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Volume 12, Issue 6 (8-2014)
IJRM 2014, 12(6): 427-0 |
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Aflatoonian A, Davar R, Hojjat F. Elevated serum progesterone/ MII oocyte ratio on the day of human chorionic gonadotropin administration can predict impaired endometrial receptivity. IJRM 2014; 12 (6) :427-0
URL: http://ijrm.ir/article-1-546-en.html
URL: http://ijrm.ir/article-1-546-en.html
1- Department of Obstetrics and Gynecology, Research and Clinical Center for Infertility, Shahid Sadoughi University of Medical Sciences, Yazd, Iran
2- Department of Obstetrics and Gynecology, Research and Clinical Center for Infertility, Shahid Sadoughi University of Medical Sciences, Yazd, Iran , farzanehhojjat@gmail.com
2- Department of Obstetrics and Gynecology, Research and Clinical Center for Infertility, Shahid Sadoughi University of Medical Sciences, Yazd, Iran , farzanehhojjat@gmail.com
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Introduction
Moderate increase serum progesterone in the peripheral circulation is visible in most superovulated cycles on the day of human chorionic gonadotropin (HCG) administration. There is debate about the origins and clinical significance of elevated serum progesterone. It has been believed that increased Luteinizing hormone (LH) in late follicular phase cause increased progesterone and it was tried to use agonists and antagonists of gonadotropin-releasing hormone to prevent the rise of LH and premature luteinization. Several publications have reported there is the relationship between progesterone concentration at the end of follicular phase and Foliicle-stimulating hormone (FSH) levels during ovarian stimulation. Probably, the source of progesterone is growing follicle by alone FSH without LH (1). Ubaldi et al concluded the greater FSH exposure, and its correlation with the progesterone genesis suggested that one of the possible factors inducing premature luteinization is the increased FSH-induced LH receptivity in granulose cells and no adverse effects of premature luteinization on the in vitro fertilization (IVF) and clinical outcome were observed (2).
FSH acts on granulosa cells, promoting cell division and steroid biosynthesis from cholesterol terminating at progesterone biosynthesis (3). The rate-limiting step in the intrafollicular steroid biosynthesis is the side-chain cleavage process converting cholesterol (27-carbon molecule) to the 21-carbon products pregnenolone and progesterone; granulose cells are very active manufacturers of progesterone, while theca cells also make significant amounts of progesterone (4). Progesterone is further metabolized to androgens by the theca cells under the trophic influence of LH, and this step can only take place in the theca cell compartment. Androgens are subsequently converted to estrogen through aromatization back in the granulose cells (1). Progesterone produced by the granulosa cells under FSH drive must pass to the vascularized theca cell compartment to be catabolized to androgens. It is probable that the greater the LH drive to the theca cells. The more progesterone catabolism to androgens will take place, leaving fewer products to find its way into the general circulation (1).
It is postulated that all three factors examined the number of follicles, the FSH drive and the LH activity-influence the concentration of progesterone in the circulation during the follicular phase of ovarian stimulation. The follicle number and FSH concentrations appear to have a positive association with raised progesterone output (5). Because in polycystic ovary syndrome (PCOS) that is a large number of developing follicle's rises progesterone levels and due to use of gonadotropin-releasing hormone antagonist, less premature luteinization in patients with PCOS. Prapas et al believed that GnRH antagonist administration during the proliferative phase at a dose of 0.25 mg per day does not appear to adversely affect endometrial receptivity (6-8). Whereas Rackow et al believed that use of GnRH antagonists may be associated with impaired HOXA10 expression in endometrial stromal cells and thus may affect endometrial receptivity (9).
Steward RG and colleagues believed that GnRH antagonists can decrease the rate of premature luteinization, but appear to have no effect on pregnancy (10). The consequences of this premature elevation of serum progesterone on IVF outcome remain controversial (11). Several authors did not find any negative effect of this on IVF outcome (12-20). Other authors reported that pregnancy rate has been inversely related to serum progesterone levels on the day of HCG administration (5, 21-42).
The objective was to evaluate whether progesterone elevation on the day of human chorionic gonadotropin administration is associated with the IVF outcome.
