Results
The results of this study may have limited applicability to broader populations due
to the
specific characteristics of the study cohort. A total of 100 patients were included,
with 60
achieving successful treatment with a single dose of methotrexate, resulting in a
success rate
of 93.75% for ectopic pregnancy (EP) management. In the successful treatment group,
the mean age
was 31.84 ± 4.59 years, while the failed treatment group had a mean age of 34.50 ±
1.71 years,
with no significant difference observed (P = 0.272). The mean parity in the
successful group was
1.45 ± 1.54 compared to 2.25 ± 1.50 in the failed group, also showing no significant
difference
(P = 0.203). Similarly, the mean gravidity was 3.25 ± 1.50 in the successful group
versus 2.50 ±
1.29 in the failed group, with no significant difference (P = 0.259). The mean
gestational age
in the successful treatment group was 37.00 ± 6.63 days, compared to 39.26 ± 12.80
days in the
failed treatment group, with no significant difference (P = 0.732). The mean β-hCG
level was
1395 ± 1464 IU/L in the successful group and 1135 ± 481.5 IU/L in the failed group,
with no
significant difference (P = 0.806). The frequency of IUD usage was 8% in the
successful group
and 0% in the failed group, with no significant difference (P = 0.547). The
frequency of prior
EP was 15% in the successful group and 0% in the failed group, also showing no
significant
difference (P = 0.900). The presence of hematoma was observed in 53% of the
successful group and
50% of the failed group, with no significant difference (P = 0.900). The frequency
of tubal ring
observation was 86% in the successful group and 50% in the failed group, with no
significant
difference (P = 0.111). Additional details of other variables studied are provided
in
Table- 1 . To assess the relationship between
key clinical
features—such as history of EP, tubal ring presence, hematoma, and endometrial
thickness—and
treatment success, we conducted logistic regression analysis. As shown in
Table- 2 , gestational age was not a
significant predictor of
successful treatment (odds ratio [OR]: 1.006, 95% confidence interval [CI]: 0.915 -
1.106, P =
0.902). A history of ectopic pregnancy demonstrated a non-significant association
with treatment
success (OR: 0.529, 95% CI: 0.049 - 5.672, P = 0.599). Although the reduced odds
ratio suggests
a potential trend, the wide confidence interval indicates high variability in the
data. The
presence of a tubal ring was borderline significant (OR: 6.500, 95% CI: 0.799 -
52.897, P =
0.080), suggesting that patients with tubal ring findings were approximately six
times more
likely to experience successful medical management compared to those without. The
presence of
hematoma was not a significant predictor of success (OR: 1.143, 95% CI: 0.151 -
8.654, P =
0.897). Endometrial thickness emerged as a borderline significant factor, with an
odds ratio of
1.317 (95% CI: 0.971 - 1.786, P = 0.077).
Right pelvic inflammatory disease (PID) was not a significant predictor (OR: 1.174,
95% CI: 0.191
- 7.227, P = 0.863). Similarly, left PID showed no significant association with
successful
treatment (OR: 1.966, 95% CI: 0.515 - 7.505, P = 0.322). HCG levels did not
significantly
predict treatment success (odds ratio [OR]: 1.000, 95% confidence interval [CI]:
0.999 - 1.001,
P = 0.654). Similarly, the presence of fluid in the cul-de-sac did not demonstrate a
significant
effect on treatment success (OR: 0.436, 95% CI: 0.043 - 4.436, P = 0.483). Patient
age exhibited
a negative but non-significant association with treatment success (OR: 0.808, 95%
CI: 0.626 -
1.044, P = 0.104). Although older patients may have slightly lower odds of
successful treatment,
this finding was not statistically conclusive. The observed negative association
between patient
age and treatment success, while not statistically significant, raises important
considerations
for clinical practice. Older patients may face marginally lower odds of successful
treatment,
potentially due to age-related factors such as decreased ovarian reserve or altered
pharmacokinetics of methotrexate. Clinicians should be mindful of these potential
differences
and consider them when counseling older patients about treatment options and
expectations.
