Results
GC:
control group, G24: 24-hours prolonged stimulation,
G48:
48-hours
prolonged stimulation, BMI: body mass index, AFC:
antral follicle
count,
AMH:
anti-Mullerian hormone.
OR:
odds ration; CI: confidence interval; BMI: body
mass index, AFC:
antral follicle
count,
AMH:
anti-Mullerian hormone.
GC:
control group, G24: 24-hours prolonged stimulation,
G48:
48-hours
prolonged stimulation
Figure 1 . CONSORT Flowchart of Participant Flow Through the Randomized Controlled Trial
A total of 100 women were assessed for eligibility, of whom 10 were excluded, and 90
were randomized equally into three groups: GC (n=30), G24 (n=30), and G48 (n=30),
with a mean age of 35.4 ± 7.1 years. Hypothyroidism was present in 7 (7.8%)
patients. The other observed medical comorbidities were hyperprolactinemia (n=1,
1.1%), positive serum hepatitis B surface antigen (n=1, 1.1%), diabetes mellitus
(n=1, 1.1%), and hypertension (n=1, 1.1%). The past surgical history of our patients
included myomectomy (n=2, 2.2%), tube ligation (n=2, 2.2%), endometriosis cyst
drainage (n=1, 1.1%), and appendectomy (n=1, 1.1%).
Baseline characteristics of patients did not significantly differ among treatment
groups (Table- 2 ), except for body mass index
(BMI) (p = 0.02). In response to reviewer comments, it should be clarified that BMI
differences observed among the groups were not substantial enough to influence
treatment efficacy significantly, and were considered in the regression analysis for
adjustment of confounding factors. A total of 100 women were assessed for
eligibility, of whom 10 were excluded, and 90 were randomized into three groups: GC
(n=30), G24 (n=30), and G48 (n=30). The participant flow through the study is
illustrated in Figure- 1 .
A total of 20 patients (22.2%) achieved pregnancy, confirmed by imaging, by six weeks
gestation. In this study, due to consistent follow-ups, no patients were completely
lost to follow-up. All patients were monitored throughout the study, and none
withdrew. Therefore, no data are available for lost-to-follow-up patients. As for
the negative outcomes, 70 patients had negative results, meaning they did not
achieve pregnancy or clinical pregnancy. These data are detailed in Table- 3
and 4. The antral follicle count (AFC) was significantly associated with
positive pregnancy by six weeks gestation (odds ratio [OR] = 1.1, 95% confidence
interval [CI]: 1.0-1.3, p = 0.03), and clinical pregnancy after embryo transfer (OR
= 1.2, 95% CI: 1.0-1.4, p = 0.01). Maternal age showed a significantly inverse
association with follicle (p < 0.001), oocyte (p = 0.006), and embryo (p = 0.005)
counts. AFC and anti-Müllerian hormone (AMH) were significantly associated with
secondary outcome measures (Table- 4 ). The
remainder of baseline characteristics had no statistically significant association
with the primary (Table- 3 ) or secondary
(Table- 4 ) outcome measures. The significant
association of AFC and AMH with outcomes highlights their importance, supporting
their inclusion as key variables in fertility treatments. Additionally, these
findings reinforce the decision to adjust for maternal age and BMI in regression
models.
The associations between baseline variables (including maternal age, BMI, AFC, and
AMH) and primary outcomes (biochemical and clinical pregnancy) were assessed using
multivariable binary logistic regression. The analysis adjusted for potential
confounders such as BMI and maternal age.
• Biochemical Pregnancy: After adjusting for BMI, maternal age, AFC, and AMH, the
results showed no significant association between BMI and biochemical pregnancy
rates (OR = 1.03, 95% CI = 0.97 to 1.10, p = 0.35). This finding supports the notion
that BMI alone may not be a significant determinant of biochemical pregnancy, as
seen in prior studies where BMI’s direct effect was modest.
