Document Type : Research article
Authors
1 Artificial Insemination and Embryo Transfer Dept. Animal Reproduction Research Institute, Agriculture Research Center, Giza, Egypt
2 Dept. of Field Investigations, Animal Reproduction Research Institute, Agriculture Research Center, Giza, Egypt
Abstract
Keywords
STUDIES ON LAPAROSCOPIC INTRAUTERINE INSEMINATION OF BARKI EWES (USING DIFFERENT INSEMINATION DOSES (AS COMPARED WITH CERVICAL INSEMINATION
EL-BADRY, D.A.*; AML Z. LEIL ** and MONA H. SHAKER *
*Artificial Insemination and Embryo TransferDept. Animal Reproduction Research Institute, Agriculture Research Center, Giza, Egypt
**Dept. of Field Investigations, Animal Reproduction Research Institute, Agriculture Research Center, Giza, Egypt
Email: diyabadry@hotmail.com
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ABSTRACT
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Received at: 1/6/2014
Accepted: 10/9/2014 |
The present study aimed to investigate the efficacy of laparoscopic intrauterine insemination as compared with cervical insemination in Barki ewes as well as to set the optimum number of spermatozoa per laparoscopic insemination. A total of 33 oestrus-synchronized Barki ewes were divided into four groups, the first three groups were inseminated laparoscopically with either 10 x 107 (group 1), 20 x 107 (group 2) or 40 x 107 sperm/dose(group 3). The 4th group was cervically inseminated. The results showed that lambing rate after laparoscopic intrauterine insemination using 20 x 107 spermatozoa (75.00%) was superior to either laparoscopic insemination using 10 or 40 x 107 spermatozoa or cervical insemination using 80 x 107 spermatozoa (37.50%, 62.50 and 55.56%, respectively). Conclusively, intrauterine insemination using the technique of laparoscopy is a relatively simple, field applicable and convenient mean of achieving high lambing rates. Furthermore, 20×107 motile spermatozoa is the recommended laparoscopic insemination dose in Barki ewes.
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Key words: Laparoscopic, Intrauterine insemination, Barki ewes.
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INTRODUCTION
Artificial insemination has become an important adjunct for breeding certain domestic species because of its great advantage for exploiting the genetic potential of superior sires. It has been known for quite long time that cervical insemination in sheep though commercially widely used, does not render satisfactory fertilization rate (Amiridis and Cseh, 2012).The cervical canal of the ewe has a convoluted and tortuous structure, reflecting the presence of 5–7 annular folds or cervical rings (Kershaw et al., 2005; Kaabi et al., 2006) that prevent trans-cervical intrauterine insemination (Kaabi et al., 2006).
Laparoscopic approach for intrauterine semen deposition is an easy technique, however, giving acceptable fertilization rates in estrous synchronized ewes (Lymberopoulos et al., 2001; Naqvi et al., 2001; Evans et al., 2002; Hiwasa et al., 2009).The advantage of laparoscopic insemination is that the semen is deposited closer to the site of fertilization. Deep uterine insemination has been shown to be advantageous in several domestic species, such as sheep (Salamon and Maxwell, 1995; Wulster-Radcliffe et al., 2004), goats (Ritar and Salamon, 1983; Moore et al., 1988), cattle (Lopez-Gatius, 2000; Verberckmoes et al., 2004), horses (Morris and Allen, 2002), and pigs (Martinez et al., 2002; Rath, 2002; Watson and Behan, 2003), especially when sperm numbers are limited or sperm quality is suboptimal.
The site of insemination of ram semen has a major effect on pregnancy rate in sheep, with greater rates achieved following laparoscopic AI than following either transcervical (Wulster-Radcliffe et al., 2004) or cervical insemination (Fair et al., 2005).Using laparoscopy, the “cervical barrier” problem has been overcome and satisfactory fertility rate has been achieved by significant reduction in the number of spermatozoa per insemination (from 200-300 to 1-10 millions, or less for sex-sorted semen, Salamon and Maxwell, 2000).
The major objectives of this study were; to compare the pregnancy and lambing rates of ewes inseminated either cervically or by intrauterine laparoscopic insemination and to determine the minimal sperm dose per intrauterine insemination in order to maximize the genetic diffusion of males, without decreasing AI success.
