Effect of the Aqueous Stem Bark Extract of Schumanniophyton magnificum on Reproductive Functions on Wistar Strain Mature Female Rats

In recent years, the rate of infertility has not stopped increasing in the world. The aim of the present study was to evaluate the effects of the aqueous extract of Schumanniophyton magnificum (Rubiaceae) on cyclicity, ovulation and gestation in mature rats. Methods: After a qualitative phytochemical analysis of these aqueous extracts, the experimental studies carried out were based on the evaluation of the pro-fertility effects of this extract in mature rats. For this purpose, 35 rats were used for the estrous cyclicity test and treated for 21 days at the end of which vaginal smears were taken and the duration, as well as the frequency of the appearance of the phases of the cycle, were evaluated. The ovulation test was performed on 80 female rats, which were divided into two groups of 40 animals and treated respectively in the morning and evenin g with distilled water, β-oestradiol or plant extract at doses of 200, 400 and 800 mg/kg. treatment of certain cases of female infertility in Cameroon.

Pharmacology & Pharmacy ning of proestrus allowed a significant increase (p < 0.0001) in the number of ovulations, bleeding points and oestradiol levels at doses of 400 and 800 mg/kg of S. magnificum extract. On the other hand, a significant decrease in progesterone levels (p < 0.0001) was noted. Concerning the effects on the estrous cycle, after 3 weeks of treatment of the rats, there was no disturbance in the total duration of the estrous cycle when compared to the control. However, there was a significant increase in the duration of proestrus coupled with a significant decrease in the duration of diestrus in these treated animals. In pregnant rats, administration of the different extracts from day 1 to day 10 resulted in a significant decrease in the number of implantation sites (p < 0.01) at the dose of 800 mg/kg. Similarly, blood discharges were observed during the first six days of treatment when compared to the control. Decreases in progesterone, implantation and pregnancy levels were observed in rats treated with 400 and 800 mg/kg (p < 0.0001). Treatment from day 18 to 22 of gestation significantly decreased fetal weight from female rats treated with S. magnificum at doses of 200, 800 mg/kg (p < 0.01) and 400 mg/kg (p < 0.05) when compared to the control. In addition, early parturition was recorded in these animals treated at dose of 400 mg/kg (21 ± 0.25 d) and 800 mg/kg (20.33 ± 0.21 d) (p < 0.0001) with S. magnificum when compared to the control (23 ± 0.16 d). Conclusion: It appears from all these investigations that the aqueous extract of S. magnificum promotes fertility in the rat but represents a danger for the good development of gestation. All these results obtained would be closely related to the presence of certain chemical compounds contained in these various extracts; which would justify their use in traditional medicine for the treatment of certain cases of female infertility in Cameroon.

Introduction
Cameroon, like most African countries, is characterized by a relatively high birth rate; a demographic indicator that does little to hide the drama of infertility experienced by many couples [1]. The consequences of infertility are not negligible because they limit the perpetuation of the animal and human species. Therefore, it is considered as a serious public health problem that represents in 15% of the cases studied, the most difficult experience in the life of a human being, causing marital frustration, violence, divorce and sometimes polygamy [2]. Infertility is a disease of the reproductive system that is defined as the inability of a couple to conceive after one or two years of unprotected sex during the woman's fertile period [3]. A variety of plants are used in Cameroon to overcome this infertility problem [4] [5]. In Cameroon, Schumanniophyton magnificum has been recognized as a plant relieving infertile women. Subsequent studies have shown the  [8]. Therefore, the present study was undertaken to investigate the effects of the aqueous extract of Schumanniophyton magnificum (Rubiaceae) on cyclicity, ovulation and gestation in mature female rats.

Plant Material
Source of the plant: The fresh bark of S. magnificum was taken from trees in the "Eseka" locality (central region of Cameroon). The botanical identification was carried out at the National Herbarium of Cameroon (HNC) at n˚65110/HNC, a sample of which is there.

Preparation of the Extract
Preparation of the extract: These barks were ground in a blender and the powder was obtained. The aqueous extract of S. magnificum was prepared following the recommendations of the traditional practitioners consulted for the treatment of sterility. Slight modifications were applied to improve the extraction yield, 2 kg of S. magnificum was soaked in distilled water (6l) and boiled for 30 min. The decoction was cooled to room temperature, filtered through whatman No. 3 paper and oven dried to give 238.3 g of dried aqueous extract (extraction yield 11, 9%; w/w based on dried starting weight). The extracts were prepared in distilled water at concentrations of 8 mg/mL (extract 1), 16 mg/mL (extract 2) and 32 mg/mL (extract 3). These preparations (extracts 1, 2 and 3) were administered orally to animals at the volume of 10 mL/kg body weight, corresponding to the doses 0, 200, 400, 800 mg/kg respectively. The concentrations of 8 mg/mL were obtained by reconstitution from the recipe mainly used by traditional practitioners following the ethnopharmacological survey carried out in the locality of Eséka (south of Cameroon), and the other two doses were its multiples.

