Social freezing of oocytes: a means to take control of your fertility


REVIEW ARTICLE

Social freezing of oocytes: a means to take control of your fertility

Anna-Lena Wennberg

Nordic IVF, Gothenburg, Sweden

ABSTRACT
In the last few decades, there have been tremendous developments of assisted reproductive technolo-
gies, but the outcome of in vitro fertilization is highly dependent on the age of the oocyte. The intro-
duction of vitrification offers a possibility to freeze eggs proactively in younger years and use them at
later ages, also called social egg freezing. Knowledge about age-related fertility decline is insufficient
among many women, and there is an overoptimistic trust that in vitro fertilization can overcome this.
The awareness of proactive egg freezing is limited, both among doctors and in the general popula-
tion. This review aims at increasing the knowledge about proactive egg freezing and offers a means
to advise women correctly. It deals with national guidelines, the best age and optimal number of eggs
to freeze, and the chance to succeed. Creating more public awareness about age-linked fertility
decline and elective egg freezing may help women reproduce at their own pace – to take control of
their fertility.

ARTICLE HISTORY
Received 1 October 2019
Revised 23 November 2019
Accepted 15 December 2019

KEYWORDS
Age; elective; fertility;
oocyte; pregnancy; results;
social egg freezing;
vitrification

Introduction

Ever since the birth of the first child from in vitro fertilization
(IVF) in 1978 (1) there have been great developments in the
area of assisted reproductive technology (ART). Many differ-
ent ways to achieve parenthood exist, and there are now
available treatments for most types of male and female infer-
tility. However, a growing problem in the developed world is
that we start families at a continuously later stage in life. The
mean age for giving birth to the first child has increased all
over the world. In Sweden it now reaches 29.4 years (2), with
similar figures in all the Nordic countries. Parallel to this,
female fertility drops with age. A recent study from Denmark
showed that fertility decreases approximately 15% between
35 and 40 years and 35% annually above 40 years (3). Studies
have shown that there is insufficient knowledge about age-
related fertility decline (4–6). Nonetheless, many women are
aware of their declining fertility potential, and it causes stress
to women who have not yet found a partner to form a fam-
ily with. On the other hand, the awareness of proactive egg
freezing is limited, and there is often an overoptimistic belief
that IVF will help to overcome age-related infertility (4,7).
Creating more public awareness about age-linked fertility
decline and elective egg freezing, also called social freezing,
is therefore a key factor to help women reproduce at their
own pace. Elective egg freezing can also serve as a means
not only to have one child, but to increase the possibility of
having a second and third child, for couples who have their
first child fairly late.

Egg freezing

Cryopreservation of spermatozoa, to protect male fertility,
was established already in the 1950s (8), and techniques to
cryopreserve embryos were developed during the 1980s (9).
Because of their size, unfertilized eggs are more sensitive to
cryopreservation than sperm and embryos. The first birth
after oocyte freezing, followed by warming and IVF, was
described already in 1986 by Chen in South Korea (10), but
the results were difficult to reproduce. Cryopreservation tech-
niques at that time were limited, with low oocyte survival
after thawing, low fertilization rates, and poor pregnancy
results. In later years a novel technique – vitrification – has
been introduced, showing good warming results and with
good fertilization and pregnancy rates (11). The technique
means that the oocytes are cooled ultra-rapidly in liquid
nitrogen to �196 �C, in a minimal volume of cryoprotectant.
In addition, a hands-on tool has made the method easier to
introduce into clinical practice than previously. Spanish and
Italian groups have, in large randomized and cohort studies,
demonstrated that live birth rates after IVF with vitrified
oocytes are comparable to IVF using fresh oocytes (12,13).
Importantly, international follow-up of children born after
oocyte vitrification have not revealed any increased risk of
adverse obstetric outcome or increased risk of birth
defects (14,15).

Becoming pregnant with cryopreserved oocytes requires
IVF. The woman’s ovaries need to be stimulated before the
eggs can be collected and cryopreserved. After warming, the

CONTACT Anna-Lena Wennberg annalena@nordicivf.se Nordic IVF, Odinsgatan 10, Gothenburg, SE-411 03, Sweden
� 2020 The Author(s). Published by Informa UK Limited, trading as Taylor & Francis Group.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use,
distribution, and reproduction in any medium, provided the original work is properly cited.

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2020, VOL. 125, NO. 2, 95–98
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eggs are fertilized, with the partner’s or donated sperm, and
an embryo is transferred to the uterus.

