Abstract
Cervical cancer remains a major threat to women’s health, followed by the endometrial cancer. Ovarian cancer is the second most common cancer of the female genital tract, but accounts for over half of all deaths related to gynecologic neoplasms. The disease typically has vague symptoms that are often ignored, and it is therefore usually diagnosed at an advanced stage. Prognosis is strongly related to the stage of disease at initial diagnosis. In the pretreatment setting, accurate staging and assessment of prognostic factors are crucial for determining the optimal treatment modality in these diseases. Integrated 18FDG PET/CT has been used successfully not only for the diagnosis and staging but also for restaging, therapy monitoring, and prognostic prediction of ovarian and gynecological cancer as well as various other malignant tumors. This chapter aimed at evaluating the role of functional imaging with PET in the management of ovarian and gynecological cancer, discussing its usefulness and limitations and compared to other radiological imaging methods in the assessment of these patients.
Access provided by Autonomous University of Puebla. Download chapter PDF
Similar content being viewed by others
Keywords
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
1 Ovarian Cancer
Among gynecologic cancers, ovarian cancer is the second most common malignancy after endometrial cancer in developed countries but causing more deaths than the remaining gynecological cancers added together [1].
The high mortality reflects advanced stage at presentation with extrapelvic peritoneal disease and/or abdominopelvic lymphadenopathy or parenchymal metastases. Ovarian cancer can spread by intraperitoneal seeding, direct invasion, or through the lymphatic and vascular circulation. Peritoneal seeding is the most common route of dissemination [2].
Functional imaging with 18FDG-PET benefits from the increased utilization of glucose by malignant cells and their high uptake of glucose compared to normal ones, opening a new field in clinical oncologic imaging. 18FDG PET/CT makes it possible to acquire both metabolic and anatomic imaging data using a single device in a single diagnostic session and provides precise anatomic localization of suspicious areas of increased 18FDG uptake [3]. In this clinical setting, 18FDG PET/CT has achieved a significant improvement in diagnostic accuracy and exerted a considerable impact on patient management including diagnosis, staging, optimization of treatment, restaging, therapy monitoring, and prognostic prediction of various malignant tumors [4].
1.1 Diagnosis and Staging
The first approach to the study of ovarian tumors is based on gynecological examination, specific serum tumor markers like CA 125, and transvaginal ultrasound (TVUS). When a lesion is confirmed, other imaging techniques such as computed tomography (CT) and/or magnetic resonance imaging (MRI) are performed [5]. The differentiation between malignant and benign ovarian tumors is better obtained with contrast-enhanced pelvic MRI thanks to its excellent spatial and contrast resolution according to recently reported good diagnostic performance of 92–100 % sensitivity and 76–94 % specificity using a 3 T magnet [6].
Also 18FDG PET/CT shows a relatively good diagnostic accuracy in differentiating malignant and benign ovarian tumors (87–100 % sensitivity, 74–100 % specificity, and 92–97 % accuracy) [7]. Ovarian lesions will show variable increase in 18FDG uptake on PET/CT. In a study by Castellucci et al., a focally increased standardized uptake value (SUV) of three or higher in the ovary was considered positive for ovarian malignancy, whereas an SUV of 2.7 or lower was considered consistent with a benign finding. Moreover, differentiation between benign and malignant uptake on PET can be aided by the contemporaneously acquired CT scan on the basis of the characteristic pattern and location of 18FDG uptake and the lack of discrete lymph nodes in patients with benign lesions [8].
But 18FDG PET/CT hardly detects low-grade and early adenocarcinomas and borderline tumors with small volume or low cellular density, and false-positive results have also been reported in cases of serous cystadenoma, endometrioma, teratoma, and fibroma [9].
In premenopausal women undergoing surveillance imaging for other malignancies, hypermetabolic ovarian uptake is seen in the late follicular to early luteal cyst phases and has been mistaken for metastases to the ovaries or pelvic sidewall nodes [10]. In contrast, hypermetabolic ovarian uptake in a postmenopausal woman is abnormal and should be considered suspicious for malignancy. Thus, in interpreting PET images, ovarian tracer uptake should be correlated with the patient’s menstrual status and phase [11].
