JRI 
Vol. 15, Issue 4, / October-December 2014
(Review Article, pages 173-183)
PMID: 25473625 (PubMed) - PMCID: PMC4227974

Tanya Timeva Corresponding Author
- Specialized Ob/Gyn Hospital for Active Treatment, Sofia, Bulgaria
Atanas Shterev
- Specialized Ob/Gyn Hospital for Active Treatment, Sofia, Bulgaria
Stanimir Kyurkchiev
- Institute of Reproductive Health, Sofia, Bulgaria

Received: 3/17/2014 Accepted: 7/27/2014 - Publisher : Avicenna Research Institute

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Abstract

The success rate of reproductive treatment methods depends on many different factors. The most important and discussed ones in the literature are maternal age, the causes of infertility, the ovarian response to stimulation, the influence of the male factor and sperm quality, embryo quality and the various uterine pathologies. Some couples fail repeatedly after transferring good quality embryos without any obvious reason and this becomes a major continuing problem after IVF/ICSI procedures. It can be speculated that in these couples, insufficiency of the endometrium might be a possible reason for implantation failure. This review article summarized current literature describing the consecutive endomertial procedures involved in successful embryo implantation. It is believed that efforts to align criteria for definition of recurrent implantation failure (RIF) and attempts to classify different RIF types would develop guidelines for treatment procedures which would result in an increase in patients’ opportunities to conceive.



Keywords: Decidua, Embryo implantation, Endometrium, In Vitro fertilization, Reproductive physiological phenomena


