Key words
double embryo transfer - embryo quality - cleavage stage - blastocyst stage - live
birth rate - multiple pregnancy
Schlüsselwörter
Doppelembryonentransfer - Embryoqualität - Teilungsstadium - Blastozystenstadium -
Lebendgeburtenrate - Mehrlingsschwangerschaft
Introduction
The number and quality of embryos transferred are important in determining the success
of assisted reproductive technology (ART) treatment cycles. Good quality embryo transfers
result in higher clinical pregnancy and live birth rates [1], and poor quality embryo transfers result in higher miscarriage and lower ongoing
pregnancy rates [2]. This is probably the result of different endometrial responses to the quality of
the embryo; decidualized endometrial stromal cells have been shown to act as biomarkers
for arrested embryos, thus preventing implantation [3]. Clinical pregnancy and live birth rates are lower with single poor quality embryo
transfers; however, when clinical pregnancy is achieved, miscarriage rates, obstetric,
and perinatal outcomes are similar to good quality embryo transfer cycles [1]. Therefore, a poor quality embryo may also have the
chance of a live birth.
There is increasing preference for elective single-embryo transfers (SET) in in vitro
fertilization (IVF) cycles because cumulative live birth rates are high after fresh
cycles followed by frozen and thawed cycles with SET [4]. However, double-embryo transfers (DET) are still preferred in many IVF clinics
because the clinical pregnancy and live birth rates are higher than with SET cycles
[5], [6]. Nevertheless, it is also known that multiple pregnancy rates are higher in DET,
resulting in higher maternal and perinatal mortality and morbidity rates [5], [6]. When there is more than one good quality embryo on the transfer day, many clinics
prefer DET, but generally, there are embryos of different qualities in the available
transfer cohort. It is difficult to decide whether to transfer the mixed quality embryos
together or
to transfer a single good quality embryo, because a good quality embryo has been
shown to have a higher implantation rate than DET with mixed quality embryos [7].
The aim of this study was to investigate whether a poor quality embryo transfer along
with a good quality embryo had a negative effect on IVF outcomes compared with DET
with two good quality embryos.
Materials and Methods
Study design
The presented retrospective clinical study was conducted at the ART clinic of Health
Sciences University Etlik Zubeyde Hanım Womenʼs Health Teaching and Research Hospital,
Ankara, Turkey. The patient files between January 2007 and February 2018 were reviewed
using a computer-based database. The IVF cycle was accepted as the process that started
with controlled ovarian stimulation (COH) and resulted with embryo transfer. We analyzed
2298 fresh cycles of women aged ≤ 40 years who had their first, second or third cycles
with SET or DET. The patients were divided into three groups: group A included two
good quality embryo transfer cycles, group B included one good and one poor quality
embryo transfer cycle, and group C included a single good quality embryo tranfer cycle.
All groups were divided into two subgroups according to the stage of the embryo transferred
as cleavage stage (day 3) or blastocyst (day 5) transfer subgroups. Patients with
endometrial, uterine pathologies,
endometriosis or hydrosalpinx were excluded. The study was approved by the institutional
ethics committee (12/11/2018 – 19). Formal consent was not required because it was
a retrospective study.
Ovarian stimulation, intracytoplasmic sperm injection (ICSI), and embryo transfer
procedures
Patients were stimulated with standard-antagonist or long-agonist protocols after
evaluation of the ovarian reserve. The dose of gonadotropins was individualized according
to the patientʼs age, basal serum follicle-stimulating hormone (FSH) level, antral
follicle count (AFC), and body mass index (BMI), and was adjusted depending on the
ovarian response. Cycle monitorization with serial transvaginal ultrasonography and
measurement of serum estradiol (E2), luteinizing hormone (LH), and progesterone levels
were continued until human chorionic gonadotropin (hCG) administration for final oocyte
maturation when at least three follicles reached a mean diameter of 18 mm. Oocyte
pick-up (OPU) was performed using transvaginal ultrasound-guided aspiration 35.5 – 36
hours after the hCG administration.