In this manner, 18FDG PET/CT had a good diagnostic value in differentiating between malignant and benign tumors and a low diagnostic value in differentiating between borderline malignant and benign tumors [12].
However, because of its high specificity, 18FDG PET/CT may be used to confirm the diagnosis and rule out the presence of metastases before the patient undergoes surgical evaluation.
Ovarian cancer is staged by exploratory laparotomy according to the International Federation of Gynecology and Obstetrics (FIGO) and/or TNM staging systems [13] (Table 34.1). The surgery options include the staging laparoscopy or extensive surgery, including large resections or port implantation for intraperitoneal chemotherapy. An accurate staging at the time of diagnosis is extremely important in order to plan adequate therapy and is the most important prognostic factor in this cancer.
For preoperative staging of ovarian cancer, MRI has been accepted as being the most useful imaging technique in the assessment of the pelvis for local extent of primary disease and the relationship of tumor with surrounding vascular and lymphatic structures [14].
In fact, high-resolution MRI including dynamic postcontrast acquisition and diffusion-weighted imaging (DWI) may remain as the best imaging technique also in detecting tiny lesions and disseminated initial peritoneal lesions [15, 16]. Moreover,to obtain the initial staging and therapeutic decision, it is necessary to perform a chest and abdominal CT, for assessment of lymphatic extension of the disease, not only in the pelvic site but also in the abdomen and thorax. The main pathways of lymphatic spread are along the ovarian vessels to the upper common iliac and para-aortic lymph nodes and along the broad ligament and parametria to the external iliac and obturator nodes [17].
The inability of CT and MRI to detect cancer in normal-sized lymph nodes or to discriminate between hyperplastic lymph nodes and metastases remains a major problem in conventional oncologic imaging [18]. In this case, we can use 18FDG PET/CT for ovarian cancer staging. In fact, it has mainly been used to assess lymph node and distant metastasis, rather than to determine tumor extension and its relationship with surrounding tissues. PET/CT has an effective role in staging patients with advanced stage, providing useful information on involvement of extrapelvic sites, such as either supraclavicular and para-aortic lymph nodes or peritoneum, omentum, bone, and muscle metastasis.
Recent studies have shown that 18FDG PET, when used in conjugation with CT, is useful in evaluating distant metastases as well as equivocal lesions [8, 17]. PET/CT has high sensitivity in identifying peritoneal deposits larger than 1 cm and lymph nodes larger than 7 mm (Fig. 34.1). It has been shown to increase the pretreatment staging accuracy to 69–75 % compared with 53–55 % obtained with CT alone [8]. Although both of these studies [8, 17] show definite evidence of improved accuracy in staging with the use of PET/CT, they also suggest that PET/CT is particularly useful in distinguishing patients with stages IIIC–IV ovarian cancer from those with stages I–IIIB cancer. For this classification, the specificity, sensitivity, and accuracy of 18FDG PET/CT were 91, 100, and 98 %, respectively, in comparison with 64, 97, and 88 % for CT alone.
Thus, PET/CT can help in identifying the clinically important group of patients for whom optimal debulking is not possible and who thus need to undergo preoperative chemotherapy.
1.2 Monitoring Chemotherapy
Neoadjuvant chemotherapy has been used to improve the outcome of patients with initial inoperable cancer, and 18FDG PET/CT has been proposed for the monitoring of cytoreductive therapy.
Conventional anatomical imaging is commonly used to assess the response to treatment by evaluating changes in tumor size as for other tumors, but this approach is limited in detecting the early response after the initiation of therapy because anatomic changes are usually seen only 2 or 3 months after the start of therapy. Metabolic changes often precede morphologic changes in tumor response and, therefore, 18FDG-PET can demonstrate this response sooner than CT and MRI.
18FDG-PET is thought to be useful in the detection of nonresponders to chemotherapy at an earlier stage during treatment. Identification of nonresponders would significantly improve patient management by reducing the use of ineffective therapies, preventing adverse effects, reducing the delay before administering more effective treatment, and minimizing costs.
