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Gonadotropin-Releasing Hormone Analog Cotreatment for the Preservation of Ovarian Function during Gonadotoxic Chemotherapy for Breast Cancer: A Meta-Analysis

  • Chuan Wang ,

    Contributed equally to this work with: Chuan Wang, Minyan Chen

    chuanwang6858@yahoo.cn

    Affiliation Department of General Surgery, Fujian Medical University Union Hospital, Fuzhou, China

  • Minyan Chen ,

    Contributed equally to this work with: Chuan Wang, Minyan Chen

    Affiliation Union Clinical School, Fujian Medical University, Fuzhou, China

  • Fangmeng Fu,

    Affiliation Department of General Surgery, Fujian Medical University Union Hospital, Fuzhou, China

  • Meng Huang

    Affiliation Fujian Center for Disease Control and Prevention, Fuzhou, China

Abstract

Objective

To determine by meta-analysis whether gonadotropin-releasing hormone analog (GnRHa) cotreatment accompanying chemotherapy for breast cancer protects ovarian function.

Methods

Randomized controlled trials (RCTs) comparing GnRH cotreatment with chemotherapy alone in premenopausal women were collected by electronic and manual searches of Pubmed, MEDLINE (OVID), CENTRAL (The Coehrane Central Register of Controlled Trials), CBM, CNKI, VIP and Wanfang data bases. All the data was analyzed by Stata 11.2.

Results

Seven studies with a total of 677 participants met the inclusion criteria. The outcome of meta-analysis implied that, compared with adjuvant chemotherapy alone, the number of patients with resumption of spontaneous menstruation was statistically greater in the GnRH cotreatment patients (OR 2.83; 95% CI, 1.52–5.25).

Conclusions

Evidence from RCTs suggests a potential benefit of GnRH cotreatment with chemotherapy in premenopausal women, producing higher rates of spontaneous resumption of menses.

Introduction

Breast cancer is the most common cancer among women, and is also common among reproductive age women. In 2011, the United States SEER data showed that approximately 6% of women with breast cancer are diagnosed before age 40 [1], and the probability of developing breast cancer before age 40 is nearly 1/200 [2]. Major advances in diagnosis and treatment of breast cancer have reduced mortality, and a majority of patients diagnosed with breast cancer will be long-term survivors. Because young women with breast cancer face challenges when considering future fertility, it is important to preserve ovarian function in cancer patients who must undergo chemotherapy.

Improved cancer survival rates are directly related to major advances in our understanding of cell division, multiplication, and growth, which has led to the development of more effective chemotherapeutic agents that selectively target rapidly dividing cells [3], [4]. However, few chemotherapeutic agents are cell type specific and they damage a wide range of rapidly dividing cell types, such as bone marrow, thymus, and gastrointestinal mucosa. Gonadal tissue is also highly sensitive to these agents, and pre-ovulatory follicles are particularly sensitive to alkylating agents [5], [6].

The majority of young patients with breast cancer receive systemic treatment with chemotherapy, hormone therapy, or both. These patients are at high risk of transient or permanent amenorrhea, and for those women who continue to menstruate or who recover their cycles, there is an additional long-term risk of premature ovarian failure (POF) [7]. Chemotherapeutic agents most likely to induce POF include cyclophosphamide, L-phenylalanine mustard, busulfan, and nitrogen mustard [8]. POF leads to symptoms of low estrogen, such as hot flashes, vaginal dryness, low libido, and osteoporosis that severely affect the quality of life. So a large number of experiments have been conducted to find ways to reduce ovarian damage or protect ovarian function. Embryo and oocyte preservation technologies are complex, expensive, and have a low success rate [9]. And before the collection both require stimulation of the ovaries to make a high levels of estrogen, which is a potential risk for hormone-dependent patients [10]. In addition, ovarian tissue cryopreservation and transplantation are still under investigation, and the potential risk of introducing cancer is not known. Compared to these methods, the GnRHa is a simple, viable, and low-cost alternative.

