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Fibrosarcoma

Fibrosarcoma is a rare and aggressive malignant arising from fibroblasts, the cells responsible for producing in connective tissues, typically presenting as a tumor composed of spindle-shaped cells arranged in a characteristic "herringbone" . It accounts for approximately 3.6% of all adult sarcomas and less than 5% of primary tumors. Primarily affecting middle-aged and older adults, with a slight predominance in males, fibrosarcoma is exceptionally uncommon in children, where it manifests as a distinct infantile or congenital form of intermediate . The of fibrosarcoma remains largely idiopathic, though it is associated with prior , chronic bone damage, formation, or implantation, potentially leading to genetic in mesenchymal cells. Pathophysiologically, these tumors originate in deep soft tissues such as , tendons, or , or within , exhibiting variable production and a propensity for high-grade in about 80% of cases. Clinically, patients often present with a painless, firm subcutaneous or deep-seated mass measuring 3 to 8 cm, which may cause symptoms of such as nerve entrapment, vascular obstruction, or, in bony involvement, chronic dull pain; advanced disease can lead to systemic effects like and anorexia. Diagnosis requires a multimodal approach, beginning with imaging—magnetic resonance imaging () is preferred for delineating extent, while computed tomography () aids in bony lesions—followed by core needle or CT-guided for histopathological confirmation, revealing the herringbone architecture and positive immunohistochemistry for . Treatment centers on wide surgical resection with negative margins (R0 resection) as the cornerstone, often supplemented by adjuvant radiotherapy for high-grade tumors exceeding 5 cm or those in anatomically challenging locations; , primarily doxorubicin-based regimens, is reserved for metastatic or unresectable cases due to limited response rates. Prognosis is generally poor, with 5-year overall survival rates ranging from 40% to 60%, a recurrence risk of 40% to 50%, and occurring in 9% to 63% of cases, most commonly to the lungs and bones; infantile variants carry a more favorable outlook with lower malignancy. Emerging explores targeted therapies, with ongoing clinical trials and a 2025 approval in for anlotinib (a multi-target ) combined with chemotherapy in advanced sarcomas, aiming for improved outcomes.

Definition and Classification

Definition

Fibrosarcoma is a rare malignant composed primarily of malignant fibroblasts with variable production, exhibiting a characteristic "herringbone" architectural pattern formed by interlacing bundles of spindle-shaped cells. It arises from the fibrous and is classified as a within the fibroblastic and myofibroblastic tumor category. The term fibrosarcoma emerged in the amid advances in cellular , which enabled pathologists to distinguish sarcomas from carcinomas based on their mesenchymal versus epithelial origins. Early descriptions encompassed a broad range of fibrous tumors, but the modern conceptualization was established by Purdy Stout in 1948, who provided a foundational classification emphasizing the tumor's fibroblastic nature. The 2020 (WHO) classification of and bone tumors further refined this entity by narrowing its diagnostic criteria to exclude mimics, such as , through integrated histological, immunohistochemical, and molecular features. Key characteristics of fibrosarcoma include aggressive local invasion and a notable potential for distant , particularly to the lungs. These tumors typically develop in the deep soft tissues of the , , or head and neck, though they can occasionally involve . Fibrosarcoma encompasses distinct subtypes, including adult-type and infantile-type, each with specific clinicopathologic profiles.

