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Home > Wellness Resources > Health Library > Ovarian Epithelial Cancer Treatment (PDQ®): Treatment - Health Professional Information [NCI]
This information is produced and provided by the National Cancer Institute (NCI). The information in this topic may have changed since it was written. For the most current information, contact the National Cancer Institute via the Internet web site at http://cancer.gov or call 1-800-4-CANCER.
Incidence and Mortality
Estimated new cases and deaths from ovarian cancer in the United States in 2013:
Several malignancies arise from the ovary. Epithelial carcinoma of the ovary is one of the most common gynecologic malignancies and the fifth most frequent cause of cancer death in women, with 50% of all cases occurring in women older than 65 years. Approximately 5% to 10% of ovarian cancers are familial, and three distinct hereditary patterns have been identified: ovarian cancer alone, ovarian and breast cancers, or ovarian and colon cancers.
The most important risk factor for ovarian cancer is a family history of a first-degree relative (e.g., mother, daughter, or sister) with the disease. The highest risk appears in women who have two or more first-degree relatives with ovarian cancer. The risk is somewhat less for women who have one first-degree and one second-degree relative (grandmother or aunt) with ovarian cancer.
Findings from risk-reducing surgeries in healthy women with BRCA1/2 mutations have reinforced the hypothesis that many high-grade serous cancers—the most common histologic subtype of ovarian cancer—may arise from precursor lesions that originate in the fimbriae of the fallopian tubes. In addition, histologically similar cancers diagnosed as primary peritoneal carcinomas share molecular findings, such as loss or inactivation of the tumor-suppressors p53 and BRCA1/2 proteins. Therefore, high-grade serous adenocarcinomas arising from the fallopian tube and elsewhere in the peritoneal cavity, together with most ovarian epithelial cancers, represent "extrauterine adenocarcinomas of Müllerian epithelial origin" and are staged and treated similarly to ovarian cancer; from 2000 onward, they are usually included in ovarian cancer clinical trials. On the other hand, clear cell and endometrioid ovarian cancers that are linked to endometriosis have different gene-expression signatures, as do mucinous subtypes.
Other Risk Factors
In most families affected with the breast and ovarian cancer syndrome or site-specific ovarian cancer, genetic linkage has been found to the BRCA1 locus on chromosome 17q21.[7,8,9]BRCA2, also responsible for some instances of inherited ovarian and breast cancer, has been mapped by genetic linkage to chromosome 13q12. The lifetime risk for developing ovarian cancer in patients harboring germline mutations in BRCA1 is substantially increased over the general population.[11,12] Two retrospective studies of patients with germline mutations in BRCA1 suggest that these women have improved survival compared with BRCA1 mutation-negative women.[13,14][Level of evidence: 3iiiA] The majority of women with a BRCA1 mutation probably have family members with a history of ovarian and/or breast cancer; therefore, these women may have been more vigilant and inclined to participate in cancer screening programs that may have led to earlier detection.
For women at increased risk, prophylactic oophorectomy may be considered after the age of 35 if childbearing is complete. In a family-based study among women with BRCA1 or BRCA2 mutations, of the 259 women who had undergone bilateral prophylactic oophorectomy, two of them (0.8%) developed subsequent papillary serous peritoneal carcinoma, and six of them (2.8%) had stage I ovarian cancer at the time of surgery. Of the 292 matched controls, 20% who did not have prophylactic surgery developed ovarian cancer. Prophylactic surgery was associated with a higher than 90% reduction in the risk of ovarian cancer (relative risk [RR], 0.04; 95% confidence interval [CI], 0.01–0.16), with an average follow-up of 9 years; however, family-based studies may be associated with biases resulting from case selection and other factors that may influence the estimate of benefit. (Refer to the Evidence of Benefit section in the PDQ summary on Ovarian Cancer Prevention for more information.)
After a prophylactic oophorectomy, a small percentage of women may develop a primary peritoneal carcinoma, similar in appearance to ovarian cancer. The prognostic information presented below deals only with epithelial carcinomas. Stromal and germ cell tumors are relatively uncommon and comprise less than 10% of cases. (Refer to the PDQ summaries on Ovarian Germ Cell Tumor Treatment and Ovarian Low Malignant Potential Tumor Treatment for more information.)
Ovarian cancer usually spreads via local shedding into the peritoneal cavity followed by implantation on the peritoneum and via local invasion of bowel and bladder. The incidence of positive nodes at primary surgery has been reported to be as much as 24% in patients with stage I disease, 50% in patients with stage II disease, 74% in patients with stage III disease, and 73% in patients with stage IV disease. In this study, the pelvic nodes were involved as often as the para-aortic nodes. Tumor cells may also block diaphragmatic lymphatics. The resulting impairment of lymphatic drainage of the peritoneum is thought to play a role in development of ascites in ovarian cancer. Also, transdiaphragmatic spread to the pleura is common.
Prognosis in ovarian cancer is influenced by several factors, but multivariate analyses suggest that the most important favorable factors include:[19,20,21,22,23]
For patients with stage I disease, the most important prognostic factor is grade, followed by dense adherence and large-volume ascites. DNA flow cytometric analysis of stage I and stage IIA patients may identify a group of high-risk patients. Patients with clear cell histology appear to have a worse prognosis. Patients with a significant component of transitional cell carcinoma appear to have a better prognosis.
