Deep uterine insemination of cattle: a fruitful way forward with smaller numbers of spermatozoa

Pregnancy percentage following deposition of sex-sorted sperm at different sites within the uterus in estrus-synchronized heifers

Our objective was to assess the effect on heifer pregnancy rate of deposition at three sites within the uterus of frozen-thawed sex-sorted sperm at a fixed time after estrus synchronization. Estrus was synchronized in 209 heifers by administration of PGF2a 14 days apart. At 80-82 h after the second PGF2a injection, X-chromosomes bearing fractions of semen with 2.2 x 10(6) sperm in insemination dose were used for single insemination into the uterine body (UB-AI, n=91) or for intracornual deposition in the middle of the uterine horn (MH-AI, n=57) or close to the utero-tubal junction (UTJ-AI, n=61). The overall pregnancy rate was 43.1%. Pregnancy rates did not differ (P>0.05) among sites of sperm sperm deposition, between the two farms at which the heifers were kept or between the two bulls producing the semen. Within UB-AI, MH-AI and UTJ-AI treatments, pregnancy rates were 41.8%, 49.1% and 39.3%, respectively (P>0.05). Pooled across classes for deposition site, pregnancy rate was 25.1% higher (P<0.01) for heifers showing strong signs of estrus than for heifers showing weak signs of estrus (45.9 versus 20.8%, respectively). Embryonic and fetal loss from diagnosis of pregnancy to term and at calving equalled 5.6%. Of 88 calves of identified sex, 93.2% were female. In conclusion, pregnancy rates of heifers did not differ significantly following deposition of 2.2 x 10(6) sex-sorted sperm 80-82 h after the second PGF2a injection near the utero-tubal junction, in the middle of the horn or into the uterine body.

Low dose insemination in cattle with the Ghent device

A new artificial insemination device for semen deposition near the uterotubal junction (UTJ) in cattle (Ghent device) was developed at Ghent University (Belgium). In this study, UTJ insemination of dairy cows with the Ghent device was compared with the conventional insemination technique to evaluate the effect on pregnancy rates after insemination with different doses of semen. In each of three field trials, the cows (n=795, 659, 360) and heifers (n=253, 182, 231) were randomly assigned to receive 12 million sperm deposited in the uterine body using conventional techniques (control) or a reduced sperm dose (RSD) deposited in the same manner as the control or bilateral deposition near the uterotubal junction using the Ghent device (Ghent). Sperm dosages for RSD and Ghent inseminations were 8, 4, and 2 million sperm for field trials 1-3, respectively. In the multivariable analysis, the pregnancy rates were significantly affected by the parity of the cow (p</=0.008) in each of the three trials, by the sire (p=0.014, 0.009) in trials 1 and 3, and by the inseminator (p<0.001) in trial 2. In none of the trials were the pregnancy rates significantly affected by the insemination technique, the order of insemination (first, second, or third), the breed of the bull or the dosage sensitivity of the bull. In conclusion, neither sperm dosage nor site of semen deposition influenced pregnancy rates in the present study.

Fertility in heifers and cows after low dose insemination with sex-sorted and non-sorted sperm under field conditions

The present study was performed to test fertility after low dose insemination with sexed and non-sexed sperm in dairy cattle under field conditions in Switzerland. Spermatozoa were stained with Hoechst 33342 and sorted by flow cytometry. A total of 132 heifers and cows were inseminated with 2 x 10(6) X-bearing, frozen-thawed sperm (A) and 91 animals were inseminated with the same dose using non-sorted, frozen-thawed sperm (B). Pregnancy examination by ultrasound was performed twice, 30-40 days (PE1) and 70-90 days (PE2) after insemination. The pregnancy rates after PE1 were 33.3% (9/27) and 59.3% (16/27) in heifers (P=0.05) and 27.6% (29/105) and 28.1% (18/64) in cows (P>0.05) for groups A and B, respectively. Embryonic losses between PE1 and PE2 in heifers were 11.1% (1/9) and 0% (0/16) and in cows 17.2% (5/29) and 5.6% (1/18), the differences between groups A and B not being significant (P>0.05). Calving rates in heifers were 29.6% (8/27) and 57.8% (15/26), whereas in cows 22.1% (23/104) and 23.4% (16/63) gave birth to calves (for both groups P>0.05). The sex ratio was different (P<0.05) between A (85.3%) and B (58.6%). From our results it can be concluded that conception rates of sorted and non-sorted semen are similar using an insemination dose of 2 x 10(6). Fertility may be increased by improving sexing technology and animal management.

