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Ovarian Cancer Essay Research Paper Ovarian Cancer

Ovarian Cancer Essay, Research Paper


Ovarian Cancer


Of all gynecologic malignancies, ovarian cancer continues to have the


highest mortality and is the most difficult to diagnose. In the United States


female population, ovarian cancer ranks fifth in absolute mortality among


cancer related deaths (13,000/yr). In most reported cases, ovarian cancer,


when first diagnosed is in stages III or IV in about 60 to 70% of patients


which further complicates treatment of the disease (Barber, 3).


Early detection in ovarian cancer is hampered by the lack of appropriate


tumor markers and clinically, most patients fail to develop significant symptoms


until they reach advanced stage disease. The characteristics of ovarian cancer


have been studied in primary tumors and in established ovarian tumor cell lines


which provide a reproducible source of tumor material. Among the major


clinical problems of ovarian cancer, malignant progression, rapid emergence of


drug resistance, and associated cross-resistance remain unresolved. Ovarian


cancer has a high frequency of metastasis yet generally remains localized


within the peritoneal cavity. Tumor development has been associated with


aberrant, dysfunctional expression and/or mutation of various genes. This can


include oncogene overexpression, amplification or mutation, aberrant tumor


suppressor expression or mutation. Also, subversion of host antitumor immune


responses may play a role in the pathogenesis of cancer (Sharp, 77).


Ovarian clear cell adenocarcinoma was first described by Peham in 1899


as “hypernephroma of the ovary” because of its resemblance to renal cell


carcinoma. By 1939, Schiller noted a histologic similarity to mesonephric


tubules and classified these tumors as “mesonephromas.” In 1944, Saphir and


Lackner described two cases of “hypernephroid carcinoma of the ovary” and


proposed “clear cell” adenocarcinoma as an alternative term. Clear cell tumors


of the ovary are now generally considered to be of mullerian and in the genital


tract of mullerian origin. A number of examples of clear cell adenocarcinoma


have been reported to arise from the epithelium of an endometriotic cyst


(Yoonessi, 289). Occasionally, a renal cell carcinoma metastasizes to the


ovary and may be confused with a primary clear cell adenocarcinoma.


Ovarian clear cell adenocarcinoma (OCCA) has been recognized as a


distinct histologic entity in the World Health Organization (WHO) classification


of ovarian tumors since 1973 and is the most lethal ovarian neoplasm with an


overall five year survival of only 34% (Kennedy, 342). Clear cell


adenocarcinoma, like most ovarian cancers, originates from the ovarian


epithelium which is a single layer of cells found on the surface of the ovary.


Patients with ovarian clear cell adenocarcinoma are typically above the age of


30 with a median of 54 which is similar to that of ovarian epithelial cancer in


general. OCCA represents approximately 6% of ovarian cancers and bilateral


ovarian involvement occurs in less that 50% of patients even in advanced cases.


The association of OCCA and endometriosis is well documented (De La


Cuesta, 243). This was confirmed by Kennedy et al who encountered histologic or


intraoperative evidence of endometriosis in 45% of their study patients.


Transformation from endometriosis to clear cell adenocarcinoma has been


previously demonstrated in sporadic cases but was not observed by Kennedy et al.


Hypercalcemia occurs in a significant percentage of patients with OCCA.


Patients with advanced disease are more typically affected than patients with


nonmetastatic disease. Patients with OCCA are also more likely to have Stage I


disease than are patients with ovarian epithelial cancer in general (Kennedy,


348).


Histologic grade has been useful as an initial prognostic determinant in


some studies of epithelial cancers of the ovary. The grading of ovarian clear


cell adenocarcinoma has been problematic and is complicated by the multiplicity


of histologic patterns found in the same tumor. Similar problems have been


found in attempted grading of clear cell adenocarcinoma of the endometrium


(Disaia, 176). Despite these problems, tumor grading has been attempted but has


failed to demonstrate prognostic significance. However, collected data suggest


that low mitotic activity and a predominance of clear cells may be favorable


histologic features (Piver, 136).


