Introduction
Infertility is a distressing symptom associated with endo-
metriosis, and the exact mechanism and optimal choice of
management in the context of this disease remains obscure.
In spite of a great deal of effort about the pathogenesis of
infertility in endometriosis, it is still not clear how
endometriosis compromises fertility. Although it is gener-
ally accepted that endometriosis is related to infertility, the
mechanism underlying this effect and its impact on
fecundity are less clear. This makes treatment very difficult
since surgery is directed at the peritoneal lesions which may
not be the only the factor affecting fertility. Fecundity is
defined as the probability of a woman giving live birth in a
given month and ranges from 0.15 to 0.20 in normal
couples and decreases to 0.02 to 0.10 in untreated women
with endometriosis [ 1, 2]. Three-year cumulative pregnancy
rates were found to be lower in women with endometriosis
(36%) as compared with women with unexplained infertil-
ity (55%) [ 3]. Numerous studies have indicated poor
pregnancy outcomes in endometriosis to be associated with
poor sperm function, poor ovarian reserve, lower oocyte/
embryo quality, decreased endometrial receptivity, and
impaired implantation. In this review article, we discuss
the existing evidence of the effects of endometriosis on
fertility.
G. Pahlajani ( *)
Cleveland Clinic,
Main Campus, OBGYN,
Cleveland, OH, USA
e-mail:
[email protected]
T. Falcone
Obstetrics, Gynecology and Women ’s Health Institute,
Cleveland, OH, USA
T. Falcone
Office of Professional Staff Affairs,
9500 Euclid Ave-A81,
Cleveland, OH, USA
Gynecol Surg (2010) 7:319 –328
DOI 10.1007/s10397-010-0564-5
Mechanism of infertility in women with endometriosis
Endometriosis and the alterations in pelvic anatomy
Distortion of the uterotubal anatomy has been proposed as
one of the mechanisms of reduced fertility in patients with
endometriosis. Adhesions may cover or distort the anatomy
of the fallopian tubes and ovaries, thereby impeding pick-
up of oocytes by the fimbriae of the fallopian tube. Kissler
et al. in 2006 [ 4] reported that endometriosis leads to a
significant restriction in uterotubal transport capacity. They
concluded that impeded hyperperistalsis and dysperistalsis
in uterotubal transport associated with endometriosis may
be the reason of infertility in these women [ 4]. Severe
endometriosis is also associated with pelvic adhesions and a
distortion of pelvic anatomy leading to a possible mechanic
or anatomic disturbance of fertility [ 5, 6]. Another factor
distorting the pelvic anatomy and thus affecting fertility are
large endometriomata seen in patients with extensive
endometriosis. Somigliana et al. [ 7] in their study found
that just the mere presence of an endometrioma will
decrease the ovarian responsiveness to stimulation in in-
vitro fertilization (IVF) cycles as compared with contralateral
intact ovaries. They concluded that, especially in women with
larger endometriomas, this difference was more evident [ 7].
Milingos et al. in a study found that laparoscopic removal of
these large endometriomata significantly improved the
fertility outcomes [8]. Therefore, diminished pregnancy rates
in endometriosis due to adhesions and impaired uterotubal
transport even with patent fallopian tubes and normal semen
quality may be one of the factors of sub-fertility in these
patients.
Endometriosis and the sperm function
The endometriosis-associated immunoinflammatory
changes may have some adverse effects on the spermatozoa
since these cells have to stay for some time in the female
genital tract which is bathed by peritoneal fluid. Mansour et
al. studied the correlation of endometriosis and sperm
damage and found positive relation between sperm damage,
stage of endometriosis, and duration of infertility [ 9]. The
same group also studied the impact of peritoneal fluid from
women with endometriosis on sperms and found a
significant increase in sperm DNA damage (Fig. 1). They
proposed this as one of the mechanisms of infertility in
patients with endometriosis [ 10]. Whether this damage is
due to oxidative stress, cytokines, or nitric oxide on the
sperms has been debated. There is compelling evidence in
literature that oxidative stress (OS) is increased in the
peritoneal fluid (PF) in patients with endometriosis. This is
thought to be due to increased production of reactive
oxygen species (ROS), defective antioxidant defense, or
both [ 11, 12]. Spermatozoa are susceptible to damage by
ROS due to limited antioxidant defense and high content of
polyunsaturated fatty acids in their membranes [ 12]. ROS
produces infertility by damaging the sperm plasma and
acrosomal membrane by lipid per oxidation, decreasing
sperm motility, and the ability of the sperm to bind and
penetrate the oocyte and causing DNA damage leading to
defective embryo [ 13–15].