Types

Fibrosarcomas are primarily classified into two main types based on age of onset, histological features, and clinical behavior: adult-type fibrosarcoma and infantile-type fibrosarcoma. Adult-type fibrosarcoma typically affects individuals over 30 years of age, with a peak incidence between 40 and 55 years, and is characterized by uniform cells arranged in a distinctive on ; it lacks recurrent specific genetic alterations and is often a after ruling out other fibroblastic tumors. These tumors often arise in the deep soft tissues of the , particularly the lower limbs, or the trunk, though primary intraosseous occurrences in bones such as the , , or have been reported as a rare variant, with radiological features that may resemble . Infantile-type fibrosarcoma, also known as congenital fibrosarcoma, predominantly occurs in children under 1 year of age, with about 75% of cases diagnosed in the first year of life, and features primitive mesenchymal cells that are ovoid, round, or spindle-shaped, often with high vascularity exhibiting hemangiopericytoma-like vessels; it is characterized by a recurrent ETV6-NTRK3 gene fusion in nearly all cases. These tumors commonly develop in the soft tissues of the and are associated with a more favorable compared to the adult type. Certain rare variants exist, such as sclerosing epithelioid fibrosarcoma, which shows epithelioid cells in a collagenous stroma, but myxofibrosarcoma, despite histological overlap with myxoid areas and curvilinear vessels, is now excluded from fibrosarcoma classification in favor of its distinct entity status per current guidelines.

Signs and Symptoms

Adult-Type

Adult-type fibrosarcoma typically manifests in adults aged 35 to 55 years, with a slight male predominance. It most commonly arises in the deep soft tissues of the thighs, posterior region, or . Patients usually present with a painless, firm, palpable mass that grows slowly over several months, often measuring 5 to 10 cm at the time of detection. As the tumor enlarges, it may cause additional symptoms due to , such as if it compresses nearby , along with potential paresthesias or restricted . The tumor exhibits aggressive local behavior, frequently invading surrounding muscle or, less commonly, adjacent . When arising primarily in , particularly the long of the lower , patients may experience local , swelling, limitation of motion, and pathological .

Infantile-Type

Infantile fibrosarcoma typically presents as a rapidly enlarging, firm, and mobile mass that is often detected at birth or within the first year of life, with approximately one-third of cases identified congenitally and 14% noted prenatally via . It most commonly arises in the distal extremities, such as the hands and feet, though it can also occur in the proximal limbs, trunk, or head and neck regions. The primary symptom is a non-tender swelling that may cause functional impairment, including limited joint movement or difficulty with if located in an extremity, due to the mass's size and local invasion of surrounding tissues. Pain is uncommon, as the tumor is often superficial and does not compress significantly, though rare cases may involve intratumoral hemorrhage leading to . In newborns, exceptional presentations include hypercalcemia from elevated .

Causes and Risk Factors

Etiology

Fibrosarcoma primarily arises from mutations in cells within mesenchymal tissues, resulting in uncontrolled cellular and tumor formation. These mutations disrupt normal regulatory pathways in fibroblasts, leading to the of malignant spindle-cell neoplasms. Genetic alterations differ markedly between infantile and adult types of fibrosarcoma. In infantile fibrosarcoma, the ETV6-NTRK3 gene fusion, resulting from a t(12;15)(p13;q25) translocation, is identified in approximately 90% of cases and drives oncogenesis through activation of neurotrophic receptor signaling. In contrast, adult-type fibrosarcoma typically exhibits complex karyotypes with multiple chromosomal abnormalities and frequent TP53 mutations, which contribute to genomic instability and tumor progression. Environmental triggers, particularly prior exposure to , play a role in a subset of cases. Therapeutic for other malignancies is associated with a small proportion of fibrosarcoma cases (less than 5% of sarcomas overall), with a typical period of 5-20 years post-exposure.