Risk factors for OCCA and ovarian cancer in general are much less clear


than for other genital tumors with general agreement on two risk factors:


nulliparity and family history. There is a higher frequency of carcinoma in


unmarried women and in married women with low parity. Gonadal dysgenesis in


children is associated with a higher risk of developing ovarian cancer while


oral contraceptives are associated with a decreased risk. Genetic and candidate


host genes may be altered in susceptible families. Among those currently under


investigation is BRCA1 which has been associated with an increased


susceptibility to breast cancer. Approximately 30% of ovarian adenocarcinomas


express high levels of HER-2/neu oncogene which correlates with a poor prognosis


(Altcheck, 375-376). Mutations in host tumor suppresser gene p53 are found in


50% of ovarian carcinomas. There also appears to be a racial predilection, as


the vast majority of cases are seen in Caucasians (Yoonessi, 295).


Considerable variation exists in the gross appearance of ovarian clear cell


adenocarcinomas and they are generally indistinguishable from other epithelial


ovarian carcinomas. They could be cystic, solid, soft, or rubbery, and may also


contain hemorrhagic and mucinous areas (O’Donnell, 250). Microscopically, clear


cell carcinomas are characterized by the presence of variable proportions of


clear and hobnail cells. The former contain abundant clear cytoplasm with often


centrally located nuclei, while the latter show clear or pink cytoplasm and


bizarre basal nuclei with atypical cytoplasmic intraluminal projections. The


cellular arrangement may be tubulo acinar, papillary, or solid, with the great


majority displaying a mixture of these patterns. The hobnail and clear cells


predominate with tubular and solid forms, respectively (Barber, 214).


Clear cell adenocarcinoma tissue fixed with alcohol shows a high


cytoplasmic glycogen content which can be shown by means of special staining


techniques. Abundant extracellular and rare intracellular neutral mucin mixed


with sulfate and carboxyl group is usually present. The clear cells are


recognized histochemically and ultrastructurally (short and blunt microvilli,


intercellular tight junctions and desmosomes, free ribosomes, and lamellar


endoplasmic reticulum). The ultrastructure of hobnail and clear cells resemble


those of the similar cells seen in clear cell carcinomas of the remainder of the


female genital tract (O’Brien, 254). A variation in patterns of histology is


seen among these tumors and frequently within the same one.


Whether both tubular components with hobnail cells and the solid part


with clear cells are required to establish a diagnosis or the presence of just


one of the patterns is sufficient has not been clearly established. Fortunately,


most tumors exhibit a mixture of these components. Benign and borderline


counterparts of clear cell ovarian adenocarcinomas are theoretical possibilities.


Yoonessi et al reported that nodal metastases could be found even when the


disease appears to be grossly limited to the pelvis (Yoonessi, 296).


Examination of retroperitoneal nodes is essential to allow for more factual


staging and carefully planned adjuvant therapy.


Surgery remains the backbone of treatment and generally consists of


removal of the uterus, tubes and ovaries, possible partial omentectomy, and


nodal biopsies. The effectiveness and value of adjuvant radiotherapy and


chemotherapy has not been clearly demonstrated. Therefore, in patients with


unilateral encapsulated lesions and histologically proven uninvolvement of the


contralateral ovary, omentum, and biopsied nodes, a case can be made for (a)no


adjuvant therapy after complete surgical removal and (b) removal of only the


diseased ovary in an occasional patient who may be young and desirous of


preserving her reproductive capacity (Altchek, 97). In the more adv-anced


stages, removal of the uterus, ovaries, omentum, and as much tumor as possible


followed by pelvic radiotherapy (if residual disease is limited to the pelvis)


or chemotherapy must be considered. The chemotherapeutic regimens generally


involve adriamycin, alkylating agents, and cisPlatinum containing combinations


(Barber, 442).


OCCA is of epithelial origin and often contains mixtures of other


epithelial tumors such as serous, mucinous, and endometrioid. Clear cell


adenocarcinoma is characterized by large epithelial cells with abundant


cytoplasm. Because these tumors sometimes occur in association with


endometriosis or endometrioid carcinoma of the ovary and resemble clear cell


carcinoma of the endometrium, they are now thought to be of mullerian duct


origin and variants of endometrioid adenocarcinoma. Clear cell tumors of the


ovary can be predominantly solid or cystic. In the solid neoplasm, the clear


cells are arranged in sheets or tubules. In the cystic form, the neoplastic


cells line the spaces. Five-year survival is approximately 50% when these


tumors are confined to the ovaries, but these tumors tend to be aggressive and


spread beyond the ovary which tends to make 5-year survival highly unlikely


(Altchek, 416).