Conclusion
Although the variables examined in this study did not demonstrate predictive power
for EP
treatment outcomes with MTX, various studies suggest that the success of
methotrexate treatment
for ectopic pregnancy is influenced by multiple factors. These include β-hCG levels,
the
presence of fetal cardiac activity, the number of doses required, patient clinical
characteristics, and the timing of diagnosis. Identifying these factors can assist
physicians in
selecting more suitable patients for treatment and achieving better outcomes. The
results
suggest that clinicians can confidently recommend methotrexate to eligible patients,
particularly those with lower initial hCG levels and without significant
complications, as it
may lead to favorable outcomes while minimizing the risks associated with surgery.
Further
research is essential to thoroughly investigate these factors and their impacts on
treatment
outcomes, with the goal of developing more effective treatment protocols. Moreover,
future
studies should focus on larger, multicenter trials to validate the results and
improve the
generalizability of the findings across diverse populations, confirming the
effectiveness of
methotrexate treatment and identifying any variations in outcomes based on
demographic or
clinical factors.
Discussion
The results of the present study indicate that single-dose methotrexate (MTX) therapy
for the
treatment of tubal ectopic pregnancy (EP) achieves a high success rate. However,
given the
limited sample size, none of the examined variables demonstrated a significant
impact or
predictive power on treatment success. This finding suggests that while MTX therapy
is
effective, the small sample may restrict our ability to draw definitive conclusions
regarding
the influence of specific clinical factors on treatment outcomes. Future studies
with larger
sample sizes are needed to better understand the predictors of success in this
context.
MTX (Methotrexate) is a folic acid antagonist that inhibits the synthesis of new
cellular DNA.
This antineoplastic and antimetabolic drug has been increasingly used for the
treatment of EP
since it was first reported by Tanaka and colleagues in 1982 [
13 ]. For many patients, single-dose systemic MTX protocols are commonly
employed as a
standard treatment option, with no significant difference in success rates. Various
studies in
different populations have reported the success rate of single-dose methotrexate in
treating EP
to be as high as 89%, as noted in the study by Bottin et al. [
14 ]. In the present study, the success rate of single-dose MTX treatment
was reported
to be 93.75%, which falls within an acceptable range and is higher and more
effective compared
to other studies. Proper patient selection for medical treatment and early detection
of EP are
likely factors that ultimately result in a positive impact on the success rate of
medical
treatment. This is because the longer the time since the onset of symptoms, the
higher the
likelihood of requiring surgical intervention.
In the present study, maternal age, parity, and gravidity parameters showed no
significant
association with the effectiveness of single-dose MTX therapy. This finding aligns
with the
results of other studies, such as those by Ghanaie et al. [
15 ] and Mirbolouk et al. [ 16 ],
where these
parameters also lacked predictive power. No opposing studies have been reported in
this regard,
and various sources have not reported a significant effect of these parameters on
the efficacy
of MTX treatment for EP. The presence of a hematoma in ectopic pregnancy (EP) can
negatively
impact the success of methotrexate (MTX) treatment and increase the likelihood of
requiring
surgical interventions [ 17 ]. In some studies,
such as
that by Chegini et al. [ 17 ], the presence of
a hematoma
has demonstrated predictive power. However, in most studies, these parameters did
not show
predictive value for the success of medical treatment with MTX [
18 ][ 5 ]. Similarly, in the present
study, no
significant association between hematoma presence and treatment success was
reported, aligning
with the majority of studies.
In the present study, the size of the EP was larger in the unsuccessful treatment
group compared
to the successful treatment group, but this difference was not statistically
significant. These
findings are consistent with studies by Arafa et al. [ 18 ]
and Mirbolouk et al. [ 16 ], where the EP size
was also
larger in the unsuccessful treatment groups. This aligns with the understanding that
larger
ectopic masses are more resistant to medication, complicating treatment and
increasing the need
for further interventions.
In our study, the ampulla of the fallopian tube was the most frequent location of EP.
However,
the frequency of this variable did not significantly differ between the two study
groups, which
is consistent with other studies and reports indicating that the ampulla is the most
common site
of EP in women. Gestational age in our study did not have predictive value for the
success of EP
treatment with single-dose MTX. This finding is in line with studies by Bonin et al.