The role of cytokines has been implicated in the
pathogenesis of endometriosis and related infertility.
Interleukin-6 (IL-6) and its soluble receptor (sIL-6R) have
been reported to be higher in the peritoneal fluid of infertile
patients with endometriosis [ 16, 17]. Y oshida et al.
proposed that combination of IL-6 and sIL-6R may be
associated with gp-130 expressed in the sperm and thus
reducing sperm motility and contributing to the pathogen-
esis of endometriosis-related infertility [ 18]. Macrophage
inhibiting factor (MIF), another multifunctional cytokine
has been found to be significantly increased in the
peritoneal fluid and endometrium of women with endome-
triosis [ 19, 20]. Carli et al. [ 21] in 2007 studied the dose-
dependent effect of MIF on sperm capacitation and
concluded that high amounts of MIF had adverse effects
on capacitation and sperm motility. They suggested that
increased levels of MIF in women with endometriosis may
play a role in endometriosis-associated infertility [ 21].
Tumor necrosis factor alpha (TNF- α), a potent cytokine
has also been found to be increased in patients with
endometriosis and has been proposed as a sensitive marker
for the non-surgical diagnosis of endometriosis [ 16, 22].
Said et al. in their study reported that pathological
concentrations of TNF- α can result in loss of sperm
motility, plasma membrane functional integrity, as well as
DNA fragmentation [ 23]. The same group implicated that
infliximab, an anti-inflammatory drug, may be used to
reverse the toxic effects of TNF- α on spermatozoa and thus
help treat female infertility in endometriosis patients [ 24].
Decreased sperm motility
Sperm DNA damage
SPERM
ROSMIF IL-6
NOTNF-α
Fig. 1 Diagram: factors affecting sperm function in endometriosis
320 Gynecol Surg (2010) 7:319 –328
Another proposed mechanism of infertility in endome-
triosis is due to deleterious effect of nitric oxide (NO) on
the sperms. Osborn et al. in a study found that peritoneal
macrophages from women with endometriosis-associated
infertility express higher levels of inducible nitric oxide
synthase and produce more NO than fertile controls, and
high levels of NO have a deleterious effect on sperm
motility and function [ 25, 26]. Moreover, Lampiao et al.
found that TNF- α and IL-6 have detrimental effect on the
spermatozoa via an increase in NO production [ 27].
Endometriosis and ovarian function
Good quality embryos originate from good quality oocytes,
which in turn originate from follicles with an adequate
environment conditioned by the follicular fluid and the
neighboring cells, which are able to influence their
progression [ 28]. Altered intrafollicular microenvironment
influences the oocyte growth and development via a close
relationship with the granulose cells and other ovarian cell
types. Mansour et al. found significant DNA damage in the
oocytes that were incubated in the peritoneal fluid of
patients with endometriosis as compared with normal
controls. The extent of damage was related to the duration
of exposure to the PF of endometriosis [ 29]. Whether this
damage to oocytes is due to hormonal factors, cytokines,
leucocytes, apoptic bodies, or OS has been studied and
documented in literature. Studies have shown consistent
evidence of subtle pituitary –ovarian dysfunction associated
with endometriosis, linked to considerable impairment of
oocyte fertilizing ability and a probable impairment of
granulosa cell steriodogenesis. Impaired follicular growth,
reduction in circulating estradiol concentration during the
pre-ovulatory phase and of estradiol and progesterone
during the early luetal phase and disturbed luteinizing
hormone surge pattern have been documented as a cause of
poor oocyte quality and sub-fertility in endometriosis [ 30].