Some debate continues as to whether clear cell or mesonephroid


carcinoma is a separate clinicopathological entity with its own distinctive


biologic behavior and natural history or a histologic variant of endometrioid


carcinoma. In an effort to characterize clear cell adenocarcinoma, Jenison et


al compared these tumors to the most common of the epithelial malignancies, the


serous adenocarcinoma (SA). Histologically determined endometriosis was


strikingly more common among patients with OCCA than with SA. Other


observations by Jenison et al suggest that the biologic behavior of clear cell


adenocarcinoma differs from that of SA. They found Stage I tumors in 50% of the


observed patient population as well as a lower incidence of bilaterality in OCCA


(Jenison, 67-69). Additionally, it appears that OCCA is characteristically


larger than SA, possibly explaining the greater frequency of symptoms and signs


at presentation.


Risk Factors


There is controversy regarding talc use causing ovarian cancer. Until


recently, most talc powders were contaminated with asbestos. Conceptually,


talcum powder on the perineum could reach the ovaries by absorption through the


cervix or vagina. Since talcum powders are no longer contaminated with asbestos,


the risk is probably no longer important (Barber, 200). The high fat content of


whole milk, butter, and meat products has been implicated with an increased risk


for ovarian cancer in general.


The Centers for Disease Control compared 546 women with ovarian cancer


to 4,228 controls and reported that for women 20 to 54 years of age, the use of


oral contraceptives reduced the risk of ovarian cancer by 40% and the risk of


ovarian cancer decreased as the duration of oral contraceptive use increased.


Even the use of oral contraceptives for three months decreased the risk. The


protective effect of oral contraceptives is to reduce the relative risk to 0.6


or to decrease the incidence of disease by 40%. There is a decreased risk as


high as 40% for women who have had four or more children as compared to


nulliparous women. There is an increase in the incidence of ovarian cancer


among nulliparous women and a decrease with increasing parity. The “incessant


ovulation theory” proposes that continuous ovulation causes repeated trauma to


the ovary leading to the development of ovarian cancer. Incidentally, having


two or more abortions compared to never having had an abortion decreases one’s


risk of developing ovarian cancer by 30% (Coppleson, 25-28).


Etiology


It is commonly accepted that cancer results from a series of genetic


alterations that disrupt normal cellular growth and differentiation. It has


been proposed that genetic changes causing cancer occur in two categories of


normal cellular genes, proto-oncogenes and tumor suppressor genes. Genetic


changes in proto-oncogenes facilitate the transformation of a normal cell to a


malignant cell by production of an altered or overexpressed gene product. Such


genetic changes include mutation, translocation, or amplification of proto-


oncogenes Tumor suppressor genes are proposed to prevent cancer. Inactivation


or loss of these genes contributes to development of cancer by the lack of a


functional gene product. This may require mutations in both alleles of a tumor


suppressor gene. These genes function as regulatory inhibitors of cell


proliferation, such as a DNA transcription factor, or a cell adhesion molecule.


Loss of these functions could result in abnormal cell division or gene


expression, or increased ability of cells in tissues to detach. Cancer such as


OCCA most likely results from the dynamic interaction of several genetically


altered proto-oncogenes and tumor suppressor genes (Piver, 64-67).


Until recently, there was little evidence that the origin of ovarian was


genetic. Before 1970, familial ovarian cancer had been reported in only five


families. A familial cancer registry was established at Roswell Park Cancer


Institute in 1981 to document the number of cases occurring in the United States


and to study the mode of inheritance. If a genetic autosomal dominant


transmission of the disease can be established, counseling for prophylactic


oophorectomy at an appropriate age may lead to a decrease in the death rate from


ovarian cancer in such families.


The registry at Roswell Park reported 201 cases of ovarian cancer in 94


families in 1984. From 1981 through 1991, 820 families and 2946 cases had been


observed. Familial ovarian cancer is not a rare occurrence and may account for


2 to 5% of all cases of ovarian cancer. Three conditions that are associated


with familial ovarian cancer are (1) site specific, the most common form, which


is restricted to ovarian cancer, and (2) breast/ovarian cancer with clustering


of ovarian and breast cases in extended pedigrees (Altchek, 229-230). One


characteristic of inherited ovarian cancer is that it occurs at a significantly


younger age than the non-inherited form.