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Full Text

Introduction
Successful embryo implantation is a process which requires both a synchronous development and interaction between hatched blastocyst and endometrium. From the clinical point of view, implantation is considered to be successful when gestational sac is diagnosed by ultrasound. According to Coughlan et al., the term "implantation failure" refers to two different types of cases, those in whom there has never been evidence of implantation (no detectable HCG production) and those who have evidence of implantation (detectable HCG production) but it did not proceed to beyond the formation of a gestational sac visible on ultrasonography (1). It is rather doubtful whether such an event should be called a pathological event because it has been reported that spontaneous pregnancy is achieved in only about 25-40% of healthy fertile women during the first cycle of intended pregnancy (2, 3).
Because of the importance of this problem and its correct definition, a whole section of this review was dedicated to the subject, presenting viewpoints published in the literature so far.
The causes of implantation failure are diverse and especially due to different maternal factors as uterine abnormalities, hormonal or metabolic disorders, infections, immunological factors, thrombophilias as well as other less common ones. Also it is essential to note the influence of severe male factor and its impact on genetic and morphological state of the embryo. Some recent studies investigated the role of many other factors in this complex process of implantation, such as contribution of cumulus cells (4). In this study, an attempt was made to classify these wide varieties of reasons for recurrent implantation failure presented with the following RIF types with the belief that it allows correct treatment for couples, who fail repeatedly after embryo transfer.
The main focus of the study was on the role of endometrium and the movement of embryo during implantation in the uterine cavity. The purpose of this review article was to emphasize the importance of the endometrial changes, embryo endometrial interaction and their impact as critical points on failure of implantation process.
Lack of consensus on the definition of RIF: After widespread application of assisted reproduction technologies (ART) and in particular IVF/ICSI, a novel pathophysiological state was recognized which was characterized by numerous failures to achieve pregnancy after embryo transfer (ET) and it was designated as recurrent implantation failure (RIF). There is no universally accepted definition despite many publications on this topic (2, 5-8). Collective data from papers reporting implantation rates in different ART clinics strongly suggest that the maximum implantation rate is between 40% and 60% (7). Regarding these data, it is obvious that not every good quality embryo would implant successfully in each cycle. It is quite difficult to give an exact scientific definition of RIF not only because different IVF centers use different criteria for defining patients with RIF but also because RIF patients should be distinguished from patients with other known infertility pathologies.
When defining RIF, researchers take into account two criteria-first, the number of embryos transferred and, second, the number of ET procedures performed. The early definition of RIF twenty years ago by Coulam was that patients with more than 12 embryos transferred in several procedures without achieving pregnancy should be classified as RIF patients (9). This definition was based on the analysis of a large IVF program. Results reported from 65 IVF clinics in the UK show that most centers include patients with 5-6 unsuccessful cycles in the RIF group and also include frozen embryo transfers (FET). The total number of embryos transferred were reported between ≥10 and ≤15, but keeping in mind the lower pregnancy rate after FET, it was recommended to include only fresh ET in the RIF definition. Thus, most centers would define RIF as failure to achieve pregnancy after 3 fresh ET-procedures and in the case of UK practice that would be 3 high-grade embryos (10). Nonetheless, another definition of RIF was suggested by the PGD Consortium, a specialized group of ESHRE. According to them, RIF is a failure to achieve pregnancy after ≥3 unsuccessful transfers of high quality embryos or transfers of ≥10 embryos in total in multiple transfers. Presence or absence of pregnancy is diagnosed by an ultrasound examination after the 5th week (11). Today, with the tendency for transferring only one or two embryos, the definition of RIF is not clear. With the introduction of blastocyst culture and transfer of blastocysts, this parameter is included in the definition of RIF and requires the transfer of ≥8, 8-cell embryos or ≥5 blastocysts without pregnancy (7). Currently, selective single embryo transfers are performed in many countries and some authors are inclined to define RIF as a failure to achieve pregnancy after 3 embryo transfers with good quality embryos (6). The latest proposed definition of RIF from Coughlan et al. includes not only the number of embryos and ET-procedures but also the age of females (2).
The following table and images summarize these data (Table.1 and Figures 1A, B, and C).
The transfer of good quality embryos should be a necessary pre-requisite for RIF diagnosis in infertile patients treated with ART. According to the recommendations of the Istanbul Consensus, good quality embryo evaluation should include morphokinetic assessment and also ploidy status (12). RIF should be distinguished from the recurrent IVF-failure which seems like its subgroup. Most commonly, RIF is associated with unexplained infertility but in fact, it also can be observed in patients with well-known causes of infertility (tubal factor, male factor, etc.). A number of excellent reviews discussing the idea that RIF is related to different factors such as endometriosis, undetected genetic defects, various uterine pathologies, etc. have been published recently (5, 6, 13, 14).
RIF types: In some cases, RIF can be defined as a unique condition due to unidentified abnormalities or damage of the endometrium which would not even allow the initial steps of embryo implantation (apposition, attachment). If that is the case, the endometrium and its ability to provide, in a timely restricted manner, an environment suitable for embryo implantation should be regarded as a crucial factor and such an idea has been proposed by Salker et al. (2010) and Teklenburg et al. (2010) (15, 16). Nevertheless, another alternative would be the existence of a combined deficiency of both the embryo and the endometrium which would transform the cross-talk between the mother and the embryo in an ineffective or unsynchronized way. This would create a total blockade or disarrangement of the sophisticated cascade of molecular signaling needed in both embryo and endometrium for successful implantation and pregnancy. The immunological relationship between mother and conceptus still remains a mystery, although the recent advances in molecular biology have lightened a lot of parameters that participate in feto-maternal cross-talk during implantation (17).
Trying to summarize the above facts and causes of implantation failure, the following classification of RIF seemes to be helpful which allows taking correct therapeutic approaches for these patients (Figure 2).
I. Multifactorial RIF (wide variety of reasons for RIF):
a. Maternal anatomic factors, including congenital uterine abnormalities, endometrial polyps, uterine fibroids, adhesions, hydrosalpinges, endometriosis, etc.
b. Male factors, when severe oligoasthenozoospermia was diagnosed or increased sperm DNA fragmentation
c. Genetic abnormalities, where embryos with good morphology have aneuploidy
d. Hormonal or metabolic disorders (uncontrolled diabetes, thyroid disease, variations in the prolactin level, etc.)
e. Infections
f. Thrombophilias or antiphospholipid syndrome
g. Immunological factors
h. Psychological factors, lifestyle
II. Endometrial RIF (impaired endometrium): unsuccessful attempts with the transferring of high grade embryos, due to thin (≤6 mm) endometrium, with or without variations in vascularity.
III. Idiopathic RIF (impaired cross-talk between endometrium and embryo): unexplained failure to achieve pregnancy after ET of good quality embryos, without any anatomical and histological changes in uterine cavity and endometrium, without any other disturbances in patient, patient-partner and embryos.