The mature oocytes were inseminated by using ICSI. Embryo transfer was performed under
transabdominal ultrasonographic guidance. All patients received luteal phase support
(Crinone 8% gel, Serano, Istanbul) starting on the day of oocyte retrieval until a
pregnancy test was performed. Serum hCG levels were measured 14 days after OPU. Positive
values (hCG > 10 IU/L) were repeated after 2 – 4 days, and in cases of pregnancy,
luteal phase support was continued up to 10 – 12 weeks of gestation.
Assesment of embryo development
The fertilization of the oocytes was assessed 18 – 20 hours after ICSI with the observation
of the presence of two pronuclei. Day 2 embryos (42 – 44 h after ICSI) were classified
according to the size, nucleation, and cytoplasmic morphology of the blastomers. Day 3
embryos (61 – 65 h after ICSI) were graded using an embryo scoring system according
to the number, size, and symmetry of the cells and degree of fragmentation [8] ([Table 1]). Grade 1 and grade 2 embryos were classified as good quality embryos, grade 3 and
grade 4 embryos were classified as poor quality embryos for cleavage stage embryos.
Grade 5 embryos were not transferred. Blastocyst-stage embryo scoring was based on
the number and adhesion of evenly sized blastomers, visible inner cell mass, and blastocyst
cavity, continuous trophoectoderm with sufficient cells, and zona pellucida thickness,
as proposed by Gardner et al. [9] ([Table 2]). Blastocysts with ≥ 3 BB score were classified as good quality embryos.
Table 1 Embryo grading according to the cleavage stage embryo scoring system [8].
|
Score
|
Description
|
|
Grade 1 and grade 2 embryos were classified as good quality embryos, grade 3 and grade
4 embryos were classified as poor quality embryos; grade 5 embryos were not transferred.
|
|
Grade 1
|
Embryo with 8 – 12 even sized blastomeres and < 5% cytoplasmic fragments
|
|
Grade 2
|
Embryo with 6 – 10 even sized blastomeres, 5 – 20% cytoplasmic fragments
|
|
Grade 3
|
Embryo with uneven blastomeres, ≤ 20% cytoplasmic fragments
|
|
Grade 4
|
Embryo with even or uneven sized blastomeres, 20 – 50% cytoplasmic fragmentation
|
|
Grade 5
|
Embryo with ≤ 4 blastomeres of any size, > 50% or complete fragmentation
|
Table 2 Embryo grading according to the blastocyst stage embryo scoring system [9].
|
Blastocysts with ≥ 3 BB (AA, AB, BA, BB) score were classified as good quality embryos.
Blastocysts graded as AC, CA, BC, CB and CC were classified as poor quality embryos.
|
|
Expansion grade
|
Description
|
|
1
|
Blastocoel cavity less than half of the embryo volume
|
|
2
|
Blastocoel cavity more than half of the embryo volume
|
|
3
|
Full blastocyst, cavity completely filling the embryo
|
|
4
|
Expanded blastocyst, cavity larger than the embryo, with thinning of the shell
|
|
5
|
Hatching out of the shell
|
|
6
|
Hatched out of the shell
|
|
Grade
|
A
|
B
|
C
|
|
Inner cell mass
|
Many cells, tightly packed
|
Several cells, loosely grouped
|
Very few cells
|
|
Trophoectoderm
|
Many cells, forming a cohesive layer
|
Few cells, forming a loose epithelium
|
Very few large cells
|
Clinical outcome
The determination of an embryo with a positive heart beat in a transvaginal scan (TVS)
was defined as a clinical pregnancy. The clinical pregnancy rate was defined as the
number of heart beat-positive embryo detected through ultrasonography divided by the
number of embryo transfers. Live birth was defined as delivery of a viable infant
after 22 weeks of gestation. The live birth rate was defined as the number of live
offspring delivered divided by the number of embryo transfers. The miscarriage rate
was defined as the percentage of pregnancy losses before 20 weeks of gestation among
all clinical pregnancies. The obstetric outcomes of the pregnancies in all three groups
were also recorded and compared.
