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Cho, Kim, Ryu, Jung, Park, and Son: Chordoma in the Tail of a Ferret

Abstract

A chordoma is an uncommon tumor that originates from the remnants of the notochord and most commonly involves the cranial and caudal regions of the axial skeleton. Chordoma has been described in laboratory animals such as dogs, rats, minks, and ferrets. This report describes a case of a chordoma in the tail of a ferret. Grossly, a grayish-white, expansile, subcutaneous soft-tissue mass was observed in the tail. Histopathologically, the mass was a loosely placed, nodular, unencapsulated neoplasm within the dermis. In the mass, tumor lobules were intermingled with fibrous tissues. Fibrous tissues contained abundant extracellular basophilic material that was consistent with mucin. The tumor was composed of a close pack of adipocyte-like vacuolated cells (physaliferous cells). The cells were centrally or eccentrically located round nuclei and eosinophilic cytoplasm with large vacuoles. Immunohistologically, neoplastic cells were positive for vimentin and S-100 protein. Based on histopathologic findings and special staining characteristics, this case was diagnosed as chordoma.

Chordomas are uncommon in humans and rare in animals. Up to now, only a few reports have been published about chordomas in dogs (Jabara and Jubb, 1971; Pease et al, 2002; Munday et al, 2003), mink (Hadlow, 1984), rats (Stefanski et al, 1988), cats (Carpenter et al, 1990; Carminato et al, 2008) and ferrets (Herron et al, 1990; Dunn et al, 1991; Williams et al, 1993). Chordomas originate from remnants of the notochord and may arise anywhere along the vertebral column, but most commonly involve the cranial and caudal limits of the axial skeleton (Carminato et al, 2008). In rats, this tumor is most commonly located in lumbosacral vertebrae (Stefanski et al, 1988). Only 2 case of feline chordoma developed, in the cervical and coccygeal regions (Carpenter et al, 1990, Carminato, 2008). In dogs, the cervical and sacrococcygeal vertebrae, brain, spinal cord, and skin are reported sites for chordomas (Jabara and Jubb, 1971, Pease et al, 2002; Munday et al, 2003). In ferrets, this tumor mainly occurs in the vertebral column, but also occurs in the sacrococcygeal and sphenooccipital regions (Heffelfinger et al, 1973; Koestner et al, 1999; Koestner et al, 2002).
Ferrets (Mustela putorius furo) share many anatomical, metabolic, and physiologic features with humans, which has promoted their use as an animal model. Ferrets are used in biomedical research in a wide variety of studies including cardio-pulmonary, neurological, and gastrointestinal research (Willias and Barrow, 1971). In addition, the ferret is an important experimental animal model for influenza virus (Maher and DeStefano, 2004; van den Brand et al., 2010).
This report describes the clinical presentation and histopathological findings of chordoma in a ferret and discusses the differential diagnosis.

Materials and Methods

A 3-year-old, 0.74 kg spayed female ferret presented with a mass in the end of the tail. The ferret was housed in indoor, was fed with a commercial ferret formula and had free access to water. General condition was good with no previous history of any disease. For light microscopy, the entire mass was removed and fixed in 10% phosphate-buffered formalin. Fixed tissue was processed by conventional methods and stained with hematoxylin-eosin (H-E), periodic acid-Schiff (PAS), and toluidine blue. Frozen sections of mass were stained with Sudan III to demonstrate lipids in the cytoplasm.
Immunohistochemical labeling was performed on formalin-fixed, paraffin wax-embedded sections with the avidin-biotin-complex technique. Sections were deparaffinized and placed in citrate buffer at pH 6.0 for microwave antigen retrieval. Then, slides were incubated with 3% hydrogen peroxide to inactivate endogenous peroxidase activity, followed by several washes in phosphate-buffered saline (PBS). After incubation, the sections were covered with 10% goat normal serum for 30 min and incubated overnight with anti-vimentin (1:200, Dako, Glostrup, Denmark) and S-100 (1:200, Millipore, Billerica, MA, USA). Sections were washed with PBS and incubated with biotinylated anti-mouse IgG (Vector, Burlingame, CA, USA) and peroxidase conjugated strepavidin (Vector) for 30 min, respectively. Diaminobenzidine (DAB) kits (Vector) were used as a substrate for the peroxidase reaction. After developing, the sections were counterstained with hematoxylin and coverslipped.