Similarly, other authors recorded zygote formation and
embryo development in vitr o and reported that the
percentage of abnormal embryos were higher in endometri-
otic patients [ 31]. Diaz et al. [ 32] in their study implicated
that even severe endometriosis did not affect the implanta-
tion rate, and the poor pregnancy outcomes were probably
due to poor quality oocytes or embryos. They found no
change in the in-vitro fertilization-embryo transfer (IVF-
ET) outcomes in endometriotic patients receiving donor
oocytes [ 32]. However, contradictory results have been
shown by other groups which found no change in granulose
luteal cell steriodogenesis, normal maturation of oocytes,
and embryo in the altered hormonal milieu [ 33, 34].
Apart from the endocrine environment, various paracrine
factors secreted by the granula cell and present in the
follicular fluid could interfere with the oocyte development.
In a study done by Pellicer et al. [ 35], serum IL-6 were
found to be increased in natural cycle in women with
endometriosis and decreased in stimulated cycles in IVF.
IL-6 was also increased in the follicular fluid of women
with endometriosis and released in higher amounts by
granulosa cells in these women. In addition, vascular
endothelial growth factor (VEGF) has been found to be in
lower concentrations in endometriotic patients [ 35], and
elevated VEGF has also been correlated in IVF with good
follicular vascularization and health [ 36]. Garrido et al.
postulated that infertility in patients with endometriosis
may be related to these changes in the follicular environ-
ment leading to altered oocytes which in turn results in poor
quality of embryos [ 37]. Another study found that the
granula cells from endometriotic patients had an increased
production of IL-1 β, IL-6, IL-8, and TNF- α compared with
healthy women, although the increase for TNF- α was more
significant. Furthermore, HCG suppressed these cytokines
in both the endometriotic and healthy women [ 38]. Whether
these changes in the follicular environment causes dis-
turbances in the synchronization of oocyte maturation,
ovulation, and uterine receptivity affecting the fertilization
need to be further investigated.
Another interesting theory postulated is the role of
ovarian leukocytes on oocyte maturation and growth.
Leukocyte present within the ovary may constitute as
potential in situ modulators of ovarian function that act
through the local secretion of numerous cytokines [ 39].
Lachapelle et al. found an increase in natural killer (NK)
cells and monocytes (CD4) in endometriotic patients [ 40].
In contrast, another study using flow cytometry to deter-
mine the presence of total leukocytes and their subsets in
the follicle from patients with endometriosis and healthy
controls found no changes in the leukocyte portions and
activity [ 41]. Establishing the definite role of leukocytes in
oocyte maturation is difficult due to the aforementioned
conflicting studies. The role of apoptic cells on folliculo-
genesis in endometriosis has also been studied. Toya et al.
concluded that in the granulosa cells of patients with
endometriosis, an increased incidence of altered cell cycle
and apoptic bodies are found as compared with healthy
controls [ 42], and it has been found that a lower incidence
of apoptic bodies in individual follicles has been associated
with better outcome of oocyte quality [ 43].
The role of OS has been implicated in various aspects of
female reproduction and infertility including oocyte viabil-
ity and its ability to fertilize with the spermatozoa [ 44, 45].
Increased production of ROS by peritoneal macrophages
and diminished peritoneal fluid antioxidant results in OS in
the peritoneal microenvironment of patients with endome-
triosis [ 46]. OS leads to localized pelvic inflammatory
reaction resulting in increased concentrations of cytokines,
growth factors, and other inflammatory mediators which in
Gynecol Surg (2010) 7:319 –328 321
turn induce lipid peroxidation, resulting in the formation of
cytotoxic lipid peroxides and DNA damage [ 46, 47]. One
of the most popular markers for oxidative DNA damage
and OS is 8-hydroxy-deoxyguanosine which is found to be
increased in infertile patients with endometriosis than
infertile patients with other causes [ 48]. These changes
caused by OS might lead to rapid cellular death and oocyte
degeneration.