Statistical analysis
A power analysis was conducted using the G*Power (version 3.1.7) software and based
on findings of comparable studies [7], [10]. An effect size of 0.237 was used with power set at 0.85 and α at 0.05 to determine
that a sample size of 163 was required in each group to conduct one-way analysis of
variance (ANOVA). Statistical analyses were completed using the Statistical Package
for the Social Sciences (SPSS Inc., Chicago, IL, USA) version 20.0 software. The variables
were investigated using visual (histograms, probability plots) and analytical methods
(Kolmogrov-Simirnov/Shapiro-Wilk test) to determine whether they were normally distributed.
ANOVA was used to compare continuous variables with normal distributions and the Kruskal-Wallis
test was used to compare variables with non-normal distributions. The χ2 test was used to compare the proportions in different groups. A p value < 0.05 was
accepted as statistically significant.
Results
Patient and tratment characteristics
Out of the 2298 cycles analyzed, 498 patients were in group A (DET with two good quality
embryos), 179 in group B (DET with one good and one poor quality embryo), and 1621
in group C (SET with a good quality embryo). The demographic and cycle characteristics
of the three groups are shown in [Table 3]. The patients in group C were statistically significantly younger than in the other
two groups (p = 0.001) because the legislation related to ART procedures in our country
prohibits DET in the first and second cycles before age 35 years, but DET is allowed
either in the third cycle and beyond independent of age or in all cycles in women
aged over 35 years. The total gonadotropin dose used for ovarian hyperstimulation
was significantly higher, and the number of mature and fertilized oocytes was significantly
lower in group B when compared with the other two groups.
Table 3 Comparison of IVF-ET treatment cycle characteristics of the patients in group A,
group B and group C.
|
|
Group A (DET with GQEʼs)
n = 498
|
Group B (DET with MQE)
n = 179
|
Group C (SET with GQE)
n = 1621
|
p*
|
|
Data presented as mean ± SD. DET: double embryo transfer; GQE: good quality embryo;
MQE: mixed quality (one good quality plus one poor quality) embryos; SET: single embryo
transfer.
a There was a significant difference between DET with GQE and DET with MQE.
b There was a significant difference between DET with GQE and SET with GQE.
c There was a significant difference between DET with MQE and SET with GQE.
d There was a significant difference between DET with GQE, DET with MQE and SET with
GQE.
* p-values with statistical significance (p < 0.05) are shown in bold.
|
|
Maternal age, years
|
33.5 ± 4.6
|
34.5 ± 4.3
|
29.2 ± 4.3
|
0.001b, c
|
|
Body mass index, kg/m2
|
26.6 ± 5.0
|
26.6 ± 4.5
|
26.0 ± 4.9
|
0.054
|
|
Total gonadotropin dose, IU
|
2557.1 ± 1042.3
|
2898.0 ± 1172.7
|
2249.3 ± 957.9
|
0.001d
|
|
Number of mature oocytes
|
9.3 ± 5.4
|
7.1 ± 4.0
|
8.9 ± 5.7
|
0.001a, c
|
|
Number of fertilized oocytes
|
5.3 ± 3.5
|
3.6 ± 2.3
|
4.8 ± 3.6
|
0.001d
|
|
Fertilization rate
|
0.60 ± 0.22
|
0.55 ± 0.26
|
0.56 ± 0.25
|
0.002d
|
|
Endometrial thickness, mm
|
10.1 ± 2.3
|
10.5 ± 5.6
|
10.3 ± 2.3
|
0.178
|
IVF and pregnancy outcomes by embryo stage at transfer: cleavage embryo transfer
The groups were divided into subgroups according to the stage of the embryo transferred.