Nishiyama et al. demonstrated that 18FDG PET/CT-derived parameters, including SUV and percentage change, have the potential to predict response to chemotherapy or chemoradiotherapy in patients with advanced gynecologic cancer (uterine cancer, n = 13; ovarian cancer, n = 8) [19]. Based on histopathologic analysis of the specimens obtained at surgery, 10 patients were found to be responders and 11 to be nonresponders. When an arbitrary SUV of 3.8 was taken as the cutoff for differentiating between responders and nonresponders after therapy, 18FDG PET/CT showed a sensitivity of 90 %, a specificity of 63.6 %, and an accuracy of 76.2 %. When an arbitrary percentage change of 65 % was taken as the cutoff, 18FDG PET/CT showed a sensitivity of 90 %, a specificity of 81.8 %, and an accuracy of 85.7 %.
1.3 Restaging
The survival of patients after first line of treatment has improved significantly as a result of advances in surgical procedures and chemotherapy. However, this extended survival has simultaneously increased the incidence of recurrence, even after surgery and adjuvant chemotherapy in early stage tumors, and it has been reported that 75 % of patients with ovarian cancer have a likelihood of disease relapse [20].
Early diagnosis of recurrence and exact anatomic localization of metastatic disease are crucial for determination of the best treatment strategy. Therefore, a close follow-up is essential utilizing noninvasive techniques such as tumor marker levels and imaging tests.
The monitoring of CA 125 tumor marker shows a high sensitivity for early diagnosis of recurrence in ovarian cancer, but it does not give any information about the extent or location of recurrence. Moreover, it has a poor negative predictive value. Currently, CA 125 level less than 35 U/mL is accepted as normal [21], and the existence of recurrence is based on higher levels in patients with normalization after the primary treatment or elevation of the nadir levels in patients with an elevated serum marker that never normalized after primary treatment [22].
There is an open debate in the literature regarding cutoff value of serum markers in women treated for ovarian cancer, since CA 125 has a good overall accuracy (80 %) but a low negative predictive value.
Nanni et al. analyzed the role of 18FDG PET/CT in a cohort of patients with suspected relapse of ovarian cancer and correlated the results with serum levels of CA 125. They demonstrated that 18FDG PET/CT was able to detect active disease at relatively low levels of CA 125, thereby facilitating the early diagnosis of recurrence or residual disease. In particular the optimal cutoff point of CA 125 after treatment to reflect active disease on PET/CT was 18 U/mL achieving a detection rate of 85.6 %. There was no relation between PET/CT negativity and the histological type of the tumor [23].
In a study by Mangili et al., 18FDG PET/CT was compared with CT for the detection of ovarian cancer recurrence. A change in the clinical management was observed in 44 % of the patients when 18FDG PET/CT information was added to conventional follow-up findings, as PET/CT increases the detection of tumor relapse compared to CT alone [24].
In particular, in women with recurrent disease, with previously treated ovarian carcinoma, 18FDG PET-CT can alter management in close to 60 % of patients, detect more sites of active disease than abdominal and pelvic CT, as it is superior in the detection of nodal, peritoneal, and subcapsular liver disease, and also offer the opportunity for technology replacement in this setting [25] (Fig. 34.2).
Because PET/CT has a high contrast between tumor and background, in the case of hypermetabolic tumor implants, especially in subdiaphragmatic or subhepatic locations, on serosal surfaces of the bowel, or in small nodes, it has been reported to have better diagnostic accuracy than CT and MRI in these clinical situations (73–100 % sensitivity, 71–100 % specificity, and 83–100 % accuracy). In addition, it is difficult to detect small local recurrence, lymph node metastasis, small peritoneal dissemination, and bone/muscle metastasis for CT [26] (Fig. 34.3).