Endometriosis and fertilization
The effect of follicular fluid on the binding of human
spermatozoa to the zona pellucida has been investigated in
women with endometriosis. Qiao et al. suggested that
patients with endometriosis had a stronger sperm –zona
binding inhibitory effect in their follicular fluid than
patients without endometriosis which may contribute to
impairment of gamete interaction [ 49]. Additionally, sperm
mixed with peritoneal fluid from women with endometri-
osis has been shown to perform poorly on a zona-free
hamster egg sperm penetration assay [ 50]. Barbara et al.
found that macrophage secretory products, particularly
TNF-α, may interfere sperm –zona pellucida binding and
may lead to infertility in women with endometriosis [ 51].
Interestingly, a retrospective study of the impact of
endometriosis on IVF outcomes found that patients with
stages 3 and 4 endometriosis had a poorer IVF-ET outcome
than patients with tubal infertility. The authors suggested
that maternal serum in patients with endometriosis adverse-
ly affects the fertilization rate, and this reduction in
fertilization may be due to either decreased oocyte quality
or the detrimental effect of the cumulus –corona complex
[52]. However, Olivennes et al. [ 53] found no difference in
the pregnancy outcome in patients with endometriosis and
tubal infertility. Pregnancy rates in pure endometriosis
patients without other concomitant infertility factors were
found to be similar to those patients with tubal infertility
[53].
Endometriosis and implantation
There have been studies in literature suggesting impairment
of implantation in patients with endometriosis [ 54].
Whether this defect is due to abnormal endometrium or
defective embryos is debated (Table 1). Minici et al.
suggested that the milieu surrounding the uterine cavity,
particularly increased peritoneal levels of TNF- α, compro-
mise the normal deciduali zation required for optimal
implantation [ 55]. Lessey et al. in their study reported a
reduced expression of αvβ3 integrin, a cellular adhesive
molecule in the endometrium of patients with endometriosis
during the window of implantation [ 56]. Another study has
shown that, in women with endometriosis, a significant
increase in endothelial nitric oxide synthase during the mid-
luteal phase was concomitant with a drastic decrease in
adhesion molecule αvβ3. Such imbalance may strongly
contribute to implantation defects [ 57]. In contrast to this,
Hii et al. found no difference in the glandular expression of
αvβ3 integrin between endometriosis patients and normal
controls [
58]. In an interesting study, Matsuzaki demon-
strated that HOXA-10m-RNA and protein expression levels
in the endometrial stromal cells were significantly lower
during the window of implantation in patients with
endometriosis probably leading to infertility [ 59]. Hugo et
al. in their study found that altered aromatase expression in
the eutopic endometrium of women with endometriosis
may hamper the ovum nidation, thus causing infertility
[60]. However, Kao et al. [ 61] suggested alteration in
candidate genes contributing to implantation failure. Their
data supported that the dysregulation of selected genes such
as BSEP , C4BP , IL-15, etc. may promote an inhospitable
environment for embryonic implantation [ 61]. In a recent
study, expression of EMX2, a transcription factor necessary
for reproductive tract development negatively regulated by
HOXA10 gene, was found to be altered. The authors
suggested that high EMX2 and low HOXA10 in the
periimplantation endometrium of patients with endometri-
osis alter the pattern of target gene expression, thus
inhibiting implantation [ 62]. Another study indicated the
possibility that infertile women with endometriosis have
abnormal production of IL-11 and leukemia inhibitory
factor which may contribute to altered uterine receptivity
and thus leading to infertility [ 63]. All of the above-
mentioned studies found a defect in the endometrium
impairing the implantation in endometriosis patients. In
contrast, other authors have given impaired oocyte/embryo
quality as an alternative explanation for decreased implan-
tation. Sung et al. in their study concluded that endometri-
osis in oocyte recipients does not lower implantation, and
the adverse effect of endometriosis on implantation is
probably due to the abnormal oocyte quality [ 64].This
finding was recently confirmed by Diaz et al. [ 32]i na
study in which oocytes from healthy donors were divided in
the same cycle between different receivers with and without
endometriosis. Recipients with stages 3 and 4 endometri-
osis had the same implantation rate as controls [ 32].These
studies show that endometriosis does not impair implanta-
tion in oocyte recipients, suggesting a defective quality of
oocytes/embryo as the cause of infertility in women with
endometriosis.