Theoretically, temporarily returning ovaries to an inactive state by inhibition of the pituitary-gonadal axis before chemotherapy might make the germ cells less susceptible to the effects of alkylating agents [11]. Originally, GnRHa were used for this purpose. In the 1980s, the effectiveness of a GnRHa during chemotherapy to preserve ovarian function was first demonstrated in rodents and monkeys [12][14]. Over the last 10 years, more than a dozen reports of small cohorts of women undergoing chemotherapy with concomitant GnRHa therapy have been published, but the results were inconsistent. Some prospective controlled studies of concomitant GnRHa and chemotherapy have demonstrated a decrease in the ovarian failure rate after chemotherapy compared with controls [15]. However, other studies have not shown a benefit [16]. The primary objective of our systematic review of the literature was to ascertain the effectiveness of adding GnRHa to chemotherapy for the preservation of ovarian function during chemotherapy for breast cancer.

Materials and Methods

Search Strategy

We searched for published trials in the electronic databases MEDLINE (OVID), PubMed, the Cochrane Central Register of Controlled Trials (CENTRAL) in the Cochrane Library, CBM, CNKI, VIP and WanFang data bases. We also did a manual retrieval of relevant academic conference papers, assemblies and dissertation. The search covers January 2000 to June 2012. At the same time, we screened the included articles and according to the referenced literature, further expanded our retrieval. The search syntax was tailored individually for each database but included the following main Medical Subject Headings (MeSH) and text words; gonadotropin-releasing hormone, chemotherapy, ovarian preservation, and breast cancer.

Inclusion and Exclusion Criteria

Studies included in the meta-analysis met the following criteria: 1) Type of research had a randomized controlled design with the language limited to Chinese or English. 2) The research object was premenopausal women with a pathological diagnosis of breast cancer, with a detailed description of the patient′s basic characteristics. 3) Intervention included the GnRH group with GnRHa and chemotherapy treatment and the control group with chemotherapy alone, with no limit to the chemotherapy scheme and the GnRHa treatment. 4) Outcome measures were the incidence of not having premature ovarian failure. 5) Published research.

Studies excluded from the meta-analysis had the following criteria: 1) Controlled trials that were not randomized. 2) Nontherapeutic clinical research and animal experiments. 3) Publications in other than the Chinese and English language literature. 4) Studies with no related outcome measured. 5) Studies with a dropout rate of greater than 10%. 6) From repeated publication of studies, we took the latest, with the most complete data.

Data Extraction and Quality Assessment

Two reviewers independently conducted data extraction and assessed the quality of each study for meeting the inclusion criteria. Data extraction included the descriptive characteristics of the study patients (gender, average age, chemotherapy scheme and estrogen receptors, etc.), the characteristics of the intervention (the dose, the time of administration, cycle and other treatment), outcome measures and the final results.

We assessed study quality using a four item method developed by Jadad and colleagues that evaluated the adequacy of randomization [17], concealment of randomization, blinding, and completeness of follow-up. When a study described the method of randomization correctly, it could get two points, but got one point if it only mentioned the randomization. We used the same principle for the blinding and completeness of follow-up. If the study mentioned the allocation concealment, it could get one point. There was a maximum score of seven points, and using the four evaluation criteria, the literature was divided into three levels. Class A - low bias with 5 to 6 points: met all the evaluation standards and the study was the least likely to produce all kinds of bias. Class B - a moderate bias with 3 to 4 points: partially met the quality standards and the possibility of producing a variety of bias was moderate. Class C - a high degree of bias with 1 to 2 points: not satisfying the quality standards, the study had a high possibility of a variety of bias.

Statistical Analysis

Data management and statistical analysis were conducted using Stata 11.2 [18]. Where possible, data were extracted to allow for an intention-to-treat analysis, defined as including in the denominator the number of all originally included patients. If data from the trial reports were insufficient or missing, the investigators of the individual trials were contacted via E-mail for additional information.

For the meta-analysis, the number of participants in each group of the trial was recorded. This review used the odds ratio (OR) and 95% confidence interval (95% CI) as the effect size. First, we analyzed the clinical heterogeneity of the included trials. Second, for statistical heterogeneity we used the chi-square test with a 5% level of statistical significance. In addition, heterogeneity was quantified using the I2 test. If P>0.05, we considered that the included trials had homogeneity of data, and the pooled OR was estimated by the fixed-effects model (the Mantel-Haenszel method) [19]. Otherwise, if P<0.05 and I2 >50%, heterogeneity was found. We attempted to determine the possible source of heterogeneity and the random-effects model (the DerSimonian and Laird method) was employed [20].

Publication bias of literature was assessed using funnel plots and Egger’s test. An asymmetric plot suggests a possible publication bias and the P value of the Egger’s test less than 0.05 was considered representative of a statistically significant publication bias [21].

