Abbreviations
HPCy: Hemangiopericytoma
DSH: Domestic short-haired
CBC: Cell blood count
Introduction
Hemangiopericytoma (HPCy) is a common neoplasm in middle-aged or older dogs [ 1 , 2 ]. These tumors represent 7% of canine cutaneous tumors and are most often found in the lower extremities [ 3 ]. According to the literature, it is uncommon in cats [ 4 ]. It accounts for around 2.5 percent of all soft tissue sarcomas in humans and is classified as a malignant neoplasm [ 3 ]. HPCys [ 1 , 5 ] are a kind of soft tissue sarcoma that arises from vascular pericytes. HPCy is a locally infiltrative tumor that recurs following surgical excision on rare occasions, although it seldom metastasizes [ 4 ]. These tumors usually appear as solitary, well-circumscribed, lobulated, and pseudocapsulated masses of gray-white to red-brown color, occasionally reaching considerable dimensions [ 3 , 4 ]. The hallmark of this tumor microscopically is whorls around blood vessels and the ‘‘fingerprint’’ pattern formed by the neoplastic cells [ 2 , 4 , 6 ]. It should be differentiated from endothelioma, angiosarcoma, fibrosarcomas, leiomyosarcomas, schwannoma, peripheral nerve sheath tumor, and seldom dermatofibrosarcoma (a variant of malignant fibrous histiocytoma) and, maybe, glomus tumor [ 5 , 6 ]. The definitive diagnosis of HPCy is immunohistochemical findings [ 4 ]. This study describes a case report of hemangiopericytoma in a domestic short-haired (DSH) cat referred to a veterinary clinic, Iran.
Case Presentation
A two-year-old female DSH cat weighing 3.5 kg was presented to a veterinary hospital, Tehran, Iran, with clinical signs of lateral recumbency position, anorexia, and abdominal enlargement. The owner assumed she was pregnant because of her swollen abdomen. The queen was highly lethargic and dehydrated, with a pale mucous membrane, a rectal temperature of 37.3 °C, and no vaginal discharge during the first inspection. Cell blood counts (CBC) and biochemical profiles were determined using a blood sample (Table 1). An ultrasonographic examination showed a heterogeneous mass with a nearly distinct border. The mass was evaluated using Doppler, and power Doppler revealed significant vascularity in the mass (Figure 1). Medetomidine (0.02 mg/kg) was used to pre-anesthetize the patient. After injection of diazepam (0.2 mg/kg, IV) and ketamine hydrochloride (6 mg/kg, IV), the patient was intubated and positioned in a dorsal recumbency position. Anesthesia was maintained by isoflurane (1.5%) inhalation. After the aseptic preparation of the surgical region, the midline incised from the xiphoid to a midline point between the umbilicus and pubis. A large soft tissue mass was in the abdominal cavity and around the lumbar vertebral column, and the uterus and other abdominal organs’ appearance were grossly normal. Due to a huge and encroaching tumor and the patient's owner's refusal to accept any further therapies, the queen was euthanized during an exploratory celiotomy. The mass was removed and shown to be white, multilobulated, and enormous, weighing around 900 grams (Figure 2A, 2B ). The specimens of mass were fixed in 10 percent formalin for histological analysis. The tissue specimens were placed in ethanol (70% for 24 h, 90% for 1 h, and 100% for 1 h) for graded dehydration, then cleaned in xylene and embedded in paraffin. Sections were made at 5 µm thickness, stained with hematoxylin and eosin for the histopathological evaluation. Immunohistochemical analysis was performed to differentiate the tumor from the peripheral nerve sheath tumor and confirm the histopathological diagnosis. On formalin-fixed, paraffin-embedded tissues, immunohistochemistry expression of S-100 protein was performed, and the sections were processed using the avidin-biotin-peroxidase complex method. Histopathologically, the tissue sections showed that the tumor contained multiple layers of spindle-shaped cells arranged around a central thin-wall vessel, a fingerprint pattern, with the collagenous stroma. The neoplastic cells had homogenous eosinophilic cytoplasm with prominent nuclei. The mitotic figures were rare (Figure 2C, 2D). By the immunohistochemical examination, the tumor cells stained negative for S-100 protein (Figure 2E). Based on histopathological and immunohistochemical findings, an HPCy was diagnosed.