Although the ovarian cancer-associated antigen, CA 125, has no prognostic significance when measured at the time of diagnosis, it has a high correlation with survival when measured 1 month after the third course of chemotherapy for patients with stage III or stage IV disease. For patients whose elevated CA 125 normalizes with chemotherapy, more than one subsequent elevated CA 125 measurement is highly predictive of active disease, but this does not mandate immediate therapy.[29,30]
Case-control studies suggest that BRCA1 and BRCA2 mutation carriers have improved responses to chemotherapy when compared with patients with sporadic epithelial ovarian cancer. This may be the result of a deficient homologous DNA repair mechanism in these tumors, which leads to increased sensitivity to chemotherapy agents.[31,32]
Survival and Follow-up
Most patients with ovarian cancer have widespread disease at presentation. This may be partly explained by relatively early spread (and implantation) of high-grade papillary serous cancers to the rest of the peritoneal cavity. Conversely, symptoms such as abdominal pain and swelling, gastrointestinal symptoms, and pelvic pain often go unrecognized, leading to delays in diagnosis. Screening procedures such as gynecologic assessment, vaginal ultrasound, and CA 125 assay have had low predictive value in detecting ovarian cancer in women without special risk factors.[34,35] Efforts have been made to enhance physician and patient awareness of the occurrence of these nonspecific symptoms.[36,37,38,39,40] (Refer to the PDQ summaries on Pain and Gastrointestinal Complications for more information.) As a result of these confounding factors, yearly mortality in ovarian cancer is approximately 65% of the incidence rate. Long-term follow-up of suboptimally debulked stage III and stage IV patients showed a 5-year survival rate of less than 10% with platinum-based combination therapy prior to the current generation of trials including taxanes. By contrast, optimally debulked stage III patients treated with a combination of intravenous taxane and intraperitoneal platinum plus taxane achieved a median survival of 66 months in a Gynecologic Oncology Group trial. Numerous clinical trials are in progress to refine existing therapy and test the value of different approaches to postoperative drug and radiation therapy. Patients with any stage of ovarian cancer are appropriate candidates for clinical trials.[42,43] Information about ongoing clinical trials is available from the NCI Web site.
Other PDQ summaries containing information related to ovarian epithelial cancer include the following:
The following is a list of ovarian epithelial cancer histologic classifications.
(Refer to the PDQ summary on Ovarian Low Malignant Potential Tumor Treatment for more information.)
In the absence of extra-abdominal metastatic disease, definitive staging of ovarian cancer requires surgery. The role of surgery in patients with stage IV disease and extra-abdominal disease is yet to be established. If disease appears to be limited to the ovaries or pelvis, it is essential at laparotomy to examine and biopsy or to obtain cytologic brushings of the diaphragm, both paracolic gutters, the pelvic peritoneum, para-aortic and pelvic nodes, and infracolic omentum, and to obtain peritoneal washings.
The serum CA 125 level is valuable in the follow-up and restaging of patients who have elevated CA 125 levels at the time of diagnosis.[2,3,4] While an elevated CA 125 level indicates a high probability of epithelial ovarian cancer, a negative CA 125 level cannot be used to exclude the presence of residual disease. CA 125 levels can also be elevated in other malignancies and benign gynecologic problems such as endometriosis, and CA 125 levels should be used with a histologic diagnosis of epithelial ovarian cancer.[6,7]
The Féderation Internationale de Gynécologie et d'Obstétrique (FIGO) and the American Joint Committee on Cancer (AJCC) have designated staging to define ovarian epithelial cancer; the FIGO system is most commonly used.[8,9]
In two large European trials, European Organization for Research and Treatment of Cancer-Adjuvant ChemoTherapy in Ovarian Neoplasm (EORTC-ACTION) and International Collaborative Ovarian Neoplasm (MRC-ICON1 [NCT00002477]), patients with stage IA and stage IB (grades II and III), all stage IC and stage II, and all stage I and stage IIA clear cell carcinoma were randomly assigned to adjuvant chemotherapy or observation. Data were reported individually and in pooled form.[12,13,14]
The EORTC-ACTION trial required at least four cycles of carboplatin or cisplatin-based chemotherapy as treatment. Although surgical staging criteria were monitored, inadequate staging was not an exclusion criterion. Recurrence-free survival (RFS) was improved in the adjuvant chemotherapy arm (hazard ratio [HR], 0.63; P = .02), but overall survival (OS) was not affected (HR, 0.69; 95% confidence interval [CI], 0.44–1.08; P = .10). OS was improved by chemotherapy in the subset of patients with inadequate surgical staging.
The MRC-ICON1 trial randomly assigned patients to six cycles of single-agent carboplatin or cisplatin or platinum-based chemotherapy (usually cyclophosphamide, doxorubicin, and cisplatin) versus observation and had similar entry criteria to the EORTC-ACTION trial; however, the MRC-ICON1 trial did not monitor whether adequate surgical staging was performed. Both RFS and OS were significantly improved; 5-year survival figures were 79% with adjuvant chemotherapy versus 70% without adjuvant chemotherapy.
The pooled data from both studies indicated significant improvement in RFS (HR, 0.64; 95% CI, 0.50–0.82; P = .001) and OS (HR, 0.67; 95% CI, 0.50–0.90; P = .008). These pooled data provided for an OS at 5 years of 82% with chemotherapy and 74% with observation, with a 95% CI in the difference of 2% to 12%. An accompanying editorial emphasized that the focus of subsequent trials must be to identify patients who do not require additional therapy among the early ovarian cancer subset.[Level of evidence: 1iA] Optimal staging is one way to better identify these patients. Except for the most favorable subset (patients with stage IA well-differentiated disease), Gynecologic Oncology Group (GOG) trials, and the evidence above, which is based on double-blinded, randomized controlled trials with total mortality endpoints, support treatment with cisplatin, carboplatin, and paclitaxel (in the United States).
In future trials, the Ovarian Committee of the GOG has opted to include patients with stage II disease in advanced ovarian cancer trials and not to include further study of patients with stage I disease at this time.
Patients with stage II ovarian cancer were also enrolled in a Japanese Gynecology Oncology Group study (JGOG-3601 [NCT00226915]) that tested a weekly dosing schedule versus the conventional every-3-week dosing schedule in first-line ovarian cancer.[16,17,18] These results are reviewed in the Stage III and Stage IV Ovarian Epithelial Cancer Treatment section.