Materials and methods
Patients
In this retrospective study, we analyzed the results of 378 women with normal ovaries participating in an IVF program-embryo transfer in Research and Clinical Center for Infertility, Yazd from October 2009 to March 2011. Who retrieved their eggs and performed embryo transfer and younger than 40 years with FSH on the 3rd day cycles less than 10 IU/L and E2 on the 3rd day cycles less than 80 P/ml included in this study. Women with more than 40 years of age or with FSH on the 3rd day cycles more than 10 IU/L or egg donors or no documented FSH and E2 in the 3rd day of the cycle excluded in this study. The article has been approved by Research and Clinical Center for Infertility Ethical Committee.
Treatment protocol
Three standard protocols for ovarian stimulation were used for all patients: 1) GnRH agonist protocol (long luteal protocol) 2) GnRH antagonist protocol (flexible protocol) 3) microdose protocol. From 378 patients, were treated 168 patients with GnRH agonist protocol, 160 patients with GnRH antagonist protocol and 50 patients with microdose protocol (Table І) Final maturation of the oocytes was effected with 10000 IU HCG when there were at least two follicles 16 mm. Ovum retrieval was performed 32-36h after HCG administration by vaginal ultrasound, and embryo transferred 48 h later.
Assays
Age, treatment protocol, basal hormone levels: FSH, LH, FSH/LH, estradiol (E2), progesterone (P), and type of gonadotropin was recorded (Table II). In the day of HCG administration, the endometrial thickness (mm) measured and the endometrial patterns evaluated. E2 (P/mL) and P (ng/mL) measured on the day of hCG administration and P/E2 ratio (P[ng/mL]×1000/E2[P/mL]) and P/mature oocyte calculated.
Table I. Treatment protocols
90-39-6/Table_1.jpg)
Table II. Demographic characteristics of patients and Effect of addition FSH without LH on serum p-level and progesterone concentration on endometrial thickness and endometrial pattern
90-39-6/Table_2.jpg)
Table III. Effect of serum p level, P/E2 ratio and P/mature on fertilization, implantation, and pregnancy rates
90-39-6/Table_3.jpg)
Discussion
In this study, we evaluate the effect of elevated serum progesterone in the day HCG administration in the outcome of IVF cycles. Success of IVF cycle was dependent to number and quality of oocytes and endometrial receptivity. Several authors reported that outcome of IVF has been inversely related to serum progesterone levels on the day of HCG administration (5, 21-43). In our study absolute p-value and P/E2 ratio were not a good predictor outcome of in-vitro fertilization. "Tavaniotou et al in 2003 were concluded endometrial integrin expression is more consistently present in the early luteal phase in stimulated cycles than in natural cycles, and this may be related to the higher serum progesterone concentration and/or the more advanced endometrial histological features" (27).
Bourgain et al in 2003 were concluded the endometrium in IVF cycles have shown premature secretory changes in the post-ovulatory and early luteal phase of IVF cycles, followed by a large proportion of dyssynchronous glandular and stromal differentiation in the mid-luteal phase. "These findings suggest a profound modification of luteal endometrial development in stimulated cycles. This hypothesis is further supported by the demonstration of a modified endometrial steroid receptor regulation and a profound antiproliferative effect in IVF cycles. The time of maximal endometrial receptivity is defined as the implantation window and is characterized by the expression of various endometrial products, among which pinopodes, integrins and leukemia inhibitory factors are best described.
Premature expression of pinopodes and integrins are in line with the observation of precocious luteal transformation following ovarian stimulation. Studies exploring the endometrium within the cycle of embryo transfer have shown a deleterious effect of severe peri-ovulatory maturation advancement exceeding three days, as no clinical pregnancies were obtained in this condition (28). Azem et al in 2008, our data demonstrate high serum P adversely affects implantation and pregnancy rates" (30).
Kilicdag et al in 2010 were concluded elevated serum progesterone levels on the day of HCG administration were associated with diminished implantation rates and live birth rates regardless of ovarian reserve (34). Bosch et al in 2011 were concluded that the elevated P levels may have a dual influence on pregnancy rate. One related to endometrial receptivity (37). Li et al in 2011 from micro RNA and microarray analysis suggests dissimilar endometrial receptivity in patients with high P levels on the day of HCG, and had poor pregnancy rates (41).