In cleavage stage (D3) transfer subgroups, there were 324 patients in group A, 127
patients in group B, and 887 patients in group C. When cleavage stage embryo transfers
were analyzed, the clinical pregnancy rates of group A and group B were similar (39.2
vs. 38.1%), and group C had the lowest clinical pregnancy rates (30.7%), which was
statistically significantly lower than in group A (p = 0.011). Live birth rates were
similar in all groups. The miscarriage rate was lowest in group C (15.2%) compared
with groups A (24%) and B (25%), but the difference was not statistically significant
(p = 0.057). Multiple pregnancy and preterm delivery rates were statistically significantly
higher in group A and group B ([Table 4]).
Table 4 Comparison of the reproductive outcomes of IVF cycles with cleavage stage embryo
transfer in group A, group B and group C.
|
|
Group A (DET with GQEʼs)
n = 324
|
Group B (DET with MQE)
n = 127
|
Group C (SET with GQE)
n = 887
|
p*
|
|
Data presented as mean ± SD. DET: double embryo transfer; GQE: good quality embryo;
MQE: mixed quality (one good quality plus one poor quality) embryos; SET: single embryo
transfer.
a There was a significant difference between DET with GQE and DET with MQE.
b There was a significant difference between DET with GQE and SET with GQE.
c There was a significant difference between DET with MQE and SET with GQE.
d There was a significant difference between DET with GQE, DET with MQE and SET with
GQE.
* p-values with statistical significance (p < 0.05) are shown in bold.
|
|
Clinical pregnancy rate
|
125 (39.2)
|
48 (38.1)
|
271 (30.7)
|
0.011b
|
|
Live birth rate
|
89 (27.5)
|
34 (26.8)
|
217 (24.5)
|
0.593
|
|
Miscarriage rate
|
30 (24)
|
12 (25)
|
40 (15.2)
|
0.057
|
|
Multiple pregnancy rate
|
28 (22.8)
|
6 (13)
|
8 (3.4)
|
0.001b.c
|
|
Preterm delivery
|
15 (12.0)
|
4 (8.3)
|
7 (2.6)
|
0.001b,c
|
IVF and pregnancy outcomes by embryo stage at transfer: blastocyst embryo transfer
In the blastocyst transfer subgroups, there were 174 patients in group A, 52 in group
B, and 734 in group C. In these subgroups, the clinical pregnancy rates were significantly
higher in group A than in groups B and C (57.5, 27.5, 42.6%, respectively; p = 0.001).
The live birth rate was significantly higher in group A than in group B (40.2 vs.
19.2%, p = 0.011). The clinical pregnancy and live birth rates were higher in group
C than in group B, but it was not statistically significant. There was no statistically
significant difference in miscarriage rates. Multiple pregnancy rates were significantly
higher in patients in group A and group B ([Table 5]).
Table 5 Comparison of the reproductive outcomes of IVF cycles with blastocyst embryo transfer
in group A, group B and group C.
|
|
Group A (DET with GQEʼs)
n = 174
|
Group B (DET with MQE)
n = 52
|
Group C (SET with GQE)
n = 734
|
p*
|
|
Data presented as mean ± SD. DET: double embryo transfer; GQE: good quality embryo;
MQE: mixed quality (one good quality plus one poor quality) embryos; SET: single embryo
transfer.
a There was a significant difference between DET with GQE and DET with MQE.
b There was a significant difference between DET with GQE and SET with GQE.
c There was a significant difference between DET with MQE and SET with GQE.
d There was a significant difference between DET with GQE, DET with MQE and SET with
GQE.