MATERIALS and METHODS
Animals and treatment:
Thirty six mature, clinically healthy Barki sheep (3 rams and 33 ewes), aged 2.0 -2.5 years were assigned to the study. Animals were kept in the experimental farm of the Animal Reproduction Research Institute (ARRI), and they were divided into four groups, the first three groups (8 ewes in each) were inseminated laparoscopically with either 10 x 107 (group 1), 20 x 107 (group 2) or 40 x 107 sperm/dose(group 3). The last group (group 4 containing 9 ewes) was trans-cervically inseminated with 80 x 107 sperm/dose(Gordon, 1997).
Collection of semen:
Semen was collected from trained rams with an artificial vagina that was adjusted to a proper condition, diluted at 30°C with Tris-based diluent to provide a sperm concentration of 80 x 107/ml, cooled slowly and kept at 16°C for up to 6 h (Langford et al., 1979). Only rams with at least 70% motile spermatozoa and good progressive motility were used. Just before insemination, dilutions were made at 16°C using Tris-based diluent to provide concentrations of 80, 40, 20 and 10 x 107/ml.
Synchronization of estrus:
The estrous cycles were synchronized using CIDR’s (EAZI-BREED, CIDR®, New Zealand), inserted for a period of 14 days (Sirjani et al., 2012). eCG (250 IU; Folligon; Germany) intramuscularly injected to ewes at the time of CIDR removal. The laparoscopic and cervical inseminations were performed on the 58th hour after removal of CIDR (Bonev et al., 2005).
Laparoscopic artificial insemination:
Laparoscopic procedures were done using Wolf Laparoscope (Wolf Co., Germany) of 5 mm diameter, 33 cm length and 0o scope viewing angle. Automatic insufflator was used to deliver the CO2 intraperitoneally (pressure 10 mmHg). Laparoscopic insemination, in details was described by Toni et al. (2012). Briefly, ewes were fasted and restricted access to water at least for 16 hours before laparoscopy, and injected intravenously with xylazine hydrochloride (Xylaject 2%, Adwia) at a dose rate of 0.05mg/kg b.w. Local anesthetic (Lidocaine 2%) was injected 10 minutes before the procedure was performed. The ewe was then placed in a laparoscopy cradle. The abdominal region was surgically prepared by shearing the wool and disinfecting the skin. Using the cradle, the ewe was positioned in a supine head-down (Trendelenburg) position to an approximate angle of 30o (Fig 1). A scalpel blade was used to make a small skin incision in order to facilitate trocar penetration (Fig 2). The trocars and cannulae for introducing laparoscope and insemination pipette were inserted 7-10 cm ventral to the udder and 5-10 cm on each side of the midline (linea alba). The 5-mm Verus needle that was connected with the CO2 is first introduced and the abdomen was slightly inflated to reduce the chance of injury to organs. Insertions of the first trocar and cannula should be well controlled and the sharp trocar was withdrawn as soon as the abdominal wall has been penetrated. The blunt cannula was pushed well into the abdomen, while the second trocar and cannula were inserted after inflation with CO2. Endoscope and AI instrument went through the cannulae (Fig 3) and the uterus was located and fixed using the grasping forceps just ventral to the urinary bladder. Semen was deposited in the lumen of each uterine horn approximately halfway between the uterine bifurcation and the utero-tubal junction (Fig. 4). Instruments were withdrawn and putted into disinfectants between each animal. An antibiotic spray was applied to the wounds before it was sutured. The sutures were removed 7 days later.
Fig. 1: Positioning of the animal in a supine head-down position for laparoscopy |
Fig. 2: A small skin incision in order to facilitate trocar penetration |
Fig. 3: Endoscope went through the cannulae for visualization of uterus |
Fig. 4: The recommended site of puncture for semen deposition is the major curvature of the uterine horn (arrow). |
Cervical artificial insemination:
The cervix was located, via a speculum fitted with a light source. The cervix of the ewe is convoluted in structure and does not dilate during oestrus. As a result it was generally only possible to deposit the semen (80 x 107 sperm) in the first fold of the cervix.
Pregnancy diagnosis:
Pregnancy rate (pregnant ewes/treated ewes ratio) was determined 35 days after AI by trans-abdominal ultrasonography examination using an Exagyne ECM, France) machine provided with a 6.5 MHz linear probe. Pregnancy loss in ewes was calculated as the number of ewes pregnant at Day 35 – the number of lambed ewes / number of ewes pregnant at Day 35.