Results

A physical examination revealed a normal condition. Grossly, an expansile, well-defined solitary mass (1.9×1.6×1.3 cm) was located at the end of the tail. The cut-surface of the mass was lobulated, rubbery-firm, with partly solid regions, and grayish-white in color. The margins were impossible to delineate (Figure 1).
Histopathological examination of the mass revealed a loosely packed, nodular, unencapsulated neoplasm within the dermis. Neoplastic cells were arranged in single or multiple rows between skeletal muscle bundles and fibrous stroma. They were varying from well-circumscribed lesions to tumors having highly infiltrative borders. Cartilage and trabecular bone formation was visible in the center of the mass. The neoplastic cells surrounding the cartilage and trabecular bone caused substantial changes to the bone (Figures 2A, 2B). Most of the subcutaneous tissues and trabecular bone with marrow was destroyed and replaced by tumor cells (Figure 2A). And the tumors grew into the bone marrow cavity with substantial changes of trabecular bone (Figure 2B). Accumulation of extracellular basophilic matrix, interpreted as mucin, was present within most lobules (Figure 2C). The matrix was stained metachromatically with toluidine blue (Figure 2D). The tumors were composed of closely packed adipocyte-like vacuolated polyhedral cells, usually described as physaliferous (having bubbles or vacuoles). The cells showed centrally or eccentrically located, round nuclei and eosinophilic cytoplasm with large vacuoles. Nuclei were small, round to oval, and centrally or eccentrically located (Figure 2E). The cytoplasm of the large tumor cells was eosinophilic and heavily vacuolated. These vacuoles stained weakly with PAS (data not shown), but negative for Sudan III staining (Figure 2F). Immunohistologically, many neoplastic cells were positive for vimentin (Figure 3A) and S-100 protein (Figure 3B).

Discussion

The present report describes a case of chordoma in the tail of a ferret. Chordoma is a rare neoplasm that arises from intraosseous remnants of the notochord and is characterized by dual expression of epithelial and mesenchymal proteins (Dunn et al, 1991).
Chordoma has been described in dogs, cats, rats, and mink (Volpe et al, 1983). Ferrets appear predisposed to developing tumors of this type. Chordoma commonly arise in the sacrococcygeal region, but they may also occur in the sphenooccipital region and rarely in other locations (Koestner et al, 2002). In rats, the tumor is most commonly located in lumbosacral vertebrae (Stefanski et al, 1988). Only 2 cases of feline chordoma have developed in the cervical and coccygeal region (Carpenter et al, 1990; Carminato, 2008). In dogs, not only the cervical and sacrococcygeal vertebrae, but also brain, spinal cord, and skin are reported sites for chordoma (Jabara et al, 1971; Pease et al, 2002; Munday et al, 2003). In our case, the tumor arose in the coccygeal vertebrae.
For the differential diagnosis of chordoma, lipo(sarco)ma, myxosarcoma, poorly differentiated chondrosarcoma, infiltrating lipoma, mucinous adenocarcinoma, and sebaceous carcinoma should be considered. Laboratory findings are not helpful in the differential diagnosis of chordoma. A definitive diagnosis of chordoma can only be made based on histopathology. Chordomas have distinct features such as flame figures in histopathologic lesions. The tumors were composed of closely packed adipocyte-like vacuolated cells (physaliferous cells). The nuclei were located centrally or eccentrically and the cytoplasm contained large vacuoles. Fibrous tissues contained abundant extracellular basophilic material that was consistent with mucin (Munday et al, 2004).
For accurate diagnosis, immunohistochemical studies are necessary. On immunohistochemistry, physaliferous cells show dual expression of cytokeratin and vimentin intermediate filaments and sporadically express S-100 protein (Nakajima et al, 1982). This feature offers a clear differentiation from other tumors. In the present study, many neoplastic cells expressed vimentin and S-100 protein (Dunn et al, 1991), which can be helpful in distinguishing chordomas from chordoma with chondroid differentiation (Ishida et al, 1994).
Limited information is available on the treatment of chordoma. They are best treated by aggressive surgical removal. The rate of recurrence after surgical removal is high in human chordomas (Heffelfinger et al, 1973). One canine chordoma, reported in 1933, recurred 12 days after surgery, and the neoplasm returned to presurgical size after 30 days (Ball et al, 1933). Complete surgical resection followed by radiation therapy offers the best chance of long-term control in humans. In addition, human chordomas most commonly metastasize to the lung, skeleton, and liver (Volpe et al, 1983). Metastases to the lung were reported in 75% of rats (Stefanski et al, 1988), and the single feline case metastasized to a local lymph node (Carpenter et al, 1990). Adjacent cutaneous metastasis was observed in ferrets (Munday et al, 2004).
In conclusion, a grayish-white, expansile, subcutaneous softtissue mass was observed in the tail of a ferret. Histopathologically, the tumor was composed of closely packed adipocyte-like vacuolated cells (physaliferous cells) that were positive for vimentin and S-100 immunohistochemically. Based on the histopathologic findings and special staining characteristics, this case was diagnosed as a chordoma.