Sensitivity Analysis

To determine whether any study of relatively poor quality was incurring undue weight in the analysis, we systematically removed the data and checked the pooled results for the remaining studies to see if they changed significantly.

Results

Search Results

A total of 623 study abstracts were identified through the electronic and manual searches (Figure 1). Of these, 598 did not meet criteria for inclusion in the meta-analysis. Full text was retrieved for 25 studies. On review of these studies, 18 were eliminated because they did not meet the criteria for inclusion in the meta-analysis. Of these trials, only seven trials met the inclusion criteria [15], [16], [22][26].

Description of Included Trials

Detailed description of the methods used in the included trials, including the type of chemotherapeutic drugs and type of GnRHa used, is provided in Table 1. The results of quality assessment for the included studies are presented in Table 2.

Meta-Analysis

Through establishing strict, unified inclusion and exclusion criteria, and keeping consistent the relevant factors, we ensured clinical homogeneity of the included studies to a certain extent. However the tests for statistical heterogeneity showed moderate heterogeneity (P = 0.046, I2 = 51%). This may reflect the differing patient populations, chemotherapy regimens, mean patient age, type of GnRHa used, or the length of the follow-up period in the respective trials. Therefore, we used the random effect model to calculate the effect size (OR, 95% CI). The incidence of women with spontaneous menstruation was statistically greater when GnRHa was used (OR 2.83; 95% CI, 1.52–5.25). (Figure 2).

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Figure 2. Forest plot of effect sizes for the incidence of women with spontaneous menstruation.

https://doi.org/10.1371/journal.pone.0066360.g002

Sensitivity Analysis

According to the results of the quality assessment for the included studies, we then excluded the two Chinese literature reports as being of the relatively poor quality [25], [26], and recalculated the pooled OR and 95% CI (OR 2.681; 95% CI, 1.169–6.146). The results were basically the same. (Figure 3).

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Figure 3. The pooled ORs for the incidence of women with spontaneous menstruation.

https://doi.org/10.1371/journal.pone.0066360.g003

Publication Bias

Funnel plots and Egger’s test were performed to assess the publication bias of the literature. Examination of the funnel plot of effect sizes by their SEs suggests a fairly even distribution of studies for the primary study outcome. Egger’s test further confirmed the absence of publication bias in this meta-analysis (P = 0.566, 95% CI, −4.17–2.51). (Figure 4).

thumbnail
Figure 4. Funnel plot and Egger’s test of effect sizes for the included studies.

https://doi.org/10.1371/journal.pone.0066360.g004

Discussion

The results of this systematic review show that the use of GnRHa treatment with chemotherapy may be beneficial in preserving future fertility in women treated with chemotherapeutic agents. The main observation of our analysis is that treatment with an agonist does seem to provide short-term return of ovulation and a menstrual cycle.

Beginning from the 1980 s, there were some studies on the role of GnRHa in the protection of chemotherapy-induced gonadal damage. However, not all studies had the same results and possible reasons could include: 1) GnRHa can reduce follicular loss in patients of different ages, but the clinical application is limited to young women with good ovarian reserve. With increasing age, female ovarian reserve gradually decreases, and the role of GnRHa in the protection of ovarian function is correspondingly weakened. In the meta-analysis, the youngest patients were those from the Badawy’s study [15] that seemed based on what is shown in the forest plot to be mainly responsible for the heterogeneity. 2) The time limits for the use of a GnRHa vary in length. For pituitary-ovarian suppression, GnRHa can stimulate the increase of gonadotropin for the short-term, the so-called "Ignition" period (about 1 to 2 weeks), and it can contribute to the primordial follicle developing into mature follicles. However, chemotherapy drugs are active against mitotically active cells, and GnRHa may make the ovaries more sensitive to chemotherapeutic drugs [27]. 3) Different GnRHa preparations act differently. Compared to short-acting GnRHa, the role of a long-acting GnRHa in pituitary-gonadal axis suppression is more lasting and stable. In the included studies, the types of GnRHa are all long-acting. 4) There were different follow-up periods in the studies. Generally, GnRHa adjuvant therapy should be maintained to the end of chemotherapy, and we should use GnRHa continually due to the metabolism of chemotherapy drugs. Therefore, two months after the completion of chemotherapy, and generally at 6-, 12-, and 18-month follow-up, we should reassess the ovarian function. However, how long we should follow-up needs further study. There is a lack of a multi-center, high-quality, large sample, homogeneous prospective randomized controlled clinical studies that could address some of these problems.