[ 19 ], Mirbolouk et al. [
16 ], and others, which also reported no significant differences in
gestational age
between successful and unsuccessful treatment groups.
In the present study, the serum β-hCG level at the start of treatment was 1395 in the
responder
group and 1135 in the non-responder group, with no significant difference between
the two.
Although the range of β-hCG levels in our study participants aligns with other
studies, such as
those by Shatkin Hamish et al. [ 20 ] and
Ghanaie et al.
[ 15 ], the lower levels in the unsuccessful
treatment
group cannot be explained except by the small sample size. This is because various
studies have
reported that serum β-hCG levels have predictive power for the success of EP
treatment with
single-dose MTX. In 2023, Ghanaie et al. reported that serum β-hCG levels at the
start of
treatment and their reduction on days 4 and 7 post-treatment can predict the success
of
single-dose MTX treatment [ 15 ]. Similarly, a
2024 study
by Deniz et al. highlighted that the predictive power of β-hCG levels, as well as
their
reduction by day 4, can guide decisions regarding the need for additional drug dose
[ 21 ].
One of the other notable trends observed was the borderline significance of
endometrial thickness
and tubal ring findings. An increased endometrial thickness was associated with
higher odds of
successful treatment, which aligns with prior studies suggesting that endometrial
thickness may
play a role in the body’s responsiveness to medical management [
22 ]. Similarly, the presence of a tubal ring was borderline significant,
indicating
its potential as a prognostic marker. However, these findings must be interpreted
cautiously due
to the p-values being slightly above the threshold for significance.
Interestingly, patient age also showed a non-significant trend toward a negative
association with
successful treatment. While older age has been linked to reduced reproductive
outcomes in
general, its specific role in predicting the success of medical management for
ectopic
pregnancies remains unclear.
The use of methotrexate as a medical approach for treating ectopic pregnancy has
shown promising
results. However, only a limited number of factors have been identified as
predictors of its
success, indicating the need for further research in this area.
This study has several limitations that should be considered when interpreting
the
results:
1. Small Sample Size: The total number of participants (100 patients) is
relatively
small,
particularly in the control group, which consisted of only 40 patients. This
limited
sample size
may restrict the statistical power of the analyses and the ability to detect
significant
associations between clinical variables and treatment success.
2. Case-to-Control Ratio: The disproportionate case-to-control ratio (60:40) may
affect the
generalizability of the findings. An optimal case-to-control ratio is essential
for
robust
conclusions in case-control studies, and the current ratio may limit the
reliability
of the
comparisons made.
3. Single-Center Study: The study was conducted at a single institution, which
may
limit the
diversity of the patient population. Results may not be generalizable to other
settings or
populations with different demographic or clinical characteristics.
4. Retrospective Data Collection: Data were extracted from archived patient
records,
which may
introduce biases related to incomplete or inconsistent documentation.
Retrospective
studies are
inherently limited by the quality of the available data.
5. Potential Confounding Variables: While we attempted to control for various
clinical factors,
there may be unmeasured confounders that could influence treatment outcomes.
Factors
such as
patient adherence to follow-up, variations in treatment protocols, and
individual
responses to
methotrexate were not fully accounted for.
6. Short Follow-Up Period: The follow-up period for assessing treatment success
may
not have been
long enough to capture all relevant outcomes. Longer follow-up may be necessary
to
evaluate the
long-term effectiveness and potential complications associated with MTX therapy.
7. Limited Predictive Power: Despite the high success rate observed, none of the
examined
variables demonstrated significant predictive power for treatment success, which
may
be
attributed to the small sample size and the inherent variability in patient
responses.
In conclusion, while the study provides valuable insights into the effectiveness
of
single-dose
MTX therapy for tubal ectopic pregnancy, these limitations highlight the need
for
further
research with larger, multi-center cohorts to validate the findings and explore
the
predictors
of treatment success more comprehensively.
Introduction
Ectopic Pregnancy (EP) refers to a condition where a developing embryo (blastocyst)
implants and grows in tissue other than the endometrial lining of the uterus.