The endometrium and diagnostic methods: Human endometrium is a complex, multicelular tissue that is regulated by steroid hormones (estrogens, progesterone, androgens and glucocorticoids) and has different characteristics in the various phases of the menstrual cycle. These changes include restructuring of the cellular architecture, expression of specific cell-surface molecules as well as a secretion of biologically active factors such as cytokines, chemokines and growth factors. The process of the regeneration of the endometrium is currently viewed as a process of cell proliferation and a consequent differentiation of endometrial multipotent stem cells. The presence and the characterization of multipotent stromal stem cells (18-21), epithelial progenitor cells (22) and endothelial progenitor cells (23) in the human endometrium and decidua have been reported by a number of research groups. These cells reside in both basal and functional layers of the endometrium (24) and can be identified and isolated even from menstrual blood (25). It was recently demonstrated that endometrial stem/progenitor cells can induce proliferation (26) and this report substantiates the hypothesis on the role of the stem cells in endometrial regeneration.
 Indisputable biological purpose of the endometrium is to secure the successful development of pregnancy. Embryo-implantation is only possible for a short period of time when the hostile uterine lining transforms to a hospitable surface to accept the embryo. The newly acquired capacity of the endometrium to welcome the embryo is termed "endometrial receptivity" and it is viewed as a dynamic process of genotypic and phenotypic changes of the endometrial cells. The result is that they are capable of participating in two-way cross-talk with the embryo which may or may not lead to successful apposition, attachment, penetration and implantation and possibly development and growth of a viable conceptus. The short period of time in the menstrual cycle, when the endometrial receptivity is optimal and embryo implantation is possible, is called “window of implantation” (WOI). Studies with donor embryos in humans have shown that this receptive period starts at day 6 post ovulation and continues 4-5 days that is days 20-24 of the cycle (27). The molecular mechanisms behind this complex and sophisticated process have been studied using animal models and knock-out (KO) mouse studies have positively identified genes for receptivity (leukemia inhibitory factor-LIF, Homeobox protein X3), responses to embryo (Cyclooxygenase 2-COX 2) and decidualization (Interleukin 11 Receptor-IL-11R) (28). Additional information has derived from in vitro studies with human endometrial cells and explants cultures, human trophoblasts and placental explant cultures.
Extensive research has been carried out in a search for markers which can be used clinically to define the exact time of the WOI which would be very important for determination of the right time for embryo transfer. Members of the cell adhesion molecules family (integrins, etc.) are expressed on the surface of the epithelial cells during the WOI in humans. Extensive studies are being currently carried out on the timed restricted expression of a number of molecules such as mucin (MUC-1), trophinin, L-selectin, Wingless (Wnt) family members, etc. in reference to the possibility of using them as biomarkers for endometrial receptivity (29). In addition to exploring the value of endometrial secretion analysis, N. Macklon has employed a human co-culture model, consisting of decidualizing endometrial stromal cells and single hatched blastocysts to identify the soluble factors involved in implantation and to correlate these to embryo development (30). The cytokines and chemokines produced and secreted by the endometrial cells have been discussed in an extensive review. It is pointed out that numerous cytokines such as IL-11, LIF, IL-15, IL-1 and members of the superfamily of the transforming growth factor (TGF) are important factors in establishing the optimal interactions between the embryo and the endometrium (31).
 The process of implantation as a scheme is presented in figure 3, where the diagram shows a preimplantation stage of embryo and some important factors thought to be necessary for uterine receptivity: COX-2 (cyclooxygenase-2), EGF (epidermal growth factor) and LIF (leukemia inhibiting factor) (Figure 3).
Recently, using sophisticated modern methods of analysis, it has been shown that the luminal epithelial cells express a number of molecules which have been tested in the search for a marker of the endometrial receptivity. Significant efforts are focused on application of proteomic and lipidomic methods to search for noninvasive biomarkers of endometrial receptivity in endometrial fluid (32-35). In a recent study, it was reported that proteomic analysis of endometrial biopsies collected between LH+5 to LH+10 revealed a distinct proteomic "fingerprint" which seemed to distinguish between fertile patients and RIF patients. Apolipoprotein A-I (Apo A-I) was identified as an anti-implantation protein which is secreted by differentiating endometrium and seemed to have higher expression in ectopic secretory endometrium in patients with endometriosis. Thus dysregulation of the Apo A-I secretion might be a significant factor in pathogenesis of endometriosis and a crucial point for RIF (36). Data collected by these techniques will lead to a new understanding of endometrial receptivity and its relation to infertility treatment. The use of "omics" as molecular tools to determine the effects of stimulation protocols on endometrial gene expression and clinical outcome have also been investigated (37). There is increasing evidence that endometrial function in stimulated cycle is adversely affected by supra-physiological levels of oestrogen and premature secretion of progesterone and these result in dysregulation of the endometrial receptivity and subsequent implantation failure (38-40).
Gene-array methods are applied to analyze the global gene profiling in endometrial cells collected on the 21st day of the menstrual cycle from patients with RIF as compared to fertile patients. Altered expression of genes was detected in RIF patients. More than 90% were found to be down-regulated and they were predominantly involved in regulation of three major pathways-cell cycle, cell-to-cell contact and Wnt pathway. On the other hand, at least two genes, Slug and DKK1 were found to be up-regulated. DKK1 gene is known to be a potent inhibitor of Wnt pathway and it is a pro-apoptotic agent. Wnt signaling regulates Slug activity and links epithelial-mesenchymal transition. Obviously, there is a general dysregulation of gene expression in the endometrium of RIF patients, however, the clinical significance of all changes in the gene expression is not evident yet (41). The same research group continued their search with studies on the changes in the profiles of microRNA in the endometrium of RIF patients. MicroRNAs are known to be posttranscriptional regulators of the gene expression which are involved in a number of physiological and pathological events. Recently, it was reported that at least 13 miRNAs are expressed quite specifically in endometrium samples as the expression of 10 of them were found to be up-regulated and 3 miRNAs were down-regulated. Since the expressed miRNAs specifically seem to regulate over 3800 genes, subsequent experiments to assess the levels of miRNAs showed that members of the cell adhesion molecules, Wnt signaling pathway and cell cycles were lower in RIF patients (42). It is obvious that the microarray techniques are very sensitive and informative but the data obtained are difficult to interpret as clinically meaningful parameters and criteria.
Human endometrial transcriptomic methods have been applied to study the expression of numerous genes during the different phases of the natural cycle in fertile women or in patients with RIF. Samples were collected by endometrial biopsy at different phases of natural cycles   and based on the results obtained and applying the bioinformatics approach, an endometrial receptivity array (ERA) test was developed that can be applied in clinical practice (43). Further trials have shown that the ERA test is a reliable and reproducible method for determination of the exact time of the WOI that can be used with better results in comparison to histological dating of endometrial receptivity (44). In patients with RIF, the endometrial receptivity was identified by ERA test and embryo transfers done according to the ERA data resulted in a 62.8% pregnancy rate. The authors have developed a clinical algorithm that will make it possible to apply a personalized embryo transfer in patients with RIF (45).
Another study compiled a Human Gene Expression Endometrial Receptivity database (HGEx-ERdb) containing 19 285 genes expressed by the endometrium. It was shown that 179 genes could be defined as Receptivity Associated Genes (RAGs) which might be useful for defining the endometrial receptivity (46). This new approach to investigate the expression and secretion of various biologically active factors that favour the embryo implantation provide new perspectives for researchers but have still a long way to go before they can achieve a place in clinical practice.