Current Clinical Trials
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with stage I ovarian epithelial cancer and stage II ovarian epithelial cancer. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
General information about clinical trials is also available from the NCI Web site.
Treatment options for patients with all stages of ovarian epithelial cancer have consisted of surgery followed by chemotherapy.
Patients diagnosed with stage III and stage IV disease are treated with surgery and chemotherapy; however, the outcome is generally less favorable for patients with stage IV disease. The role of surgery for patients with stage IV disease is unclear, but in most instances, the bulk of the disease is intra-abdominal, and surgical procedures similar to those used in the management of patients with stage III disease are applied. The options for intraperitoneal (IP) regimens are also less likely to apply both practically (as far as inserting an IP catheter at the outset) and theoretically (aimed at destroying microscopic disease in the peritoneal cavity) in patients with stage IV disease.
Surgery has been used as a therapeutic modality and also to adequately stage the disease. Surgery should include total abdominal hysterectomy and bilateral salpingo-oophorectomy with omentectomy and debulking of as much gross tumor as can safely be performed. While primary cytoreductive surgery may not correct for biologic characteristics of the tumor, considerable evidence indicates that the volume of disease left at the completion of the primary surgical procedure is related to patient survival. A literature review showed that patients with optimal cytoreduction had a median survival of 39 months compared with survival of only 17 months in patients with suboptimal residual disease.[Level of evidence: 3iA]
Results of a retrospective analysis of 349 patients with postoperative residual masses no larger than 1 cm suggested that patients who present at the outset with large-volume disease and achieve small-volume disease by surgical debulking have poorer outcomes than similar patients who present with small-volume disease. Gradual improvement in survival with decreasing residual tumor volume is likely. Although the association may not be causal, retrospective analyses, including a meta-analysis of patients receiving platinum-based chemotherapy, have found cytoreduction to be an independent prognostic variable for survival.[3,4]
A study led by the European Organization for the Research and Treatment of Cancer (EORTC) Gynecological Cancer Group, together with the National Cancer Institute of Canada (NCIC) Clinical Trials Group (EORTC-55971 [NCT00003636]) between 1998 and 2006 included 670 women with stage IIIC and IV ovarian, tubal, and primary peritoneal cancers. The women were randomly assigned to primary debulking surgery followed by at least six courses of platinum-based chemotherapy or to three courses of neoadjuvant platinum-based chemotherapy followed by so-called interval debulking surgery, and at least three more courses of platinum-based chemotherapy. Methods included efforts to ensure accuracy of diagnosis (vis-à-vis peritoneal carcinomatosis of gastrointestinal origin) and stratification by largest preoperative tumor size (excluding ovaries) (<5 cm, >5 cm–10 cm, >10 cm–20 cm, or >20 cm). Other stratification factors were for institution, method of biopsy (i.e., image-guided, laparoscopy, laparotomy, or fine-needle aspiration), and tumor stage (i.e., stages IIIC or IV). The primary endpoint of the study was overall survival (OS), with primary debulking surgery considered the standard.
Median OS for the primary debulking surgery was 29 months, compared with 30 months for patients assigned to neoadjuvant chemotherapy. The hazard ratio (HR) for death in the group assigned to neoadjuvant chemotherapy followed by interval debulking, as compared with the group assigned to primary debulking surgery followed by chemotherapy, was 0.98 (90% confidence interval [CI], 0.84–1.13; P = .01 for noninferiority).[Level of evidence: 1iiA] Perioperative and postoperative morbidity and mortality were higher in the primary-surgery group (7.4% severe hemorrhage and 2.5% deaths, contrasting with 4.1% severe hemorrhage and 0.7% deaths in the neoadjuvant group). The strongest independent predictor of prolonged survival was the absence of residual tumor after surgery. The subset of patients achieving optimal cytoreduction (≤1 cm residuum) whether after primary debulking surgery or after neoadjuvant chemotherapy followed by interval debulking surgery had the best median OS.
For the past 3 decades, the Gynecologic Oncology Group (GOG) has conducted separate trials for women whose disease has been optimally cytoreduced (most recently defined as ≤1 cm residuum) and for those who had suboptimal cytoreductions (>1 cm residuum). The extent of residual disease following the initial surgery is a determinant of outcome in most series [1,2,3,4] and has been used in the design of clinical trials, particularly by the GOG.
On the basis of these findings, the standard treatment approaches are subdivided into the following:
A trial of the Japanese Gynecologic Oncology Group (JGOG-3601 [NCT00226915]) circumvented this treatment trend and included patients with stage II through stage IV disease in addition to the patients undergoing neoadjuvant therapy. With results initially published in 2009 and long-term results updated in 2013, the JGOG-3601 has stimulated a number of other trials that address weekly dosing schedules versus the conventional every-3-weeks (intermittent) dosing in first-line epithelial ovarian cancer.[6,7,8] Conducted between 2003 and 2006, the Japanese trial accrued 637 patients and randomly assigned them to a range of six to nine cycles of the weekly (named "dose-dense") 80 mg/m2 of paclitaxel or to the usual intermittent schedule of paclitaxel at 180 mg/m2. Both regimens were given with carboplatin (area under the curve 6) in every-3-weeks cycles. With a primary endpoint of progression-free survival (PFS), an increase from 16 to 21 months in the PFS of the weekly paclitaxel-based regimen was sought.
The PFS surpassed expectations at the 1.5-year follow-up after cessation of treatment. The weekly regimen had a median PFS of 28.0 months (95% CI, 22.3–35.4 months), and the intermittent median PFS was 17.2 months (15.7–21.1; HR, 0.71), favoring the weekly regimen (P = .0015). The 3-year OS also favored the weekly regimen (P = .03). The 2013 updated results revealed unexpected median survival results for the weekly regimen (median OS, 8.3 years vs. 5.1 years; P = .040); the intermittent regimen results are also noteworthy relative to other clinical trials of weekly dosing schedules.
