Fertility preservation for patients with hematologic malignancies: The Korean Society for Fertility Preservation clinical guidelines

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Clin Exp Reprod Med. 2017;44(4):187-192
Publication date (electronic) : 2017 December 31
doi : https://doi.org/10.5653/cerm.2017.44.4.187
1Department of Obstetrics and Gynecology, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul, Korea.
2Department of Obstetrics and Gynecology, Seoul National University Bundang Hospital, Seongnam, Korea.
3Department of Obstetrics and Gynecology, Ajou University School of Medicine, Suwon, Korea.
4Department of Obstetrics and Gynecology, Seoul National University College of Medicine, Seoul, Korea.
Corresponding author: Miran Kim. Department of Obstetrics and Gynecology, Ajou University School of Medicine, 206 World cup-ro, Yeongtong-gu, Suwon 16499, Korea. Tel: +82-31-219-5300, Fax: +82-31-219-5245, kmr5300@ajou.ac.kr
Received 2017 February 28; Revised 2017 March 14; Accepted 2017 March 28.


Although the survival rate of hematologic malignancies in young patients is very high, cytotoxic therapies such as chemotherapy and total body irradiation therapy can significantly reduce a patient's reproductive capacity and cause irreversible infertility. Early ovarian failure also commonly occurs following additional cancer treatment, bone marrow transplantation, or autologous transplantation. Because the risk of early ovarian failure depends on the patient's circumstances, patients with a hematologic malignancy must consult health professionals regarding fertility preservation before undergoing treatments that can potentially damage their ovaries. While it is widely known that early menopause commonly occurs following breast cancer treatment, there is a lack of reliable study results regarding fertility preservation during hematologic malignancy treatment. Therefore, an in-depth discussion between patients and health professionals about the pros and cons of the various options for fertility preservation is necessary. In this study, we review germ cell toxicity, which occurs during the treatment of hematologic malignancies, and propose guidelines for fertility preservation in younger patients with hematologic malignancies.


The risk of infertility and early menopause due to ovulatory dysfunction caused by cancer treatment varies by the type of cancer and the treatment method used. Cytotoxic therapy, which is administered to premenopausal women with acute leukemia, Hodgkin lymphoma (HL) and non-Hodgkin lymphoma (NHL), and chronic myeloid leukemia (CML), can induce infertility and early menopause. Hematopoietic cell transplantation (HCT) is also strongly associated with a risk of early menopause and infertility.

Acute myeloid leukemia (AML) and NHL usually develop at older ages. Patients younger than 50 comprise 20% of AML cases and 17% of NHL cases, and their cure rates are 50% to 60%. However, the cure rates for HL (64%) and acute lymphoblastic leukemia (ALL, 75%), which usually develop before the age of 50, are 80% and 78%–92%, respectively, which are considered to be very high [1]. More than half of all cases of ALL (56%) occur among people aged less than 20 years. The remission rate of ALL has been reported to be 95% among teenagers and 78%–92% among adults [2].

While the survival rate of blood cancer that occurs at young ages is very high, chemotherapy and total body irradiation therapy performed as part of cancer treatment can significantly reduce a patient's reproductive capacity and cause irreversible infertility.

In the present study, we review germ cell toxicity, which occurs during the treatment of hematologic malignancies, and propose guidelines for fertility preservation in younger patients with blood cancer.

Why does treatment of blood cancer lead to infertility?

Typically, alkylating agents and radiation are used in blood cancer treatment, and they exhibit dose-dependent germ cell toxicity. The degree of gonadal damage during radiotherapy to the pelvic area, which includes the ovaries, is determined by the patient's age, the radiation dose, and the irradiation site. In general, a dose of 2 Gy can kill more than 50% of all ovarian follicles, and infertility and menopause can occur after high-dose irradiation of children and young women. Over 90% of women become menopausal after undergoing total body irradiation therapy prior to transplantation. According to the Childhood Cancer Survival Study, the pregnancy rate among cancer survivors is around 20% lower than among their siblings. The study also reported that the pregnancy rate decreased by 82% when women were exposed to ≥10 Gy [3]. Furthermore, the risk of infertility was three times higher for cancer survivors who underwent cancer treatment before the age of 20 [4], and the Bone Marrow Transplant (BMT) Survivor Study reported that the infertility rate was 36 times higher in transplant recipients [5].

The uterus can also be damaged by radiotherapy. Radiotherapy can increase the risk of spontaneous abortion, premature birth, and having a low-birth-weight baby. Women undergoing puberty, who are still in the process of maturation, are especially vulnerable to these risks.