Formation of decidua: The postovulatory rise of progesterone triggers profound changes in the epithelial cells, stromal cells and the matrix and blood vessels of the endometrium (47). The process of remodeling triggered and controlled by progesterone is termed "decidualization" and consists of changes of the stromal cells to secretory phenotype, angiogenesis and influx of uterine NK cells which are the dominant cell types. Formation of decidua is still a poorly understood process in mammalian pregnancy. Firstly, there are no suitable or easily obtainable   models for the study of this process called "an enigmatic transformation" (48). Human decidua is unique because a conceptus does not need to be present to initiate decidualization of the stromal "predecidual cells" (49). Secondly, the effect of progesterone for longer time results in a general transfromation of the stromal cells over the whole surface of the uterus into cells secreting specific factors such as prolactin, insulin-like growth factor binding protein-1 (IGFBP-1) (50), vascular endothelial growth factor (VEGF) (51) etc., IGFBP-1 is the predominant protein in decidualized cells and is considered to be a biochemical marker of decidualization.
Prostaglandins are secreted by decidual cells and are actively engaged in the complex inter-play between progesterone, prolactin, relaxin and other cytokines and growth factors. Data have been published that defective synthesis of prostaglandin by endometrial cells on days 21-24 of the cycle of patients with RIF has been detected at both mRNA and protein level. A number of components of the prostaglandin synthesis system-cyclooxygenase-2 (COX-2), secretory phospholipase A2 group: IIA, V, and IB (sPLA2-IIA, sPLA2-V, sPLA2-IB), glypican-1, PG-E synthase, PG-E receptors, and lysophosphatidic acid receptor 3 (LPA3) have been estimated and very low levels of sPLA2-IIA and COX-2 were measured in 85% of RIF patients. These enzymes are of key importance for the synthesis of prostaglandins and it is quite acceptable that the levels of endometrial prostaglandins are low too. It has been suggested that defective prostaglandin synthesis might be a key factor in proper development of the endometrial receptivity (52). These findings make logical conclusion that prostaglandin supplementation previous to embryo transfer may have some beneficial effects for a selected group of RIF patients.
Cells, resembling but still different from peripheral NK cells, were identified in human decidua and were initially designated large granulated lymphocytes. These cells called uterine NK (uNK) cells are characterized by a high expression of CD56 (CD56brihgt), lack of CD16 expression, high secretion of cytokines and rather low cytotoxic activity. It has been shown that uNK cells increase in number during the late secretory phase and during early pregnancy (53). Uterine NK cells are the major leukocyte population in decidua and they account for about 70% up to 83.2% of the CD45+ cells in the mid- to late luteal phase and first trimester of pregnancy (54, 55). Discordant data have been published about the alterations of the uterine NK cells sub-types in infertile patients. Some reports describe a decrease in CD56bright CD16dim and an increase in concentrations of CD56dim, CD16bright cells when endometrial biopsies from patients with habitual abortions were analyzed by flow cytometry (56). On the other hand, it has been recently reported that the concentration of CD56bright NK cells in the endometrium of infertile women analyzed by flow cytometry is similar to that of normal fertile women. Moreover, in young patients with RIF, the mean percentage of CD56bright CD16- and CD56+CD16- cells in the late secretory did not differ from the mean percentages in normal endometrium of healthy women (57). Immunocytochemical methods have been used to assess the number of uterine NK cells in peri-implantation endometrium from patients with RIF and an increase of CD56+ cell density was found as compared to control healthy women (14% versus 5%). However, the density of CD16+ and CD69+ in endometrium of RIF patients was not very different from those of control patients thus showing that there was no activation of this cell subtype (58).
Therapeutic approaches to improve the functions of the endometrium: The treatment offered should be evidence based and aimed to improve endometrial receptivity. Several therapeutic approaches have been described as options to improve the functions of the endometrium as an important factor for pregnancy and they include immunomodulatory agents, local endometrial injury, autologous adipose derived stem cells, anti-oxitocyn preparations, etc. Immunological factors have been implicated in the pathogenesis of RIF for a long time and different immunomodulatory agents and approaches have been applied for the treatment of these patients. For these purposes, immunomodulation IVIG (intravenous immunoglobulin IgG) has been widely used with rather conflicting results reported. Initially, positive effects of IVIG application in RIF patients were reported as far as the pregnancy rates were concerned (59-62). A systematic review of the papers through PubMed made the overall conclusion that immunotherapy with IVIG or intralipids when applied in patients with abnormal immunological risk factors might increase the live birth rates (63). However, a multicenter randomized placebo-controlled trial confirmed the statement that application of IVIG in patients with recurrent miscarriages showed no significant beneficial effects (64). Similarly, in a double blind placebo controlled trial including 51 couples with RIF, no positive effects were recorded on the live birth rates (65). Extensive discussions on the efficacy of application of immunomodulatory agents have not led to one definite conclusion so this immunomodulatory approach is left to the discretion of each clinical setting.
A positive effect of local endometrial injury (LEI) on the pregnancy and live birth rates was published by Barash et al. (66). Infertile patients with good response to controlled ovarian hyperstimulation (COH) but with one or two unsuccessful IVF/ET attempts were treated at least 4 times by endometrial biopsy using a biopsy catheter (pipelle device) during the menstrual cycle, before the next IVF-ET cycle. The reported results showed that after 4 injuries of the endometrium, the pregnancy rate reached 66.7% versus 30.3% in the control group and live birth rates were 48.9% per ET versus 22.5% in the control group (66). These initial results have been confirmed in a number of studies reported later which demonstrate the positive effect of LEI (67-69). The general understanding is that LEI would induce upregulation of inflammatory cytokines, chemokines and growth factors. Detailed studies have shown that following LEI monocytes are recruited to the injury sites which can differentiate in monocytic dendritic cells/macrophages which secrete a number of cytokines, chemokines and growth factors. In patients treated by LEI, increased expression is detected for growth-regulated oncogene-a (GRO-a), IL-15, and macrophage inflammatory protein 1B (MIP-1B), tumor necrosis factor-α (TNF-α), osteopontin, αvβ3 integrins and most of these biologically active factors are involved in the interactions between the embryo and the maternal endometrium (70).
As far as clinical aspects of LEI treatment are concerned, it is still not clear when and how many manipulations should be done in order to achieve the best effects from these treatments. Initially, up to 4 manipulations ("scratches") have been applied (66). Later on, some research groups preferred to do the endometrial biopsies twice where the first one was during the proliferative phase (day 7 - 10) and the second one was during the secretory phase (day 24-25) of the menstrual cycle prior to COH (71). Others reported that a single endometrial biopsy done during hysteroscopy on days 4-7 of the cycle before the embryo transfer cycle leads to a significant increase in clinical pregnancy and live birth rates (72).
A recent systematic review of published literature and meta-analysis of the included papers provided strong evidence that endometrial injury done in the cycle before ovarian stimulation and IVF/ET increased the pregnancy rate in RIF patients. Effects of LEI are associated with induction of new cascades of inflammation with the participation of various cytokines and growth factors and all these improve the process of decidualization (73). Another advantage of LEI could be a combination of this procedure with the embryo co-culture system with autologous endometrial epithelial cells (EEC) as a therapeutic approach with proven effectiveness (74). It is quite clear that LEI is a beneficial procedure for patients with RIF, but further well designed studies are needed where a strictly defined procedure is applied in selected patient groups, enlisting a larger number of women.