Other than ethnicity, this trial population differed from other studies in the following ways:
Several ongoing trials include an intermittent dosing arm comparing both intraperitoneal chemotherapy and conventional-schedule intravenous (IV) treatment in patients after both optimal and suboptimal cytoreduction. When these results are available, it will be easier to identify the patient populations that are best suited for intermittent dosing.
Treatment Options for Patients With Optimally Cytoreduced Stage III Disease
The pharmacologic basis for the delivery of anticancer drugs by the IP route was established in the late 1970s and early 1980s. When several drugs were studied, mostly in the setting of minimal residual disease at reassessment after patients had received their initial chemotherapy, cisplatin alone and in combination received the most attention. Favorable outcomes from IP cisplatin were most often seen when tumors had shown responsiveness to platinums and with small-volume tumors (usually defined as tumors <1 cm). In the 1990s, randomized trials were conducted to evaluate whether the IP route would prove superior to the IV route. IP cisplatin was the common denominator of these randomized trials.
The use of IP cisplatin as part of the initial up-front approach in patients with stage III optimally debulked ovarian cancer is supported principally by the results of three randomized clinical trials (SWOG-8501, GOG-0114, and GOG-0172).[10,11,12] These studies tested the role of IP drugs (IP cisplatin in all three studies and IP paclitaxel in the last study) against the standard IV regimen. In the three studies, superior PFS and OS favoring the IP arm was documented. Specifically, the most recent study, GOG-0172, resulted in a median survival rate of 66 months for patients on the IP arm versus 50 months for patients who received IV administration of cisplatin and paclitaxel (P = .03).[Level of evidence:1iiA] Toxic effects were greater in the IP arm, contributed to in large part by the cisplatin dose per cycle (100 mg/m2) and by sensory neuropathy from the additional IP as well as from the IV administration of paclitaxel. The rate of completion of six cycles of treatment was also less frequent in the IP arm (42% vs. 83%) because of the toxic effects and catheter-related problems.
Notwithstanding these problems, IP therapy for patients with optimally debulked ovarian cancer is receiving wider adoption, and efforts are under way by the GOG to examine some modifications of the IP regimen used in GOG-0172 to improve its tolerability (e.g., to reduce by ≥25% the total 3-hour amount of cisplatin given; a shift from the less practical 24-hour IV administration of paclitaxel to a 3-hour IV administration). A Cochrane-sponsored meta-analysis of all randomized IP versus IV trials shows an HR of 0.79 for disease-free survival and 0.79 for OS, favoring the IP arms. In another meta-analysis of seven IP versus IV randomized trials that were conducted by Cancer Care of Ontario, the relative ratio (RR) of progression at 5 years based on the three trials that reported this endpoint was 0.91 (95% CI, 0.85–0.98) and the RR of death at 5 years based on six trials was 0.88 (95% CI, 0.81–0.95).
Treatment Options for Patients With Suboptimally Cytoreduced Stage III and Stage IV Disease
The value of interval cytoreductive surgery has been the subject of two large phase III trials. In the first study, performed by the EORTC, patients subjected to debulking after four cycles of cyclophosphamide and cisplatin (with additional cycles given later) had an improved survival rate compared with patients who completed six cycles of this chemotherapy without surgery.[Level of evidence: 1iiB] The GOG-0162 trial was designed to answer a very similar question but used the then-standard paclitaxel-plus-cisplatin regimen as the chemotherapy. This trial did not demonstrate any advantage from the use of interval cytoreductive surgery. The divergence of results may be caused by the efficacy of the chemotherapy obscuring any effects of interval cytoreduction, the wider use of maximal surgical effort at the time of diagnosis by U.S. gynecologic oncologists, or unknown factors. Although many patients with stage IV disease also undergo cytoreductive surgery at diagnosis, whether this improves survival has not been established.
First-line treatment of ovarian cancer is cisplatin, given IV, or its second-generation analog, carboplatin, given either alone or in combination with other drugs. Clinical response rates from these drugs regularly exceed 60%, and median time-to-recurrence usually exceeds 1 year in this subset of suboptimally debulked women. Trials by various cooperative groups in the subsequent 2 decades addressed issues of optimal dose-intensity [17,18,19] for both cisplatin and carboplatin, schedule, and the equivalent results obtained with either of these platinum drugs, usually in combination with cyclophosphamide. With the introduction of the taxane paclitaxel, two trials confirmed the superiority of cisplatin combined with paclitaxel to the previous standard of cisplatin plus cyclophosphamide; however, two trials that compared the agent with either cisplatin or carboplatin as a single agent failed to confirm such superiority in all outcome parameters (i.e., response, time-to-progression, and survival) (see Table 2).
Nevertheless, for patients with ovarian cancer, the combination of cisplatin or carboplatin and paclitaxel has been used as the initial treatment (defined as induction chemotherapy) for several reasons:
Since the adoption of the platinum-plus-taxane combination as the standard nearly worldwide, clinical trials have demonstrated:
In this large study consisting of 84% to 87% of patients with the Féderation Internationale de Gynécologie et d'Obstétrique stage III disease, as expected, the extent of cytoreduction was an important prognostic factor in OS. Results of PFS in patients with residuum greater than 1cm, less than or equal to 1 cm, or microscopic were 13, 16, and 29 months, respectively; whereas for OS, the results were 33, 40, and 68 months, respectively.