Cyto

genetic investigations of sporadic (non-inherited) ovarian tumors


have revealed frequent alterations of chromosomes 1,3,6, and 11. Many proto-


oncogenes have been mapped to these chromosomes, and deletions of segments of


chromosomes (particularly 3p and 6q) in some tumors is consistent with a role


for loss of tumor suppressor genes. Recently, a genetic linkage study of


familial breast/ovary cancer suggested linkage of disease susceptibility with


the RH blood group locus on chromosome 1p.


Allele loss involving chromosomes 3p and 6q as well as chromosomes 11p,


13q, and 17 have been frequently observed in ovarian cancers. Besides allele


loss, point mutations have been identified in the tumor suppressor gene p53


located on chromosome17p13. Deletions of chromosome 17q have been reported in


sporadic ovarian tumors suggesting a general involvement of this region in


ovarian tumor biology. Allelic loss of MYB and ESR genes map on chromosome 6q


near the provisional locus for FUCA2, the locus for a-L-fucosidase in serum.


Low activity of a-L-fucosidase in serum is more prevalent in ovarian cancer


patients. This suggests that deficiency of a-L-fucosidase activity in serum may


be a hereditary condition associated with increased risk for developing ovarian


cancer. This together with cytogenetic data of losses of 6q and the allelic


losses at 6q point to the potential importance of chromosome 6q in hereditary


ovarian cancer (Altchek, 208-212).


Activation of normal proto-oncogenes by either mutation, translocation,


or gene amplification to produce altered or overexpressed products is believed


to play an important role in the development of ovarian tumors. Activation of


several proto-oncogenes (particularly K-RAS, H-RAS, c-MYC, and HER-2/neu)


occurs in ovarian tumors. However, the significance remains to be determined.


It is controversial as to whether overexpression of the HER-2/neu gene in


ovarian cancer is associated with poor prognosis. In addition to studying


proto-oncogenes in tumors, it may be beneficial to investigate proto-oncogenes


in germ-line DNA from members of families with histories of ovarian cancer


(Barber, 323-324). It is questionable whether inheritance or rare alleles of


the H-RAS proto-oncogene may be linked to susceptibility to ovarian cancers.


Diagnosis and Treatment


The early diagnosis of ovarian cancer is a matter of chance and not a


triumph of scientific approach. In most cases, the finding of a pelvic mass is


the only available method of diagnosis, with the exception of functioning tumors


which may manifest endocrine even with minimal ovarian enlargement.


Symptomatology includes vague abdominal discomfort, dyspepsia, increased


flatulence, sense of bloating, particularly after ingesting food, mild digestive


disturbances, and pelvic unrest which may be present for several months before


diagnosis (Sharp, 161-163).


There are a great number of imaging techniques that are available.


Ultrasounds, particularly vaginal ultrasound, has increased the rate of pick-up


of early lesions, particularly when the color Doppler method is used.


Unfortunately, vaginal sonography and CA 125 have had an increasing number of


false positive examinations. Pelvic findings are often minimal and not helpful


in making a diagnosis. However, combined with a high index of suspicion, this


may alert the physician to the diagnosis.


These pelvic signs include:


Mass in the ovarian area


Relative immobility due to fixation of adhesions


Irregularity of the tumor


Shotty consistency with increased firmness


Tumors in the cul-de-sac described as a handful of knuckles


Relative insensitivity of the mass


Increasing size under observation


Bilaterality (70% for ovarian carcinoma versus 5% for benign cases)


(Barber, 136)


Tumor markers have been particularly useful in monitoring treatment,


however, the markers have and will probably always have a disadvantage in


identifying an early tumor. To date, only two, human gonadotropin (HCG) and


alpha fetoprotein, are known to be sensitive and specific. The problem with


tumor markers as a means of making a diagnosis is that a tumor marker is


developed from a certain volume of tumor. By that time it is no longer an early


but rather a biologically late tumor (Altchek, 292).


Many reports have described murine monoclonal antibodies (MAbs) as


potential tools for diagnosing malignant ovarian tumors. Yamada et al attempted


to develop a MAb that can differentiate cells with early malignant change from


adjacent benign tumor cells in cases of borderline malignancy. They developed


MAb 12C3 by immunizing mice with a cell line derived from a human ovarian tumor.


The antibody reacted with human ovarian carcinomas rather than with germ cell


tumors. MAb 12C3 stained 67.7% of ovarian epithelial malignancies, but


exhibited an extremely low reactivity with other malignancies. MAb 12C3


detected a novel antigen whose distribution in normal tissue is restricted.