Risk Factors

Fibrosarcoma exhibits a bimodal age distribution, with peaks in infancy and adulthood. The infantile form predominantly affects children under 1 year of age, with a median age at of 3 to 4 months and approximately 75% of cases occurring during the first year of life. In contrast, the adult form typically presents between 30 and 60 years of age, with a peak incidence in the fourth to sixth decades. There is a slight male predominance in adult cases, with male-to-female ratios around 1.1:1 to 1.5:1 observed in population studies. Certain genetic syndromes confer a rare but increased risk for developing fibrosarcoma. type 1 (NF1), an autosomal dominant disorder caused by mutations in the NF1 gene, is associated with a 10% lifetime risk of of neurofibromas into sarcomas, including fibrosarcoma or malignant peripheral nerve sheath tumors with fibrosarcomatous features. Li-Fraumeni syndrome (LFS), resulting from germline TP53 mutations, elevates the overall risk of sarcomas, including fibrosarcoma, as part of its predisposition to multiple cancers. These associations are uncommon, and most fibrosarcoma cases arise sporadically without identifiable genetic syndromes. Occupational and environmental exposures to certain chemicals have been investigated as potential risk factors, though evidence remains limited and inconsistent for fibrosarcoma specifically. Studies on sarcomas, including fibrosarcoma subtypes, suggest a possible weak association with prolonged exposure to phenoxyherbicides (such as 2,4,5-T) and chlorophenols, particularly among agricultural or workers. Similarly, exposure to , a compound used in , has been linked to increased sarcoma risk in some cohort studies, but causality for fibrosarcoma is not firmly established. These findings are derived largely from case-control research on broader categories, and confounding factors like or other exposures complicate interpretations. Prior exposure to , such as therapeutic radiation for other cancers, is a recognized for secondary fibrosarcoma development in previously irradiated tissues, though this is addressed in detail under .

Pathophysiology

Cellular Origin

Fibrosarcoma arises from the of fibroblasts or myofibroblasts within fibrous , tendons, or ligaments. These spindle-shaped cells, derived from mesenchymal origins, exhibit uncontrolled , leading to the formation of sarcomatous tumors primarily in deep soft tissues. The degree of cellular differentiation in fibrosarcoma varies by subtype. In adult-type fibrosarcoma, tumor cells demonstrate greater maturity, often producing variable amounts of and displaying a herringbone architectural pattern indicative of fibroblastic . In contrast, infantile-type fibrosarcoma consists of primitive, immature fibroblastic cells that are largely undifferentiated, arranged in highly cellular sheets or fascicles with minimal pleomorphism and a myxoid or collagenous stroma. Primary intraosseous fibrosarcoma, a rarer variant, originates from fibroblasts in the or of , distinguishing it from the more common soft tissue forms by its direct osseous involvement and osteolytic growth pattern.

Tumor Characteristics

Fibrosarcoma tumors typically present macroscopically as firm, white to tan-gray masses with a whorled or fleshy cut surface, often measuring 5 to 20 cm in diameter, though smaller lesions around 3 to 8 cm are also common. Despite appearing well-circumscribed, these tumors exhibit infiltrative borders and nonencapsulated growth, with possible areas of hemorrhage or on gross examination. Microscopically, fibrosarcomas, particularly the adult type, are composed of malignant spindle-shaped fibroblastic cells arranged in interlacing fascicles, often forming a characteristic with variable production between the cells. The cells feature scant , elongated nuclei with tapered ends, and granular ; mitotic activity is moderate, typically ranging from 5 to 10 mitoses per 10 high-power fields (HPF), with occasional atypical forms. Low-grade tumors show scant , while higher-grade variants may exhibit more prominent areas of . Grading of fibrosarcoma follows the French Fédération Nationale des Centres de Lutte Contre le Cancer (FNCLCC) for sarcomas, which assesses tumor differentiation, mitotic count, and to classify tumors as grade 1 (low), 2 (), or 3 (high). Fibrosarcomas are often grade (grade 2), though approximately 80% are high-grade (grade 2 or 3) at .

