Document Type : Theriogenology and Reproduction
Authors
1 Departmeny of Theriogenology, Faculty of Veterinary Medicine, University of Tehran, Tehran, Iran
2 DVSC candidate, Department of Theriogenology, Faculty of Veterinary Medicine, University of Tehran, Tehran-Iran
3 DVM graduated student, Faculty of Veterinary Medicine, University of Tehran, Tehran-Iran.
4 Professor, Department of Theriogenology, Faculty of Veterinary Medicine, University of Tehran, Tehran-Iran
Abstract
Keywords
Article Title [Persian]
Authors [Persian]
زمینه مطالعه: روش های مختلف ایجاد سیکل استروس و تسریع اولین تخمک گذاری سال، در مادیان گزارش شده است. هدف: هدف از انجام این مطالعه بررسی اثر پروژسترون (کیومیت) در همزمانی و تسریع اولین تخمک گذاری سال، تحت رژیم نوردهی در مادیان های آنستروس زمستانه بوده است. روش کار: پس از شناسایی مادیان های آنستروس ، رژیم نوردهی مصنوعی 16 ساعته از اوئل آذر برای هر دو گروه درمان و شاهد اجرا شد. پس از شناسایی فولیکول با قطر 25 میلی متر بر روی تخمدان، مادیان های گروه درمان، کیومیت دریافت کردند و سپس با کمک سونوگرافی مقعدی مورد معاینه قرار گرفتند تا آنکه قطر فولیکول به اندازه 35 میلی متر رسید که در این زمان کیومیت خارج شد. معاینه روزانه اولتراسونوگرافی و عمل تیزینگ تا شناسایی تخمک گذاری انجام گرفت. نتایج: بر اساس نتایج حاصله، تفاوت معنی داری بین دو گروه درمان و شاهد در میزان تخمک گذاری (66% در مقابل 60%) و اندازه فولیکول تخمک گذاری کرده دیده نشد. بعلاوه، علیرغم کاهش فاصله زمانی رشد فولیکول از قطر 25 تا 35 میلی متر در گروه درمان در قیاس با گروه شاهد (به ترتیب 0/88 ± 8/33 و 2/28 ± 10/75) و نیز از این اندازه تا سایز تخمک گذاری، هیچگونه تفاوت معنی داری بین این دو گروه مشاهده نشد. نتیجه گیری نهایی: این اولین گزارش مقدماتی بررسی تاثیر پروژسترون بهمراه نوردهی مصنوعی در جهت تسریع اولین تخمک گذاری سال در ابتدای آنستروس زمستانه می باشد. بنظر می رسد مطالعات بیشتری با در نظر گرفتن تعداد بیشتر مادیان ها در سنین مختلف مورد نیاز است.
Keywords [Persian]
Introduction
The mare is seasonally polyestrous with regular ovulatory cycles occurring in response to increasing day length (Donadeu and Watson, 2007). In mares that have entered a seasonal anestrous phase during the winter of temperate latitudes, ovulatory cycles do not normally commence until April or early May (October or early November in the Southern Hemisphere) (Ginther, 1974). Most breeder associations use a single date, January 1st for registering all foals born in a calendar year, however, from an economic standpoint production of foals early in the year is essential for performance in the show ring and maximizing prices obtained for yearlings (Squires, 2008). Getting mares pregnant around February 15th is essential and various hormonal and non-hormonal methods have been described for advancing first ovulatory cycle of mares in both anestrus and transitional phase. Non-hormonal method which is based on photostimulation can be implemented by using various artificial lighting procedures including: Indoor conventional and modified light therapy which requires mares to be kept in stalls during lighting period or mobile light therapy which allows outdoor maintenance of mares by using blue light emitting diode (LED; 468nm) mask (Murphy, et al. 2014). Conventional lighting regimen can be done by 14.5 to 16h daily light (8-9.5h darkness) beginning from December in deep anestrus mares. Modified light regimens use photosensitive phases of the mare’s circadian clocks including that of post dusk therapy which uses 2.5h additional light after sunset or skeletal lighting which works based on night interruption through 1 -2 h. lighting, 9.5-10.5 hours after beginning of darkness. Lighting regimens are successful, albeit variable in response time between individuals, but must be started many weeks before ovulation (McKinnon, et al. 2011).