In this study since high levels of progesterone no effect on the fertilization rate while significantly reduced the implantation rate, can be concluded that high levels of progesterone, reduce the endometrial receptivity. According to previous studies because the main sources of productive progesterone are follicles, in effect of FSH, the level of progesterone produced per mature oocyte is the better predictor for IVF results (1). In our study the positive relationship seen between the number of mature oocyte and serum progesterone concentrations. In this study from 50 patients were treated with microdose protocol 30 patients had a P/MII oocyte ratio>0.32, despite from 160 patients were treated with GnRH antagonist protocol 24 patients had a P/MII oocyte ratio>0.32 shows if adding the GnRH antagonist can be decreased the LH surge and progesterone levels.
"The abrupt pituitary suppression that rapidly follows administration of the GnRH antagonist, occurs too late in the cycle of stimulation to suppress LH before it begins adversely affect follicle, egg and endometrium development. Low-dose HCG alone in the late COH stages avoid increasing progesterone. Patients received ovarian priming with recombinant FSH/HMG followed by low-dose HCG (200 IU/day) alone" (46). The addition of LH (HCG) to the stimulation protocol results in a higher yield of mature oocytes, excellent-quality embryos and increase endometrial receptivity (47). Interests this protocol was included: I) more catabolism the progesterone to androgen in follicular fluid due to increased LH a result less appears progesterone in the blood circulation, II) reduced recombinant FSH/HMG consumption III) reduced number of small preovulatory follicles, IV) more estrogenic intrafollicular environment thereupon to estrogen formed from androgen created as a result of more catabolism the progesterone due to LH. V) Higher fertilization rate
The use of a less aggressive agonist treatment such as intranasal Nafarelin, which has been shown to reduce the demand for FSH injections, may also reduce the incidence/degree of profound LH suppression, and the consequences reduced the levels of circulating progesterone (48). Flexible antagonist protocol with Low-dose HCG alone started simultaneously starting antagonist: in IVF-ICSI patients undergoing COS with the antagonist protocol, significantly increases pregnancy rates and reduces the incidence of premature luteinization (49).
The antagonist administration was initiated according to at least one of the following patient-specific criteria: (i) At least, one follicle measuring >14 mm; (ii) estradiol levels >600 P/ml; (iii) LH levels >10 IU/l (50). "Use of Mifepristone, COH is associated with advanced endometrial histology and relatively high p-levels in the late follicular phase occurring in a relatively large proportion of IVF cycles despite GnRH analog treatment, which is associated with impaired implantation and lower pregnancy rates. Low dosages of mifepristone have been shown to delay endometrial maturation" (51).
Mifepristone and FSH were administered daily from the beginning of the COH and concomitantly with an intra-muscular injection of 50 mg progesterone to reverse residual antiprogestogenic activity of mifepristone on the day of HCG administration (52). If the serum progesterone level more than 0.32 per metaphase II oocytes, the embryo transfer canceled and was considered freezing for all embryos to future transfer.
Conclusion
We suggest to avoid the increased progesterone that the cause of advanced endometrial maturation and impaired endometrial receptivity administration Low-dose HCG alone in the late COH stages and the use of a less aggressive agonist treatment and in flexible antagonist protocol administration, Low-dose HCG alone simultaneously starting antagonist and adding the GnRH antagonist with microdose protocol and use of Mifepristone daily from the beginning of the COH. If the progesterone greater than 0.32 per oocyte metaphase the better embryo transfer canceled and considered freezing all embryos for future transfer. To increase acceptance of the endometrium and thus increase the success rate.
Acknowledgements
This study was financially supported by Yazd Research and Clinical Center for Infertility.
Conflict of interest
The authors declare that there is no conflict of interest in this paper.