Consolidation and/or maintenance therapy
Trials of consolidation and/or maintenance therapy have been carried out with drugs that contribute to the treatment of recurrent ovarian cancer. Presently, not one of the treatments given after the initial platinum/paclitaxel induction has been shown to improve survival; these treatments include the following:
A GOG-178 study of 277 patients compared three doses versus twelve doses of monthly paclitaxel given every 4 weeks following a clinically defined complete response at the time of completion of platinum/paclitaxel induction. However, the study was stopped early because of a very significant difference in PFS (28 months vs. 21 months).[Level of evidence: 1iiDiii] Subsequent updates of this data have raised the possibility that a subset of patients with low CA 125 levels might show a survival benefit. A trial to confirm the value of maintenance with taxanes versus observation is being conducted by the GOG.
A smaller Italian study entered 200 patients over 7 years who were randomly assigned to either 12 similar courses of monthly paclitaxel or observation; patients were in clinical complete response (n = 95) or pathologic complete response (n = 105) after induction therapy at the time of their random assignment. Sensory neuropathy was the most prominent toxicity and was grade 2 in 21.3% of the patients and grade 3 in 6.7% of the patients. The median PFS for the maintenance paclitaxel arm was 34 months (95% CI, 20–43 months) and 30 months (95% CI, 17–53 months) for the observation arm. Neither PFS nor OS differences were significant.
An accompanying editorial points out the weaknesses of both studies in order to draw conclusions (both stopped early and were noninformative for survival endpoint). Also, although both studies addressed the issue of maintenance paclitaxel administered monthly, the patient populations differed. This was reflected by the considerably better outcome in both arms of the Italian study. Taken together, paclitaxel maintenance is of unproven value and requires validation by the ongoing and larger GOG-178 study cited above.
Two phase III trials (GOG-0218 [NCT00262847] and ICON 7 [NCT00483782]) have evaluated the role of bevacizumab in first-line therapy for ovarian, fallopian tube, and primary peritoneal cancers following surgical cytoreduction.[41,42] Both trials showed a modest improvement in PFS when bevacizumab was added to initial chemotherapy and continued every 3 weeks for 16 and 12 additional cycles, respectively, as a maintenance phase.
GOG-0218 was a double blind, randomized, controlled trial that included 1,873 women with stage III or IV disease, all of whom received chemotherapy—carboplatin (AUC 6) and paclitaxel (175 mg/m2 for six cycles). Participants were randomly assigned to receive:
The women were enrolled with a primary endpoint of PFS; 40% of the patients had suboptimally resected stage III disease, and 26% had stage IV disease. There was no difference in PFS between the control group and the bevacizumab-initiation group. There was a statistically significant increase in PFS in the bevacizumab-throughout group when compared with the control group (14.1 vs. 10.3 months), with a HR of progression or death of 0.717 in the bevacizumab-throughout group (95% CI, 0.625–0.824; P < .001). Median OS was 39.3, 38.7, and 39.7 months for the control group, bevacizumab-initiation group, and the bevacizumab-throughout group, respectively. Quality of life was not different between the three groups. Hypertension grade 2 or greater was more common with bevacizumab than with the placebo. There were more treatment-related deaths in the bevacizumab-throughout arm (10 of 607, 2.3%) than in the control arm (6 of 601, 1.0%).[Level of evidence: 1iDiii]
ICON 7 randomly assigned 1,528 women after initial surgery to chemotherapy—carboplatin (AUC 5 or 6) plus paclitaxel (175 mg/m2 for six cycles)—or to chemotherapy plus bevacizumab (7.5 mg/kg for six cycles), followed by bevacizumab alone for an additional 12 cycles. The women were randomly assigned, and PFS was the main outcome measure; 9% of patients had early-stage, high-grade tumors, and 70% had stage IIIC or IV disease. Twenty-six percent had more than 1 cm of residual tumor prior to initiating chemotherapy. Median PFS was 17.3 months in the control group and 19 months in the bevacizumab group. HR for progression or death in the bevacizumab group was 0.81 (95% CI, 0.70–0.94; P = .004). Bevacizumab was associated with an increase in bleeding, hypertension (grade 2 or higher), thromboembolic events (grade 3 or higher), and gastrointestinal perforations. Grade 3 or greater adverse events were more common in the bevacizumab group. Quality of life was not different between the two groups.[Level of evidence: 1iiDiii]
A third trial, OCEANS (Ovarian Cancer Study Comparing Efficacy and Safety of Chemotherapy and Anti-Angiogenic Therapy in Platinum-Sensitive Recurrent Diseases [NCT00434642]), assessed the role of bevacizumab in the treatment of platinum-sensitive recurrences (see Table 3 for other trials in this setting). In this double-blind, placebo-controlled, phase III trial of chemotherapy (gemcitabine + carboplatin) with or without bevacizumab for recurrent epithelial ovarian, primary peritoneal, or fallopian tube cancer, 242 patients were randomly assigned per arm. Median PFS for patients receiving bevacizumab was 12.4 months versus 8.4 months for those receiving a placebo. The effect of bevacizumab on HR to progression in patients assigned to the bevacizumab arm compared with placebo was 0.484 (95% CI, 0.388–0.605; P <.0001). Objective responses to chemotherapy were increased when combined with bevacizumab (78.5% vs. 57.4%; P < .0001).
In contrast to the first-line studies, treatment was allowed to continue beyond six cycles to ten cycles in responding patients, but there was no maintenance. A subsequent analysis will appear when additional survival data become mature; however, at the time of publication, differences in median survival were not apparent, and crossover from a placebo to bevacizumab had occurred in 31% of the patients. Bevacizumab-associated toxicities such as hypertension and proteinuria were more prominent than in the first-line trials, but feared safety issues, such as gastrointestinal perforations, did not occur during the study. Discontinuing treatment because of adverse events was more common with bevacizumab (n = 55 vs. n = 12 for placebo) but fewer patients discontinued treatment because of disease progression (n = 104 vs. n = 160 for placebo).[Level of evidence: 1iiDiii]
These three studies confirm the effect of improving PFS when bevacizumab is added to chemotherapy for ovarian cancer. In the OCEANS trial, the HR for progression was even more prominent than in the first-line trials, and a significant effect was seen when the bevacizumab and chemotherapy combination was extended beyond six cycles until progression. Without additional data, a statement about how bevacizumab should be used in ovarian cancer treatment is not possible because of the uncertain impact on OS, lack of clear delineation of who derives the greatest benefit, and prominent, associated toxicities.