Acknowledgment

This research was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (2010-0011450).

References

1. Ball V, Auger L. Les chordomas su tumeurs de la dorsal chez l'homme et les animaux. Rev Vet Zootech. 1933; 85:185–195.
2. Carminato A, Marchioro W, Melchiotti E, Vascellari M, Mutinelli F. A case of coccygeal chondroid chordoma in a cat: morphological and immunohistochemical features. J Vet Diagn Invest. 2008; 20(5):679–681. PMID: 18776111.
crossref
3. Carpenter JL, Stein BS, King NW Jr, Dayal YD, Moore FM. Chordoma in a cat. J Am Vet Med Assoc. 1990; 197(2):240–242. PMID: 2384326.
4. Dunn DG, Harris RK, Meis JM. Sweet DE. A histomorphologic and immunohistochemical study of chordoma in twenty ferrets (Mustela putorius furo). Vet Pathol. 1991; 28(6):467–473. PMID: 1722924.
5. Zaki FA. Spontaneous central nervous system tumors in the dog. Vet Clin North Am. 1977; 7(1):153–163. PMID: 191973.
crossref
6. Hadlow WJ. Vertebral chordoma in two ranch mink. Vet Pathol. 1984; 21(5):533–536. PMID: 6485214.
crossref
7. Heffelfinger MJ, Dahlin DC, MacCarty CS, Beabout JW. Chordomas and cartilaginous tumors at the skull base. Cancer. 1973; 32(2):410–420. PMID: 4722921.
crossref
8. Herron AJ, Brunnert SR, Ching SV, Dillberger JE, Altman NH. Immunohistochemical and morphologic features of chordomas in ferrets (Mustela putorius furo). Vet Pathol. 1990; 27(4):284–286. PMID: 2402855.
9. Ishida T, Dorfman HD. Chondroid chordoma versus low-grade chondrosarcoma of the base of the skull: can immunohistochemistry resolve the controversy? J Neurooncol. 1994; 18(3):199–206. PMID: 7525890.
crossref
10. Jabara AG, Jubb KV. A case of a probable chordoma in a dog. Aust Vet J. 1971; 47(8):394–397. PMID: 5106797.
crossref
11. Koestner A, Bilzer T, Fatzer R, Schulman FY, Summers BA, Van Winkle TJ. Schulman FY, editor. Local extensions of regional tumors. World Health Organization Histologic Classification of Tumors of Domestic Animals. 1999. 2nd ed. Washington DC: Armed Forces Institute of Pathology;p. 35–36.
12. Koestner A, Higgins RJ. Meuten DJ, editor. Tumors of the nervous system. Tumors in Domestic Animals. 2002. 4th ed. Iowa: Iowa State Press;p. 728–729.
crossref
13. Maher JA, DeStefano J. The ferret: an animal model to study influenza virus. Lab Anim (NY). 2004; 33(9):50–53. PMID: 15457202.
crossref
14. Munday JS, Brown CA, Richey LJ. Suspected metastatic coccygeal chordoma in a ferret (Mustela putorius furo). J Vet Diagn Invest. 2004; 16(5):454–458. PMID: 15460332.
15. Munday JS, Brown CA, Weiss R. Coccygeal chordoma in a dog. J Vet Diagn Invest. 2003; 15(3):285–288. PMID: 12735353.
crossref
16. Nakajima T, Watanabe S, Sato Y, Kameya T, Hirota T, Shimosato Y. An immunoperoxidase study of S-100 protein distribution in normal and neoplastic tissues. Am J Surg Pathol. 1982; 6(8):715–727. PMID: 6301296.