* p-values with statistical significance (p < 0.05) are shown in bold.
|
|
Clinical pregnancy rate
|
100 (57.5)
|
14 (27.5)
|
309 (42.6)
|
0.001a,b
|
|
Live birth rate
|
70 (40.2)
|
10 (19.2)
|
234 (31.9)
|
0.011a
|
|
Miscarriage rate
|
23 (23.0)
|
3 (21.4)
|
58 (18.8)
|
0.609
|
|
Multiple pregnancy rate
|
32 (32.7)
|
4 (28.6)
|
8 (2.6)
|
0.001b,c
|
|
Preterm delivery
|
7 (7.0)
|
1 (7.1)
|
11 (3.6)
|
0.313
|
IVF and pregnancy outcomes of DET with mixed quality embryos in both stages
For patients in group B, in cleavage stage transfers, clinical pregnancy (38.1%) and
live birth (26.0%) rates were higher than in blastocyst stage transfers (27.5 and
19.2%, respectively), but the difference was not statistically significant (p = 0.179
and p = 0.287). The miscarriage rate was similar in both embryo transfer stages. However,
the multiple pregnancy rate was higher in blastocyst stage transfers (28.6%) than
in cleavage stage transfers (13.0%), although it did not reach statistical significance
(p = 0.172).
Discussion
Despite new advances in the field of ART, factors that influence implantation are
still unclear. In this study, we aimed to evaluate the effect of a poor quality embryo
transfer along with a good quality embryo on IVF outcomes. Our study was different
from previous studies because we compared the pregnancy outcomes according to the
stage of the transferred embryos, cleavage stage and blastocyst stage.
The number and the quality of transferred embryos are important predictors of IVF
cycle outcomes. Good quality embryo transfers result in higher clinical pregnancy
and live birth rates [1], [11]. Although ongoing pregnancy rates have been shown to be lower [2], poor quality embryos may also have the chance of clinical pregnancy, and when clinical
pregnancy is achieved, live birth rates and pregnancy outcomes can be similar with
good quality embryo transfer pregnancies [1]. In our study group, when one good and one poor quality embryo was transferred,
the live birth rates were statistically significantly lower than two good quality
embryo transfers on blastocyst stage transfers, but were not different on cleavage
stage transfers. The live birth rates with SET with a good quality embryo were similar
to DET with two good quality embryos in both transfer
stages, but higher than DET with mixed quality embryos in the blastocyst transfer
subgroup. The pregnancy complications apart from preterm delivery were similar in
all three groups.
In IVF treatment cycles, DET is performed in many clinics because clinical pregnancy
rates are higher than with SET. In a fresh IVF cycle after DET, the live birth rate
is reported as 40%, whereas it ranges between 22 and 30% after SET [12]. However, cumulative live birth rates are high after fresh cycles followed by frozen
and thawed cycles with SET in a remarkable number of countries practicing elective
SET [4]. On the other hand, multiple pregnancy rates are significantly high in patients
receiving DET cycles. When there are two good quality embryos available for transfer,
DET is performed although the multiple pregnancy risk is taken into account. Whether
DET with a good quality embryo accompanied by a poor quality embryo demonstrates similar
results is debatable. It is known that morphologically poor quality embryos are more
likely to be genetically abnormal, and theoretically, a poor quality embryo may
impair the implantation of the good quality embryo when transferred together.
The question is whether the poor quality embryo impairs the implantation potential
of the good embryo when transferred together or each transferred embryo has its own
implantation potential.
A series of studies reported that group culture of embryos had a beneficial effect
on embryo development and growth [13], [14], [15]. There is growing evidence of an interaction among embryos that is mediated by specific
released growth factors, which promote their own development. In contrast, it has
also been demonstrated that this interaction depends highly on the quality of cultured
embryos [16]. The presence of poor quality embryos in the embryo culture may result in a lower
blastulation rate of all embryos in comparison with good quality embryos cultured
together. In Tao et al.ʼs study, poor quality embryos reduced blastocyst development
when cultured with good quality embryos [16], suggesting a negative effect on implantation, but there was no effect on clinical
pregnancy and live birth rates. Besides, there
are studies proving that the endometrium acts as a biosensor [17], and prevents abnormal embryos from implanting [3].