Hematology | Value | Unit | Reference Range |
---|---|---|---|
HCT | 31 | % | 37-55 |
Hb | 102 | g/l | 120-180 |
RBC | 4.77 | ×1012cell/l | 5.5-8.5 |
MCV | 65 | fl | 60-72 |
MCH | 25 | Pg | 21-26 |
MCHC | 330 | g/l | 310-360 |
NRBC | 0 | cell/100 wbc | 0-1 |
Reticulocyte | 0.7 | % | 1: None Regenerative |
1-4: Week Regenerative | |||
5-20: Moderate Regenerative | |||
21-50: Strong Regenerative | |||
PLT | 750 | ×109cell/l | 150-500 |
WBC | 18.6 | ×109cell/l | 4.5-17 |
Neutrophil | 12.7 | ×109cell/l | 3-11.5 |
Lymphocyte | 3.35 | ×109cell/l | 1-4.8 |
Monocyte | 1.8 | ×109cell/l | 0-1.3 |
Eosinophil | 0.3 | ×109cell/l | 0.1-1.2 |
Basophil | 0 | ×109 cell/l | 0-0.1 |
Band Neutrophil | 0.45 | ×109cell/l | ˂0.3 |
Total Protein | 94 | g/l | 54-74 |
Albumin | 37 | g/l | 27-45 |
Globulin | 57 | g/l | 19-37 |
BUN | 310 | mg/l | 70-280 |
Creatinine | 12 | mg/l | 3-13 |
ALP | 267 | IU/l | 10-140 |
ALT | 55 | IU/l | 17-95 |
AST | 39 | IU/l | 5-65 |
GGT | 2 | IU/l | 0-8 |
Total Bilirubin | 1 | mg/l | 0-4 |
Glucose | 1410 | mg/l | 750-1300 |
Triglyceride | 830 | mg/l | 290-1200 |
Cholesterol | 1970 | mg/l | 1300-3700 |
Na | 151 | mEq/l | 145-150 |
K | 4.1 | mEq/l | 3.9-5.5 |
Cl | 109 | mEq/l | 106-127 |
Corrected Chloride | 112 | mEq/l | 107-113 |
Total Ca | 119 | mg/l | 90-115 |
Ionized Ca | 62 | mg/l | 50-58 |
P | 37 | mg/l | 28-61 |
Serum Iron | 690 | µg/l | 970-2630 |
TIBC | 2970 | µg/l | 2800-4890 |
Transferrin Saturation | 23.23 | % | 27-66 |
ACTH Stimulation Test | |||
Basal cortisol | 50 | µg/l | 20-60 |
1 Hour after Injection | 170 | µg/l | 60-180 |
HPCy has been found in both dogs and men [ 5 ]. It is, however, infrequently documented in cats [ 3 ]. HPCy is most often observed in the legs and hindlimbs of both humans and dogs [ 6 ]. In cats, it is seen on the thoracic side and the left thigh, according to prior case reports [ 3 , 5 ]. In dogs, metastatic HPCy is unusual [ 6 ], with just 5 individuals having metastasized to the lungs, sublumbar lymph nodes, or chest [ 7 - 10 ], whereas in men, the metastatic rate ranges from 11.7 percent to 56.5 percent [ 6 ]. Dogs have a broad variety of recurrence rates (ranging from 26 to 60%) [ 6 ]. In a DSH cat, it was found in the belly cavity and surrounding the lumbar spinal column.