Experimental Animal
The animals used in this study were mature female albino wistar rats, 10 to 12 weeks old and weighing between 150 g and 180 g. they were bred and raised in pet shops of the department of animal sciences of the University of Douala-Cameroon, housed under natural light (12 h cycle) and temperature (22˚C ± 2˚C) conditions and fed a standard laboratory diet and tap water ad libitum.

Experimental Design
Pre-treatment stage: The animals were acclimated for two weeks. Vaginal swabs were taken to select females with at least four regular estrous cycles as described by some authors [9]. and normal saline (0.9% NaCl) between 9 and 10 a.m., then the smears were placed on slides and examined using the light microscope. Rats with a 4-to 5-day estrous cycle of proestrus-oestrus-metoestrus-dioestrus were classified as normal, whereas any deviation from this pattern in duration and sequence was classified as abnormal.

2) Ovulation study
After rat distribution, treatments were administered as follows:
Effects on implantation: 24 female rats were divided into four subgroups (1a, 1b, 1c and 1d) of 6 rats each, then crossed on the evening of their proestrous phase to rats of proven fertility at the rate of one male for two females per cage. The next day, the presence of sperm clusters in the vaginal smear or a cervical plug in the vagina made it possible to confirm the effectiveness of a coupling the day before. This day was considered the 1st day of pregnancy. The rats of subgroup 1a-1b-1c-1d received respectfully distilled water (10 mL/kg), 200, 400 and 800 mg/kg body weight extract by gavage for 10 days. The following day (11th day), the different groups of rats were laparotomized under ether anesthesia. The number of implants was counted, weighed; fetal resorption sites (if present) were recorded.
Effects on pregnancy: Preparation of the animals for this experiment was the same as for the implantation study of S. magnificum. The only difference is that the treated group received the oral treatment from the 11th to the 17th day of gestation to observe possible teratogenic effects. After day 15, a laparotomy was performed and fetal parameters recorded. The placentas were weighed; the length of the umbilical cord and the body of the fetus were measured and the pups were examined for any abnormalities. Effects on parturition: 20 rats pregnant for 17 days were subdivided into 4 groups of 5 rats each. They were gavaged daily from day 18 to day 22 of the plant extract at doses of 200, 400 and 800 mg/kg body weight and the equivalent of distilled water was administered to the control group. During the treatment period, the rats were inspected minutely for vaginal secretions related to early parturition. Finally, any parturition initiated before day 22 of gestation was recognised as early parturition. Parameters such as the number of pups, their body weight, their antifertility activity, their fertility index and their parturition index were determined. Hormonal assay Sex hormone levels were assessed using a competitive indirect ELISA binding technique for estradiol and progesterone. The reagents used for these assays were kits obtained from Cloud-Clone Corp.

Statistical Analysis
The results were expressed as mean ± standard deviation and subjected to statistical analysis using one-way analysis of variance (ANOVA) followed by a Tukey post-test of the graph pat program. The level of significance was considered at p < 0.05.  (Figure 1(a)) at doses of 200 and 800 mg/kg (p < 0.05) and 400 mg/kg (p < 0.01). Similarly, a significant reduction in the frequency of occurrence of diestrus with the same doses was also recorded. However, no disturbance in total cycle time was felt when compared to controls (Figure 1(b)).
-Effects of aqueous extract of Schumanniophyton magnificum on gestational parameters  Effects on the first stage of pregnancy and implantation; from day 1 to 10) The follow-up of the weight evolution during the first 10 days of gestation in adult rats treated with S. magnificum, made it possible to note a uterine discharge materialized by blood flows from the 6th day of gestation until the end of the treatment. These blood flows were very significant with the high doses of 400 and 800 mg/kg (p < 0.0001) when compared to the controls. Similarly, a significant decrease in body weight from the 7th day, at the same doses as before of 400 mg/kg (p < 0.01) and 800 mg/kg (p < 0.001) and a decrease in the number of implants at all these doses were recorded with great significance at the dose of 800 mg/kg (p < 0.001) when compared to the controls. A significant decrease in the rate of implantation and pregnancy was noted at all doses of this extract (p <  during the proestrus period (morning/evening) of female rats. Each histogram represents the mean ± SEM; n = 5. *p < 0.05; **p < 0.001; ***p < 0.0001: significant differences from the neutral control group α 1 : p < 0.05; α 2 : p < 0.001; α 3 : p < 0.0001 significant differences when compared to the positive control. The administration of the extract of S. magnificum to albino rats on the first ten days of pregnancy reveals through Figure 4 a significant decrease (p < 0.0001) in the level of progesterone observable at doses of 400 and 800 mg/kg when compared to the control.
 Effect of S. magnificum on the 2nd stage of pregnancy (Gestation; from 11th-17th day) The effects of S. magnificum on the gestational parameters of adult rats treated from day 11 to day 17 of pregnancy showed no significant variation recorded from the control in the gestational parameters assessed.
 Effects of S. magnificum on the 3rd stage of pregnancy (Parturition; from 18th-22nd) Table 3 illustrates the effect of S. magnificum on some fertility and gestational parameters. The treatment of adult rats from the 18th to the 22nd day of gestation did not lead to any particular difference when compared to controls con-