Hormonal treatment methods for induction or hastening earlier cyclicity can be classified into two categories: treatments for inducing onset of cyclicity in anestrus mares including administration of GnRH osmotic pump or implant and recombinant LH and FSH or those whose efficacy has been mainly proved for hastening cyclicity among mares in transition phase like using ovulation inducing agents (GnRH agonists and hCG), dopamine D2-receptor antagonists for increasing prolactin secretion (Panzani, et al. 2011) and progesterone or progestin treatment to suppress GnRH release allowing a surge after cessation of treatment (Squires, 2008). Efficacy of reFSH in stimulating follicular development and advancing the first ovulation of the year in deep anestrous mares maintained under ambient lights was determined. The results of this study indicated that reFSH was effective in stimulating the development of ovarian follicles and advancing the first ovulation of the year in seasonally anestrous mares under ambient lights but was not successful in inducing continued cyclicity (Meyers-Browna, et al. 2013). Diastral level of progesterone inhibit ovulation and cause follicular regress in ruminants, while in equids they just prevent showing of estrus behavior and with regards to the possibility of continuing diastral follicles’ development, ovulation is presumable. In one study, short-term preovulatory progestogen (CIDR or altrenogest) treatment in mares could not delay ovulation. Also, treatments had no effect on follicular growth rate or the size of the ovulatory follicle immediately preceding ovulation (Caniso, et al. 2013).
We hypothesized that progesterone supplementation increase efficiency of lighting therapy and results in earlier ovulation induction compared with control group.
The goal of present study was to investigate the effect of progesterone on synchronization and acceleration of the first ovulation of the year in winter anestrous mares under artificial lighting system.
Material and Methods
Animals: Crossbred and mixed bred barren mares (n=10), aged from 5 to 10 years old, body weight averaged of 500 Kg and good body condition were used in this study.) in research and training hospital of Faculty of Veterinary Medicine, University of Tehran-Iran located in Mohammad Abad (in Alborz province-Iran). They were fed with hay, alfalfa and cereals concentrate in standard rations. Because of stallion exposure effect on hastening onset of cyclicity, we were careful not to be allowed the mares to have contacted with stallions. Mares were weekly examined by rectal palpation and ultrasonography from late November of 2014. Mares with signs of anestrus condition, were characterized by inconclusive or no estrous behavior, a relatively relaxed cervical canal, little or no uterine tone, absence of ultrasonically visible endometrial edema or a corpus luteum, and usually follicles of less than 20 mm. They were examined at least 2 weeks apart and were divided randomly in two groups (each group = 5 mares).
Treatments: All of enrolled mares were exposed daily to artificial lighting regimens of 16h light (8h darkness) from early December by using incandescent 200 W bulb and daily programmed analog time switcher (theben Co.). The status of mares’ reproductive system in terms of follicular growth and uterine edema was evaluated by ultrasonography examination, twice a week. Unfortunately, 2 mares in treatment group were eliminated from the study after about one month due to some problems. So, we continued with 3 and 5 mares in study and control group respectively. Treatment group mares also received Cue-mate (Bayer Animal Health, New zealand), which is a type of progesterone releasing intravaginal device (PRID) containing Progesterone 1.56g within two silicone pods attached to a flexible ‘wishbone’ for insertion into the vagina (Fig. 1). The device was originally designed for use in cattle to induce and synchronize estrus. In the mare, sufficient progesterone is absorbed through the vaginal wall to give peripheral plasma concentrations above 10.5 nm/l for the first 4 days. Concentrations diminish to about 7 nm/l by the 8 day and to 5.3 nm/l or lower by day 16.
Study design: If the follicle with a diameter of 25 mm was observed, mares were divided randomly into two groups:
Treatment group: Mares treated by insertion of a Cue-Mate in vaginal region. They were re-examined ultrasonographically about 6 days after insertion of the Cue-Mate and then daily according to the level of follicular activity found. When a follicle of 35 mm or greater had developed, the Cue-Mate was removed. If such a follicle had not developed after 12 to 16 days, the Cue-Mate was also removed. Daily teasing began on the day after Cue-Mate removal until estrus was detected. Then, reproductive examination for detection of reproductive signs of estrus and ovulation was done by ultrasonography.