In our study, the preoperative findings were in terms of the physical examination, ultrasonography, CBC, and serum biochemical profile (Table 1). Mild normocytic normochromic- non-regenerative anemia (because of mild anemia: HCT 31, MCV normal, normochromic: MCHC normal) besides low serum iron concentration and low TIBC indicates anemia due to chronic disease or acute inflammation. Neutrophilic leukocytosis with monocytosis and left shift indicates chronic active inflammatory response which is anticipated from the case presentation with inflammatory/neoplastic reaction. Hyperproteinemia regarding the hyperglobulinemia and normal serum albumin concentration is compatible with active antigenic stimulation by neoplastic tissue. Differential diagnoses of hypercalcemia and normophosphatemia (increased total and ionized serum Ca2+ concentration alongside normal serum phosphorus concentration), regarding the case history, were hypoadrenocorticism and focal osteolytic lesions [ 11 ]. Hypoadrenocorticism was ruled out by an ACTH stimulation test and a normal Na/K concentration. As a result, hypercalcemia and normophosphatemia are thought to be associated with localized spinal bone osteolysis caused by tumor invasion. The liver and renal functions were found to be normal. The tumor's intra-abdominal or bone metastatic pathology may cause a moderate (less than 3 times) rise in serum ALP activity. Thrombocytosis may occur because of inflammation.
Based on these findings, the abdominal tumor's presumptive diagnosis was made, but we performed the histopathological and immunohistochemical studies for the definitive diagnosis. Microscopically, whorls around blood vessels and the "fingerprint" pattern have been identified as a feature of this tumor [ 2 , 4 , 6 ]. The tissue slices in this research had a hypercellular pattern that looked like a fingerprint, which is a common occurrence. In canines and men, HPCy histopathological categorization is a valuable diagnostic technique for predicting prognosis, recurrence, and metastatic rates. Based on tissue differentiation, mitotic count, and necrosis quantification, this categorization might range from grade I to III (poor diagnostic) [ 1 , 12 ]. The tumor showed features consistent with grade II in this case. As it is mentioned previously, immunohistochemistry is useful in ruling out other spindle cell tumors, which present the same whorl pattern [ 4 , 6 ]. The neoplastic cells stained positively for vimentin, anti-muscle actin, and laminin and negative for S-100 protein, factor VIII-related antigen, lysozyme, and UEA I lectin [ 2 , 4 , 5 , 6 , 13 ]. S-100 is detected in 100% of schwannomas, 100% of neurofibromas (weaker than schwannomas), 50% of malignant peripheral nerve sheath tumors (may be weak and/or localized), paraganglioma stromal cells, histiocytoma, and clear-cell sarcomas [ 14 ]. The absence of immunoreactivity against S-100 helped rule out a diagnosis of other soft tissue sarcomas.
Treatment options for HPCy include surgery and radiation. Chemotherapy and other systemic therapies have had mixed results [ 15 ]. Without radiation, the canine HPCy recurrence rate was found to be 26 percent [ 9 ] and 38 percent [ 16 ]. Meantime to recurrence with or without radiotherapy after surgery 27 and 16 months, respectively. Maruo et al. suggested that conservative resection and intraoperative radiotherapy may control local tumors (e.g HPCy) without an adequate margin [ 1 ]. Baldi et al. used electrochemotherapy for the treatment of thoracic HPCy in a cat. Electrochemotherapy is a new treatment for tumors [ 5 ].
In conclusion, a hemangiopericytoma was diagnosed based on the physical examination, radiography, ultrasonography, histomorphology, and immunohistochemical reactivity in the cat. To the authors' knowledge, this is the third reported hemangiopericytoma and the largest among them in cats. This tumor is rare in cats; therefore, the diagnosis of HPCy in cats needs more information.
Authors' Contributions
ESJ and HK performed review literature and manuscript writing. MM and FN performed the pathological analysis MH examined the animal and performed review literature. FH performed surgery, review litera, ture, and manuscript writing.
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