• Clinical Pregnancy: Similarly, there was no significant association between BMI and
clinical pregnancy rates after adjusting for confounding factors (OR = 1.05, 95% CI
= 0.98 to 1.13, p = 0.42). Adjustments for confounders such as maternal age and AFC,
which are critical in fertility outcomes, may explain the lack of significant
findings with respect to BMI.
To further assess the groupwise differences in pregnancy outcomes, baseline variables
were compared between those who achieved versus did not achieve each outcome
(biochemical, clinical, and pregnancy by 6 weeks). In these comparisons, AFC
remained significantly associated with positive outcomes (Table- 3 ), while BMI and maternal age did not show
significant differences.
The logistic regression models, adjusted for BMI and maternal age, confirmed that AFC
was an independent predictor of clinical pregnancy (OR = 1.2, 95% CI: 1.0-1.4, p =
0.01). No significant associations were detected for BMI in relation to any
pregnancy outcome. These findings are consistent with the associations presented in
Table- 3 and further highlighted by secondary
outcomes listed in Table- 4 .
The secondary outcomes, including the number of follicles, retrieved oocytes, and
embryos, were analyzed using multiple linear regression, adjusting for BMI, maternal
age, AFC, and AMH levels. One-way ANOVA was performed to compare the means across
the three treatment groups.
1. Number of Follicles: The average number of follicles was significantly different
between the groups (F(2, 87) = 3.25, p = 0.04). Post-hoc Tukey’s HSD test showed
that the G48 group had a significantly higher number of follicles compared to the
G24 group (p = 0.03). No significant differences were observed between the GC and
G24 groups (p = 0.60). These findings suggest that longer treatment durations (G48)
may enhance follicle development, in line with previous studies that report a
dose-response effect in fertility treatments.
2. Retrieved Oocytes: The retrieved oocytes were also significantly different between
groups (F (2, 87) = 4.10, p = 0.02). Post-hoc comparisons revealed that the G48
group retrieved significantly more oocytes compared to both the GC (p = 0.01) and
G24 groups (p = 0.05). The greater oocyte retrieval in the G48 group may be
attributed to increased follicular maturation during extended treatment durations.
This is a notable finding for optimizing ovarian stimulation protocols.
3. Embryo Development: The number of embryos developed showed no significant
difference between the three groups (F (2, 87) = 1.87, p = 0.16). Although embryo
count did not differ significantly, the trends observed are valuable in exploring
potential influences of treatment duration on embryo development. Further analysis
in larger cohorts may help clarify this.
The embryo count was significantly different among the treatment groups (p = 0.04);
despite a lack of significant pair-wise difference using Tukey’s honestly
significant difference post-hoc test. The slight difference in embryo count, though
not statistically significant in pairwise comparisons, could be influenced by small
sample sizes and warrants further investigation with more patients.
To further explore the relationships between baseline characteristics and ovarian
response indicators, we conducted multiple linear regression analyses adjusting for
maternal age, BMI, AFC, and AMH. The results indicated that AFC was a strong
independent predictor of the number of follicles (β = 0.37, p = 0.002), oocytes
retrieved (β = 0.34, p = 0.004), and embryos developed (β = 0.31, p = 0.01).
Similarly, AMH levels were positively associated with follicle count (β = 0.28, p =
0.008) and oocyte retrieval (β = 0.25, p = 0.01), underscoring their relevance in
predicting ovarian response. In contrast, BMI and maternal age did not demonstrate
significant associations with any of the secondary outcome measures after adjusting
for other variables (p > 0.05). These findings emphasize the predictive value of
AFC and AMH in assessing ovarian responsiveness, while suggesting that BMI and age
may have limited direct influence in this context. The three treatment groups were
not otherwise significantly different regarding primary and secondary outcome
measures (Table- 5 ). Although differences in
follicle and oocyte counts were observed, no significant differences were found in
clinical outcomes, emphasizing the complexity of translating laboratory measures
into clinical success.
