The University of Medicine and Dentistry of New Jersey, Robert Wood Johnson Medical School at Camden, Cooper Hospital/University Medical Center, Department of Obstetrics and Gynecology, Division of Reproductive Endocrinology & Infertility, Camden, New Jersey, USA
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Abstract |
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Key words: IVF/leiomyoma/matched controls/pregnancy rates/pre-term delivery
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Introduction |
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However, myomectomy is not without its risks. Uterine fistulae (Nezhat, 1992) and uterine rupture (Harris, 1992
; Dubuisson et al., 1995
) have been reported after laparoscopic myomectomy. Subsequent abdominal and pelvic adhesions have complicated myomectomy whether performed with laparotomy (Starks, 1988
; Tulandi et al., 1993
; Bulletti et al., 1996
) or laparoscopy (Nezhat et al., 1994
). In many of the published series, myomectomy was performed by the most experienced surgeons (Babaknia et al., 1978
; Berkely et al., 1983; Rosenfeld, 1986
; Verkauf, 1992
; Gehlbach et al., 1993
; Dubuisson and Chapron, 1996
; Dubuisson et al., 1996
). Thus before physicians suggest myomectomy, it is important to determine if the benefits of myomectomy outweigh the risks.
IVF is an expensive invasive procedure. One question facing a physician is whether myomectomy should be performed prior to embryo transfer. Unfortunately there have been several conflicting studies in the literature as to whether smaller intramural fibroids adversely affect IVF pregnancy outcome. One study (Stovall et al., 1998) concluded that leiomyomata decreased implantation rates, but no distinction was made between intramural or subserosal fibroids. Another group (Eldar-Geva et al., 1998
) concluded that intramural and submucosal fibroids but not subserosal fibroids decrease implantation rates even if no uterine cavity distortion is present.
However, Ramzy et al. concluded that uterine corporal myomata <7 cm that do not encroach the uterine cavity had no adverse affect on implantation or spontaneous abortion rates (Ramzy et al., 1998). Another study (Farhi et al., 1995
) found that decreased implantation is associated with uterine fibroids only when uterine cavity abnormalities coexist.
A priori, smaller intramural or subserosal fibroids which do not compress the uterine cavity would seem to be less likely to impair implantation or increase the risk of spontaneous abortion than larger (>5 cm) fibroids, fibroids of any size which compress the uterine cavity, or submucosal fibroids. Before any randomized study comparing conservative treatment versus myomectomy to improve IVF success rates in women with smaller fibroids with no uterine cavity involvement should be performed, it is necessary to establish first whether these fibroids reduce fecundity with IVF. Since one study concluded that smaller, intramural (but not subserosal) fibroids lead to decreased implantation rates (Eldar-Geva et al., 1998) we decided to limit our study to women who have at least one intramural fibroid.
As mentioned, some theories suggest that obstruction to gamete transport may be responsible for the impairment of fertility (Farhi et al., 1995). Another theory is that fibroids may impair implantation (Farhi et al., 1995
). This is the reason for choosing the IVF group to study since at least obstruction to gamete transport would be eliminated. Thus, the study would also evaluate whether fibroids in this category impair implantation and possibly whether they affect subsequent fetal survival.
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Materials and methods |
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All patients were treated between January 1, 1997 and March 31, 1998. Staffing, laboratory conditions and IVF protocols were not changed during this period.
Diagnosis of uterine fibroids was made using transvaginal sonography performed with a multi-frequency endovaginal transducer on a GE Logic 400 (General Electric Medical Systems, Milwaukee, WI, USA). Recorded was the type of fibroid (intramural, subserosal, submucosal, or pedunculated) based on the location in the uterus. The measurements of the dimensions of the fibroids, i.e. length, width and depth, and the mean diameter was then calculated. Also recorded was the position of the fibroid in the uterus based on height (fundus, corpus, lower uterine segment or cervical). If more than 3 months elapsed between the initial sonogram and the start of an IVF cycle, the fibroid was re-measured every 3 months to determine any increase or decrease in size.
The first embryo transfer occurring following ovarian stimulation and oocyte retrieval was included in the evaluation. If embryo transfer was deferred after the retrieval, because of inadequate endometrial thickness or risk of hyperstimulation, the outcome of the first frozen transfer was used. This occurred for six patients in the study group and 11 in the control group. Ovarian stimulation regimens used leuprolide acetate started either in early follicular phase or in mid-luteal phase in dosages ranging from 0.1 mg daily to 2 mg daily. The gonadotrophins were either all FSH (either urinary or recombinant) or mixtures of HMG and FSH. Exclusive use of FSH for stimulation was used by 29 women in the fibroid group and 32 of the controls. Embryo transfer occurred 3 days after oocyte retrieval. If available, up to twice as many embryos as intended to transfer were allowed to cleave and the rest were cryopreserved at the two-pronuclear stage. The best embryos (based on blastomere number and fragmentation) were transferred and any leftover embryos were then cryopreserved at the multi-cell stage (Baker et al., 1997). Assisted hatching was performed on all embryos transferred. A small hole was drilled in the zona pellucida of each embryo using acidic Tyrode's solution gently expelled from a small glass needle (Cohen et al., 1990
; Check et al., 1996
).
A serum ß-HCG value >100 mIU/ml was considered as a chemical pregnancy. Demonstration of a sac by ultrasound at 8 weeks was a clinical pregnancy. A live delivery is self-explanatory.
2-Analysis was used to compare the pregnancy rates by presence of fibroids. P
0.05 was considered significant.