Diagnosis

Imaging Techniques

Imaging plays a crucial role in the detection, , and staging of fibrosarcoma, a rare malignant tumor arising from fibroblasts. Non-invasive modalities such as (MRI), computed (CT), and positron emission -computed (PET-CT) are employed to assess tumor extent, involvement of adjacent structures, and metastatic spread, guiding subsequent for histological confirmation. MRI is the preferred imaging modality for evaluating fibrosarcomas due to its superior for musculoskeletal structures. On T1-weighted images, fibrosarcomas typically appear hypointense or isointense relative to , while T2-weighted images show heterogeneous hyperintense signal intensity, often with low-signal band-like fibrous streaks reflecting the tumor's collagenous matrix. Post- administration reveals heterogeneous enhancement, which may be peripheral or exhibit a spoke-wheel , highlighting viable tumor components; associated peritumoral muscle is common. -weighted imaging often demonstrates restricted in solid areas. These features aid in delineating tumor margins and fascial involvement, though findings are nonspecific and overlap with other sarcomas. CT is particularly useful for assessing fibrosarcomas with potential involvement, such as cortical or periosteal reaction, and for detecting calcifications in osseous variants. Tumors generally present as isoattenuating masses relative to muscle density, with possible hypoattenuating necrotic areas or hyperattenuating fibrous components in advanced lesions. CT excels in evaluating chest, , and for distant metastases, complementing MRI when bony or calcific changes are suspected. PET-CT, utilizing 18F-fluorodeoxyglucose (FDG), is valuable for fibrosarcomas by identifying metabolically active metastases, particularly in lungs, bones, and nodes. FDG uptake correlates with tumor , with high-grade fibrosarcomas showing moderate to intense and maximum standardized uptake values (SUVmax) typically ranging from 4 to 10, distinguishing them from low-grade lesions (SUVmax often <4). This modality helps in detecting occult metastases and assessing tumor aggressiveness noninvasively.

Histopathology and Biopsy

Diagnosis of fibrosarcoma requires histopathological examination of tissue obtained through biopsy, with core needle biopsy serving as the preferred initial method due to its minimally invasive nature and lower risk of tumor seeding compared to excisional biopsy. This approach allows for adequate sampling under imaging guidance while minimizing contamination of surrounding tissues, particularly important in soft tissue sarcomas where seeding along the biopsy tract can complicate subsequent surgical margins. Excisional biopsy may be considered for smaller lesions but is generally avoided to prevent potential dissemination of malignant cells. Histological evaluation reveals a proliferation of malignant spindle cells arranged in a characteristic herringbone or fascicular pattern, with interlacing bundles separated by collagenous bands that impart a fibrous texture to the tumor. The spindle cells exhibit fusiform nuclei with mild to moderate pleomorphism, prominent nucleoli, and scant eosinophilic cytoplasm, often accompanied by variable mitotic activity and areas of necrosis in higher-grade tumors. Accurate diagnosis relies on pattern recognition of these features, with differentiation from mimics such as leiomyosarcoma—characterized by smoother muscle-like fascicles and positivity for muscle markers—and malignant peripheral nerve sheath tumor (MPNST), which may show wavy nuclei and association with nerve tissue. Immunohistochemical staining supports the diagnosis by confirming mesenchymal origin, with strong positivity for vimentin in nearly all cases, reflecting the fibroblastic differentiation of the tumor cells. In contrast, stains for actin (including ) are typically negative, helping to exclude myogenic sarcomas like . Additional negative markers, such as for neural differentiation and desmin for muscle, further aid in distinguishing fibrosarcoma from and . For the infantile type, molecular testing is crucial to identify characteristic gene fusions, particularly ETV6-NTRK3, which occurs in over 90% of cases and guides targeted therapies like TRK inhibitors. Fluorescence in situ hybridization (FISH) targeting ETV6 or NTRK3 loci or next-generation sequencing (NGS) panels for fusion detection are recommended, with FISH offering high sensitivity for known partners and NGS providing broader screening for rare variants. These tests are especially valuable in pediatric presentations where histological overlap with other spindle cell tumors may occur.