Conclusion
The most significant endometrial changes occurr during the process of implantation. This review focused on the dysregulation of the endometrial cells at both cellular and molecular levels as a major reason for the lack of implantation when a good quality embryo is transferred into a uterus free of any pathology, in the presence of optimal hormonal levels, i.e. idiopathic RIF. Tailoring stimulation protocols and individual approaches are some of the steps that could be offered to RIF-patients. It is our opinion that the concept of the crucial role of the endometrium for embryo implantation and for the repeated failures of implantation deserves a detailed discussion. RIF patients should be enrolled in well designed studies in order to expand our understanding. Repeated implantation failure is a problem for every IVF clinic because the unsuccessful IVF/ET attempts impose a significant psychological, emotional and financial burden on the infertile couples and are frustrating for the doctors trying to help them.

Conflict of Interest
The authors declare no conflict of interest.




Figures, Charts, Tables

High Resolution
Figure 1. Images of high grade embryos, A: Day 3-8-cell embryo; B: Day 5-blastocyst; C: Day 5-hatching blastocyst
Figure 1. Images of high grade embryos, A: Day 3-8-cell embryo; B: Day 5-blastocyst; C: Day 5-hatching blastocyst


High Resolution
Figure 2. The different types of RIF
Figure 2. The different types of RIF


High Resolution
Firure 3. Schematic diagram of implantation process
Firure 3. Schematic diagram of implantation process



Table 1. Criteria for defining RIF
* Fresh or frozen ET procedures, ** High-grade embryos
Table 1. Criteria for defining RIF * Fresh or frozen ET procedures, ** High-grade embryos