At this time, the evidence does not support the use of bevacizumab as front-line therapy, because the gain in PFS comes with increased toxicity without improvement in OS or quality of life.
Treatment Options Under Clinical Evaluation
Information about ongoing clinical trials is available from the NCI Web site.
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with stage III ovarian epithelial cancer and stage IV ovarian epithelial cancer. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
Overall, approximately 80% of patients diagnosed with ovarian epithelial cancer will relapse after first-line platinum-based and taxane-based chemotherapy and may benefit from subsequent therapies. Early detection of persistent disease by second-look laparotomies after completing first-line treatment is no longer practiced; when the outcomes in the 50% of institutions practicing such procedures were informally compared with the outcomes in those institutions not using such procedures, additional lack of support for them grew, as was found in the case for patients entered in GOG-0158. However, the practice of close follow-up of patients completing treatment by serial CA 125s at intervals of 1 to 3 months was nearly universally adopted. In patients who are in clinical complete remission, increases in CA 125 from their initial treatment represent the most common method to detect disease that will eventually relapse clinically.
A trial by the Medical Research Council and European Organization for Research and Treatment of Cancer (MRC-OV05, which is now closed) examined the consequences of early institution of treatment for recurrence versus treatment delayed until clinical symptoms appeared. Patients in clinical complete remission after platinum-based chemotherapy were registered and followed with CA 125s only and clinical visits. Upon detection of a twofold elevation over the normal range, patients were randomly assigned to disclosure of the result (and early treatment for recurrence) versus continued blinding and treatment upon development of signs and symptoms indicative of clinical relapse. The number of randomly assigned patients was to exceed 500 in order to yield a superior survival outcome at 2 years with early institution of therapy; this required 1,400 registrations, which were accrued between May 1996 and August 2005. Among 1,442 registrants, 29% continued to show no evidence of relapse, 19% relapsed without evidence of CA 125 doubling beyond normal or at the same time, and another 4% died prior to becoming eligible for random assignment. Registrants had stage III and stage IV disease in 67% of the cases, whereas these stages represented 80% of the randomly assigned patients. The median survival of all patients registered was 70.8 months.
Median survival for patients randomly assigned to early treatment (n = 265) was 25.7 months compared with 27.1 months for those patients in the delayed-treatment group (n = 264) (HR, 0.98; 95% CI, 0.8–1.2). The median delay in instituting second-line chemotherapy was 4.8 months, and the median delay in instituting third-line chemotherapy was 4.6 months. Treatments for second-line chemotherapy were comparable among the two groups (mostly platinum- and taxane-based), whereas third-line treatments were less often applied to the delayed-treatment group. The study concluded that there was no benefit in the detection of early presence of disease by CA 125; this is consistent with the failure of second-look surgeries to provide improved outcomes after early detection of persistent disease. Monitoring CA 125 levels in follow-up may play a role in identifying appropriate candidates for secondary cytoreduction, although this strategy awaits confirmation with a randomized trial.
Local Modalities: Surgery and Radiation Therapy
Cytoreduction is often employed, but such intervention only now is being studied in the setting of a randomized clinical trial (GOG-0213). The role of radiation therapy in patients with recurrent ovarian cancer has not been defined.
Systemic treatment options for patients with recurrent disease are subdivided as follows:
Carboplatin was approved in 1987 for the treatment of patients with ovarian cancer whose disease recurred after treatment with cisplatin, based on improved survival with etoposide or 5-fluorouracil. In a randomized, phase II trial of paclitaxel, a currently used second-line drug, the cisplatin-containing combination of cisplatin plus doxorubicin plus cyclophosphamide (CAP) yielded a superior survival outcome. This, and subsequent studies (see Table 3), have reinforced using carboplatin as the treatment core for patients with platinum-sensitive recurrences. Cisplatin is occasionally used, particularly in combination with other drugs, because of its lesser myelosuppression, but this advantage over carboplatin is counterbalanced by its greater intolerance. Oxaliplatin, initially introduced with the hope that it would overcome platinum resistance, has activity mostly in platinum-sensitive patients  but has not been compared with carboplatin alone or in combinations.
With all platinums, outcome is generally better the longer the initial interval without recurrence from the initial platinum-containing regimens. Therefore, on occasion, patients with platinum-sensitive recurrences relapsing within 1 year have been included in trials of nonplatinum drugs. In one such trial, comparing the pegylated liposomal doxorubicin (PLD) to topotecan, the subset of patients who were platinum sensitive had better outcomes with either drug (and in particular with PLD) relative to the platinum-resistant cohort.
Several randomized trials have addressed whether the use of a platinum in combination with other chemotherapy agents is superior to single agents (see Table 3). In an analysis of data examining jointly the results of three trials performed by the Medical Research Council/Arbeitsgemeinschaft Gynaekologische Onkologie (MRC/AGO) and ICON investigators (known as ICON-4), a platinum-plus-paclitaxel combination yielded a superior outcome, in terms of response rates, progression-free survival (PFS), and overall survival (OS), compared with carboplatin as a single agent or other platinum-containing combinations as controls. Platinum plus paclitaxel was compared with several control regimens, although 71% used carboplatin as a single agent in the control, and 80% used carboplatin plus paclitaxel. Prolonged PFS (HR, 0.76; 95% CI, 0.66–0.89; P = .004) and OS (HR, 0.82; 95% CI, 0.69–0.97; P = .023) were improved in the platinum-plus-paclitaxel arm.; [Level of evidence: 1iiA] The AGO had previously compared the combination of epirubicin plus carboplatin to carboplatin alone and had not found significant differences in outcome.