Moderate increase serum progesterone in the peripheral circulation is visible in most superovulated cycles on the day of human chorionic gonadotropin (HCG) administration. There is debate about the origins and clinical significance of elevated serum progesterone. It has been believed that increased Luteinizing hormone (LH) in late follicular phase cause increased progesterone and it was tried to use agonists and antagonists of gonadotropin-releasing hormone to prevent the rise of LH and premature luteinization. Several publications have reported there is the relationship between progesterone concentration at the end of follicular phase and Foliicle-stimulating hormone (FSH) levels during ovarian stimulation. Probably, the source of progesterone is growing follicle by alone FSH without LH (1). Ubaldi et al concluded the greater FSH exposure, and its correlation with the progesterone genesis suggested that one of the possible factors inducing premature luteinization is the increased FSH-induced LH receptivity in granulose cells and no adverse effects of premature luteinization on the in vitro fertilization (IVF) and clinical outcome were observed (2).
FSH acts on granulosa cells, promoting cell division and steroid biosynthesis from cholesterol terminating at progesterone biosynthesis (3). The rate-limiting step in the intrafollicular steroid biosynthesis is the side-chain cleavage process converting cholesterol (27-carbon molecule) to the 21-carbon products pregnenolone and progesterone; granulose cells are very active manufacturers of progesterone, while theca cells also make significant amounts of progesterone (4). Progesterone is further metabolized to androgens by the theca cells under the trophic influence of LH, and this step can only take place in the theca cell compartment. Androgens are subsequently converted to estrogen through aromatization back in the granulose cells (1). Progesterone produced by the granulosa cells under FSH drive must pass to the vascularized theca cell compartment to be catabolized to androgens. It is probable that the greater the LH drive to the theca cells. The more progesterone catabolism to androgens will take place, leaving fewer products to find its way into the general circulation (1).
It is postulated that all three factors examined the number of follicles, the FSH drive and the LH activity-influence the concentration of progesterone in the circulation during the follicular phase of ovarian stimulation. The follicle number and FSH concentrations appear to have a positive association with raised progesterone output (5). Because in polycystic ovary syndrome (PCOS) that is a large number of developing follicle's rises progesterone levels and due to use of gonadotropin-releasing hormone antagonist, less premature luteinization in patients with PCOS. Prapas et al believed that GnRH antagonist administration during the proliferative phase at a dose of 0.25 mg per day does not appear to adversely affect endometrial receptivity (6-8). Whereas Rackow et al believed that use of GnRH antagonists may be associated with impaired HOXA10 expression in endometrial stromal cells and thus may affect endometrial receptivity (9).
Steward RG and colleagues believed that GnRH antagonists can decrease the rate of premature luteinization, but appear to have no effect on pregnancy (10). The consequences of this premature elevation of serum progesterone on IVF outcome remain controversial (11). Several authors did not find any negative effect of this on IVF outcome (12-20). Other authors reported that pregnancy rate has been inversely related to serum progesterone levels on the day of HCG administration (5, 21-42).
The objective was to evaluate whether progesterone elevation on the day of human chorionic gonadotropin administration is associated with the IVF outcome.
Materials and methods
Patients
In this retrospective study, we analyzed the results of 378 women with normal ovaries participating in an IVF program-embryo transfer in Research and Clinical Center for Infertility, Yazd from October 2009 to March 2011. Who retrieved their eggs and performed embryo transfer and younger than 40 years with FSH on the 3rd day cycles less than 10 IU/L and E2 on the 3rd day cycles less than 80 P/ml included in this study. Women with more than 40 years of age or with FSH on the 3rd day cycles more than 10 IU/L or egg donors or no documented FSH and E2 in the 3rd day of the cycle excluded in this study. The article has been approved by Research and Clinical Center for Infertility Ethical Committee.
Treatment protocol
Three standard protocols for ovarian stimulation were used for all patients: 1) GnRH agonist protocol (long luteal protocol) 2) GnRH antagonist protocol (flexible protocol) 3) microdose protocol. From 378 patients, were treated 168 patients with GnRH agonist protocol, 160 patients with GnRH antagonist protocol and 50 patients with microdose protocol (Table І) Final maturation of the oocytes was effected with 10000 IU HCG when there were at least two follicles 16 mm. Ovum retrieval was performed 32-36h after HCG administration by vaginal ultrasound, and embryo transferred 48 h later.