Oocyte freezing is valuable for a variety of medical rea-
sons such as egg donation, genetic predisposition of prema-
ture ovarian failure, severe endometriosis, or any
gonadotoxic treatment that may result in premature ovarian
failure, e.g. cancer treatment. There may also be ethical or
religious reasons to freeze unfertilized eggs instead of
embryos. Elective egg freezing without medical reasons is
somewhat more controversial, and there was a big debate
when the method was introduced. However, most people
today have a positive attitude towards the procedure. A
Swedish questionnaire study among 2000 women of repro-
ductive age showed that a majority were positive to elective
egg freezing, both for medical and for non-medical purposes,
and almost half of the women would consider the procedure
themselves (16). The Swedish National Council of Medical
Ethics (SMER) has also made a statement in favour of non-
medical egg freezing (17), as have the European Society of
Human Reproduction and Endocrinology (ESHRE) (18) and
the Nordic Fertility Society (NFS).

Elective egg freezing for non-medical reasons was intro-
duced in Sweden by Nordic IVF Gothenburg in 2011 and is
now offered by most private clinics in Sweden. There is no
specific law regulating oocyte cryopreservation in Sweden.
National guidelines have therefore been created by the
Swedish Society of Obstetrics and Gynaecology (SFOG) (19)
based on guidelines from SMER (17) and ESHRE (18). The
guidelines state that elective egg freezing for non-medical
reasons is ethically acceptable provided that the woman
receives thorough information about the procedure, the risks,
and the chance of having a child by use of the cryopre-
served eggs. The importance of information is also stressed
in the recommendations by ESHRE, but the organization at
the same time points out that it should be each woman’s
free choice weather to freeze eggs or not.

According to SMER the cost for non-medical egg freezing
should be covered by the individual. From 1 October 2013
drugs are not subsidized by the Swedish state for women
who freeze eggs just by choice. One argument is that only a
small percentage of the banked oocytes will probably ever
be used (20–22), and the procedure is thus not cost-effective
(23). It is, however, not obvious that this approach is equal
and just. One can argue for various systems of public fund-
ing, part-funding, or pay-back systems for women who pro-
actively freeze their eggs in younger years, similarly to
funding IVF with public means (24). Younger women have
better egg quality, better chance of becoming pregnant, and
require a lower hormonal dose at stimulation than older
women. It is also likely that is more cost-effective to try and
get pregnant with own frozen young eggs than by egg
donation at a more advanced age. Moreover, there are con-
ditions that are neither purely medical nor non-medical, such
as congenital low ovarian reserve or reduced ovarian reserve
due to endometriosis, benign ovarian cysts, or unilateral
adnexal operations. Egg freezing in this intermediate group
is today not subsidized by the state.

When to freeze?

The debate is ongoing regarding the suitable age for elective
oocyte freezing. The biologically optimal time would be in
the mid-20s, when fertility is at its peak, but it may not be
cost-effective in relation to the low usage. In one study from
the United States, a decision-tree model was constructed to
determine the cost-effectiveness of oocyte preservation in
comparison to no action at ages 25–40 years (25). In this
model, a mathematical calculation was made of the probabil-
ity of a live birth seven years after the decision of whether
to freeze eggs or to take no action. The highest probability
of live birth was seen when oocyte cryopreservation was per-
formed at ages >34 years. Elective oocyte freezing compared
to no action gave the greatest improvement in likelihood of
live births at the age of 37 years (52% after oocyte freezing
and 22% at no action), but there was little benefit over no
action at ages 25–30 years. Furthermore, in this US setting,
the cost-effectiveness for elective oocyte freezing was high-
est at the age of 37 years.

There is a distinction between effectiveness and cost-
effectiveness, and it may be misleading to suggest an opti-
mal age of 37 years for freezing in general. Advice regarding
elective egg freezing should always be based on individual
assessments. Also, based on data that follow, there may be
reasons for women to consider egg freezing if they have not
yet found a partner or are not planning a pregnancy when
approaching the age of 35 years.

How many eggs to freeze?

Another important issue is how many eggs to preserve in
order to have at least one child. It is challenging to deter-
mine the ideal number of oocytes since it depends on many
factors, including maternal age and health, ovarian reserve,
reproductive goals, and also paternal health. No number of
oocytes can offer a guarantee. Many clinics recommend
banking around 20 eggs, which for most women means
going through the procedure more than once. Two
American prediction models, based on IVF/ICSI-treatments,
estimate that approximately 20 oocytes are needed, to have
around 75% likelihood of achieving at least one child pro-
vided that the woman is younger than 38 years (Table 1)
(26,27). The models also show that the chance of success is
highly age-dependent and confirm that attempting fertility
preservation in women at an age of over 40 years is unlikely
to succeed.

Appropriate information about the potential to bank a
sufficient number of oocytes is vital for women’s decision-
making. Cryopreservation of too few oocytes would limit the
possibility of success, while an excessive number would
increase the physical discomfort and the expense. Most

Table 1. Live birth predictions by age, with 20 mature oocytes banked (24).