Another trial by European and Canadian groups compared gemcitabine plus carboplatin to carboplatin. The PFS of 8.6 months with the combination was significantly superior to 5.8 months for the carboplatin alone (HR, 0.72; 95% CI, 0.58–0.90; P = .003). The study was not powered to detect significant differences in OS, and the median survival for both arms was 18 months (HR, 0.96; CI, 0.75–1.23; P = .73).
Carboplatin plus paclitaxel has been considered the standard regimen for platinum-sensitive recurrence in the absence of residual neurological toxic effects. The GOG-0213 trial is comparing this regimen to the experimental arm that adds bevacizumab to carboplatin plus paclitaxel.
In a phase III trial, carboplatin plus PLD (CD) was compared to carboplatin plus paclitaxel (CP) in patients with platinum-sensitive recurrence (>6 months). The primary endpoint was PFS with a median PFS for the CD arm of 11.3 months versus 9.4 months for the CP arm (HR, 0.823; 95% CI, 0.72–0.94; P = .005).[Level of evidence: 1iiDiii] The CP arm was associated with increased severe neutropenia, alopecia, neuropathy, and allergic reaction; the CD arm was associated with increased severe thrombocytopenia, nausea, and hand-foot syndrome. Although OS data have not been reported, given its toxicity profile and noninferiority to the standard regimen, CD is an important option for patients with platinum-sensitive recurrence.
Platinum-Refractory or Platinum-Resistant Recurrence
Clinical recurrences that take place within 6 months of completion of a platinum-containing regimen are considered platinum-refractory or platinum-resistant recurrences. Anthracyclines (particularly when formulated as PLD), taxanes, topotecan, and gemcitabine are used as single agents for these recurrences based on activity and their favorable therapeutic indices relative to agents listed in Table 4. The long list underscores the marginal benefit, if any, generally conveyed by these agents. Patients with platinum-resistant disease should be encouraged to enter clinical trials.
Treatment with paclitaxel historically provided the first agent with consistent activity in patients with platinum-refractory or platinum-resistant recurrences.[14,15,16,17,18] Subsequently, randomized studies have indicated that the use of topotecan achieved results that were comparable to those achieved with paclitaxel. Topotecan was compared with PLD in a randomized trial of 474 patients and demonstrated similar response rates, PFS, and OS at the time of the initial report, which was contributed primarily by the platinum-resistant subsets.
Drugs used to treat platinum-refractory or platinum-resistant recurrence:
The combination of weekly topotecan and biweekly bevacizumab was evaluated in a phase II study that showed an objective response rate of 25% (all partial responses) in a platinum-resistant patient population. The most common grade 3 and grade 4 toxicities were hypertension, neutropenia, and gastrointestinal (GI) toxicity, though no bowel perforations occurred.
Liposomal doxorubicin and topotecan have been compared in a randomized trial of 474 patients with recurrent ovarian cancer. Response rates (19.7% vs. 17.0%; P = .390), PFS (16.1 wk vs. 17.0 wk; P = .095), and OS (60 wk vs. 56.7 wk; P = .341) did not differ significantly between the liposomal doxorubicin and topotecan arms, respectively.[Level of evidence: 1iiA] Survival was longer for the patients with platinum-sensitive disease who received liposomal doxorubicin.
A randomized trial of gemcitabine versus PLD showed noninferiority and no advantage in therapeutic index of one drug over the other.
In a phase III study, 235 patients who did not respond to initial treatment with a platinum-based regimen but who had not previously received paclitaxel or topotecan, were randomly assigned to receive either topotecan as a 30-minute infusion daily for 5 days every 21 days or paclitaxel as a 3-hour infusion every 21 days. The overall objective response rate was 20.5% for those patients who were randomly assigned to treatment with topotecan and 13.2% for those patients who were randomly assigned to treatment with paclitaxel (P = .138). Both groups experienced myelosuppression and GI toxic effects. Nausea and vomiting, fatigue, and infection were observed more commonly following treatment with topotecan, whereas alopecia, arthralgia, myalgia, and neuropathy were observed more commonly following paclitaxel. (Refer to the PDQ summary on Gastrointestinal Complications for information on gastrointestinal toxic effects; refer to the PDQ summary on Nausea and Vomiting and the PDQ summary on Fatigue; and, refer to the PDQ summary on Pain for information on arthralgia, myalgia, and neuropathy.)
The first study (GOG-0170D) included 62 patients who had received only one or two prior treatments (these last patients had received one additional platinum-based regimen because of an initial interval of 12 months or greater after first-line regimens and also had to have a performance status of 0 or 1). Patients received a dose of 15 mg/kg every 21 days; there were two complete responses and 11 partial responses, a median PFS of 4.7 months, and an OS of 17 months. This activity was noted in both platinum-sensitive and platinum-resistant subsets.
The second study only included patients with platinum-resistant disease using an identical dose schedule, but the study was stopped because five of 44 patients experienced bowel perforations, one of them fatal; seven partial responses had been observed. This increased risk of bowel perforations was associated with three or more prior treatments.[33,34,35][Level of evidence: 3iiiDii]
The third study (CCC-PHII-45) included 70 patients who received 50 mg of oral cyclophosphamide daily, in addition to bevacizumab (10 mg/kg every 2 wk); 17 partial responses were observed and four patients had intestinal perforations.
A phase II study by the Gynecologic Oncology Group utilized pemetrexed (900 mg/m2) IV every 3 weeks in 51 patients with platinum-resistant recurrent disease. The response rate was 21% in a heavily pretreated population in which 39% had five or more prior regimens. Myelosuppression and fatigue were the most common severe toxicities.