PET/CT not only helps in diagnosing recurrence, but also affects subsequent management. With its ability to precisely localize the lesion, as well as the extent of recurrence and distant metastases, PET/CT plays an important role in restaging of recurrent ovarian cancer. Fagotti et al. studied the ability of PET/CT to predict the possibility of optimal cytoreduction in recurrent ovarian cancer and reported an accuracy of 79 %, sensitivity of 93 %, specificity of 56 %, positive predictive value of 77 %, and negative predictive value of 83 % and, hence, good efficacy of PET/CT in planning surgical treatment of patients with recurrent ovarian cancer [27]. In another study, PET/CT was found to be comparable to staging laparoscopy for this purpose. Again, the false-negative results on PET/CT in that study were small peritoneal implants <7 mm in size [28].
2 Cervical Cancer
Despite advances in screening and prevention, cervical cancer remains as a major threat to women’s health, however; actually, it tends to present clinically before and, then, to have better survival rates [1]. Functional imaging with 18FDG PET/CT can be used in initial staging (Table. 34.2), detection of recurrent disease, and evaluation of therapy response in patients with cervical cancer.
2.1 Diagnosis and Staging
In regard to the definition of the primary tumor, PET/CT does not appear to be very accurate in detecting the margins of the tumor. Tumors with a diameter <7 mm are negative for metabolic evaluation and areas of necrosis or fluid collections/bleeding/purulent content are not 18FDG avid [29]. In the case of infiltration of the bladder or rectum, PET-CT, even with the difficulties related to the physiological accumulation of the tracer in the bladder, can detect increased uptake of the radiopharmaceutical as a nodular thickening at the involved viscera.
Since ultrasound and MRI allow visualization of even small-size cervical neoplasia, both techniques are adequate for the evaluation of tumor size and degree of stromal invasion.
In recent comparative studies between intracavitary ultrasound and MRI, it has been reported a similar accuracy between the two techniques in this task [30]. In the evaluation of lymph node metastases, MRI and CT scan showed a comparable diagnostic accuracy with relatively low sensitivity and specificity rates. From the recent literature, it can be concluded that 18FDG-PET provides a higher sensitivity than MRI in the diagnosis of lymph node metastases. In a recent meta-analysis, PET-CT showed a sensitivity (79–84 %) and specificity (95–99 %) higher than those obtained by CT (sensitivity of 47–50 % and specificity of 92–97 %) and MRI (sensitivity of 56–72 % and specificity of 92–96 %) [31]. The limited use of anatomical imaging in cervical cancer has led to the use of 18FDG-PET for the evaluation of pelvic and para-aortic lymph nodes, not only in assessing the extent of disease but also with a prognostic role (Fig. 34.3).
Grigsby et al. compared the results of CT and 18FDG-PET in the pretreatment N-staging of 101 patients with cervical carcinoma [32]. Patients were treated with a combination of radiotherapy and chemotherapy. CT demonstrated abnormally enlarged pelvic lymph nodes in 20 (20 %) and para-aortic lymph nodes in seven (7 %) of the 101 patients. PET demonstrated abnormal 18FDG uptake in 67 (67 %) pelvic lymph nodes, in 21 (21 %) para-aortic lymph nodes, and in eight (8 %) supraclavicular lymph nodes. All positive lymph nodes on CT were also detected in PET scans. The disease-free survival at 2 years, based solely on para-aortic lymph nodes status, was 64 % in patients with negative CT and PET, 18 % in patients with negative PET and positive CT, and 14 % in patients with positive CT and PET. In conclusion, based on this study, 18FDG hyperfixation to lumbo-aortic lymph nodes is the most important factor predictive of disease progression.
Singh et al. used 18FDG-PET in patients with cervical cancer in clinical stage IIIB [33]. Three-year survival was that of 79 % in patients without lymph node involvement at presentation, while in patients with pelvic lymph node involvement was 58 % and in patients with positive para-aortic lymph nodes only 29 %. They concluded that PET should be performed in all patients with carcinoma of the cervix before treatment, to detect the presence of disease in para-aortic and pelvic lymph nodes. As normal-sized nodes may be metastatic, they can be negative in CT but show 18FDG uptake.