Ectopic pregnancies most frequently occur within the fallopian tube. However, they
can also develop in other locations, such as the interstitial area, cornua of the
uterus, ovaries, cervix, surgical scars, abdominal cavity, or in combination with an
intrauterine pregnancy, known as a heterotopic pregnancy [ 1 ]. Ruptured ectopic pregnancy is the leading cause of maternal
mortality in the first trimester, accounting for 9% to 14% of maternal deaths and
representing 5% to 10% of all pregnancy-related deaths [ 2 ]. Women with EP may exhibit non-specific symptoms such as
lower abdominal pain and vaginal bleeding, which can clinically resemble
appendicitis, urinary stones, early miscarriage, or trauma [ 3 ].
The current standard for diagnosis includes ultrasound imaging (US)—either
transvaginal (TVUS) or transabdominal (TAUS)—and monitoring of beta-human chorionic
gonadotropin (β-hCG) levels [ 4 ]. Early and
accurate diagnosis of EP can help reduce maternal mortality rates. Notably, no
identifiable risk factor exists in half of the diagnosed EP cases. Risk factors
include a history of EP, fallopian tube damage, prior pelvic surgery, pelvic
infections, prior fallopian tube pathology or surgery, infertility, smoking,
advanced maternal age (over 35 years), pelvic inflammatory disease, endometriosis,
anatomical abnormalities of the reproductive system, pregnancy with an intrauterine
device (IUD) in place [ 5 ][ 6 ]. EPs are particularly challenging and have
become more common due to the rise in assisted reproductive technologies (ART). The
incidence is approximately 1 in 100 pregnancies involving in vitro fertilization
(IVF) and 1 in 7000 pregnancies using ART with ovulation induction [ 7 ]. The growing use of IVF has contributed to
higher rates of EPs, with studies reporting 2.1%-8.6% of IVF pregnancies
experiencing EP after embryo transfer, compared to 2% in spontaneous conceptions
[ 8 ]. Additionally, the World Health
Organization (WHO) highlights a global increase in cesarean sections, now accounting
for 21% of all deliveries. This trend is linked to a rising incidence of cesarean
scar pregnancies (CSPs), a specific type of EP [
9 ].
After confirming the diagnosis of EP, treatment can be either conservative or
invasive, depending on the location of the EP, gestational age, and size of the
gestational sac (GS). There are three primary approaches to managing EP: medical
treatment, surgical intervention, and expectant management [ 10 ]. The current standard for medical management of EP involves
intramuscular injection of methotrexate (MTX), a folate antagonist that inhibits
rapid cell division, thereby terminating the EP [
11 ]. Additionally, given the significant health risks associated with
ectopic pregnancies, timely and effective management is crucial. Methotrexate has
emerged as a key medical treatment for unruptured ectopic pregnancies, offering a
non-invasive alternative to surgical intervention. However, the efficacy and safety
of methotrexate, as well as the factors influencing treatment outcomes, remain areas
of active research. Scientific reports estimate the success rate of MTX treatment
without the need for surgical intervention at 70% to 95%, although its efficacy is
lower in patients with higher initial β-hCG levels. However, recent meta-analyses
have shown inconsistent findings regarding the success rates and risk of side
effects with different treatment regimens, highlighting the need for further
research in this area. Several studies have identified predictive factors that may
influence the success of methotrexate treatment in ectopic pregnancies. For
instance, a study by Stovall et al. (4) found that lower serum human chorionic
gonadotropin (hCG) levels at the time of treatment are associated with higher
success rates. Specifically, patients with initial hCG levels below 5,000 mIU/mL had
a significantly greater likelihood of successful treatment without the need for
surgical intervention[ 12 ]. A better
understanding of the factors influencing MTX efficacy in EP treatment could help
clinicians select the most appropriate therapeutic approaches. Identifying
predictors of treatment success could prevent side effects from ineffective
therapies, reduce treatment costs, and improve both the physical and mental
well-being of patients. Therefore, the purpose of this study was to determine the
factors associated with and predictive of successful medical management of EP using
MTX.