Statistical analysis:
The recorded data among all treatment groups was analyzed by Chi square analysis. The level of significance was observed at 5% (Snedecor and Cochran, 1989).
RESULTS
Regarding the results of laparoscopic intrauterine insemination (table 1), the insemination dose of 20 x 107 spermatozoa (group 2) and 40 x 107 spermatozoa (group 3) resulted in the same pregnancy rate at 35 days post-insemination (75.00% for each). However, insemination of 20 x 107 spermatozoa resulted in significantly (P ≤ 0.05) higher lambing rate when compared with using 10 x 107 and 40 x 107 spermatozoa (75.00% vs. 37.50 and 62.50%, respectively). On the other hand, ewes of group 1 had the significantly higher rate of pregnancy loss (40.00%) when compared with rates of groups 2 and 3 (0.00% and 16.67%, respectively).
The results presented in table (1) revealed that, laparoscopic intrauterine insemination using optimum insemination dose (20 x 107 spermatozoa, group 2) was superior to cervical insemination using 80 x 107 spermatozoa (group 4) in terms of pregnancy rate (75.00% vs. 55.56%, respectively) and lambing rate (75.00% vs. 55.56%, respectively).
Table 1: Pregnancy and lambing rates of ewes after cervical and laparoscopic intrauterine insemination using different insemination doses.
Method of Insemination |
Laparoscopic intrauterine Insemination |
Cervical Insemination |
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Treatment Groups |
GP1 |
GP2 |
GP3 |
GP4 |
Insemination dose (sperm) |
10 x 107 |
20 x 107 |
40 x 107 |
80 x 107 |
No. of ewes inseminated |
8 |
8 |
8 |
9 |
No. of pregnant ewes (%) |
5 (62.50) b |
6 (75.00) a |
6 (75.00) a |
5 (55.56) c |
Lambing rate (%) |
3 (37.50) d |
6 (75.00) a |
5 (62.50) b |
5 (55.56) c |
Pregnancy loss (%) |
2 (40.00) a |
0 (0.00) c |
1 (16.67) b |
0 (0.00) c |
Values with different superscripts in the same raw differs significantly at least at P < 0.05
DISCUSSION
In the current study, the lambing rate after laparoscopic insemination using 20 x 107 spermatozoa (group 2) was significantly (P ≤ 0.05) higher than that after cervical insemination using 80 x 107 spermatozoa (75.00% vs. 55.56%, respectively). Similarly, Rojero et al. (2009) concluded that middle fertility rate of 43.7% resulting from cervical insemination in ewes can be considered as acceptable, but it is no possible to obtain similar fertility rate (75.00%) as with laparoscopic intrauterine insemination. Artificial insemination techniques have been considered in many previous studies. According to several authors (Armstrong and Evans, 1984; Rodriguez et al., 1988; Correa et al., 1994; Byrne et al., 2000; Romano, 2013),laparoscopic insemination ensures significantly higher parturition rates than trans-cervical insemination, despite the fact that relatively lower numbers of spermatozoa are used. This difference in fertility can be explained by the fact that the sheep cervix has a very high structural complexity, preventing deep cervical insemination (Halbert et al., 1990; Kaabi, 2002). Laparoscopic insemination allows this barrier to be bypassed, improving fertility even with lower quality spermatozoa (Salamon and Maxwell, 2000; Naqvi et al., 2001).
The lambing rate of 75.00% achieved after laparoscopic intrauterine insemination in present study coincided with the same rates (75.00%) reported by McKelvey et al. (1985) and Rojero et al. (2009),and higher than lambing rates of 48.00%, 71.10%, 43.90%, 72.70%, 60.00%, 71.00% and 71.40% reported by Windsor et al. (1994), Hill et al. (1998), McKusick et al. (2000); Paulenz et al. (2005), Toni et al., 2012, Al-Wataar (2009) and Alfaris et al. (2012), respectively. Sayre and Lewis (1997)reported a higher lambing rate (92.50%) after intrauterine insemination. Concerning the cervical insemination, the lambing rate of 55.56% achieved after cervical insemination in this study was similar to that (57.00%) reported by Ghalsasi and Nimbkar (1996),and lower than lambing rates of 68.60%, 78.00%, 69.00%, 67.00%, 65.75% and 60.00% reported by Lightfoot and Salamon (1970), Langford et al. (1979), Tervit et al. (1984), McKelvey et al. (1985), Donovan et al. (2000), Nour et al. (2010), respectively,and higher than lambing rates of 43.70% and 50.00% reported by Rojero et al. (2009) and Al-Wataar (2009), respectively.The fertility rates following cervical and laparoscopic insemination all vary with the insemination technique used as well as with the farm, age, male, number of insemination per ewe, lambing-insemination interval, technician, flock and management conditions (Anel et al., 2005; Paulenz et al., 2005).