2.2 Restaging
About one-third of patients with advanced-stage disease will develop recurrent or progressive cervical cancer, which usually occurs within the first 2 years after completion of primary treatment. The likelihood of recurrence depends on tumor stage, histologic findings, and lymph node status at the time of initial diagnosis, as well as treatment efficacy [34].
Recurrent disease is defined as tumor development at least 6 months after the treated lesion has regressed. Routine abdominopelvic CT is not particularly helpful for the detection of recurrent disease [35]. While 18FDG-PET has excellent sensitivity and specificity for the evaluation of initial local recurrence and lymph node relapse. In particular, Ryu et al. reported that the sensitivity and specificity of 18FDG-PET for the detection of recurrent disease were 90 and 76 %, respectively, and the positive and negative predictive values were 35 and 98 %, respectively, in the evaluation of local recurrence for patients surgically treated (Fig. 52.9) [34].
Cervical cancer relapse can affect abdominal and pelvic lymph nodes but also supradiaphragmatic (phrenic and supraclavicular) ones. About 20 % of patients present lung and bone metastasis, predominantly involving the pelvic bones and the lumbar and thoracic spine (Fig. 34.3).
Liu et al. [36] demonstrated the superiority of 18FDG-PET over CT and MR imaging in detecting hematogenous bone metastasis in patients with advanced cervical cancer. 18FDG PET/CT is also useful in identifying recurrent cervical cancer in both asymptomatic and symptomatic patients with elevated tumor markers and negative imaging findings (squamous cell carcinoma antigen >1.5 ng/mL) [37].
In another study by Unger et al., 18FDG-PET detected recurrent disease in 31 % of asymptomatic women [38]. In this way, with the use of 18FDG-PET in the follow-up of treated patients, it is possible to intervene in the recovery of recurrences that would previously have been discovered in more advanced stages. In fact, Brooks et al. showed that 3-year survival for symptomatic recurrences was 19 % versus 59 % for asymptomatic recurrences [39].
2.3 Radiotherapy Planning
18FDG-PET can play an important role in patients with cervical cancer that are candidates for radiation therapy. The introduction of functional data in the planning of radiotherapy treatment is currently under clinical development. The combination of PET and CT in a single system allows having an imaging modality that may be used in the calculation of the tumor volume and in the definition of treatment plans, particularly when integrated with the virtual simulation. In addition, 18FDG-PET imaging can provide data on metabolically active tumor volume.
These functional data have the potential to change the volume of treatment. Initial studies on the use of 18FDG-PET in radiation treatment planning involved fusion of PET and CT images, including images obtained later (in a different moment) [40].
Dolezelova et al. studied 51 patients with advanced cervical cancer (stage IIB-IIIB) treated with a combination of external beam radiotherapy and brachytherapy, with or without concomitant cisplatin. The radiation treatment plans of lymphatic metastasis were based on fused PET/CT images. 18FDG-PET images led to a change in the extent of disease in 19 (37 %) patients and of radiation fields in 9 (17.5 %) patients compared to CT planning [41].
In addition, 18FDG-PET has been shown to provide useful additional information for planning brachytherapy in patients with gynecological malignancies. Lin et al. studied 11 patients with 18FDG PET/CT in conjunction with their first, middle, or last brachytherapy treatment. A total of 31 intracavitary brachytherapy treatments were performed. The percent coverage of the target isodose surface for the first implant with and without optimization was 73 and 68 % (p = 0.21), and the dose to 2 and 5 cm3 of both the bladder and rectum were not significantly different. The authors concluded that this technique has the potential to improve tumor coverage in patients with cervical cancer, saving critical structures at the same time [42]. Therefore, 18FDG-PET based treatment planning allowed for improved dose coverage of the tumor without significantly increasing the dose to the bladder and rectum. Furthermore, in patients who have undergone radiation therapy, PET/CT can be effective in distinguishing postoperative changes or radiation fibrosis from recurrent tumor.
3 Endometrial Cancer
Overall, endometrial cancer is the fourth most common malignancy in women and the eighth most common cause of death in women [43]. The majority of cases occur in postmenopausal women with the highest incidence in the seventh decade of life. Abnormal uterine bleeding is the most frequent clinical presentation of endometrial cancer, leading to early diagnosis in the majority of patients.