In the meta-analysis, seven randomized controlled trials were finally included. The results showed that GnRHa added to adjuvant chemotherapy has a protective effect on ovarian function in premenopausal women; in the GnRHa group compared with the control group, the pooled OR and 95% CI was significantly increased. However, there were bias factors that may affect the authenticity of the meta-analysis results. Through the funnel plot analysis the included studies had a distribution of basic symmetry, showing an inverted funnel, and Egger’s test analysis showed that the funnel plot is symmetrical. So, the publication bias of included literature is small and the potential bias has no substantive effect on the final conclusions. Similarly, in 2011, Bedaiwy also applied meta-analysis and obtained the same results [28].

This study had some limitations: 1) In the literature data retrieval stage, because of the limiting conditions, the included literature was only published literature, and language is limited to English and Chinese. The existence of language bias and unpublished literature results may affect the results of the meta-analysis. 2) In order to implement the strict inclusion and exclusion criteria, a small number of studies were retrieved. 3) In this study, the quality of the included studies was low. None mentioned the use of blinding, and some studies had no description of the method of randomization and did not mention the allocation concealment. These lower-quality studies may change the combined effect of the interventions in the meta-analysis. 4) The included articles only adopted menstrual recovery to reflect the ovarian function, the outcome measure was single. It would be best to assess more comprehensively by the combination of detection of ovarian reserve before and after treatment; such as the determination of the basis of sex hormones, cytokines, and ovarian ultrasonography. 5) Adverse reactions to GnRHa were not mentioned.

Conclusion

Based on the results of this meta-analysis, GnRH treatment with chemotherapy in premenopausal women provides a potential benefit for ovarian function preservation, with higher rates of spontaneous resumption of menses. However, in order to further define the role and mechanism of GnRHa in ovarian function preservation, more well-designed and powered trials are needed. More data are needed with respect to real fertility preservation, and perhaps, more urgently, the safety of concomitant chemotherapy and hormone therapy when given at a potentially curable disease stage.

Author Contributions

Conceived and designed the experiments: CW. Performed the experiments: MC. Analyzed the data: MH. Contributed reagents/materials/analysis tools: FF MC. Wrote the paper: MC.