For AML and ALL, the risk of gonadal damage due to radiotherapy alone is low as long as transplantation is not performed. The risk is also low with the use of tyrosine kinase inhibitors, which are used to treat CML. In the case of HL, the risk of gonadal damage varies depending on the type of drug used. While doxorubicin, bleomycin, vinblastine, and dacarbazine (ABVD) used for early-stage cancer has a low risk, bleomycin, etoposide, adriamycin, cyclophosphamide, oncovin, procarbazine, and prednisone (BEACOPP) used for advanced or non-reactive cancer poses a high risk. Cyclophosphamide, doxorubicin, vincristine, and prednisone (CHOP) and cyclophosphamide, vincristine, dexamethasone, cytarabine, and methotrexate (CVAD) used for NHL pose a relatively low risk of gonadal damage. Transplantation is associated with a high risk of early ovarian failure, and total body irradiation therapy reduces ovarian function to a greater extent than does chemotherapy.

How do patients with blood cancer differ from patients with other types of cancer?

Since permanent amenorrhea has been reported to occur in less than 20% of all patients treated with the chemotherapeutic regimens that are typically used for AML, ALL, and HL, fertility preservation may appear to be unnecessary for most patients. However, in actuality, most cancer survivors have reduced ovarian function, experience subfertility, and have a shortened fertility window after chemotherapy [6].

Most patients diagnosed with acute leukemia and lymphoma must urgently undergo cytotoxic therapy and cannot afford to wait for 10 days of preparation before fertility preservation. Furthermore, because these patients are in a clinically unhealthy state due to cytopenia, the risks of intraoperative active infection, cardiopulmonary issues, or other possible complications must be considered.

Blood cancer has a high recurrence rate. Although permanent amenorrhea is rarely caused by the first round of cancer treatment, a patient may develop recurrent cancer after undergoing additional rounds of even more intense chemotherapy or HCT. During additional rounds of treatment, potent cytotoxic agents may be used or total body irradiation may be performed, and all of these lead to acute ovarian failure in most cases [7]. Therefore, it is important that patients seek health professionals' advice on future fertility even after their blood cancer treatment is completed.

CML mostly occurs after the age of 50 years, but 25% of cases occur among people aged 50 years or less. CML is treated with tyrosine kinase inhibitors (TKIs) over a long period of time, and this can affect fetal development and lead to infertility. TKIs increase the rate of natural abortion and fetal cardiac abnormalities [8910]. Therefore, a patient who wishes to become pregnant in the future must consider discontinuing TKIs.


1. Hormone therapy

Hormone therapy is currently the most controversial method of fertility preservation. According to a Cochrane meta-analysis that included results of multiple retrospective analyses, the use of gonadotropin-releasing hormone (GnRH) analogs increased the rate of menstruation and of ovulation after cancer treatment 1.9-fold and 2.7-fold, respectively, and significantly reduced the rate of amenorrhea. However, it ultimately did not affect the pregnancy rate or the number of antral follicles [11].

However, in studies on patients with lymphoma, GnRH agonist (GnRHa)-treated patients had a higher pregnancy rate than control patients [12], and regular ovulatory functions were likewise more significantly recovered in the GnRHa-treated group following autologous HCT [13]. However, these effects of GnRHa on ovarian preservation were not observed for patients with leukemia. Other studies have reported that GnRHa had no fertility-preserving effects [1415].

Recently, Demeestere et al. [1617] reported that after more than 5 years of follow-up, GnRHa administration did not significantly reduce primary ovarian failure or increase the pregnancy rate. Although several issues should be considered in interpreting the results of this study, GnRHa during chemotherapy remains an option for women interested in preserving ovarian function and fertility [18].

While there are reports that continuous use of combined oral contraceptives can lower the rate of amenorrhea and premature ovarian failure [1920], combined oral contraceptives cannot be used as a primary method of fertility preservation since no prospective research comparing combined oral contraceptives-treated patients with those treated with other methods has been conducted.

Research on the effects of hormone therapy on the preservation of ovulatory functions is still lacking, and only a few studies on this topic have presented reliable results. Therefore, hormone therapy should be considered only when no other appropriate treatment options are available.

2. Embryo or oocyte cryopreservation

Embryo or oocyte cryopreservation is currently the most well-established method of fertility preservation [2122]. Embryo or oocyte cryopreservation follows a similar procedure for blood cancers as for other types of cancer. With the recent introduction of the randomstart method, it has become possible to start stimulation at any time without having to wait for the next menstrual cycle, and it takes 10 to 14 days until oocyte retrieval. Random-start ovarian stimulation provides a significant advantage, and in emergent settings, can be started at a random cycle date for the purpose of fertility preservation without compromising oocyte yield or maturity [23]. The live birth rates among patients who attempted to become pregnant by thawing previously frozen oocytes and using them after completing cancer treatment were 35% to 40%, which can be considered to be very high. Since oocyte cryopreservation as a method of fertility preservation is no longer in an experimental stage, it may become an option for active consideration by young female patients with cancer who currently have no partner [24].