3.1 Diagnosis and Staging
A TVUS is recommended to obtain an impression of the endometrial layer or suspicious lesions in the female pelvis. The diagnosis of endometrial cancer is usually established by histology from endometrial biopsy with hysteroscopy, while for staging it is necessary to evaluate the extent of the primary tumor, regional lymph node involvement, and presence or absence of distant metastases as described by FIGO classification (Table 34.3).
In fact, endometrial cancer is also surgically staged, but accurate assessment by pretreatment imaging can potentially optimize surgical and nonsurgical treatment, particularly with regard to the use of preoperative, neoadjuvant therapy in advanced disease. MRI is used to evaluate the depth of myometrial and cervical invasion, which affects overall prognosis [44]. 18FDG PET/CT imaging has been shown to be more accurate in identifying metastatic lymph nodes, particularly in nodes considered normal by size criteria.
Early data suggest that combined 18FDG PET/CT may be useful in the management of endometrial cancer, particularly in the preoperative detection of pelvic and para-aortic metastatic lymphadenopathy [45]. Picchio et al. studied 32 consecutive patients with histological diagnosis of primary high-risk endometrial cancer with 18FDG PET/CT. 18FDG PET/CT findings were correlated with pathological findings on a patient-by-patient basis after surgery. In this study, sensitivity of 18FDG PET-CT was 90.6 %, for primary tumor detection, 88.5 % for assessment of lymph node involvement, and 96.9 % for distant metastasis depiction. In particular, while the suspicion of distant metastases was documented by conventional imaging in only two patients, 18FDG PET/CT correctly identified metastatic lesions in seven patients (21.9 % of cases) [46].
3.2 Recurrence and Follow-up
Recurrent carcinoma of endometrium has a poor prognosis. However, successful salvage treatment with long-term survival has been achieved after hormone therapy, radical surgery, and radiotherapy/chemotherapy in patients with recurrent disease. Conventional imaging and tumor markers have limited accuracy for detecting recurrence in these patients, while functional imaging can show earlier a recurrence.
In a retrospective study of Sharma et al., a total of 101 patients were evaluated with 18FDG PET/CT for suspected recurrence and compared with CT and with clinical/imaging follow-up and/or histopathology. 18FDG PET/CT was positive for recurrence in 51 (50.5 %) patients and negative in 50 (49.5 %), with an accuracy of 92.1 %. In addition, 18FDG PET/CT showed a strong positive correlation with final diagnosis based on reference standard. Compared to CT, 18FDG PET/CT has much higher specificity (62 % vs. 96.4 %), and accuracy (76.3 % vs. 92.1 %), with comparable sensitivity (85.1 % vs. 89.5 %) [47] (Fig. 34.4).
4 Conclusion
In all gynecological cancers, functional imaging with 18FDG PET/CT appears to be a prominent and complementary method to morphological radiological techniques, allowing a complete evaluation of all types of cancers at all stages of natural history.
Abbreviations
- CA 125:
-
Cancer antigen 125
- CT:
-
Computed tomography
- DWI:
-
Diffusion-weighted imaging
- 18FDG:
-
F-18-fluoro-deoxy-glucose
- FIGO:
-
International Federation of Gynecology and Obstetrics
- MRI:
-
Magnetic resonance imaging
- PET:
-
Positron emission tomography
- SUV:
-
Standardized uptake ratio
- TVUS:
-
Transvaginal ultrasound
References
Jemal A, et al. Cancer statistics, 2008. CA Cancer J Clin. 2008;58:71–96.
Kyriazi S, et al. Imaging ovarian cancer and peritoneal metastases—current and emerging techniques. Clin Oncol. 2011;7:381–93.
Sosna J, Esses SJ. Blind spots at oncological CT: lessons learned from PET/CT. Cancer Imaging. 2012;10:259–68.
Patel CN, et al. FDG PET/CT in oncology: “raising the bar”. Clin Radiol. 2010;65:522–35.