Endometriosis and immune-endocrine interaction
There is considerable evidence in literature indicating the
association of humoral and cell-mediated immunity with
endometriosis. The peritoneal fluid of women with endo-
322 Gynecol Surg (2010) 7:319 –328
metriosis contains an increased number of immune cells
which facilitate the development of endometriosis rather
than inhibiting it [ 65]. Autoantibodies, several cytokines,
and growth factors display increased levels in the peritoneal
fluid of women with endometriosis. Mathur et al. were the
first to report IgG and IgA antibodies in the vaginal and
cervical secretions of women with endometriosis [ 66].
Gleicher et al. [ 67] in their study found a wide variety of
autoantibodies in endometriosis patients suggesting poly-
clonal activation of B cell, characteristic of autoimmune
disease. They argued that ectopic endometrium might
induce an autoimmune response and contribute to infertility
associated with endometriosis [ 67]. Furthermore, treatment
with danazol and GnRH analog suppresses the antiendo-
metrial antibodies associated with endometriosis [ 68].
Another study showed that infertile women with endome-
triosis had various kinds of autoantibodies, especially
against phospholipids in serum and the peritoneal fluids
that could reduce the success of spontaneous and artificial
implantation [ 68]. Although these data suggest that auto-
antibodies may play a role in infertility associated with
endometriosis, the importance of autoimmunity in patho-
genesis of infertility in these patients needs to be further
explored.
Cytokines are diverse proteins that play a central role in
regulating cellular activity. Several studies have reported a
potential link between cytokines and the pathogenesis of
endometriosis. Interluekin-1 (IL-1) is one of the major
proinflammatory cytokines found in the peritoneal fluid of
women with endometriosis, and studies have found that IL-
1m a yp l a yar o l ei nt h ei n f e r t i l i t ya s s o c i a t e dw i t h
endometriosis [ 69, 70]. IL-1 has been found to inhibit
mouse embryo development, impairing the capacity of
sperm to penetrate the oocyte without altering the sperm
motility [ 71, 72]. In a recent study, it was suggested that an
imbalance between IL-1 and its inhibitory soluble IL-1
receptor type 2 levels in peritoneal fluid of women with
endometriosis may cause a defect in the local control of IL-
1 and may be involved in the pathophysiology of
endometriosis and its related infertility [ 73]. IL-6, another
pleiotropic cytokine, has been associated with reproductive
physiology and found to be increased in the peritoneal fluid
of women with endometriosis [ 16, 17]. The elevated levels
of IL-6 has been associated with poor sperm motility and
altered follicular functions [ 18, 35]. Deura et al. in their
study showed that IL-6 suppressed estrogen production and
aromatase activity in the granula cell line and may be
associated with infertility with endometriosis [ 74]. Another
cytokine IL-17 has been found to induce IL-6 and TNF- α
in the macrophages, which play a crucial role in the
pathogenesis of endometriosis and infertility [ 75]. Zhang et
al. in their study found that IL-17 was significantly higher
in patients with mild/minimal endometriosis and also when
endometriosis was associated with infertility [ 76]. TNF-α is
another cytokine that plays a key role in the multitude of
inflammatory processes. TNF- α has been implicated in the
pathophysiology of endometriosis and its associated infer-
tility. It affects sperm motility and also shows embryotoxic
effects [ 23, 55].
RANTES (regulated on activation, normal T-cell
expressed and secreted) is another cytokine chemo-
attractant for monocytes as well as memory T cells and
eosinophils. The level of RANTES is found to be increased
in the peritoneal fluid of women with endometriosis, and its
level correlates with the severity of disease [ 77]. Xu et al.
[78] found poor IVF outcomes in endometriosis-related
infertility than in tubal infertility. They concluded that
elevated follicular fluid RANTES evokes an altered
inflammatory milieu within the follicular fluid environment
leading to poor oocyte quality [ 78]. MIF is a multifunc-
tional cytokine that regulates immune response, cell
proliferation, and angiogenesis. Morin et al. found elevated
levels of MIF in the peripheral blood of women with
endometriosis and suggested that MIF may adversely affect
fertility in these women [ 79]. Monocyte chemo-tactic
protein 1 is a β chemokine produced mainly by the
monocytes, and macrophages have been found to be
increased in infertile patients with endometriosis [ 80].