In sheep, the numbers of spermatozoa used by intrauterine insemination were reported to be 80 million (Windsor et al., 1994), 150 million (Halbert et al., 1990; Buckrell et al., 1994), 200 million, (Lawrence, 1985; Husein et al., 1998a) and 400 million (Smith et al., 1995; Husein et al., 1998b). In general, the numbers of spermatozoa used for intrauterine insemination are higher than the recommended numbers used for trans-cervical artificial insemination (Maxwell and Hewitt, 1986; Ritar, 1993; Romano, 2013).In the current study, a low intrauterine insemination dose (10×107) resulted in decreased lambing rate (37.50%), whereas a higher insemination dose (20×107) increased lambing rate (75.00%) and this result was in agreement with other researches (Maxwell and Salamon, 1993; Martin and Watson, 1976; Emsen et al., 2011). Higher dose of spermatozoa (40×107) was not recorded with significant increase in lambing rate (62.50%). This result came in accordance with the findings of Emsen et al. (2011). Thus, it can be recommended that the minimum necessary for laparoscopic artificial insemination in Barki ewes is 20×107 motile spermatozoa. Similarly, Milczewski et al. (2000) recommended that higher pregnancy rates (69.56%) could be obtained with at least 25 x 107 spermatozoa per dose in intrauterine inseminations of ewes. On the other hand, Leethongdee (2010) recommended a minimum number of 40 x 106 spermatozoa per laparoscopic insemination. Also, Evans and Maxwell (1987) recommend a minimum dose of only 20 x 106 motile sperm while there are several reports of acceptable fertility (> 50%) using doses as low as 5 x 106 (Eppleston et al., 1986)and 10 x 106 (Salamon et al., 1985) motile spermatozoa. Furthermore, acceptable levels of fertility were achieved after low-dose insemination using flow cytometrically sorted ram sperm at a dose of 1 x 106 motile sperm per ewe (de Graaf et al., 2007).
In conclusion, as compared to cervical insemination, intrauterine insemination using the technique of laparoscopy is a relatively simple and convenient mean of achieving high lambing rates in Barki ewes. The recommended insemination dose for laparoscopic artificial insemination of Barki ewes was 20×107 motile spermatozoa.
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دراسةمقارنة بين تلقيح النعاجالبرقى بالمنظار داخل الرحم (بإستخدام جرعات مختلفة من السائل المنوى)
وداخل عنق الرحم
ضياءالدينعبدالمؤمنالبدري، أمل زکريا ليل ، منى حامد شاکر
Email: diyabadry@hotmail.com
يهدف هذا البحث إلى دراسة کفائة تلقيح النعاج البرقى داخل الرحم بالمنظار مقارنة بالتلقيح بعنق الرحم بالإضافة لمعرفة العدد الأمثل من الحيوانات المنوية للتلقيح داخل الرحم. تم لإجراء هذا البحث إستخدام 33 نعجة برقى بعد عمل تزامن شبقى لها وتم تقسيمهن إلى أربع مجموعات ولقحت المجموعات الثلاثة الأولى منها داخل الرحم بالمنظار بإستخدام 10 X 107 (المجموعة الأولى) و 20 X 107 (المجموعة الثانية) و 40 X 107 حيوان منوى (المجموعة الثالثة) بينما لقحت نعاج المجموعة الرابعة إصطناعياً داخل عنق الرحم. وقد أوضحت النتائج أن معدل الولادة للمجموعة الثانية (75.00%) کان أعلى من معدلات الولادة فى المجموعة الأولى والثالثة والرابعة (37.50%, 62.50% , 55.56% , على الترتيب). يستنتج من هذا البحث أن حقن السائل المنوى للکباش داخل الرحم عن طريق المنظار البطنى يعتبر تقنية سهلة التطبيق تحت ظروف الحقل لتحقيق معدل مرتفع من الولادات وتوصى نتائج البحث بأفضلية إستخدام 20 X 107 حيوان منوى کجرعة مثلى لتلقيح النعاج البرقى بإستخدام هذة التقنية.