References

  1. Coughlan C, Ledger W, Wang Q, Liu F, Demirol A, Gurgan T, et al. Recurrent implantation failure: definition and management. Reprod Biomed Online. 2014;28(1):14-38.   [PubMed]
  2. Racowsky C. High rates of embryonic loss, yet high incidence of multiple births in human ART: is this paradoxical? Theriogenology. 2002;57(1):87-96.   [PubMed]
  3. Gnoth C, Godehardt D, Godehardt E, Frank-Herrmann P, Freundl G. Time to pregnancy: results of the German prospective study and impact on the management of infertility. Hum Reprod. 2003;18(9):1959-66.   [PubMed]
  4. Benkhalifa M, Demirol A, Sari T, Balashova E, Tsouroupaki M, Giakoumakis Y, et al. Autologous embryo-cumulus cells co-culture and blastocyst transfer in repeated implantation failures: a collaborative prospective randomized study. Zygote. 2012;20(2):173-80.   [PubMed]
  5. Urman B, Yakin K, Balaban B. Recurrent implantation failure in assisted reproduction: how to counsel and manage. A. General considerations and treatment options that may benefit the couple. Reprod Biomed Online. 2005;11(3):371-81.   [PubMed]
  6. Margalioth EJ, Ben-Chetrit A, Gal M, Eldar-Geva T. Investigation and treatment of repeated implantation failure following IVF-ET. Hum Reprod. 2006;21(12):3036-43.   [PubMed]
  7. Rinehart J. Recurrent implantation failure: definition. J Assist Reprod Genet. 2007;24(7):284-7.   [PubMed]
  8. Simon A, Laufer N. Repeated implantation failure: clinical approach. Fertil Steril. 2012;97(5):1039-43.   [PubMed]
  9. Coulam CB. Implantation failure and immunotherapy. Hum Reprod. 1995;10(6):1338-40.   [PubMed]
  10. Tan BK, Vandekerckhove P, Kennedy R, Keay SD. Investigation and current management of recurrent IVF treatment failure in the UK. BJOG. 2005;112(6):773-80.   [PubMed]
  11. Thornhill AR, deDie-Smulders CE, Geraedts JP, Harper JC, Harton GL, Lavery SA, et al. ESHRE PGD Consortium 'Best practice guidelines for clinical preimplantation genetic diagnosis (PGD) and preimplantation genetic screening (PGS)'. Hum Reprod. 2005;20(1):35-48.   [PubMed]
  12. Alpha Scientists in Reproductive Medicine and ESHRE Special Interest Group of Embryology. The Istanbul consensus workshop on embryo assessment: proceedings of an expert meeting. Hum Reprod. 2011;26(6):1270-83.   [PubMed]
  13. Johnston-MacAnanny EB, Hartnett J, Engmann LL, Nulsen JC, Sanders MM, Benadiva CA. Chronic endometritis is a frequent finding in women with recurrent implantation failure after in vitro fertilization. Fertil Steril. 2010;93(2):437-41.   [PubMed]
  14. Toth B, Wurfel W, Germeyer A, Hirv K, Makrigiannakis A, Strowitzki T. Disorders of implantation--are there diagnostic and therapeutic options? J Reprod Immunol. 2011;90(1):117-23.   [PubMed]
  15. Salker M, Teklenburg G, Molokhia M, Lavery S, Trew G, Aojanepong T, et al. Natural selection of human embryos: impaired decidualization of endometrium disables embryo-maternal interactions and causes recurrent pregnancy loss. PLoS ONE.2010;5(4):e10287.   [PubMed]
  16. Teklenburg G, Salker M, Molokhia M, Lavery S, Trew G, Aojanepong T, et al. Natural selection of human embryos: decidualizing endometrial stromal cells serve as sensors of embryo quality upon implantation. PLoS One. 2010;5(4):e10258.   [PubMed]
  17. Makrigiannakis A. Repeated implantation failure: Immunological aspects and evidence based treatment modalities. In: Makrigiannakis A, editor. Proceeding of MSRM International Meeting “Implantation-recurrent miscarriages science and clinical aspects”; 2010 Sept 24-26; Chania, Crete, Greece: Mediterranean Society for Reproductive Medicine; 2010. p. 21-2.
  18. Gargett CE. Uterine stem cells: what is the evidence? Hum Reprod Update. 2007;13(1):87-101.   [PubMed]
  19. Cervello I, Simon C. Somatic stem cells in the endometrium. Reprod Sci. 2009;16(2):200-5.   [PubMed]
  20. Dimitrov R, Kyurkchiev D, Timeva T, Yunakova M, Stamenova M, Shterev A, et al. First-trimester human decidua contains a population of mesenchymal stem cells. Fertil Steril. 2010;93(1):210-9.   [PubMed]
  21. Kyurkchiev S, Shterev A, Dimitrov R. Assessment of presence and characteristics of multipotent stromal cells in human endometrium and decidua. Reprod Biomed Online. 2010;20(3):305-13.   [PubMed]
  22. Gargett CE, Schwab KE, Zillwood RM, Nguyen HP, Wu D. Isolation and culture of epithelial progenitors and mesenchymal stem cells from human endometrium. Biol Reprod. 2009;80(6):1136-45.   [PubMed]
  23. Mints M, Jansson M, Sadeghi B, Westgren M, Uzunel M, Hassan M, et al. Endometrial endothelial cells are derived from donor stem cells in a bone marrow transplant recipient. Hum Reprod. 2008;23(1):139-43.   [PubMed]
  24. Chan RW, Schwab KE, Gargett CE. Clonogenicity of human endometrial epithelial and stromal cells. Biol Reprod. 2004;70(6):1738-50.   [PubMed]
  25. Meng X, Ichim TE, Zhong J, Rogers A, Yin Z, Jackson J, et al. Endometrial regenerative cells: a novel stem cell population. J Transl Med. 2007;15;5:57.   [PubMed]
  26. Chan RW, Kaitu'u-Lino T, Gargett CE. Role of label-retaining cells in estrogen-induced endometrial regeneration. Reprod Sci. 2012;19(1):102-14.   [PubMed]
  27. Bergh PA, Navot D. The impact of embryonic development and endometrial maturity on the timing of implantation. Fertil Steril. 1992;58(3):537-42.   [PubMed]