Complement, another component of the humoral immunity,
has been found to be altered in endometriosis. Kabut et al.
in their study found increased concentrations of C3c and
decreased concentration of iC3b in the PF of women with
Factor Level of the factor Reference
TNF-α Increased Minci et al. [ 55]
αvβ3 integrin Decreased Lessey et al. [ 56]
e-NOS Increased Khorram et al. [ 57]
HOXA-10m-RNA Decreased Matsuzaki et al. [ 59]
Aromatase expression Increased Hugo et al. [ 60]
BSEP , C4BP ,IL-15 genes Dysregulated Kao et al. [ 61]
EMX2 Increased Daftary et al. [ 62]
IL-11, LIF Decreased Dimitriadis et al. [ 63]
Table 1 Endometrial factors
impairing implantation
Gynecol Surg (2010) 7:319 –328 323
endometriosis, both of which are derivatives of C3
component of the complement cascade [ 81]. A higher
concentration of iC3b, produced from the oviductal C3/C3b
has been found to enhance the development of blastocyst
and also stimulate embryo development [ 82]. This de-
creased iC3b found in the PF of women with endometriosis
could lead to infertility. There is a controversy on the role
of increased level of leptin in endometriosis-related
infertility. Leptin, a product of the obese gene, is a cytokine
similar to various members of the interleukin family. Barcz
et al. suggested that the increased levels of leptin in
peritoneal fluid in women with endometriosis may be
associated with infertility [ 83]. On the other hand, Bedaiwy
et al. in their study found that increased peritoneal fluid
leptin levels may be associated with pain but not infertility
in patients with endometriosis [ 84].
Endometriosis is associated with changes in cell-
mediated immunity as well. V arious components of cellular
immunity have been found to be altered in endometriosis.
Peritoneal macrophages are the major resident cells in the
peritoneal cavity, and their number, concentration, and
activity are higher in patients with endometriosis than
controls [ 85]. NK cell activity in women with endometri-
osis has been shown to have a decreased cytotoxic activity,
which indicates alteration in immune response, and co-
existing with endometrial abnormalities [ 86]. These
changes in the peritoneal environment may also have a
role in endometriosis-related infertility [ 87]. Moreover,
danazol and GnRH analogs, which are commonly used
for treatment of endometriosis down-regulate humoral and
cellular immunity concomitantly with their effect on
endometriotic implants [ 88].
Hyperprolactinemia has been reported to exist in patients
with endometriosis-related infertility, but the role of
prolactin (PRL) in infertile women with endometriosis is
less clear [ 89]. In a study, it was suggested that altered PRL
secretion and decreased serum estradiol after thyrotrophin-
releasing hormone administration in infertile women with
endometriosis was strongly related to a dysfunction of the
hypothalamic–hypophyseal–ovarian axis and could be the
cause of infertility in these patients [ 90]. Matrix
metalloproteinase-2 (MMP-2) has emerged as one of the
key participants in the adhesion and proliferation of shed
menstrual tissue in the pathogenesis of endometriosis [ 91].
Estradiol has been shown to up-regulate the MMP-2 action
leading to formation of endometriosis, and progesterone has
been associated with down-regulation of MMP-2 action
inhibiting the development of endometriosis [ 92]. MMP-2
has shown to have a role in ovulation and luteal function
[93].
There is clear evidence from the above discussion on the
interaction between immune mediators and hormones on
the development of endometriosis and its associated
infertility. A better understanding of these interactions will
set the stage for immune-targeted therapies not only for the
management of endometriosis but also its associated
infertility.
Endometriosis and role of laparoscopy in management
of infertility
Although there is an association between endometriosis and
infertility, the discussion about exact causal relationship is
still ongoing. Nevertheless, laparoscopy has been used for
the diagnosis, staging, and treatment of endometriosis.