El-Danasouri et al. concluded that morphologically and developmentally impaired embryos
significantly reduced the implantation chance of good quality embryos, independent
of the transfer date [18]. By contrast, Li et al. and Wintner et al. reported that the poor quality embryos
did not impair the implantation of good quality embryos when transferred together
[7], [19].
Blastocyt stage transfers are widely preferred in order to increase the reproductive
outcome of ART cycles because a vast number of studies have shown that the predictive
value of morphological assessment of day 3 embryos for embryonic development is limited
and the risk of aneuploidy is significantly lower in day 5 embryos [20], [21], [22]. Therefore, as much as embryo quality, transfer stage can also be important in determining
treatment cycle success.
Dobson et al. reported that DET of mixed quality embryos at the blastocyst stage did
not increase the live birth rate when compared with SET with a good quality embryo
[10], it was even possible that a poor quality embryo might have a detrimental impact
on blastocysts used during DET.
In our study, we found that in patients undergoing blastocyst transfer, the live birth
rates in DET with mixed quality embryos were lower than with DET with two good quality
embryos. The live birth rates in the SET group with a good quality embryo were higher
than in the DET group with mixed quality embryos, but the differences between the
groups did not reach statistical significance.
Li et al. found that in patients undergoing cleavage stage embryo transfer, there
was no difference between DET with two good quality embryos and DET with a poor quality
embryo and a good quality embryo in terms of clinical pregnancy and live birth rates
[19]. Similarly, we found that patients undergoing cleavage stage embryo transfer had
similar clinical pregnancy rates to the DET group with two good quality embryos, and
DET with one good and one poor quality embryo. SET with a good quality embryo resulted
in significantly lower clinical pregnancy rates, but the live birth rates were comparable
between the three groups (p = 0.59).
Previous studies showed that multiple pregnancy rates were increased with DET [5], [6], [23], [24]. Interestingly, Li et al. reported a higher multiple pregnancy rate in DET with
two good quality embryos when compared with DET with one good and one poor quality
embryo, and related this finding with the higher implantation rate of good quality
embryos. In our study, the multiple pregnancy rate was higher in both DET groups compared
with the SET group.
Previous studies have shown that clinical pregnancy achieved with a poor quality embryo
had a similar chance of reaching live birth as a high quality embryo pregnancy [1], [6]. Consistent with other studies, we found no statistically significant differences
in terms of miscarriage and ectopic pregnancy rates between the groups [6], [7], [19]. The miscarriage rate was almost significantly lower in the cleavage stage SET group,
which was probably due to the younger age of this group; the incidence of aneuploidy
is expected to be lower in this group.
In contrast to Gelbaya et al.ʼs study [25], we found that preterm delivery rates were significantly high in DET subgroups in
accordance with the increased multiple pregnancy rates. In the cleavage stage transfer
subgroups, preterm delivery rates were significantly high in DET subgroups (p = 0.01);
however, the difference was not statistically significant for the blastocyst transfer
subgroups (p = 0.31).
The main limitation of our study is the retrospective case-control design and the
younger age of the SET group patients due to legislation related to ART procedures
in our country. The low patient number in group B at the blastocyst stage may be a
limiting factor. Another universal limitation is the subjective morphologic assessment
of the embryo, even when performed by experienced embryologists. More advanced methods
to evaluate embryos will provide a better definition of good and poor quality embryos.
In conclusion, DET with mixed quality embryos has lower clinical pregnancy rates and
live birth rates compared with DET with two good quality embryos at the blastocyst
stage, but there is no difference between DET groups with cleavage stage transfer.
Transferring a poor quality embryo with a good quality embryo does not influence miscarriage
and multiple pregnancy rates in both cleavage and blastocyst stage transfers.
Author Contributions
Conception and design: OA, RO, SD; Project development: IK, OMT; Data analysis: EB,
BD; Writing the Manuscript: OA, RO.