Age
(y)

Probability of
one live birth (%)

Probability of
two live births (%)

Probability of
three live births (%)

34 90 66 38
37 75 39 15
42 37 7 1

96 A.-L. WENNBERG



clinics use a combination of age, antral follicle count, and
measurement of anti-M€ullerian hormone (AMH) to advise
women properly. Observing a low ovarian reserve at a young
age would cause a stronger incitement to preserve oocytes,
but it would also increase the cost because of the necessity
to repeat the freezing procedure.

What is the chance of having a child?

An appropriate question is evidently what the chance to
have a child is. Previous studies have shown that frozen
eggs are as good as fresh ones (12,13), but direct pregnancy
results from non-medical elective egg freezing are scarce. To
a great extent we have had to rely on outcomes from con-
ventional IVF, but data from egg freezing are now com-
ing up.

Cobo et al. (20) presented a series of 137 out of 1468
women who returned for autologous IVF. The women pre-
served eggs for both medical and non-medical reasons and
constituted 9% of the total number of women freezing eggs
electively. The cumulative ongoing pregnancy rate/live birth
rate (OPR/LBR) per patient was almost 60%.

In an Australian study, 95 women who had stored oocytes
for non-medical reasons answered a non-anonymous ques-
tionnaire (21). Six of these women had returned for autolo-
gous IVF (in total 6% of the responders), and three of them
had given birth as a result.

At Nordic IVF Gothenburg we recently published our own
data from 1 August 2011 to 31 October 2018 (22). During
this period of time 254 women had frozen their eggs for
non-medical reasons, and 38 of them (15%) had returned to
use their banked oocytes. The cumulative LBR/OPR was 63%
for women 36–37 years of age at freezing and 26% for
women 38–39 years of age at freezing. There were unfortu-
nately no births or ongoing pregnancies for women who
were 40 years of age or older at the time of the freezing.
Although our study includes only a limited population, it
clearly demonstrates that the chance of having a child drops
with the age at freezing.

Age-limits

In the work with national guidelines age-limits have been
discussed. There may be reasons to consider age-limits both
for freezing eggs and for using them. Since the probability
of a pregnancy is highly related to the age of the woman at
freezing, elective egg freezing is usually discouraged after
the age of 38 years (18). It is, however, agreed that setting
an upper age-limit for freezing is up to the individual clinic.

It is more difficult to define an upper age-limit for
attempting pregnancy with frozen eggs. Pregnancies at
advanced maternal age are generally considered more haz-
ardous than at younger age. The risks of pregnancy diabetes,
hypertensive disorders of pregnancy, and preeclampsia are
increased, as is the risk of perinatal complications. The num-
ber of caesarean sections is also very high (28–31). Based on
this knowledge and on international practice, the general
recommendation in Sweden is not to thaw eggs at a higher

age than 46 years. On the other hand, the surveys suggest
that the risk of maternal and neonatal complications depend
on the mother’s preconceptional health (28–31). SMER states
that it is improper to define a certain age-limit as ageing is
individual. According to SMER, the basis should be a wom-
an’s medical capacity of coping with a pregnancy and the
best interest of the future child, rather than her actual
age (32).

Social egg freezing

The expression ‘social egg freezing’ can be questioned since
it implies that women deliberately postpone childbearing for
various social reasons, e.g. career, studies, or simply because
a child does not fit in to their present situation of life.
Several studies have shown that this assumption is wrong.
Most women who freeze eggs have a strong wish for a child,
but wish to share their parenthood with a partner rather
than being a single parent (33,34). Elective egg freezing is
often a last resort. At Nordic IVF, where almost 300 women
have banked their eggs, the mean age for freezing eggs is
around 37 years, which is in line with others (20–22). It
reflects the fact that women hope to find a partner and wait
to the last second to freeze their eggs.

Even after thorough information, however, many women
state that freezing is better that doing nothing, and that
they would regret it if not (35,36). The women in the study
by Gold et al. (35) also stated that they would have frozen
earlier if they had been aware of the possibility.

Our mission as gynaecologists must be to inform that the
possibility of having a child is greatest at younger ages, but
also to inform about elective egg freezing alongside other
reproductive alternatives. Egg freezing by choice means no
guarantee to have a child but offers women a means to take
control of their fertility. Many women are insufficiently aware
that fertility drops with age, and, by adding information of
the possibility to freeze eggs to the message of fertility
decline, women may feel helped rather than lectured.

Disclosure statement

No potential conflict of interest was reported by the authors.

Notes on contributor

Anna Lena Wennberg, MD, PhD, Nordic IVF G€oteborg-EUGIN,
Gothenburg, Sweden.

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98 A.-L. WENNBERG

https://www.sfog.se/start/raadriktlinjer/sfog-raad-gynekologi/reproduktion/
https://www.sfog.se/start/raadriktlinjer/sfog-raad-gynekologi/reproduktion/

	Abstract
	Introduction
	Egg freezing
	When to freeze?
	How many eggs to freeze?
	What is the chance of having a child?
	Age-limits
	Social egg freezing

	Disclosure statement
	References