Visual look of the disease through laparoscopy has become
an integral part of management of infertility in endometri-
osis. The effect of destruction of peritoneal endometriosis
(ASRM stage I-II) by laparoscopy on pregnancy rates in
infertile women has been debated [ 94]. It is unclear how
removing or ablating a lesion by laparoscopy will improve
the alterations described above. Two randomized controlled
trials did not agree on the effect of laparoscopic ablation or
excision of endometriotic lesions on pregnancy rates. The
larger study, by the Canadian Collaborative Group on
Endometriosis, showed that excision or laparoscopic abla-
tion of minimal and mild endometriosis increased ongoing
pregnancy rates in infertile women (OR 1.95, 95% CI 1.18 –
3.22) [ 95]. The number needed to treat in the Canadian
study was nine. A smaller trial by an Italian group failed to
show significant impact on the live birth rate (OR 0.85,
95% CI 0.32 –2.28) [
96]. However, when these two results
were combined, the pooled odds ratio showed a significant
improvement in live birth rate following surgical treatment
(OR 1.64, CI 1.05 –2.57) [ 97]. If we combine the Canadian
and the Italian studies, the number needed to treat is 12.
Thus, there is reasonable evidence to treat minimal and
mild endometriosis to improve the subsequent fertility
outcome. Laparoscopic treatment of mild endometriosis
either by excision or coagulation was shown to have no
influence on the pregnancy rate and had similar outcomes
[98].
An interesting study by Bedaiwy et al. on the impact of
s u r g e r yo nI V Fo u t c o m ef o u n dn oi m p r o v e m e n ti n
pregnancy outcomes [ 99]. In light of the complex patho-
physiological changes taking place in the peritoneum in
endometriosis, surgical removal of lesions may therefore
not necessarily have a substantial impact on fertility.
Similarly, laparoscopic treatment of ovarian endometri-
osis (ASRM III-IV) showed varied outcomes and the
pregnancy rates ranged from 30% to 67% [ 100, 101].
Despite the possible risk of loss of ovarian tissue and
disruption of blood supply leading to ovarian damage,
literature shows increased pregnancy rates following lapa-
roscopic treatment of endometriomas [ 102]. In a recent
Cochrane review, it was concluded that the excision of the
324 Gynecol Surg (2010) 7:319 –328
endometriomas improves the subsequent spontaneous preg-
nancy rates in comparison to drainage and ablation of the
endometrioma [ 103]. The removal of endometriomata may
be associated with risk of damage to ovarian function.
Ovarian cystectomy may cause resection of the healthy
ovarian cortex with follicles rather than excision of intra-
ovarian cyst. Somigliana found fewer follicles in response
to gonadotropin stimulation after laparoscopic removal of
endometriomata thereby alte ring the ovarian response
during IVF [ 104]. Additionally, adverse changes in the
ovarian artery blood flow have been reported following
laparoscopic stripping [ 105]. Nonetheless, careful removal
of endometriomas will improve spontaneous fertility sub-
stantially and should be removed.
Recently, interest has been shown on the influence of
laparoscopic treatment of bowel endometriosis on post-
operative fertility. Stepniewska et al. [ 106] in one of the
largest series retrospectively looked at the effect of
laparoscopic surgery for en dometriosis with colorectal
segmental resection on subsequent fecundity rate. They
concluded that complete removal of endometriosis with
bowel segmental resection had better post-operative fertility
than removal of endometriosis without bowel resection
[106]. Ferrero et al. in their study suggested that although
spontaneous pregnancy may occur after bowel resection,
these patients may require infertility treatment, especially
women ≥35 years [ 107]. V ercellini et al. [ 108] studied the
role of conservative surgery for rectovaginal endometriosis
on the fertility outcome. Their group concluded that, in
patients with no other associated major infertility factors,
surgical resection of rectovaginal endometriosis did not
improve the pregnancy outcome [ 108].
Another interesting aspect is the impact of laparoscopic
surgery for recurrent endometriosis on subsequent fertility.
Fedele et al. [ 109] compared the 5-year cumulative
pregnancy after laparoscopic excision of primary versus
recurrent ovarian endometrioma in the same ovary as the
primary cyst. The 5-year cumulative pregnancy rate was
40.8% after the first surgical procedure and 32.4% after the
second procedure. The authors concluded that the effect of
repetitive laparoscopic surgery is similar to that observed
after first-line surgery and that the women with repetitive
surgery underwent assisted reproduction techniques more
frequently [ 109].
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