Treatment

Surgical Approaches

Surgical resection remains the cornerstone of treatment for fibrosarcoma, aiming to achieve complete tumor removal while preserving function whenever possible. Wide local excision is the standard approach, involving the removal of the tumor along with a surrounding cuff of normal tissue to ensure negative margins and minimize local recurrence risk. This technique is applicable to most cases, particularly those in accessible locations such as the extremities, trunk, or head and neck, and is guided by preoperative imaging to plan the extent of resection. Wide local excision typically incorporates margins of 2-5 cm of healthy tissue beyond the palpable or radiographic tumor borders, depending on tumor grade, size, and location; for high-grade , wider margins (closer to 5 cm) are preferred to account for potential microscopic extension. This approach facilitates limb-sparing surgery in approximately 80-90% of extremity cases, allowing preservation of the affected limb through careful dissection that avoids major neurovascular structures. In infantile , which often presents in distal limbs, neoadjuvant chemotherapy may be used to shrink the tumor prior to excision, enabling non-mutilating wide local excision with adequate margins. Amputation is reserved for a minority of cases, comprising about 5-10% of presentations, particularly when the tumor is deemed unresectable with wide margins or involves critical neurovascular structures that cannot be spared without compromising oncologic outcomes. This is more common in advanced or recurrent disease where local control cannot be achieved through limb-preserving methods, though advances in multidisciplinary care have reduced its necessity over time. Post-resection reconstruction is essential to restore form and function, especially following wide excisions that create significant soft tissue defects. Techniques such as local or pedicled flaps, free tissue transfers, or skin grafts are employed, with particular emphasis on vascularized reconstructions in infantile distal limb tumors to support healing and growth in young patients. These methods, often combined with adjuvant therapies like radiation, help optimize cosmetic and functional results while maintaining oncologic safety.

Adjuvant Therapies

Adjuvant therapies for fibrosarcoma primarily include radiation therapy, chemotherapy, and targeted agents, employed to improve local control and address microscopic disease or metastases following surgical resection. These modalities are particularly indicated for high-grade tumors, incomplete margins, or unresectable cases, with selection guided by tumor histology, size, location, and patient factors such as age. Radiation therapy, typically external beam, is recommended postoperatively for high-grade fibrosarcomas larger than 5 cm or those with close/positive margins to reduce local recurrence risk. Standard dosing involves 50-60 Gy delivered in 1.8-2 Gy fractions, often with a boost to the tumor bed; preoperative radiation may be used neoadjuvantly to facilitate resection in borderline cases. Studies in soft tissue sarcomas, including fibrosarcoma subtypes, demonstrate that adjuvant radiation lowers local recurrence rates by approximately 20-30% compared to surgery alone, from baseline risks of 30-50%. Chemotherapy regimens, often doxorubicin-based, serve as adjuvant or neoadjuvant options for high-grade or metastatic fibrosarcoma, aiming to eradicate systemic micrometastases. Common protocols include doxorubicin combined with ifosfamide (AI) or dacarbazine, administered for 4-6 cycles; in infantile fibrosarcoma, neoadjuvant use with vincristine, actinomycin D, and cyclophosphamide (VAC) or similar can shrink unresectable tumors to enable surgery. Meta-analyses of adjuvant doxorubicin in high-grade soft tissue sarcomas report a 10-31% improvement in recurrence-free survival, though overall survival benefits are modest (hazard ratio 0.80). Targeted therapy with larotrectinib, a TRK inhibitor, is approved for NTRK gene fusion-positive fibrosarcomas, particularly the infantile subtype where fusions occur in up to 90% of cases. The FDA granted accelerated approval in 2018 based on trials showing an objective response rate of 75% in NTRK-fusion solid tumors, with durable responses (median >2 years) enabling limb-sparing surgery or treatment discontinuation in pediatric patients. Full approval followed in 2025, confirming efficacy across ages.