This study was approved by the ethics committee for the Cooper Center for IVF. The matched control study was suggested by the Institutional Review Board (IRB) of Cooper Hospital as a prelude to any subsequent randomized study of myomectomy. All patients knew their results may be used for analysis and publication.
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Results |
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A comparison of IVF outcome by presence of fibroids is presented in Table III. Positive pregnancy tests were observed in 52.4% of the controls and 42.6% of the study group (P = 0.277). Clinical pregnancy rates were 47.5 and 34.4% respectively (P = 0.141, not significant). The spontaneous abortion rates for clinical pregnancies was 20.7% (6/29) for the controls and 33.3% (7/21) for the study group (P = 0.314, not significant). The delivery rates were 37.7 and 22.9% respectively (P = 0.076, not significant). Ninety-five per cent confidence intervals (CI) for the delivery rates were 25.5 to 49.9 for the controls and 12.3 to 33.3 for the study group. A 95% CI for the difference in the delivery rates for the two groups is 0.01 to 0.31. Given the sample size available in each group, this study had 50% power to detect a difference of at least 15% in the rates assuming a baseline rate of 20% at the 5% level of significance. To detect the same effect with 80% power, one would need 163 patients per group. The average gestational age at delivery was 37.0 weeks in the study group and 36.9 weeks in the control group. There were two pre-term deliveries in the study group and three in the control group. The implantation rates were 20.2% (41 sacs/203 embryos transferred) in the control group versus 13.6% (27 sacs/208 embryos transferred) in the fibroid group (P = 0.08, not significant).
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Discussion |
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We had proposed to our IRB to randomly assign women with small intramural fibroids who failed to conceive after one embryo transfer to either having myomectomy before the next transfer or no surgery (controls). The committee concluded that the previous studies were equally divided as to whether or not these fibroids negatively affected implantation following IVF. They suggested that we should first evaluate a prospective matched study, as presented here, and if we found that in our own population fibroids appear to negatively affect fecundity, to resubmit the proposal to evaluate surgery.
These data presented here do not show a significant adverse affect of this type of fibroids on either the percentage of positive ß-HCG levels (>100 mIU/ml), clinical pregnancies or percentage delivered. However, there appeared to be a trend for lower delivery rates in this group, but there was insufficient power to demonstrate significance. The 42.6% rate of positive serum ß-HCG level in the group with fibroids was respectable. It suggests that if smaller intramural fibroids have any negative affect on pregnancy outcome following IVF, it is probably not by preventing implantation but more so in losses occurring after conception. One would need 163 patients per group to detect a difference of 15% in the spontaneous abortion rates and delivery rates at the 0.05 level of significance with 80% power.
A study by Seoud et al. found only 11 of 1415 IVF patients without previous myomectomy having confirmed fibroids (Seoud et al., 1992). Possibly in another study we should eliminate women whose fibroids are below a certain size; the mean size for the study presented here was 1.5 cm but was 2.9 cm in Stovall's study (Stovall et al., 1998
). If we kept the sizes the same, for the Cooper Center for IVF to have approximately the right number of patients to show significant differences it would take about 6 more years. Hopefully this study will encourage a multicentre cooperative study to evaluate sooner than this whether fibroids negatively affect IVF outcome.
There have been further publications since we began our prospective matched controlled study. One retrospective study concluded that the presence of untreated intramural fibroids significantly reduced the delivery rate following hysteroscopic resection of submucous myomas (Bernard et al., 2000). However, the most recent study, once again a retrospective analysis, did not show a significant difference in live birth rates in women <40 years with fibroids versus controls (though a mild trend for lower rates) (Surrey et al., 2001
). However, they did find a lower implantation rate in those with fibroids (Surrey et al., 2001
). Nevertheless because of the relatively high live birth rate in all groups, they stated that surgical intervention cannot be justified (Surrey et al., 2001
).
Bajekal and Li recently reviewed the effect of fibroids on fertility and miscarriage (Bajekal and Li, 2000). They stated that different types of fibroids may affect reproductive outcome to a different extent. They suggested that submucous fibroids were most responsible for infertility and miscarriage, and subserosal the least responsible. Intramural fibroids have an intermediate role. They stated that proper assessment of the benefits and risks of surgery for individual patients should be carefully considered. If one combines the data from the only two prospective matched controlled studies (Stovall et al., 1998
and the present study) there seems to be a definite adverse effect of intramural fibroids
5 cm on the live birth rate. However, the live birth rates are sufficient so that myomectomy does not seem to be a reasonable procedure to suggest prior to attempting at least one IVF cycle. After a thorough review of the literature and evaluation of our own data, it is not likely that any one IVF centre would have a sufficient number of patients with small intramural fibroids not compressing the uterine cavity to be able to prospectively compare the effects of myomectomy for these type of fibroids. Thus we will not re-submit to our IRB. Instead we hope that this study encourages (rather than discourages as in the Surrey et al., 2001
study) a multicentre cooperative study to determine which patients to evaluate, and then randomly compare myomectomy or control to determine the risk/benefit ratio for this procedure.
Unless such data are provided, it is probably unethical as yet to subject women needing IVF to the risks of myomectomy for small intramural fibroids not encroaching the uterine cavity. However, based on these data, we think it more appropriate not to evaluate women failing to conceive after her first transfer, but rather women attaining a positive serum ß-HCG level but failing to achieve a viable pregnancy.
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Notes |
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References |
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Submitted on December 14, 2001; resubmitted on November 12, 2001; accepted on January 10, 2002.