  28. Elder K, Dale B, editors. In vitro fertilization. 3rd ed. Vol. 6, Implantation and early stages of fetal development. New York: Cambridge University Press; 2011. p. 82-92.
  29. Lessey BA. Assessment of endometrial receptivity. Fertil Steril. 2011;96(3):522-9.   [PubMed]
  30. Macklon N. Factors affecting implantation. In: Makrigiannakis A, editor. Proceeding of MSRM International Meeting “Implantation-recurrent miscarriages science and clinical aspects”; 2010 Sept 24-26; Chania, Crete, Greece: Mediterranean Society for Reproductive Medicine; 2010. p. 14-5.
  31. Dimitriadis E, White CA, Jones RL, Salamonsen LA. Cytokines, chemokines and growth factors in endometrium related to implantation. Hum Reprod Update. 2005;11(6):613-30.   [PubMed]
  32. Al-Rumaih HM, Price KM, Gillott DJ, Grudzinskas GJ. Proteomic analysis of uterine flushings from infertile women in the proliferative phase of the menstrual cycle with respect to estrogen level. Middle East Fertil Soc J. 2006;11(3):183-90.
  33. Salamonsen LA, Edgell T, Rombauts LJ, Stephens AN, Robertson DM, Rainczuk A, et al. Proteomics of the human endometrium and uterine fluid: a pathway to biomarker discovery. Fertil Steril. 2013;99(4):1086-92.   [PubMed]
  34. Cheong Y, Boomsma C, Heijnen C, Macklon N. Uterine secretomics: a window on the maternal-embryo interface. Fertil Steril. 2013;99(4):1093-9.   [PubMed]
  35. Vilella F, Ramirez LB, Simon C. Lipidomics as an emerging tool to predict endometrial receptivity. Fertil Steril. 2013;99(4):1100-6.   [PubMed]
  36. Brosens JJ, Hodgetts A, Feroze-Zaidi F, Sherwin JR, Fusi L, Salker MS, et al. Proteomic analysis of endometrium from fertile and infertile patients suggests a role for apolipoprotein A-I in embryo implantation failure and endometriosis. Mol Hum Reprod. 2010;16(4):273-85.   [PubMed]
  37. Haouzi D, Dechaud H, Assou S, De Vos J, Hamamah S. Insights into human endometrial receptivity from transcriptomic and proteomic data. Reprod Biomed Online. 2012;24(1):23-34.   [PubMed]
  38. Devroey P, Bourgain C, Macklon NS, Fauser BC. Reproductive biology and IVF: ovarian stimulation and endometrial receptivity. Trends Endocrinol Metab. 2004;15(2):84-90.   [PubMed]
  39. Papanikolaou EG, Bourgain C, Fatemi H, Verpoest W, Polyzos NP, De Brabanter A, et al. Endometrial advancement after triggering with recombinant or urinary HCG: a randomized controlled pilot study. Reprod Biomed Online. 2010;21(1):50-5.   [PubMed]
  40. Aboulghar M. Stimulation protocols and implantation. In: Makrigiannakis A, editor. Proceeding of MSRM International Meeting “Implantation-recurrent miscarriages science and clinical aspects”; 2010 Sept 24-26; Chania, Crete, Greece: Mediterranean Society for Reproductive Medicine; 2010. p. 19.
  41. Koler M, Achache H, Tsfrir A, Smith Y, Revel A, Reich R. Disrupted gene pattern in patients with repeated in vitro fertilization (IVF) failure. Hum Reprod. 2009;24(10):2541-8.   [PubMed]
  42. Revel A, Achache H, Stevens J, Smith Y, Reich R. MicroRNAs are associated with human embryo implantation defects. Hum Reprod. 2011;26(10):2830-40.   [PubMed]
  43. Diaz-Gimeno P, Horcajadas JA, Martinez-Conejero JA, Esteban FJ, Alama P, Pellicer A, et al. A genomic diagnostic tool for human endometrial receptivity based on the transcriptomic signature. Fertil Steril. 2011;95(1):50-60.   [PubMed]
  44. Diaz-Gimeno P, Ruiz-Alonso M, Blesa D, Bosch N, Martinez-Conejero JA, Alama P, et al. The accuracy and reproducibility of the endometrial receptivity array is superior to histology as a diagnostic method for endometrial receptivity. Fertil Steril. 2013;99(2):508-17.   [PubMed]
  45. Garrido-Gomez T, Ruiz-Alonso M, Blesa D, Diaz-Gimeno P, Vilella F, Simon C. Profiling the gene signature of endometrial receptivity: clinical results. Fertil Steril. 2013;99:1078-85.   [PubMed]
  46. Bhagwat SR, Chandrashekar DS, Kakar R, Davuluri S, Bajpai AK, Nayak S, et al. Endometrial receptivity: a revisit to functional genomics studies on human endometrium and creation of HGEx-ERdb. PLoS One. 2013;8(3):e58419.   [PubMed]
  47. Finn CA. Why do women and some other primates menstruate? Perspect Biol Med. 1987;30(4):566-74.   [PubMed]
  48. Dunn CL, Kelly RW, Critchley HO. Decidualization of the human endometrial stromal cell: an enigmatic transformation. Reprod Biomed Online. 2003;7(2):151-61.   [PubMed]
  49. Kennedy TG, Gillio-Meina C, Phang SH. Prostaglandins and the initiation of blastocyst implantation and decidualization. Reproduction. 2007;134(5):635-43.   [PubMed]
  50. Richards RG, Brar AK, Frank GR, Hartman SM, Jikihara H. Fibroblast cells from term human decidua closely resemble endometrial stromal cells: induction of prolactin and insulin-like growth factor binding protein-1 expression. Biol Reprod. 1995;52(3):609-15.   [PubMed]
  51. Sugino N, Kashida S, Karube-Harada A, Takiguchi S, Kato H. Expression of vascular endothelial growth factor (VEGF) and its receptors in human endometrium throughout the menstrual cycle and in early pregnancy. Reproduction. 2002;123(3):379-87.   [PubMed]
  52. Achache H, Tsafrir A, Prus D, Reich R, Revel A. Defective endometrial prostaglandin synthesis identified in patients with repeated implantation failure undergoing in vitro fertilization. Fertil Steril. 2010;94(4):1271-8.   [PubMed]