According to Yamada et al, MAb 12C3 will serve as a powerful new tool for the


histologic detection of early malignant changes in borderline epithelial


neoplasms. MAb 12C3 may also be useful as a targeting agent for cancer


chemotherapy (Yamada, 293-294).


Currently there are several serum markers that are available to help


make a diagnosis. These include CA 125, CEA, DNB/70K, LASA-P, and serum inhibin.


Recently the urinary gonadotropin peptide (UCP) and the collagen-stimulating


factor have been added. Although the tumor markers have a low specificity and


sensitivity, they are often used in screening for ovarian cancer. A new tumor


marker CA125-2 has greater specificity than CA125. In general, tumor markers


have a very limited role in screening for ovarian cancer.


The common epithelial cancer of the ovary is unique in killing the


patient while being, in the vast majority of the cases, enclosed in the


anatomical area where it initially developed: the peritoneal cavity. Even with


early localized cancer, lymph node metastases are not rare in the pelvic or


aortic areas. In most of the cases, death is due to intraperitoneal


proliferation, ascites, protein loss and cachexia. The concept of debulking or


cytoreductive surgery is currently the dominant concept in treatment.


The first goal in debulking surgery is inhibition of debulking surgery


is inhibition of the vicious cycle of malnutrition, nausea, vomiting, and


dyspepsia commonly found in patients with mid to advanced stage disease.


Cytoreductive surgery enhances the efficiency of chemotherapy as the survival


curve of the patients whose largest residual mass size was, after surgery, below


the 1.5 cm limit is the same as the curve of the patients whose largest


metastatic lesions were below the 1.5 cm limit at the outset (Altchek, 422-424).


The aggressiveness of the debulking surgery is a key question surgeons


must face when treating ovarian cancers. The debulking of very large metastatic


masses makes no sense from the oncologic perspective. As for extrapelvic masses


the debulking, even if more acceptable, remains full of danger and exposes the


patient to a heavy handicap. For these reasons the extra-genital resections


have to be limited to lymphadenectomy, omentectomy, pelvic abdominal peritoneal


resections and rectosigmoid junction resection. That means that stages IIB and


IIC and stages IIIA and IIB are the only true indications for extrapelvic


cytoreductive surgery. Colectomy, ileectomy, splenectomy, segmental hepatectomy


are only exceptionally indicated if they allow one to perform a real optimal


resection. The standard cytoreductive surgery is the total hysterectomy with


bilateral salpingoophorectomy. This surgery may be done with aortic and pelvic


lymph node sampling, omentectomy, and, if necessary, resection of the


rectosigmoidal junction (Barber. 182-183).


The concept of administering drugs directly into the peritoneal cavity


as therapy of ovarian cancer was attempted more than three decades ago. However,


it has only been within the last ten years that a firm basis for this method of


drug delivery has become established. The essential goal is to expose the tumor


to higher concentrations of drug for longer periods of time than is possible


with systemic drug delivery. Several agents have been examined for their


efficacy, safety and pharmacokinetic advantage when administered via the


peritoneal route.


Cisplatin has undergone the most extensive evaluation for regional


delivery. Cisplatin reaches the systemic compartment in significant


concentrations when it is administered intraperitoneally. The dose limiting


toxicity of intraperitoneally administered cisplatin is nephrotoxicity,


neurotoxicity and emesis. The depth of penetration of cisplatin into the


peritoneal lining and tumor following regional delivery is only 1 to 2 mm from


the surface which limits its efficacy. Thus, the only patients with ovarian


cancer who would likely benefit would be those with very small residual tumor


volumes. Overall, approximately 30 to 40% of patients with small volume


residual ovarian cancer have been shown to demonstrate an objective clinical


response to cisplatin-based locally administered therapy with 20 to 30% of


patients achieving a surgically documented complete response. As a general rule,


patients whose tumors have demonstrated an inherent resistance to cisplatin


following systemic therapy are not considered for treatment with platinum-based


intraperitoneal therapy (Altchek, 444-446).


In patients with small volume residual disease at the time of second


look laparotomy, who have demonstrated inherent resistance to platinum-based


regimens, alternative intraperitoneal treatment programs can be considered.


Other agents include mitoxantrone, and recombinant alpha-interpheron.


Intraperitoneal mitoxanthone has been shown to have definite activity in small


volume residual platinum-refractory ovarian cancer. Unfortunately, the dose


limiting toxicity of the agent is abdominal pain and adhesion formation,


possibly leading to bowel obstruction. Recent data suggests the local toxicity


of mitoxanthone can be decreased considerably by delivering the agent in


microdoses.