Assays
Age, treatment protocol, basal hormone levels: FSH, LH, FSH/LH, estradiol (E2), progesterone (P), and type of gonadotropin was recorded (Table II). In the day of HCG administration, the endometrial thickness (mm) measured and the endometrial patterns evaluated. E2 (P/mL) and P (ng/mL) measured on the day of hCG administration and P/E2 ratio (P[ng/mL]×1000/E2[P/mL]) and P/mature oocyte calculated.
Numbers of mature oocyte after retrieval of the ovum counted. All the cycles were grouped according to the serum progesterone concentration and P/E2 ratio and P/mature oocyte ratio on the day of hCG administration. According to previous studies premature luteinization defined as serum P and P/E2 ratio ≥1 (46, 71, 72) and cut off for the P/mature oocyte ratio calculated (p/mature oocyte >0.32). Then impact of these hormonal ratios on fertilization rate, implantation rate and pregnancy rate were evaluated.
Statistical analysis
After data collection and coding, enter them into the computer and using SPSS software (Statistical Package for the Social Sciences, version 18.0, SPSS Inc, Chicago, Illinois, USA) and Mann-whitney, Chi-square, Independent-samples T-test, analysis the results. We determine the normal distribution of data by Kolmogorov-Simron z test. Our statistical significant was set at p<0.05.
Results
In this study, all the cycles were in two groups according to serum progesterone concentration, P/E2 ratio and P/mature oocyte. There were no significant differences in age (year), basal FSH (IU/L), basal LH (IU/L), FSH/LH, basal E2 (P/ml), basal progesterone (ng/ml) in two groups (Table II). In the group with the serum progesterone level <1, fertilization rate=59.5±8%, implantation rate=24.4±25%, chemical pregnancy=52±5% and in the group with the serum progesterone level ≥1, fertilization rate=58±10%, implantation rate=22.7±32%, chemical pregnancy=44±5% as a result fertilization rate, implantation rate and pregnancy rate no significant difference between two groups.
And in the patients with P/E2 ratio <1 were fertilization rate=58.7±8%, implantation rate=23.8%±27, chemical pregnancy=48±5% and in the patients with P/E2 ratio≥1: fertilization rate=58.7±11%, implantation rate=22.9±32%, chemical pregnancy=47±5%, fertilization rate, implantation rate and pregnancy rate no significant difference between two groups. In the group with P/mature oocyte ratio≤0.32: fertilization rate=58.8±8.3%, implantation rate=28.5±30%, chemical pregnancy=57±5% and in the group 2 with the P/mature oocyte ratio>0.32: fertilization rate=58.6±12.5%, implantation rate=8±20%, chemical pregnancy=20±4%, fertilization rate no significant difference between two groups despite implantation rate and pregnancy rate significant difference between two groups (Table III).
Positive relationship between the number of mature oocyte and serum progesterone concentrations was seen. From 378 patients, in 179 cases oocyte's numbers were equal 9.25±2 and progesterone <1 (ng/ml) and in 199 cases numbers of oocyte were equal 11.5±3 and progesterone ≥1 (ng/ml) (p<0.0001). Add FSH without LH increase the serum progesterone concentrations. In 122 patients, alone FSH was used for ovarian stimulation, in 66 cases was the P/MII oocyte ratio >0.32 and in 256 patients, FSH+LH used for ovarian stimulation only in 26 cases P/MII oocyte ratio>0.32 (p<0.0001). Concentrations of progesterone have no effect on endometrial thickness but are effective on endometrial pattern (Table II).
Statistical analysis
After data collection and coding, enter them into the computer and using SPSS software (Statistical Package for the Social Sciences, version 18.0, SPSS Inc, Chicago, Illinois, USA) and Mann-whitney, Chi-square, Independent-samples T-test, analysis the results. We determine the normal distribution of data by Kolmogorov-Simron z test. Our statistical significant was set at p<0.05.
