Follicular dendritic cell sarcoma (FDCS) is an extremely rare neoplasm. While the existence of FDC tumors was predicted by Lennert in 1978, the tumor wasn’t fully recognized as its own cancer until 1986 after characterization by Monda et al. It accounts for only 0.4% of soft tissue sarcomas, but has significant recurrent and metastatic potential and is considered an intermediate grade malignancy. The major hurdle in treating FDCS has been misdiagnosis. It is a newly characterized cancer, and because of its similarities in presentation and markers to lymphoma, both Hodgkin and Non-Hodgkin subtypes, diagnosis of FDCS can be difficult. With recent advancements in cancer biology better diagnostic assays and chemotherapeutic agents have been made to more accurately diagnose and treat FDCS. Follicular dendritic cell sarcoma (FDCS) is an extremely rare neoplasm. While the existence of FDC tumors was predicted by Lennert in 1978, the tumor wasn’t fully recognized as its own cancer until 1986 after characterization by Monda et al. It accounts for only 0.4% of soft tissue sarcomas, but has significant recurrent and metastatic potential and is considered an intermediate grade malignancy. The major hurdle in treating FDCS has been misdiagnosis. It is a newly characterized cancer, and because of its similarities in presentation and markers to lymphoma, both Hodgkin and Non-Hodgkin subtypes, diagnosis of FDCS can be difficult. With recent advancements in cancer biology better diagnostic assays and chemotherapeutic agents have been made to more accurately diagnose and treat FDCS. Follicular dendritic cells are localized in germinal centers of lymphoid follicles and have an integral role in regulation of the germinal center reaction and present antigens to B cells. Most cases of FDCS develop in the lymph nodes, but about 30% develop in extranodal sites. In 1998 the largest study on the disease was a retrospective review with fifty-one patients. Of these fifty-one patients, no conclusive pattern was found in regard to age, sex, race or presentation. The median patient age was 41 (range 14–76), and while most cases presented with cervical and axillary lymphadenopathy, 17 presented in extranodal sites including the liver, spleen, bowel and pancrease. With such a range of patient histories no definitive cause has been linked to FDCS. There has, however, been some evidence that previous exposure to the Epstein Barr Virus (EBV) or diagnosis of Castleman's disease can increase the risk of developing FDCS—medical literature in 2000 reported approximately 12% of all cases of FDC tumors are associated with EBV, with variance in different organs, but the role of EBV remains unclear in FDC tumor pathogenesis; and EBV does not appear to play a role in the transformation process of Castleman's disease to FDC sarcoma because all cases the report found associated with Castleman's disease were EBV negative. Symptoms of FDCS vary, and are largely dependent on the part of the body the tumor develops. The most common symptom is painless swelling in lymph nodes. This symptom alone, however, is nonconclusive as it is associated with many other diseases including the common cold. Other symptoms include cough, sore throat, difficulty swallowing, weight loss and tiredness. In cases that present in extranodal sites outside of the head and neck region, organ specific symptoms are observed. Proliferation of FDC cells is characteristic of many neoplastic conditions including follicular hyperplasia, follicular lymphoma, nodular lymphocyte predominate Hodgkin’s disease and angioimmunoblastic T-cell lymphoma. Despite finally being recognized as its own disease in 1986, diagnosis of FDCS is still difficult. FDC cells are large, contain two nuclei, and form clusters with lymphocytes making them difficult to distinguish in staining. These cells are best visualized with immunostaining using the FDC markers CD21, CD35, R4/23, clusterin, and KiM4p. Marker analysis has also led to debate over the origin of the cell type; it coexpresses CD45, a leukocyte common antigen, and CD15, a monocyte common antigen. Because of the debate and difficulty of staining, pathologic diagnosis often requires morphologic, cytochemical and electron microscope analysis as well. Biological mutations of the FDCS tumor have been exploited for diagnostic purposes. Characteristically FDCS have mircotubuloreticular structures (MTRS) and increased levels of intracellular clusterin. MTRS contribute to microtubule formation of many structures including the mitotic spindle during cell division. This contributes to many of the hallmarks of cancer including proliferative signaling, growth activation, and replicative immortality. Clusterin is a heterodimeric protein that aids in the clearance of cellular debris and is involved with apoptosis. Clusterin can be stained to help distinguish FDCS and is involved in the many important cancer hallmarks including resistance to cell death and evading growth suppressors. At the time of the follicular dendritic cell sarcoma discovery information on the effect of chemotherapy and radiation on it was nonexistent. The best physicians could do was try existing chemotherapeutic agents. With no evidence of the clinical benefit of chemotherapy, many of the first cases were treated solely with complete resection and/or radiation. However, 12 of 31 patients who had surgery alone as primary treatment relapsed. Of the patients who received surgery and radiation 2 of 8 relapsed. It became apparent that better treatment options were necessary. Being so similar to lymphomas, physicians began using a common leukemia and non-Hodgkin’s lymphoma chemotherapy regimen on FDCS patients: CHOP. The CHOP regimen consists of Cyclophosphamide, Doxorubicin, Oncovin, and Prednisone (CHOP). They all exploit different pathways common in cancer cells. Cyclophosphamide slows or stops cell growth cells. It targets cells that are rapidly dividing which include cancer cells that are self-sufficient in growth signals and insensitive to antigrowth signals. More importantly, the biological actions of cyclophosphamide are dose-dependent. At high doses it is very cytotoxic; its metabolite phosphoromide adds an alkyl group to the N7 position on guanine resulting in arrested growth and cell death. The metabolite is only formed in cells with low levels of cytoplasmic aldehyde dehydrogenase (ALDH) resulting in relatively low chemotherapy toxicity in other non-cancer cells like bone marrow. It is also an immunosuppressant and decreases the inflammatory response. At low doses, while it is less cytotoxic, it shows some anti-angiogenic properties. The mechanism is not fully understood but it is thought that it interferes with the VEGF growth factors produced in and around the tumor microenvironment. Doxorubicin interferes with cell growth and replication by intercalating in DNA. This stops topoisomerase II from relaxing the DNA strands and inhibiting transcription. Recent studies have also shown that doxorubicin may be involved in the Akt pathway. An important hallmark of cancer, Akt is part of the cell survival pathways by inhibiting apoptosis. There is also evidence that Akt is involved in angiogenesis and vascular maturation. Activation of PI3-kinase/Akt mediates VEGF production in cells. Therefore, doxorubicin has a dual role in cancer treatment: it inhibits cell survival (causes apoptosis), and decreases angiogenesis. Oncovin, more commonly known as vincristine, is a mitotic inhibitor. It binds to tubulin dimers, inhibiting the assembly of microtubule structures like the cytoskeleton and mitotic spindle. Although this drug still cannot strictly target cancer cells, cancer cells have a higher average turnover of microtubules making them more susceptible to the cytotoxicity of oncovin. Prednisone, the last drug in the CHOP combination therapy is a corticosteroid that acts as an immunosuppressant decreasing inflammation.