However, many patients with blood cancer experience serious anxiety during the 10 days of stimulation before and after gamete cryopreservation or during the process of oocyte retrieval. They fear that their cancer treatment will be delayed due to gamete cryopreservation, and that they may develop complications as a result of the invasive procedure. However, if a patient is in a relatively healthy state, and has a sufficient desire to preserve her fertility, embryo or oocyte cryopreservation can be performed, as is done for patients with other types of cancer who desire fertility preservation.

3. Ovarian tissue cryopreservation

For patients with blood cancer, for whom gamete cryopreservation is difficult, ovarian tissue cryopreservation can be a useful method of fertility preservation. Ovarian tissue cryopreservation is superior to other therapies in several aspects. First, it can be performed right away without any waiting period and can be performed in the absence of a partner. Upon successful transplantation, hormone function returns to normal. Ovarian tissue cryopreservation can also be attempted for prepubertal children.

However, there is always a possibility of the presence of cancer cells in frozen ovarian tissue, and this possibility is higher for patients with blood cancer than for those with other types of cancer. While it has been reported that cancer cells do not invade the ovaries in most patients with lymphoma, this is not always true [25262728]. Despite this, autotransplantation of ovarian tissue has been frequently performed in patients with lymphoma, and so far, there has been no report of recurrent cancer following ovarian tissue cryopreservation and transplantation [25].

No case of autotransplantation of ovarian tissue in patients with leukemia has been reported to date. This is because in previous studies, cancer cells were detected [2428] during xenotransplantation of ovaries in patients with leukemia [2930] through a histological examination, polymerase chain reaction [3132], or at autopsy [27]. Although some studies have reported not detecting any cancer cells after histological examination and xenotransplantation of ovaries of patients with leukemia [3133], clinicians do not feel comfortable recommending autotransplantation of cryopreserved ovaries to patients with leukemia.

A group of fertility preservation specialists has recommended the use of the following methods to ensure the safety of patients with leukemia during ovarian tissue cryopreservation and transplantation.

In vitro fertilization is not recommended for patients with AML or ALL who require urgent treatment. Ovarian tissue cryopreservation is also not recommended for these patients, since a large number of leukemic cells may be present in the bone marrow and blood during the acute phase.

AML treatment does not lead to serious loss of ovarian function [34]. However, patients who need to undergo an intense treatment that poses a high ovarian toxicity risk, such as high dose radiotherapy or bone marrow transplantation, in addition to the AML treatment should actively undergo fertility preserving treatment. Since cancer cells are not detected in the blood and bone marrow following the first round of cancer treatment in most patients, the probability of finding cancer cells in the ovaries is very low. However, the presence of residual leukemic cells in the ovaries must be checked using the most sensitive method possible prior to transplantation of the cryopreserved ovaries.

Because chemotherapy for ALL does not reduce ovarian function over a short period of time, a few rounds of chemotherapy can be performed to ensure the complete elimination of cancer cells in the blood before performing tissue cryopreservation. Because ALL mostly develops before the age of 20, oocyte retrieval from patients with ALL is difficult, and the effects of ovarian stimulation are reduced in these patients. Furthermore, since genetically abnormal oocytes retrieved after chemotherapy increase the rates of natural abortion and fetal abnormalities, in vitro fertilization, egg freezing, and in vitro maturation are not recommended for patients with ALL [353637].

By performing ovarian tissue cryopreservation after administering chemotherapy and ensuring that no cancer cells are present in the blood and bone marrow, the additional risks associated with surgery can be avoided, and the possibility of reinvasion by cancer cells can be reduced.

Although fertility preserving treatment is generally not necessary for patients with CML, these patients may consider undergoing ovarian tissue cryopreservation if TKI treatment fails to work or if transplantation becomes necessary due to a blast crisis. Ovarian tissue cryopreservation can also be performed for patients with HL before they complete two rounds of chemotherapy. Reinvasion by cancer cells is rare in these cases.

Taken together, cryopreservation of ovarian tissue is not a universally applicable option, but is an efficient option to preserve fertility in young patients facing or undergoing gonadotoxic therapies. It should be proposed only after careful evaluation of the surgical risks. Other options, such as vitrification of oocytes or embryos, may be a better choice for older patients or in patients with a high risk of neoplastic cells within the ovaries [38].


While early ovarian failure rarely occurs immediately after blood cancer treatment, early ovarian failure commonly occurs following additional cancer treatment, bone marrow transplantation, or autologous transplantation. Because the risk of early ovarian failure depends on the patient's circumstances, patients with blood cancer must consult health professionals regarding fertility preservation before undergoing treatments that can potentially damage their ovaries. While it is widely known that early menopause commonly occurs following breast cancer treatment, there is a lack of reliable study results regarding fertility preservation during blood cancer treatment. Therefore, an in-depth discussion between patients and health professionals about the pros and cons of the various options for fertility preservation is necessary.


Conflict of interest: No potential conflict of interest relevant to this article was reported.


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