Prognosis and Outcomes

Survival Rates

Survival rates for fibrosarcoma vary significantly based on disease stage, patient age, and tumor type, with overall 5-year survival ranging from 57% in adults to 73% in pediatric cases according to Surveillance, Epidemiology, and End Results () program data spanning 1973-2008. For localized disease (stages I-II), 5-year survival rates are substantially higher, typically 75-87%, reflecting the efficacy of complete surgical resection in non-metastatic presentations. In contrast, metastatic disease (stage IV) is associated with markedly poorer outcomes, with 5-year survival dropping to 15-28%, as distant spread significantly limits curative options. Infantile fibrosarcoma, a subtype occurring in children under 2 years, demonstrates the most favorable prognosis among variants, with 5-year survival rates of 84-93% even in challenging cases managed conservatively. Adult fibrosarcoma, conversely, yields 5-year survival of 50-61%, influenced by tumor grade and histologic subtype, where higher-grade lesions portend worse outcomes. Historical analysis from the SEER database reveals progressive improvements in survival, particularly for adults, rising from 48% in 1973-1989 to 61% in 1990-2008, driven by enhanced diagnostic imaging and multimodal therapies; more recent National Cancer Database analyses up to 2019 report overall 5-year survival nearing 75%, suggesting ongoing advancements.

Factors Influencing Prognosis

Several tumor-related characteristics significantly influence the prognosis of fibrosarcoma. Tumors larger than 5 cm are associated with a higher risk of malignancy and poorer outcomes due to increased likelihood of metastasis and incomplete resection. High-grade tumors, which constitute approximately 80% of adult fibrosarcomas, exhibit aggressive behavior and are linked to reduced long-term survival rates, with 10-year survival below 30% for high-grade primary cases. Additionally, deep-seated tumors, such as those in intraosseous locations or deep soft tissues, portend a worse prognosis compared to superficial soft-tissue variants, owing to challenges in achieving wide surgical excision and higher metastatic potential. Patient-specific factors also play a critical role in determining fibrosarcoma outcomes. Individuals over 50 years of age generally face a less favorable than younger patients, as advanced age correlates with reduced tolerance to aggressive therapies and higher burdens in soft tissue sarcomas including fibrosarcoma. The presence of at markedly worsens , with rates below 55% at 5 years compared to localized disease, reflecting the aggressive systemic spread typical of advanced fibrosarcomas. In contrast, infantile fibrosarcoma, which occurs predominantly in children under 1 year, carries a more favorable outlook, with rare and exceeding 80% at 5 years when complete resection is feasible, highlighting the less aggressive biology of this subtype. Therapeutic response further modulates prognosis, particularly in molecularly defined subsets. For infantile fibrosarcomas harboring NTRK gene fusions—which are present in over 90% of cases—targeted therapies such as TRK inhibitors (e.g., or ) yield tumor shrinkage in approximately 70% of pediatric patients, substantially improving outcomes and enabling durable responses in fusion-positive tumors.

Epidemiology

Incidence in Humans

Adult-type fibrosarcoma is a rare , accounting for less than 1% of all soft tissue sarcomas (STS) and less than 0.01% of adult malignancies. Its annual incidence is estimated at less than 0.1 cases per 100,000 population (1 per million), with refined diagnostic classifications leading to declining recognition of the entity over recent decades as many cases are reclassified into other STS subtypes. In adults, fibrosarcoma predominantly affects individuals in middle age, with the majority of cases occurring between 30 and 60 years, representing about 40% of reported instances; it is rare in children and shows a slight male predominance. The infantile form, a distinct subtype, arises primarily in the first year of life and accounts for approximately 5-10% of all pediatric sarcomas, often presenting as a congenital or early-onset tumor. Geographic variation in fibrosarcoma incidence is modest, with slightly higher rates observed in Western countries likely due to improved diagnostic capabilities and registry data, while global patterns show no strong racial or ethnic disparities based on recent analyses from cancer registries.