Other drugs used to treat platinum-refractory or platinum-resistant recurrence
This group includes drugs that are not fully confirmed to have activity in a platinum-resistant setting, have a less desirable therapeutic index, and have a level of evidence lower than 3iiiDiv.
Treatment Options for Patients with Recurrent or Persistent Disease
Check for U.S. clinical trials from NCI's list of cancer clinical trials that are now accepting patients with recurrent ovarian epithelial cancer. The list of clinical trials can be further narrowed by location, drug, intervention, and other criteria.
The PDQ cancer information summaries are reviewed regularly and updated as new information becomes available. This section describes the latest changes made to this summary as of the date above.
General Information About Ovarian Epithelial Cancer
Added text to state that findings from risk-reducing surgeries in healthy women with BRCA1/2 mutations have reinforced the hypothesis that many high-grade serous cancers may arise from precursor lesions that originate in the fimbriae of the fallopian tubes (cited Levanon et al. as reference 5). Also added that histologically similar cancers diagnosed as primary peritoneal carcinomas share molecular findings, such as loss or inactivation of the tumor-suppressors p53 and BRCA1/2 proteins; therefore, high-grade serous adenocarcinomas arising from the fallopian tube and elsewhere in the peritoneal cavity, together with most ovarian epithelial cancers, represent "extrauterine adenocarcinomas of Müllerian epithelial origin" and are staged and treated similarly to ovarian cancer. On the other hand, clear cell and endometrioid ovarian cancers that are linked to endometriosis have different gene-expression signatures, as do mucinous subtypes (cited Birrer as reference 6).
Stage I and Stage II Ovarian Epithelial Cancer Treatment
Added text to state that patients with stage II ovarian cancer were also enrolled in a Japanese Gynecology Oncology Group (JGOG) study that tested a weekly dosing schedule versus the conventional every-3-week dosing schedule in first-line ovarian cancer (cited 2009 Katsumata et al., 2013 Katsumata et al., and Scambia et al. as references 16, 17, and 18, respectively).
Stage III and Stage IV Ovarian Epithelial Cancer Treatment
Added text to state that a JGOG trial circumvented the standard treatment trend and included patients with stage II through stage IV disease in addition to the patients undergoing neoadjuvant therapy. Also added that with results initially published in 2009 and long-term results updated in 2013, the JGOG-3601 trial has stimulated a number of other trials that address weekly dosing schedules versus the conventional every-3-week dosing in first-line epithelial ovarian cancer (cited 2009 Katsumata et al., 2013 Katsumata et al., and Scambia et al. as references 6, 7, and 8, respectively). Also added that, conducted between 2003 and 2006, the Japanese trial accrued 637 patients and randomly assigned them to a range of six to nine cycles of the weekly 80 mg/m2 of paclitaxel versus the usual intermittent schedule of paclitaxel at 180 mg/m2; both regimens were given with carboplatin (area under the curve 6) in every-3-weeks cycles. With a primary endpoint of progression-free survival (PFS), an increase from 16 to 21 months in the PFS of the weekly paclitaxel-based regimen was sought.
Added text to state that the PFS surpassed expectations at the 1.5-year follow-up after cessation of treatment; the weekly regimen had a median PFS of 28.0 months, and the intermittent median PFS was 17.2 months, favoring the weekly regimen. The 3-year overall survival also favored the weekly regimen. Added that the 2013 updated results revealed unexpected median survival results for the weekly regimen; the intermittent regimen results are also noteworthy relative to other clinical trials of weekly dosing schedules. Other than ethnicity, the JGOG-3601 trial population differed from other studies in terms of median age, number of stage II patients, use of the neoadjuvant setting, number of patients with histologies other than high-grade serous or endometrioid, and number of patients without high-grade histologies.
Added text to state that several ongoing trials include an intermittent dosing arm comparing both intraperitoneal chemotherapy and conventional-schedule intravenous treatment in patients after both optimal and suboptimal cytoreduction. When these results are available, it will be easier to identify the patient populations that are best suited for intermittent dosing.
This summary is written and maintained by the PDQ Adult Treatment Editorial Board, which is editorially independent of NCI. The summary reflects an independent review of the literature and does not represent a policy statement of NCI or NIH. More information about summary policies and the role of the PDQ Editorial Boards in maintaining the PDQ summaries can be found on the About This PDQ Summary and PDQ NCI's Comprehensive Cancer Database pages.
Purpose of This Summary
This PDQ cancer information summary for health professionals provides comprehensive, peer-reviewed, evidence-based information about the treatment of ovarian epithelial cancer. It is intended as a resource to inform and assist clinicians who care for cancer patients. It does not provide formal guidelines or recommendations for making health care decisions.
Reviewers and Updates
This summary is reviewed regularly and updated as necessary by the PDQ Adult Treatment Editorial Board, which is editorially independent of the National Cancer Institute (NCI). The summary reflects an independent review of the literature and does not represent a policy statement of NCI or the National Institutes of Health (NIH).
Board members review recently published articles each month to determine whether an article should:
Changes to the summaries are made through a consensus process in which Board members evaluate the strength of the evidence in the published articles and determine how the article should be included in the summary.
The lead reviewers for Ovarian Epithelial Cancer Treatment are:
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Levels of Evidence
Some of the reference citations in this summary are accompanied by a level-of-evidence designation. These designations are intended to help readers assess the strength of the evidence supporting the use of specific interventions or approaches. The PDQ Adult Treatment Editorial Board uses a formal evidence ranking system in developing its level-of-evidence designations.
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National Cancer Institute: PDQ® Ovarian Epithelial Cancer Treatment. Bethesda, MD: National Cancer Institute. Date last modified <MM/DD/YYYY>. Available at: http://cancer.gov/cancertopics/pdq/treatment/ovarianepithelial/HealthProfessional. Accessed <MM/DD/YYYY>.
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Last Revised: 2014-01-31
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