Nam EJ, Yun MJ. Diagnosis and staging of primary ovarian cancer: correlation between PET/CT, Doppler US, and CT or MRI. Gynecol Oncol. 2010;116:389–94.
Booth SJ, et al. I. The accurate staging of ovarian cancer using 3T magnetic resonance imaging—a realistic option. BJOG. 2008;15:894–901.
Yamamoto Y, et al. Preoperative evaluation of pelvic masses with combined (18)F-fluorodeoxyglucose positron emission tomography and computed tomography. Int J Gynaecol Obstet. 2008;102:124–7.
Castelluci P, et al. Diagnostic accuracy of 18F-FDG PET/CT in characterizing ovarian lesions and staging ovarian cancer: correlation with transvaginal ultrasonography, computed tomography, and histology. Nucl Med Commun. 2007;28:589–95.
Cottrill HM, et al. Positron emission tomography in a premenopausal asymptomatic woman: a case report of increased ovarian uptake in a benign condition. Int J Gynecol Cancer. 2005;15:1127–30.
Ames J, et al. 18F-FDG uptake in an ovary containing a hemorrhagic corpus luteal cyst: false-positive PET/CT in a patient with cervical carcinoma. AJR Am J Roentgenol. 2005;185:1057–9.
Kim SK, et al. Incidental ovarian 18F-FDG accumulation on PET: correlation with the menstrual cycle. Eur J Nucl Med Mol Imaging. 2005;32:757–63.
Kitajima K, Murakami K. Present and future of FDG-PET/CT in ovarian cancer. Ann Nucl Med. 2011;25:155–64.
Mironov S, et al. Ovarian cancer. Radiol Clin North Am. 2007;45:149–66.
Forstner R. Radiological staging of ovarian cancer: imaging findings and contribution of CT and MRI. Eur Radiol. 2007;17:3223–35.
Namimoto T, et al. Role of diffusion-weighted imaging in the diagnosis of gynecological diseases. Eur Radiol. 2009;19:745–60.
Javitt MC, Fleischer AC, Andreotti RF et al. Staging and Follow-up of ovarian cancer. American college of Radiology. 2005. http://www.acr.org recommendations.
Kitajima K, et al. Diagnostic accuracy of integrated FDG-PET/contrast-enhanced CT in staging ovarian cancer: comparison with enhanced CT. Eur J Nucl Med Mol Imaging. 2008;35:1912–20.
Ricke J, et al. Prospective evaluation of contrast-enhanced MRI in the depiction of peritoneal spread in primary or recurrent ovarian cancer. Eur Radiol. 2003;13:943–9.
Nishiyama Y, et al. Monitoring the neoadjuvant therapy response in gynecological cancer patients using FDG PET. Eur J Nucl Med Mol Imaging. 2008;35:287–95.
Greenlee RT, et al. Cancer statistics. CA Cancer J Clin. 2001;51:15–36.
Kenemans P, et al. Heterologous double-determinant immunoradiometric assay CA 125 II: reliable second-generation immunoassay for determining CA 125 in serum. Clin Chem. 1993;39:2509–13.
Han LY, et al. Doubling time of serum CA125 is an independent prognostic factor for survival in patients with ovarian cancer relapsing after first-line chemotherapy. Eur J Cancer. 2010;46:1359–64.
Palomar A, et al. Value of FDG PET/CT in patients with treated ovarian cancer and raised CA125 serum levels. Mol Imaging Biol. 2012;14:123–9.
Mangili G, et al. Integrated PET/CT as a first-line re-staging modality in patients with suspected recurrence of ovarian cancer. Eur J Nucl Med Mol Imaging. 2007;34:658–66.
Fulham MJ, et al. The impact of PET/CT in suspected recurrent ovarian cancer: a prospective multi-centre study as part of the Australian PET data collection project. Gynecol Oncol. 2009;112:462–8.
Sebastian S, et al. PET-CT vs. CT alone in ovarian cancer recurrence. Abdom Imaging. 2008;33:112–8.