Ovarian tumors may have either intrinsic or acquired drug resistance.


Many mechanisms of drug resistance have been described. Expression of the MDR1


gene that encodes the drug efflux protein known as p-glycoprotein, has been


shown to confer the characteristic multi-drug resistance to clones of some


cancers. The most widely considered definition of platinum response is response


to first-line platinum treatment and disease free interval. Primary platinum


resistance may be defined as any progression on treatment. Secondary platinum


resistance is the absence of progression on primary platinum-based therapy but


progression at the time of platinum retreatment for relapse (Sharp, 205-207).


Second-line chemotherapy for recurrent ovarian cancer is dependent on


preferences of both the patient and physician. Retreatment with platinum


therapy appears to offer significant opportunity for clinical response and


palliation but relatively little hope for long-term cure. Paclitaxel (trade


name: Taxol), a prototype of the taxanes, is cytotoxic to ovarian cancer.


Approximately 20% of platinum failures respond to standard doses of paclitaxel.


Studies are in progress of dose intensification and intraperitoneal


administration (Barber, 227-228). This class of drugs is now thought to


represent an active addition to the platinum analogs, either as primary therapy,


in combination with platinum, or as salvage therapy after failure of platinum.


In advanced stages, there is suggestive evidence of partial


responsiveness of OCCA to radiation as well as cchemotherapy, adriamycin,


cytoxan, and cisPlatinum-containing combinations (Yoonessi, 295). Radiation


techniques include intraperitoneal radioactive gold or chromium phosphate and


external beam therapy to the abdomen and pelvis. The role of radiation therapy


in treatment of ovarian canver has diminished in prominence as the spread


pattern of ovarian cancer and the normal tissue bed involved in the treatment of


this neoplasm make effective radiation therapy difficult. When the residual


disease after laparotomy is bulky, radiation therapy is particularly ineffective.


If postoperative radiation is prescribed for a patient, it is important that


theentire abdomen and pelvis are optimally treated to elicit a response from the


tumor (Sharp, 278-280).


In the last few decades, the aggressive attempt to optimize the


treatment of ovarian clear cell adenocarcinoma and ovarian cancer in general has


seen remarkable improvements in the response rates of patients with advanced


stage cancer without dramatically improving long-term survival. The promises of


new drugs with activity when platinum agents fail is encouraging and fosters


hope that, in the decades to come, the endeavors of surgical and pharmacoogical


research will make ovarian cancer an easily treatable disease.


Bibliography


Altchek, A., & Deligdisch, L. (1996). Diagnosis and Management of Ovarian


Disorders. New York: Igaku Shoin.


Barber, H. (1993). Ovarian Carcinoma: Etiology, Diagnosis, and Treatment. New


York: Springer Verlag.


Coppleson, M. (Ed.). (1981). Gynecologic Oncology (vol. 2). New York:


Churchill Livingstone.


Current Clinical Trials Oncology. (1996). Green Brook, NJ: Pyros Education.


De La Cuesta, R., & Eichorn, J. (1996). Histologic transformation of benign


endometriosis to early epithelial ovarian cancer. Gynecologic Oncology,


60, 238- 244.


Disaia, P, & Creasman, W. (1989). Clinical Gynecologic Oncology (3rd ed.). St.


Louis: Mosby.


Jenison, E., Montag, A., & Griffiths, T. (1989). clear cell adenocarcinoma of


the ovary: a clinical analysis and comparison with serous carcinoma. Gynecologic


Oncology, 32, 65-71.


Kennedy, A., & Biscotti, C. (1993). Histologic correlates of progression-free


interval and survival in ovarian clear cell adenocarcinoma. Gynecologic Oncology, 50,


334-338.


Kennedy, A., & Biscotti, C. (1989). Ovarian clear cell adenocarcinoma.


Gynecologic Oncology, 32, 342-349.


O’Brien, M., Schofield, J., & Tan, S. (1993). Clear cell epithelial ovarian


cancer: Bad prognosis only in early stages. Gynecologic Oncology, 49, 250-254.


O’Donnell, M, & Al-Nafussi, A. (1995). Intracytoplasmic lumina and mucinous


inclusions in ovarian carcinoma. Histopathology, 26, 181-184.

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