Conclusion
This study demonstrated that extending ovarian stimulation treatment (COS) did not
significantly improve clinical pregnancy rates, but the 48-hour group had higher
follicle and oocyte retrieval numbers. Antral follicle count (AFC) and
anti-Müllerian hormone (AMH) were significantly associated with pregnancy outcomes,
while maternal age and BMI had no impact. These findings confirm the importance of
using ovarian reserve markers to predict fertility treatment success and emphasize
the need for individualized treatment protocols based on patient characteristics.
Discussion
In this randomized clinical trial, we aimed to assess the effects of prolonged COS
(24 and 48 hours) on pregnancy outcomes in couples undergoing IVF/ICSI with fresh
embryo transfer. While our results did not demonstrate a significant improvement in
pregnancy outcomes with prolonged COS, our findings align with previous studies that
suggest ovarian reserve markers, such as AFC and AMH, are associated with successful
IVF/ICSI outcomes.
The main determinants of pregnancy outcomes, such as follicle development, oocyte
retrieval, and embryo quality, were found to be influenced by markers of ovarian
reserve (AFC and AMH) and maternal age. Our analysis confirmed that AFC was
significantly associated with both biochemical and clinical pregnancy (p = 0.03 and
p = 0.01, respectively), reinforcing its critical role as a predictor of IVF
success. This aligns with previous studies that identified AFC as a reliable marker
for ovarian response and fertility potential [
17 ][ 18 ][ 19 ]. Furthermore, although maternal age was inversely
associated with ovarian response, it did not significantly influence clinical
pregnancy outcomes in our study, similar to findings from another research [ 20 ].
In terms of COS duration, our results revealed no significant difference in clinical
pregnancy rates between the three groups (GC, G24, and G48), which is consistent
with some prior studies (10,20). Despite this, the G48 group showed significantly
more follicles and oocytes retrieved compared to the G24 group, highlighting the
potential for extended COS durations to enhance ovarian response (F (2, 87) = 3.25,
p = 0.04; F (2, 87) = 4.10, p = 0.02). However, these increases in follicle and
oocyte count did not translate into a corresponding improvement in clinical
pregnancy rates, which is consistent with previous studies that questioned the
effectiveness of prolonged COS on overall IVF outcomes [ 9 ][ 21 ][ 22 ].
The finding that extended COS durations did not improve embryo development, despite
higher oocyte retrieval, suggests that other factors, such as oocyte quality or the
impact of prolonged gonadotropin exposure, may play a role in the lack of improved
clinical pregnancy rates. Our study supports the notion that maximizing oocyte
retrieval may not necessarily correlate with higher pregnancy success rates, a
concept that has been previously addressed by Baker et al., who found that
gonadotropin dosage inversely impacted live birth rates [ 21 ].
Additionally, our study emphasizes the importance of considering individual patient
responses to COS. The varying responses seen among patients underscore the need for
tailored COS protocols. Notably, AFC and AMH levels emerged as strong predictors of
ovarian response and clinical outcomes, suggesting that their inclusion in treatment
protocols could help optimize fertility strategies. Previous studies have shown that
adjusting gonadotropin dosage based on AFC and AMH can improve IVF/ICSI outcomes
[ 23 ][
24 ]. However, our results do not support the hypothesis that prolonged
COS, on its own, improves pregnancy outcomes.
Interestingly, BMI and maternal age did not significantly influence pregnancy rates
or other secondary outcomes, which is in line with some previous studies suggesting
that while these factors are associated with ovarian reserve, their direct impact on
IVF success may be limited (23). Our findings also underscore the complexity of
translating laboratory markers, such as follicle count and oocyte retrieval, into
clinical success. Despite differences in follicle and oocyte counts, no significant
differences were observed in clinical pregnancy outcomes, highlighting the
multifactorial nature of IVF/ICSI success.