Fagotti A, et al. A treatment selection protocol for recurrent ovarian cancer patients: the role of FDG-PET/CT and staging laparoscopy. Oncology. 2008;75:152–8.
Bristow RE, et al. Clinically occult recurrent ovarian cancer: patient selection for secondary cytoreductive surgery using combined PET/CT. Gynecol Oncol. 2003;90:519–28.
Grigsby PW. The contribution of new imaging techniques in staging cervical cancer. Gynecol Oncol. 2007;107:S10–2.
Fischerova D, et al. Transrectal ultrasound and magnetic resonance imaging in staging of early cervical cancer. Int J Gynecol Cancer. 2008;18:766–72.
Choi HJ, et al. Diagnostic performance of computer tomography, magnetic resonance imaging, and positron emission tomography or positron emission tomography/computer tomography for detection of metastatic lymph nodes in patients with cervical cancer: meta-analysis. Cancer Sci. 2010;101:1471–9.
Grigsby PW, et al. Lymph node staging by positron emission tomography in patients with carcinoma of the cervix. J Clin Oncol. 2001;19:3745–9.
Singh AK, et al. FDGPET lymfonode staging and survival of patients with FIGO stage IIIb cervical carcinoma. Int J Radiat Oncol Biol Phys. 2003;56:489–49329.
Ryu SY, et al. Detection of early recurrence with 18F-FDG PET in patients with cervical cancer. J Nucl Med. 2003;44:347–52.
Bodurka-Bevers D, et al. Posttherapy surveillance of women with cervical cancer: an outcomes analysis. Gynecol Oncol. 2000;78:187–93.
Liu FY, et al. Detection of hematogenous bone metastasis in cervical cancer: 18F-fluorodeoxyglucose-positron emission tomography versus computed tomography and magnetic resonance imaging. Cancer. 2009;115:5470–80.
Jover R, et al. Role of PET/CT in the evaluation of cervical cancer. Gynecol Oncol. 2008;110:S55–9.
Unger JB, et al. Detection of recurrent cervical cancer by whole-body FDG PET scan in asymptomatic and symptomatic women. Gynecol Oncol. 2004;94:212–6.
Brooks RA, et al. Surveillance FDG-PET detection of asymptomatic recurrences in patients with cervical cancer. Gynecol Oncol. 2009;112:104–9.
Langen KM, Jones DT. Organ motion and its management. Int J Radiat Oncol Biol Phys. 2001;50:265–78.
Dolezelova H, et al. The impact of PET with 18FDG in radiotherapy treatment planning and in the prediction in patients with cervix carcinoma – results of pilot study. Neoplasma. 2008;55:5.
Lin LL, et al. Adaptive brachytherapy treatment planning for cervical cancer using FDG-PET. Int J Radiat Oncol Biol Phys. 2007;67:91–6.
Jemal A, et al. Cancer statistics 2007. CA Cancer J Clin. 2007;57:43–66.
Balleyguier C, et al. Staging of endometrial cancer with MRI: guidelines of the European Society of Urogenital Imaging. Eur Radiol. 2011;21:1102–10.
Chao A, et al. 18F-FDG PET in the management of endometrial cancer. Eur J Nucl Med Mol Imaging. 2006;33:36–44.
Picchio M, Mangili G. High-grade endometrial cancer: value of [(18)F]FDG PET/CT in preoperative staging. Nucl Med Commun. 2010;31:506–12.
Sharma P, Kumar R. Carcinoma endometrium: role of 18-FDG PET/CT for detection of suspected recurrence. Clin Nucl Med. 2012;37:649–55.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer-Verlag Berlin Heidelberg
About this chapter
Cite this chapter
Caroli, P., Fanti, S. (2014). PET-CT of Gynecological Malignancies and Ovarian Cancer. In: Luna, A., Vilanova, J., Hygino Da Cruz Jr., L., Rossi, S. (eds) Functional Imaging in Oncology. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-40582-2_11
Download citation
DOI: https://doi.org/10.1007/978-3-642-40582-2_11
Published:
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-40581-5
Online ISBN: 978-3-642-40582-2
eBook Packages: MedicineMedicine (R0)