Results
In this study, all the cycles were in two groups according to serum progesterone concentration, P/E2 ratio and P/mature oocyte. There were no significant differences in age (year), basal FSH (IU/L), basal LH (IU/L), FSH/LH, basal E2 (P/ml), basal progesterone (ng/ml) in two groups (Table II). In the group with the serum progesterone level <1, fertilization rate=59.5±8%, implantation rate=24.4±25%, chemical pregnancy=52±5% and in the group with the serum progesterone level ≥1, fertilization rate=58±10%, implantation rate=22.7±32%, chemical pregnancy=44±5% as a result fertilization rate, implantation rate and pregnancy rate no significant difference between two groups.
And in the patients with P/E2 ratio <1 were fertilization rate=58.7±8%, implantation rate=23.8%±27, chemical pregnancy=48±5% and in the patients with P/E2 ratio≥1: fertilization rate=58.7±11%, implantation rate=22.9±32%, chemical pregnancy=47±5%, fertilization rate, implantation rate and pregnancy rate no significant difference between two groups. In the group with P/mature oocyte ratio≤0.32: fertilization rate=58.8±8.3%, implantation rate=28.5±30%, chemical pregnancy=57±5% and in the group 2 with the P/mature oocyte ratio>0.32: fertilization rate=58.6±12.5%, implantation rate=8±20%, chemical pregnancy=20±4%, fertilization rate no significant difference between two groups despite implantation rate and pregnancy rate significant difference between two groups (Table III).
Positive relationship between the number of mature oocyte and serum progesterone concentrations was seen. From 378 patients, in 179 cases oocyte's numbers were equal 9.25±2 and progesterone <1 (ng/ml) and in 199 cases numbers of oocyte were equal 11.5±3 and progesterone ≥1 (ng/ml) (p<0.0001). Add FSH without LH increase the serum progesterone concentrations. In 122 patients, alone FSH was used for ovarian stimulation, in 66 cases was the P/MII oocyte ratio >0.32 and in 256 patients, FSH+LH used for ovarian stimulation only in 26 cases P/MII oocyte ratio>0.32 (p<0.0001). Concentrations of progesterone have no effect on endometrial thickness but are effective on endometrial pattern (Table II).
Table I. Treatment protocols
Table II. Demographic characteristics of patients and Effect of addition FSH without LH on serum p-level and progesterone concentration on endometrial thickness and endometrial pattern
Table III. Effect of serum p level, P/E2 ratio and P/mature on fertilization, implantation, and pregnancy rates
Discussion
In this study, we evaluate the effect of elevated serum progesterone in the day HCG administration in the outcome of IVF cycles. Success of IVF cycle was dependent to number and quality of oocytes and endometrial receptivity. Several authors reported that outcome of IVF has been inversely related to serum progesterone levels on the day of HCG administration (5, 21-43). In our study absolute p-value and P/E2 ratio were not a good predictor outcome of in-vitro fertilization. "Tavaniotou et al in 2003 were concluded endometrial integrin expression is more consistently present in the early luteal phase in stimulated cycles than in natural cycles, and this may be related to the higher serum progesterone concentration and/or the more advanced endometrial histological features" (27).
Bourgain et al in 2003 were concluded the endometrium in IVF cycles have shown premature secretory changes in the post-ovulatory and early luteal phase of IVF cycles, followed by a large proportion of dyssynchronous glandular and stromal differentiation in the mid-luteal phase. "These findings suggest a profound modification of luteal endometrial development in stimulated cycles. This hypothesis is further supported by the demonstration of a modified endometrial steroid receptor regulation and a profound antiproliferative effect in IVF cycles. The time of maximal endometrial receptivity is defined as the implantation window and is characterized by the expression of various endometrial products, among which pinopodes, integrins and leukemia inhibitory factors are best described.
Premature expression of pinopodes and integrins are in line with the observation of precocious luteal transformation following ovarian stimulation. Studies exploring the endometrium within the cycle of embryo transfer have shown a deleterious effect of severe peri-ovulatory maturation advancement exceeding three days, as no clinical pregnancies were obtained in this condition (28). Azem et al in 2008, our data demonstrate high serum P adversely affects implantation and pregnancy rates" (30).