Control group: Mares were not treated using insertion of a Cue-Mate, but they were re-examined daily according to the level of follicular activity. When a follicle with ≥35 mm diameter had developed, teasing and ultrasonography was performed daily until ovulation.
Statistical analysis: The obtained data such as rate of estrous, rate of ovulation, and rate of antral hemorrhagic follicles occurrence were analyzed by Chi-square statistical test. The numerical data included time interval from size of deviation (≈ 20 mm diameter) to becoming inducible follicle (≈ 35 mm), time interval from gaining capability of ovulation (≈ 35 mm) to ovulation, and diameter of follicles at ovulation and day of ovulation following photostimulation program were tested by T-test. All of the data were analyzed by SAS statistical software version 9.2 through PROC FREQ and PROC T-TEST, respectively.
Results
Mares in treatment group were treated by Cue-Mate for a mean of 11.6±0.6 days. During the treatment period, none of the intravaginal devices (Cue-Mate) was expelled. Mild vaginitis was seen in just one mare and resolved spontaneously after Cue-Mate removal. One of the mares in control group did not respond to lighting regimen and her ovaries remained inactive during the study. All mares in both groups ovulated after Cue-Mate removal except one in treatment group.
In spite of shortened duration observed in follicular growth from ≈25 mm to ≈35 mm (8.33±0.88 days vs 10.75±2.28 days in treatment and control groups respectively) and from each of these sizes to ovulatory size, no significant difference existed between treatment and control groups (Table 1). It was found that mean diameter of follicles at the time of ovulation (44.7 ± 3.3 mm and 43.1 ± 3.3 mm in treatment and control groups respectively) did not show any difference between two groups (Table 2). Also, there was no significant difference in time interval from the beginning of lighting program to ovulation (Table 2). No significant difference was found in ovulation rate and proportion of mares showing estrus between treatment and control group (Figure 2).
Table 1. Effect of tBHQ levels and different semen concentrations on post-thaw sperm motility and motion parameters (LS mean ± SEM).
Parameter (unit) |
Semen concentration |
SEM |
P value |
||
100 |
50 |
25 |
|||
TM (%) |
75.1a |
70.8b |
67.9b |
1.3 |
**
|
PM (%) |
43.6 |
41 |
38. 8 |
1.7 |
NS |
VAP (μm/s) |
73.3b |
79.4a |
78.3a |
1.6 |
** |
VSL (μm/s) |
58.3 |
61.4 |
60.1 |
1.3 |
NS |
VCL (μm/s) |
118b |
136.5a |
139.9a |
3.5 |
** |
ALH (μm) |
6b |
6.5a |
6.6a |
0.1 |
** |
LIN (%) |
49.3a |
46.7b |
45.5b |
0.8 |
** |
STR (%) |
80.5a |
78.1b |
77.7b |
0.7 |
** |
a–c Means with different superscript in each row differ significantly (** P < 0.01; NS: not significant).
Table 2. Effect of different semen concentrations on mitochondrial activity (MA) and apoptosis status of post-thawed spermatozoa (LS mean ± SEM).
Parameter (unit) |
Semen concentration |
SEM |
P value |
||
100 |
50 |
25 |
|||
MA (%) |
68.6a |
68.5a |
54.1b |
1.2 |
**
|
Live (%) |
75.2a |
68.8b |
60.5c |
1.1 |
** |
Early apoptotic (%) |
11.5b |
11.7b |
14.3a |
0.5 |
** |
Late apoptotic (%) |
9.4c |
16.1b |
22.8a |
1.3 |
** |
Necrotic (%) |
4.4 |
3.7 |
2.4 |
0.8 |
NS |
a–c Means with different superscript in each row differ significantly (* P < 0.01; NS: not significant).