Prevalence in Animals

Fibrosarcoma represents a significant in , particularly among domestic animals like and , where it arises from mesenchymal tissues and contributes to a notable portion of tumors. sarcomas, including fibrosarcoma as a key subtype, comprise approximately 15% of all skin and subcutaneous tumors in and 7-9% in . In , fibrosarcoma is the predominant histological type, accounting for 80-92% of sarcomas, often linked to injection-site reactions. In , fibrosarcoma forms a common component of these sarcomas, though exact proportions vary by study, typically representing a substantial share alongside other subtypes like myxosarcoma. Species-specific patterns highlight differences in aggressiveness and occurrence. In , fibrosarcoma exhibits heightened local invasiveness and rates of 10-28%, particularly in injection-site cases, contrasting with where occurs in 2-41% of instances but is generally lower for low-grade tumors. The tumor is rare in large animals such as horses, comprising only 1.9% of cutaneous and musculocutaneous neoplasms, and even less frequent in species like and sheep, where mesenchymal tumors overall are uncommon. Diagnostic trends indicate a rise in reported cases, driven by improved veterinary imaging modalities like and MRI, which enhance early detection, alongside increased pet lifespans. (AVMA) resources through 2024 note broader increases in cancer diagnoses in companion animals, reflecting better awareness and diagnostic capabilities rather than a true surge in incidence. In comparison to humans, where fibrosarcoma incidence is rare at about 1 per million annually, its prevalence in animals underscores unique veterinary challenges.

Fibrosarcoma in Animals

In Dogs

Fibrosarcoma in dogs primarily affects middle-aged to older large-breed dogs, with a age of 7 to 11 years, and certain breeds such as Golden Retrievers, , and Doberman Pinschers showing increased predisposition. These tumors commonly arise in the cutaneous or subcutaneous tissues of the limbs, accounting for over 50% of cases, or in the oral cavity, where they represent the third most frequent oral . Clinical presentation often includes a firm, sometimes ulcerated mass that may cause lameness in limb-affected dogs or oral bleeding, , and difficulty eating in those with oral involvement. Pathologically, fibrosarcoma resembles the adult type seen in humans, characterized by spindle-shaped fibroblasts producing in a , and it exhibits high local invasiveness by infiltrating fascial planes despite a pseudocapsule. , primarily hematogenous to the lungs, occurs in approximately 20-30% of cases, with rates varying by histologic grade—lower for grade I (around 10%) and higher for grade III (up to 40%). Diagnosis relies on histopathologic confirmation and grading, often following or , while treatment centers on wide surgical excision with 2-3 cm margins as the standard approach. is commonly employed for incomplete margins or high-grade tumors, improving local control. In veterinary studies from 2020-2024, median survival post-surgery ranges from 1 to 2 years for cases treated with excision alone, extending to over 3 years with combined and , though local recurrence remains a challenge in 20-57% of oral cases.

In Cats

Fibrosarcomas in are most commonly associated with prior injections, particularly , and are known as feline injection-site sarcomas (FISS). These tumors typically present as firm, fixed subcutaneous masses at common vaccination sites, such as the interscapular (scapular) region or flanks (lateral thoracic or ), in over 7 years of , with a peak incidence around 10-12 years. Pathologically, FISS are highly infiltrative tumors originating from fibroblasts, featuring -shaped cells arranged in interlacing bundles with a ous stroma, and they exhibit a metastatic rate of approximately 25%, most often to the lungs. While sharing histological similarities with fibrosarcomas in —such as the production of and morphology—feline variants, especially FISS, frequently display more anaplastic features, including higher mitotic rates and , contributing to their aggressive local behavior. The for with FISS is generally poor, with local recurrence rates reaching 50% following surgical excision alone due to the tumor's infiltrative nature. Treatment often involves aggressive interventions, such as limb for distal lesions or wide-margin excision combined with , which can extend median survival times to 6-18 months, though outcomes vary based on tumor and completeness of removal. In contrast to fibrosarcomas, which may have breed-specific patterns, cases are predominantly linked to injection-site .