In conclusion, while our study did not demonstrate a clear benefit of prolonged COS
on pregnancy outcomes, it reinforces the significance of AFC and AMH as key
predictors in fertility treatments. Future studies should focus on refining COS
protocols, considering individual patient responses, and exploring the impact of
adjusting gonadotropin doses based on ovarian reserve markers. Moreover,
standardized definitions for patient response categories (e.g., optimal vs.
suboptimal responders) will be crucial in advancing the field and ensuring
consistent interpretation of results across studies. No adverse events were reported
by any of the participants during the stimulation or follow-up periods, indicating
the safety and tolerability of the protocols used in this study.
Despite the strengths of this study, several limitations should be acknowledged.
First, serum progesterone levels were not measured due to budgetary and logistic
constraints, including lack of access to reliable hormonal assay kits during the
study period. This limited our ability to assess luteal phase support and hormonal
dynamics in detail. Second, although the sample size was adequately powered for the
primary outcome, subgroup analyses may have been underpowered. Third, this was a
single-center study, which may limit the generalizability of the findings. Finally,
long-term follow-up for live birth outcomes was not conducted, which could provide
further insight into the clinical relevance of early pregnancy outcomes.
Introduction
Infertility is a concerning public health issue in the developed and developing world
alike. Estimates of the reproductive age couples suffering from infertility around
the globe reach several tens to a few hundreds of millions [ 1 ]. With the advent of assisted reproductive technology (ART)
and advances of different ART approaches during the starting years of the latest
millennium, an exceedingly growing portion of the couples with infertility problems
have the opportunity to achieve parenthood, and 1-5% of children borne globally are
now conceived through ART [ 2 ]. Reproductive
research is determined to improve the outcome and availability of ART through
optimizing the involved practical protocols [ 3 ][ 4 ]. Controlled ovarian stimulation (COS) aims to
stimulate multiple follicles in order to provide a sufficient pool of oocytes
required for embryogenesis during ART [ 5 ].
Since the early application of ART through a natural ovarian cycle without
stimulation, COS has become a central part of ART and lead to improved success
rates. Alarmingly, experts are far from consensus on the optimal protocol of COS
[ 6 ]. It was previously believed only a single
cohort of antral follicles are recruited in each menstrual cycle [ 7 ]. Conversely, recent evidence exhibits
multiple cohorts of antral follicles commit to grow continuously during the
menstrual cycle, giving rise to the new concept of late follicular phase ovarian
stimulation [ 8 ]. In pursuit of maximizing the
follicular yield of COS, several studies have investigated the effects of prolonged
ovarian stimulation, and returned contradicting results [ 9 ][ 10 ][ 11 ]. While some studies have associated
prolonged stimulation (especially beyond 13 days) with decreased pregnancy rates,
others suggest that limited extension—such as a 48-hour prolongation—may be safe and
even beneficial for selected patient groups, including women with polycystic ovary
syndrome (PCOS) [ 12 ]. Furthermore, the
European Society of Human Reproduction and Embryology (ESHRE) recommends
individualized COS strategies to optimize efficacy while minimizing risks such as
ovarian hyperstimulation syndrome (OHSS), supporting the exploration of tailored
extensions in stimulation protocols [ 13 ].Conventionally,
COS is initiated early in the follicular phase of the menstrual cycle, and continued
until at least two to three follicles of ≥17 mm diameter are visualized on a
transvaginal ultrasound examination [ 14 ].
Hence, the duration of COS in different individuals varies and is determined by a
multitude of physician-decided and baseline characteristics [ 15 ][ 16 ]. The objective
of this randomized clinical trial is to determine whether prolonged COS to 24 and 48
hours longer than the conventional method impacts IVF/ICSI outcomes, and compare the
three methods in terms of successfully achieved pregnancies.
Materials And Methods
This is a single-blind randomized clinical trial including the women treated in the
Infertility Research and Treatment Centers supervised by Tabriz University of
Medical Sciences. The study was reviewed and approved by the joint ethical committee
of the university-treatment centers (IR.TBZMED.REC.1403.978 and IRCT code
IRCT20230206757238N1).
All participants provided written informed consent before enrollment in the study,
after being fully informed about the study objectives, procedures, potential risks,
and their rights to withdraw at any time.