Discussion
Various types of progesterone therapy, including long act injectable (Lopez-Bayghen, et al. 2008) or orally administered progestins (Squires, et al. 1983) and intravaginal releasing progesterone (Handler, et al. 2007) has been used for synchronizing and hastening of ovulation in the mares. Intravaginal route offers a relatively cheap and convenient method of delivering progesterone to mares which does not require daily administration. Treatment of transitional mares with an intravaginal progesterone containing device specifically designed for mares (Cue-Mare) for 10 days, resulted in follicular growth and ovulation within 4 days of device removal and it was associated with minimal discomfort and vaginitis (Grimmett, et al. 2002). Induction of ovulation of mare using hormonal methods did not receive as much attention in the past as dairy cattle and sheep (Squires, 2008, Talebkhan Garoussi, and Golzar, 2012a). It was associated with earlier pregnancy during breeding season and increased risk of pregnancy at the end of it (Hanlon and Firth, 2012). Moreover, intravaginal devices designed for cattle, including CIDR (1.38 g P4), PRID (1.55 g P4) and cue-mate (1.56g P4) have been used off-label in mares and are effective in stimulating follicle growth in transitional mares (Klug and Jochle 2001). Regardless of shape and a little difference in amount of progesterone content, all of these devices have a silicone layer which slowly releases progesterone and maintains its plasma level over 1 ng/ml during 7 to 10 days of treatment period (Klug and Jochle 2001).
Even though artificial photoperiod has been shown to be quite effective in hastening the first ovulation of the year, mares still experience a transition period from winter anestrus to normal cyclicity. Conversely, administration of PRID to anestrus mares without sufficient pre-treatment artificial lighting has limited value and generally results in the follicular growth without ovulation, hence combination of artificial photoperiod for approximately 30 to 60 days and then 12 to 15 day exposure to exogenous progesterone after some follicular development on the ovary can be used to synchronize and accelerate the first ovulation of the year, resembling applied procedure during vernal transition period (Squires, et al. 1979).
Most experiments about the use of PRID are confined to vernal transition mares. It has been reported that using PRID together with ovulation inducing agents (GnRH analogs and hCG) enhanced efficacy of both treatments in comparison with administration of each of them alone (Newcombe, et al. 2002). It should be mentioned that we did not use any ovulation agent in this study. Newcombe (2002) reported that PRID administration to photostimulated anestrus mares resulted in ovulation in 92% of mares, 6.6 days after PRID removal, our finding about ovulation of 66% of mares, 5±2 days after removal is comparable with this result. Although positive effect of PRID for induction of estrus in transition mares has been reported (Hanlon and Firth, 2012, Kumar, 2011), based on our finding no significant difference in rate of showing of estrus existed between treatment and control group. Sufficient effect of lighting therapy for induction of follicular growth in control group mares can justify our results. Lack of difference in time interval to ovulation from beginning of lighting therapy in treatment and control groups mares also imply this point.
Regarding the size of ovulatory follicles, it has been reported that administration of CIDR in transitional mares stimulates follicular growth (Handler, et al. 2006), possibly due to mimicking changes of luteal phase progesterone level and enhancing LH concentration after day 6 of its insertion (Hanlon, et al. 2010). However, our results did not show significant differences in size of ovulatory follicles between treatment and control groups. The good results may arise from different study designs and time of transition phase in which treatment has been applied.
It has been reported that priming the follicles by progesterone decreased time interval of 20 mm follicle to 35 mm follicle (Staempfli, et al. 2011) and 35 mm follicle to ovulation (Newcombe, et al. 2002). According to our results, time interval from beginning of treatment at the time of follicular growth to 35mm, from 35 mm follicle to ovulation and from beginning of treatment to ovulation, were all lower in treatment group mares compared with control group. Lack of significance is probably due to low number of mares in the experiment. It seems that additional studies are needed to evaluate the effect of progesterone and lighting on induction of ovulation and hastening the first ovulation of the year in early winter anestrous. Also, ovulation induction agents such as hCG can also be applied in a discrete group to evaluate their effect on these criteria.
Acknowledgments
This study was supported by Faculty of Veterinary Medicine, University of Tehran, Tehran, Iran.
Investigating the effect of progestrone (Cue-MateTM) administration on ovulation induction in photostimulated anestrus mares