Discussion
The objective of the present study was to evaluate the effect of aqueous extracts of Schummaniophyton magnificum on the fertility of adult rats through the estrous cycle, ovulation and gestational parameters, a medicinal plant whose previous studies have proven its stimulatory effect on fertility in immature rats [6].   Values are mean ± SEM, n = 5. *p < 0.05; **p < 0.01; ***p < 0.0001.
Concerning the estrous cycle, the extract did not disturb its total duration.
However, a significant decrease in the frequency of appearance of diestrus and a prolongation of the proestrus was observed during the periods of treatment and post treatment. This indicates a stimulating effect of the extract on the follicular growth mechanism and/or ovulation and wich lead to high mitotic activities to the uterus. These results are not agreed with those reported by Westwood (2008) [11] who found mitotic activity from the end of estrus, but are in accordance to those reported by some authors [12] who indicated the amplification of the mitotic activities rather during the proestrus phase. Indeed, Soto et al. (2002) [13] investigated that systemic and local IGF-I play an important role in the effect of estrogen on growth and epithelial proliferation of rat uterus. However, our work has shown that the aqueous extract of Schumanniophyton magnificum has estrogenic properties by causing vaginal opening in immature rats [6]. It is therefore clear that the aqueous extract of Schumanniophyton magnificum could stimulate the production of IGF-I and induce the effects observed in the treated rats. It should be noted that all cellular proliferative activity that takes place in the rodent uterus depends on direct action of estrogens [14]. The extract could therefore directly stimulate cell proliferation by behaving like estrogen or by stimulating the release of estradiol as observed in Figure 2 at the dose of 200 mg/kg and 800 mg/kg when compared to control. Definitively, one could conclude that the aqueous extract of Schumanniophyton magnificum could have interfered with hormonal synthesis, which could have led to changes in the cycle mechanism and cell cytology during the proestrus phase: This plant extract in addition to inducing folliculogenesis would also induce ovulation.
Regarding ovulation, the significant increase in the number of excreted oocytes and estradiol level in rats given the extract in the morning of proestrus; indicate that estrogen is involved in controlling the rate of ovulation [15]. In addi- proestrus had no effect on ovulation. But, our results rather showed an increase in ovulatory activity in the morning of proestrus and had no effect in the evening of proestrus. These differences observed between our results and those of these authors could be attributed to the fact that plants like Schumanniophyton magnificum having an estrogenic property, could directly act on the pituitary gland by peripheral modulation of LH and FSH, thus increasing the secretion of these hormones and particularly of estradiol which would stimulate the growth of the uterine lining, causing its thickening during the preovulatory phase of the cycle. In synergy with FSH, estradiol stimulates the proliferation of granulosa cells during follicular development by promoting ovulation [8]. Ultimately, the aqueous extract of Schumanniophyton magnificum would have induced folliculogenesis by increasing the number of follicles at different evolutionary stages and would also have induced ovulation by behaving like an endogenous estrogen [19].
The treatment of female rats with the aqueous extract of Schumanniophyton magnificum presented us with unexpected results in the different stages of pregnancy. Indeed, the post-coital administration of the aqueous extract of Schumanniophyton magnificum during the first ten consecutive days of gestation of the rats caused an implantation failure marked by vaginal bleeding from the 6th day. At the same time, a tendency for the progesterone level and the number of implantation sites to decrease was noted, particularly in animals treated at doses of 400 mg/kg and 800 mg/kg. These results indicate that hormonal imbalances could be caused by many chemical agents contained in plant extracts [20] [21].
The failure of certain implantation sites observed in this study could be attributed to an alteration or interference in the production of hormones (estrogen and progesterone). Thus, the uterine lining has not developed sufficiently to support or nourish the fertilized eggs, thus preventing implantation [22] [23].
This implantation failure could also be related to the deleterious effect of the extracts on the blastocysts or on the final stage of implantation, probably due to an altered endometrial environment or a combination of both. Indeed, the studies of Paria et al. (2001) [24] reported that implantation can only be successful when activation of the blastocyst coincides with the receptive state of the uterus.
We have also noticed in this work the decrease of the weight of pups after parturition. Indeed, the presence of phytoestrogens in this extract [4] would have induced chemical interactions that produced alterations in the uterine milieu and created hostile conditions in the uterus [25]. It is these chemical components when given at the third stage of pregnancy that induced early parturition to female rats. In the other hand, some [26] [27] indicated that endogenous estradiol activates oxytocin receptors in the uterine myometrium at term by altering the sites of binding of the calcium ion (Ca 2+ ) which increases reactivity to oxytocin which would thus have facilitated parturition by initiating the onset of labour. This indicates that the aqueous stem extract of Schumanniophyton magnificum is also toxic when it is administered in the late period of pregnancy. It is

Conclusion
In conclusion, these studies show that, although the administration of Schumanniophyton magnificum extract stimulates ovulation, it has adverse effects throughout the period of pregnancy development until term. This confirms its traditional use to stimulate fertility in young girls and as a contraceptive for those who do not want to have children.