crossref
17. Pease AP, Berry CR, Mott JP, Peck JN, Mays MB, Hinton D. Radiographic, computed tomographic and histopathologic appearance of a presumed spinal chordoma in a dog. Vet Radiol Ultrasound. 2002; 43(4):338–342. PMID: 12174996.
crossref
18. Stefanski SA, Elwell MR, Mitsumori K, Yoshitomi K, Dittrich K, Giles HD. Chordomas in Fischer 344 rats. Vet Pathol. 1988; 25(1):42–47. PMID: 3344569.
crossref
19. van den Brand JM, Stittelaar KJ, van Amerongen G, Rimmelzwaan GF, Simon J, de Wit E, Munster V, Bestebroer T, Fouchier RA, Kuiken T, Osterhaus AD. Severity of pneumonia due to new H1N1 influenza virus in ferrets is intermediate between that due to seasonal H1N1 virus and highly pathogenic avian influenza H5N1 virus. J Infect Dis. 2010; 201(7):993–999. PMID: 20187747.
crossref
20. Volpe R, Mazabraud A. A clinicopathologic review of 25 cases of chordoma (a pleomorphic and metastasizing neoplasm). Am J Surg Pathol. 1983; 7(2):161–170. PMID: 6859391.
21. Williams BH, Eighmy JJ, Berbert MH, Dunn DG. Cervical chordoma in two ferrets (Mustela putorius furo). Vet Pathol. 1993; 30(2):204–206. PMID: 7682370.
22. Willis LS, Barrow M. The ferret (Mustela putorius furo L.) as a laboratory animal. Lab Anim Sci. 1971; 21(5):712–716. PMID: 4329234.
Figure 1
Gross appearance of the mass in the tail of a three-year-old female ferret. Bar=5 mm. (A) Grossly, an expansile, well-defined solitary mass is located at the end of the tail. (B) Cross-section across the middle of the fixed mass showing an infiltrative pattern with an irregular border. Bar=10 cm.
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Figure 2
Histopathological lesions of the tumor. (A) Most of the subcutaneous tissues and trabecular bone (T) with marrow is destroyed and replaced by tumor cells. H-E stain, Bar=500 µm. (B) The tumor cells grow into the bone marrow cavity with substantial changes of trabecular bone. H-E stain, Bar=500 µm. (C) Tumor cells are arranged within poorly defined lobules. Within the lobules, pleomorphic cells contain large vacuoles and small dark, centrally located nuclei (physaliferous cells). Also an interlobular amorphous matrix is visible. H-E stain, Bar=500 µm. (D) Between the lobules matrix containing mucin is highlighted with toluidine blue staining. Bar=100 µm. (E) Physaliferous cells contain large clear cytoplasmic vacuoles and small dark nuclei are visible. H-E stain, Bar=50 µm. F) Sudan III staining was negative for lipid. Bar=100 µm.
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Figure 3
Photographs of the tumor with immunohistochemical stains. (A) Immunohistochemistry for vimentin shows diffuse positive reactions. (B) Immunohistochemistry for S-100 protein shows diffuse positive reactions. ABC method, Bar=100 µm.
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