References

  1. 1. Surveillance, Epidemiology and End Results (SEER) (2010) Available: http://www.seer.cancer.gov.Based on the November 2009 submission. Accessed June 20, 2011.
  2. 2. Jemal A, Siegel R, Xu J, Ward E (2010) Cancer statistics 2010. CA Cancer J Clin 60: 277–300.
  3. 3. Klimm B, Schnell R, Diehl V, Engert A (2005) Current treatment and imm unotherapy of Hodgkin’s lymphoma. Haematologica 90: 1680–1692.
  4. 4. Olopade OI, Grushko TA, Nanda R, Huo D (2008) Advances in breast cancer: pathways to personalized medicine. Clin Cancer Res 14: 7988–7999.
  5. 5. Blumenfeld Z (2003) Gynaecologic concerns for young women exposed to gonadotoxic chemotherapy. Curr Opin Obstet Gynecol 15: 359–370.
  6. 6. Blumenfeld Z, Dann E, Avivi I, Epelbaum R, Rowe JM (2002) Fertility after treatment for Hodgkin’s disease. Ann Oncol 13 (Suppl1): 138–147.
  7. 7. Partridge A, Gelber S, Gelber RD, Castiglione-Gertsch M, Goldhirsch A, et al. (2007) Age of menopause among women who remain premenopausal following treatment for early breast cancer: long-term results from International Breast Cancer Study Group Trials V and VI. Eur J Cancer 43: 1646–1653.
  8. 8. Shenns RJ (1993) Gonadal dysfunction. In: DeVita VTJ, Hellma NS, Rosenberg SA, editors. Cancer-principles and practice of oncology. Philadelphia: J.B. Lippincott.
  9. 9. Suzuki N, Yoshioka N, Sugishita Y, Takae S, Horage Y, et al. (2012) The possibility of the fertility preservation in young cancer patients based on practice of oncofertility treatment. Gan Uo Kagaku Ryoho 39(2): 151–157.
  10. 10. Decanter C, Gligorov J (2011) Oocyte/embryo cryopreservation before chemotherapy for breast cancer. Gynecol Obstet Fertil 39(9): 501–503.
  11. 11. Sutcliffe SB (1979) Cytotoxic chemotherapy and gonadal function in patients with Hodgkin’s disease: facts and thoughts. JAMA 242: 1898–1899.
  12. 12. Ataya K, Rao LV, Lawrence E, Kimmel R (1995) Luteinizing hormone-releasing hormone agonist inhibits cyclophospha-mide-induced ovarian follicular depletion in rhesus monkeys. Biol Reprod 52: 365–372.
  13. 13. Ataya K, Ramahi-Ataya A (1993) Reproductive performance of female rats treated with cyclophosphamide and/or LHRH agonist. Reprod Toxicol 7: 229–235.
  14. 14. Bokser L, Szende B, Schally AV (1990) Protective effects of D-Trp6-luteinising hormone-releasing hormone microcapsules against cyclophosphamide-induced gonadotoxicity in female rats. Br J Cancer 61: 861–865.
  15. 15. Badawy A, Elnashar A, El-Ashry M, Shahat M (2009) Gonadotropin-releasing hormone agonists for prevention of chemotherapy-induced ovarian damage: prospective randomized study. Fertil Steril 91: 694–697.
  16. 16. Munster PN, Moore AP, Ismail-Khan R, E Cox, Lacevic M, et al. (2012) Randomized trial using gonadotropin-releasing hormone agonist triptorelin for the preservation of ovarian function during (neo) adjuvant chemotherapy for breast cancer. J Clin Oncol 30: 533–538.
  17. 17. Jadad AR, Moore RA, Carroll D, Jenkinson C, Reynolds DJM, et al. (1996) Assessing the quality of reports of randomized clinical trials: is blinding necessary? Control Clin Trials 17: 1–12.
  18. 18. Jianling B, Wenzhao Z, Minghua Z, Feng C (2007) Meta - Analysis in Stata. The Journal of Evidence-Based Medicine 6: 363–368.
  19. 19. Mantel N, Haensze l W (1959) Statistical aspects of the analysis of data from retrospective studies of disease. J Natl Cancer Inst 22: 719–748.
  20. 20. Der Simonian R, Laird N (1986) Meta-analysis in clinical trials. Control Clin Trials 7: 177–188.
  21. 21. Egger M, Davey Smith G, Schneider M, Minder C (1997) Bias in meta-analysis detected by a simple graphical test. BMJ 315: 629–634.
  22. 22. Gerber B, Stehle H, Ricardo F, Minckwitz G, Reimer T, et al. (2011) Effect of Luteinizing Hormone–Releasing Hormone Agonist on Ovarian Function After Modern Adjuvant Breast Cancer Chemotherapy: The GBG 37 ZORO Study. J Clin Oncol 29: 2334–2341.
  23. 23. Sverrisdottir A, Nystedt M, Johansson H, Fornander T (2009) Adjuvant goserelin and ovarian preservation in chemotherapy treated patients with early breast cancer: results from a randomized trial. Breast Cancer Res Treat 117: 561–567.
  24. 24. Del Mastro L, Boni L, Michelotti A, Gamucci T, Olmeo N, et al. (2011) Effect of the Gonadotropin-Releasing Hormone Analogue Triptorelin on the Occurrence of Chemotherapy-Induced Early Menopause in Premenopausal Women With Breast Cancer: A Randomized Trial. JAMA 306: 269–276.
  25. 25. Li M, Huang H, Liang Y, Tan J, Lin D (2008) Effect of Zoladex Administered before Chemotherapy on Menstruation of Patients with Breast Cancer. Chinese Journal of Clinical Oncology 35: 905–907.
  26. 26. Sun J, Ren Y, Li W (2011) Effect of Zoladex Administered before Chemotherapy on Menstruation of Patients with Breast Cancer. China Disability Medicine 19: 15–16.
  27. 27. Clowse ME, Behera MA, Anders CK, Copland S, Coffman CJ, et al. (2009) Ovarian preservation by GnRH agonists during chemotherapy: a meta-analysis. J Womens Health (Larchmt) 18: 311–319.
  28. 28. Bedaiwy MA, Abou-Setta AM, Desai N, Hurd W, Starks D, et al. (2011) Gonadotropin-releasing hormone analog cotreatment for preservation of ovarian function during gonadotoxic chemotherapy: a systematic review and meta-analysis. Fertil Steril 95: 906–914.