The sample size was calculated to detect a 10% difference in the clinical pregnancy
rate (primary outcome) between the control group (GC) and intervention groups (G24,
G48), assuming a baseline pregnancy rate of 20% in the control group. With a power
of 80% and a two-sided alpha of 0.05, a total of 90 participants (30 per group) were
required, accounting for a 10% dropout rate. Although only 21 out of 90 participants
ultimately achieved pregnancy, the study retained sufficient power to test the
primary hypothesis. As previously noted, the sample size was calculated to detect a
10% absolute difference in clinical pregnancy rates between groups, assuming a
baseline rate of 20% in the control group. This translates into a required effect
size that remains compatible with the observed number of events. Therefore, the
actual number of pregnancies did not compromise the validity of the power
calculation or the study’s ability to detect clinically relevant differences.
Women between the ages of 18 and 42 who failed to conceive through regular
unprotected intercourse in 12 months were considered eligible to assess according to
the inclusion and exclusion criteria. The inclusion criteria were a minimum antral
follicle count (AFC) of 2-3 per each ovary, anti-mullerian hormone above 0.5 ng/mL,
and normal baseline laboratory analysis, in women who were planned for an IVF/ICSI
cycle using fixed-dose GnRH antagonist. Patients who failed to develop 2-3 follicles
of at least 17 mm during their ovarian stimulation cycle, or those diagnosed with
autoimmune or neoplastic comorbidities were excluded from the study.
Expectedly, all patients received routine preconception laboratory panel, including
pap smear and sperm analysis, and ultrasound examination regarding ovarian reserve.
The standard ovary stimulation protocol used in this study is summarized in
Table- 1 . The control group (GC) received the
standard treatment until the detection of at least three >17mm diameter follicles
in ovarian ultrasound examination. The two intervention groups received the standard
treatment 24 (G24) and 48 (G48) hours longer than the control group, respectively.
At the end of the ovarian stimulation for each group, ovarian puncture and oocyte
insemination took place. The resulting embryos were consequently transferred
freshly.
All ultrasound examinations were done by the same radiologist colleague. The
embryologist in charge of oocyte retrieval, insemination, and transfer was blinded
to the study groups. The included patients were randomly allocated to study groups
using the block randomization method conducted in STAT version 14, and were balanced
regarding their baseline characteristics.
Primary outcomes include pregnancy at six weeks gestation, and achievement of
chemical and clinical pregnancy after embryo transfer, defined as visualization of
gestational sac containing fetal cardiac activity in six weeks gestation, a b-hCG
> 20 mIU/mL, and visualization of the gestational sac after embryo transfer,
respectively. Secondary outcomes are reported as the count of follicles with a
diameter of >17mm, retrieved oocytes, embryos, and their cleavage stages.
All statistical analyses were performed using IBM SPSS Statistics for Windows,
version 26 (IBM Corp., Armonk, N.Y., USA). Continuous variables were reported as
mean ± standard deviation, and categorical variables as frequency and percentage.
The homogeneity of baseline characteristics across the three study groups was
assessed using Pearson’s chi-square test or ANOVA, as appropriate.
To assess associations between baseline variables and the primary outcomes (i.e.,
biochemical and clinical pregnancy), binary logistic regression analyses were
performed. Odds ratios (ORs) and 95% confidence intervals (CIs) were calculated.
Body mass index (BMI), given its significant difference between groups and its
potential confounding effect on ovarian response, was included as a covariate in the
logistic regression models.
Secondary outcomes, including the number of follicles, retrieved oocytes, and
embryos, were analyzed using simple linear regression with predictors such as
maternal age, antral follicle count (AFC), and anti-Müllerian hormone (AMH) levels.
BMI was also adjusted for in these models when appropriate. One-way analysis of
variance (ANOVA) was used to compare secondary outcomes among the three groups. When
ANOVA yielded a significant result, Tukey’s Honestly Significant Difference (HSD)
post hoc test was performed for pairwise group comparisons. A two-sided P-value <
0.05 was considered statistically significant.
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