Kilicdag et al in 2010 were concluded elevated serum progesterone levels on the day of HCG administration were associated with diminished implantation rates and live birth rates regardless of ovarian reserve (34). Bosch et al in 2011 were concluded that the elevated P levels may have a dual influence on pregnancy rate. One related to endometrial receptivity (37). Li et al in 2011 from micro RNA and microarray analysis suggests dissimilar endometrial receptivity in patients with high P levels on the day of HCG, and had poor pregnancy rates (41).
In this study since high levels of progesterone no effect on the fertilization rate while significantly reduced the implantation rate, can be concluded that high levels of progesterone, reduce the endometrial receptivity. According to previous studies because the main sources of productive progesterone are follicles, in effect of FSH, the level of progesterone produced per mature oocyte is the better predictor for IVF results (1). In our study the positive relationship seen between the number of mature oocyte and serum progesterone concentrations. In this study from 50 patients were treated with microdose protocol 30 patients had a P/MII oocyte ratio>0.32, despite from 160 patients were treated with GnRH antagonist protocol 24 patients had a P/MII oocyte ratio>0.32 shows if adding the GnRH antagonist can be decreased the LH surge and progesterone levels.
"The abrupt pituitary suppression that rapidly follows administration of the GnRH antagonist, occurs too late in the cycle of stimulation to suppress LH before it begins adversely affect follicle, egg and endometrium development. Low-dose HCG alone in the late COH stages avoid increasing progesterone. Patients received ovarian priming with recombinant FSH/HMG followed by low-dose HCG (200 IU/day) alone" (46). The addition of LH (HCG) to the stimulation protocol results in a higher yield of mature oocytes, excellent-quality embryos and increase endometrial receptivity (47). Interests this protocol was included: I) more catabolism the progesterone to androgen in follicular fluid due to increased LH a result less appears progesterone in the blood circulation, II) reduced recombinant FSH/HMG consumption III) reduced number of small preovulatory follicles, IV) more estrogenic intrafollicular environment thereupon to estrogen formed from androgen created as a result of more catabolism the progesterone due to LH. V) Higher fertilization rate
The use of a less aggressive agonist treatment such as intranasal Nafarelin, which has been shown to reduce the demand for FSH injections, may also reduce the incidence/degree of profound LH suppression, and the consequences reduced the levels of circulating progesterone (48). Flexible antagonist protocol with Low-dose HCG alone started simultaneously starting antagonist: in IVF-ICSI patients undergoing COS with the antagonist protocol, significantly increases pregnancy rates and reduces the incidence of premature luteinization (49).
The antagonist administration was initiated according to at least one of the following patient-specific criteria: (i) At least, one follicle measuring >14 mm; (ii) estradiol levels >600 P/ml; (iii) LH levels >10 IU/l (50). "Use of Mifepristone, COH is associated with advanced endometrial histology and relatively high p-levels in the late follicular phase occurring in a relatively large proportion of IVF cycles despite GnRH analog treatment, which is associated with impaired implantation and lower pregnancy rates. Low dosages of mifepristone have been shown to delay endometrial maturation" (51).
Mifepristone and FSH were administered daily from the beginning of the COH and concomitantly with an intra-muscular injection of 50 mg progesterone to reverse residual antiprogestogenic activity of mifepristone on the day of HCG administration (52). If the serum progesterone level more than 0.32 per metaphase II oocytes, the embryo transfer canceled and was considered freezing for all embryos to future transfer.
Conclusion
We suggest to avoid the increased progesterone that the cause of advanced endometrial maturation and impaired endometrial receptivity administration Low-dose HCG alone in the late COH stages and the use of a less aggressive agonist treatment and in flexible antagonist protocol administration, Low-dose HCG alone simultaneously starting antagonist and adding the GnRH antagonist with microdose protocol and use of Mifepristone daily from the beginning of the COH. If the progesterone greater than 0.32 per oocyte metaphase the better embryo transfer canceled and considered freezing all embryos for future transfer. To increase acceptance of the endometrium and thus increase the success rate.
Acknowledgements
This study was financially supported by Yazd Research and Clinical Center for Infertility.
Conflict of interest
The authors declare that there is no conflict of interest in this paper.
Type of Study: Original Article |
References
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