe River and its tributaries (Belgium). J Wildl Dis. 2009;45:279–87 .PubMed
- Palomares F, Palencia G, Ambrosio JR, Ortiz A, Jung-Cook H. Evaluation of the efficacy of albendazole sulphoxide and praziquantel in combination on Taenia crassiceps cysts: in vitro studies. J Antimicrob Chemother. 2006;57:482–8 . DOI
- Nash TE, Garcia HH. Diagnosis and treatment of neurocysticercosis. Nature reviews. Neurology. 2011;7:584–94 .PubMed
Figure
Suggested citation for this article: Eberwein P, Haeupler A, Kuepper F, Wagner D, Kern WV, Muntau B, et al. Human infection with marten tapeworm [letter]. Emerg Infect Dis [Internet]. 2013 Jul [date cited]. http://dx.doi.org/10.3201/eid1907.121114
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