  53. Bulmer JN, Morrison L, Longfellow M, Ritson A, Pace D. Granulated lymphocytes in human endometrium: histochemical and immunohistochemical studies. Hum Reprod. 1991;6(6):791-8.   [PubMed]
  54. Nishikawa K, Saito S, Morii T, Hamada K, Ako H, Narita N, et al. Accumulation of CD16-CD56+ natural killer cells with high affinity interleukin 2 receptors in human early pregnancy decidua. Int Immunol. 1991;3(8):743-50.   [PubMed]
  55. Flynn L, Byrne B, Carton J, Kelehan P, O'Herlihy C, O'Farrelly C. Menstrual cycle dependent fluctuations in NK and T-lymphocyte subsets from non-pregnant human endometrium. Am J Reprod Immunol. 2000;43(4):209-17.   [PubMed]
  56. Lachapelle MH, Miron P, Hemmings R, Roy DC. Endometrial T, B, and NK cells in patients with recurrent spontaneous abortion. Altered profile and pregnancy outcome. J Immunol. 1996;156(10):4027-34.   [PubMed]
  57. Matteo MG, Greco P, Rosenberg P, Mestice A, Baldini D, Falagario T, et al. Normal percentage of CD56bright natural killer cells in young patients with a history of repeated unexplained implantation failure after in vitro fertilization cycles. Fertil Steril. 2007;88(4):990-3.   [PubMed]
  58. Tuckerman E, Mariee N, Prakash A, Li TC, Laird S. Uterine natural killer cells in peri-implantation endometrium from women with repeated implantation failure after IVF. J Reprod Immunol. 2010;87(1-2):60-6.   [PubMed]
  59. Coulam CB, Krysa LW, Bustillo M. Intravenous immunoglobulin for in-vitro fertilization failure. Hum Reprod. 1994;9(12):2265-9.   [PubMed]
  60. Balasch J, Creus M, Fabregues F, Font J, Martorell J, Vanrell JA. Intravenous immunoglobulin preceding in vitro fertilization-embryo transfer for patients with repeated failure of embryo transfer. Fertil Steril. 1996;65(3):655-8.   [PubMed]
  61. Sher G, Zouves C, Feinman M, Maassarani G, Matzner W, Chong P, et al. A rational basis for the use of combined heparin/aspirin and IVIG immunotherapy in the treatment of recurrent IVF failure associated with antiphospholipid antibodies. Am J Reprod Immunol.1998;39(6):391-4.   [PubMed]
  62. Christiansen OB, Pedersen B, Rosgaard A, Husth M. A randomized, double-blind, placebo-controlled trial of intravenous immunoglobulin in the prevention of recurrent miscarriage: evidence for a therapeutic effect in women with secondary recurrent miscarriage. Hum Reprod. 2002;17(3):809-16.   [PubMed]
  63. Coulam CB, Acacio B. Does immunotherapy for treatment of reproductive failure enhance live births? Am J Reprod Immunol. 2012;67(4):296-304.   [PubMed]
  64. Stephenson MD, Kutteh WH, Purkiss S, Librach C, Schultz P, Houlihan E, et al. Intravenous immunoglobulin and idiopathic secondary recurrent miscarriage: a multicentered randomized placebo-controlled trial. Hum Reprod. 2010;25(9):2203-9.   [PubMed]
  65. Stephenson MD, Fluker MR. Treatment of repeated unexplained in vitro fertilization failure with intravenous immunoglobulin: a randomized, placebo controlled Canadian trial. Fertil Steril. 2000;74(6):1108-13.   [PubMed]
  66. Barash A, Dekel N, Fieldust S, Segal I, Schechtman E, Granot I. Local injury to the endometrium doubles the incidence of successful pregnancies in patients undergoing in vitro fertilization. Fertil Steril. 2003;79(6):1317-22.   [PubMed]
  67. Karimzadeh MA, Ayazi Rozbahani M, Tabibnejad N. Endometrial local injury improves the pregnancy rate among reccurent implantation failure patients undergoing in vitro fertilization/intracytoplasmic sperm injection: a randomised clinical trial. Aust N Z J Obstet Gynecol. 2009;49(6):677-80.
  68. Zhou L, Li R, Wang R, Huang HX, Zhong K. Local injury to the endometrium in controlled ovarian hyperstimulation cycles improves implantation rates. Fertil Steril. 2008;89(5):1166-76.   [PubMed]
  69. Raziel A, Schachter M, Strassburger D, Bern O, Ron-El R, Friedler S. Favorable influence of local injury to the endometrium in intracytoplasmic sperm injection patients with high-order implantation failure. Fertil Steril. 2007;87(1):198-201.   [PubMed]
  70. Gnainsky Y, Granot I, Aldo PB, Barash A, Or Y, Schechtman E, et al. Local injury of the endometrium induces an inflammatory response that promotes successful implantation. Fertil Steril. 2010;94(6):2030-6.   [PubMed]
  71. Narvekar SA, Gupta N, Shetty N, Kottur A, Srinivas M, Rao KA. Does local endometrial injury in the nontransfer cycle improve the IVF-ET outcome in the subsequent cycle in patients with previous unsuccessful IVF? A randomized controlled pilot study. J Hum Reprod Sci. 2010;3(1):15-9.   [PubMed]
  72. Shohayeb A, El-Khayat W. Does a single endometrial biopsy regimen (S-EBR) improve ICSI outcome in patients with repeated implantation failure? A randomised controlled trial. Eur J Obstet Gynecol Reprod Biol. 2012;164(2):176-9.   [PubMed]
  73. Potdar N, Gelbaya T, Nardo LG. Endometrial injury to overcome recurrent embryo implantation failure: a systematic review and meta-analysis. Reprod Biomed Online. 2012;25(6):561-71.   [PubMed]
  74. Rubio C, Simon C, Mercader A, Garcia-Velasco J, Remohi J, Pellicer A. Clinical experience employing co-culture of human embryos with autologous human endometrial epithelial cells. Hum Reprod. 2000;15 Suppl 6:31-8.   [PubMed]

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