Materials And Methods
The study was a case-control design and conducted with the approval of the Medical
Ethics Committee of Iran University of Medical Sciences (Ethics Code:
IR.IUMS.FMD.REC.1403.159). Patients diagnosed with tubal ectopic pregnancy who had
undergone single-dose methotrexate medical treatment at Akbarabadi Hospital in
Tehran between 2017 and 2023 were included in the study. These patients were
categorized into two groups: those with successful medical treatment (case group)
and those with failed medical treatment (control group).
Patients were categorized into two groups based on treatment outcomes:
• Successful Treatment (Case Group): Defined as a decrease in serum beta-hCG
levels
to less than 15 mIU/mL within 4-6 weeks following methotrexate administration,
without the need for surgical intervention. Successful treatment was also
confirmed
by follow-up ultrasound showing resolution of the ectopic mass.
• Unsuccessful Treatment (Control Group): Defined as either a failure to achieve
the
aforementioned decrease in serum beta-hCG levels or the need for surgical
intervention (laparoscopy or laparotomy) due to persistent or increasing hCG
levels
or clinical symptoms indicating complications.
•
The study included a total of 100 patients diagnosed with tubal ectopic pregnancy
who
underwent single-dose methotrexate (MTX) treatment. To ensure that this sample
size
was adequate for the analyses performed, a power analysis was conducted prior to
the
study. Based on previous literature, we anticipated an expected success rate of
80%
for single-dose MTX treatment. Our goal was to detect a minimum difference of
15% in
success rates between the successful and unsuccessful treatment groups. Assuming
a
significance level (alpha) of 0.05 and a desired power (1 - beta) of 0.80, we
calculated the required sample size using the following formula for comparing
two
proportions:
n=(p1 −p2 )2(Zα/2 +Zβ )2.(p1 (1−p1 )+p2 (1−p2 ))
Where:
• Zα/2 is the Z-value for a two-tailed test at the 0.05 significance level
(approximately 1.96).
• Zβ is the Z-value for the desired power (approximately 0.84 for 80% power).
• p1 is the expected success rate in the case group (0.80).
• p2 is the expected success rate in the control group (0.65, assuming a 15%
lower
success rate).
The power analysis indicated that a minimum sample size of approximately 60
patients
per group would be required to achieve adequate power for detecting a
significant
difference in treatment success rates. However, we acknowledge that our final
sample
included 60 patients in the case group and only 40 patients in the control
group,
resulting in a case-to-control ratio that is not optimal. This limitation may
affect
the statistical power of our comparisons and the generalizability of our
findings.
Demographic data, including age, gestational age, gravidity, parity, history of
ectopic pregnancy in previous pregnancies, use of assisted reproductive
technology
(ART), and contraceptive methods (e.g., IUD placement), were extracted from
archived
patient records and documented in the study checklist. Additionally, serum
beta-hCG
levels and ultrasound findings—such as the size and location of the ectopic
pregnancy, presence of hematoma, fluid in the cul-de-sac, tubal ring shape,
endometrial thickness, and Doppler findings—were recorded and compared between
the
two groups. Data analysis was performed using IBM SPSS Statistics for Windows,
version 30 (IBM Corp., Armonk, N.Y., USA). Qualitative variables were expressed
as
frequency and percentage, while quantitative variables were presented as mean
and
standard deviation. Comparisons between the two groups were conducted using
T-tests
and Chi-square tests (Fisher’s exact test), with a P-value of less than 0.05
considered statistically significant. Logistic regression was performed to
evaluate
the association of multiple clinical variables with the likelihood of successful
treatment. Univariate analyses were conducted to identify variables
significantly
associated with treatment success, with those having a P-value of less than 0.1
considered for inclusion in the multivariate logistic regression model. This
approach helps ensure that the final model accounts for potential confounders
while
maintaining statistical power. The final logistic regression model was assessed
for
goodness-of-fit using the Hosmer-Lemeshow test, and multicollinearity among
predictor variables was evaluated using variance inflation factors (VIF), with a
VIF
value greater than 10 indicating multicollinearity.
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