[Deep intrauterine insemination in cattle]

INTRODUCTION

Most of the artificial inseminations in cattle nowadays are being performed in the uterine body with a rigid insemination device. Uterotubal junction insemination can only be performed in cattle with a device which is rigid enough to pass the cervix and flexible enough to follow the curvature of the uterine horns. At the Faculty of Veterinary Medicine in Ghent, a new insemination device has been developed for semen deposition near the utero-tubal junction in cattle and other animals.

MATERIALS AND METHODS

In a first field trial the feasibility of the newly developed Ghent device was evaluated. Four thousand sixty-four dairy cows were inseminated by 12 inseminators with a standard insemination dose (10-15 million of frozen-thawed spermatozoa). Three insemination methods were compared; group 1: insemination in the uterine body with the conventional insemination device, group 2: insemination in the uterine body with the Ghent device, and group 3: insemination in the tip of both uterine horns with the Ghent device. In a second field trial insemination of dairy cows with the Ghent device was compared with the conventional insemination technique to evaluate the effect on pregnancy rates. The insemination dose was lowered to eight million (trial 1), four million (trial 2), and finally to two million frozen-thawed spermatozoa (trial 3). In each field trial, cows were divided into three groups: the first group was inseminated with a full insemination dose (12 x 10(6)) in the uterine body with the conventional insemination device, the second group with a lowered insemination dose in the uterine body with the conventional insemination device, and the third group with a lowered insemination dose in the tip of both uterine horns with the Ghent device. It can be concluded that decreasing the insemination dose from 12 to four million frozen-thawed spermatozoa had no effect on pregnancy rate in our experiments, neither with the conventional insemination device, nor with the Ghent device. The device is made of disposable materials and has been tested to be non-toxic for bovine spermatozoa, can be used by one person and is adapted for application in the field.

CONCLUSION

In the near future, similar field trials will be performed with even lower doses of semen. It is only in these cases that we truly hope to show a positive effect of uterotubal junction insemination by using low quality semen or by using sexed semen.

Intra-uterine Insemination in Farm Animals and Humans

Artificial insemination (AI) is the oldest and currently most common technique in the assisted reproduction of animals and humans. The introduction of AI in farm animals was forced by sanitary reasons and the first large-scale applications with a commercial goal were performed in cattle in the late 1930s of last century. After the Second World War, cryopreservation of semen facilitated distribution and AI was mainly performed for economic reasons, especially in dairy cattle industry. In humans however, AI was initially performed in cases of physiological and psychological sexual dysfunction, but later on also in cases of infertility caused by immunological problems. Currently, the most common indications for intra-uterine insemination (IUI) in humans are unexplained infertility and male subfertility. In these cases, IUI is considered as the treatment of the first choice, before more invasive techniques such as in vitro fertilization (IVF) and intracytoplasmatic sperm injection (ICSI) are used. In contrast with humans, the quantity and quality of semen produced by farm animals is much higher and permits dilution and production of several insemination doses per ejaculate. However, with the introduction of sex-sorted semen in farm animals, the same problem of low-quality semen as in humans has arisen. In cattle, pigs and horses, conventional insemination with low numbers of sex-sorted spermatozoa results in a significant decrease in fertility. To improve the fertility rates with this semen, new insemination techniques have been developed in order to deposit spermatozoa closer to the site of fertilization. In sows and mares the advantage of utero-tubal junction (UTJ) insemination has already been proven; however, in cattle it is still under investigation. In this review, the differences and similarities in the application of AI between animals and humans are discussed and as AI in farm animals is most successful in cattle, the situation in this species is elaborated the most.

Effect of insemination with doses of 2 or 15 million frozen-thawed spermatozoa and semen deposition site on pregnancy rate in dairy cows

The effects of low-dose artificial insemination (AI) on pregnancy rates have seldom been studied in lactating dairy cows. We evaluated the pregnancy results after AI with doses of 2 and 15 million frozen-thawed spermatozoa and the effect of semen deposition in lactating dairy cows. A total of 284 first inseminations with 2 million spermatozoa and 312 first inseminations with 15 million spermatozoa were performed on 480 dairy farms. Low-dose inseminations (2 million spermatozoa) under field conditions in commercial dairy herds, without estrus synchronization, generally resulted in significantly reduced pregnancy rates compared with normal doses (15 million spermatozoa). The bull x technician effect on fertility was statistically significant. This finding indicates that there is a high variability in fertility among bulls using 2 million spermatozoa per dose. The semen deposition site did not influence pregnancy rates. It is concluded that a dose of 2 million frozen-thawed spermatozoa is probably too low for most bulls to achieve acceptable pregnancy rates in dairy cows.

Assessment of a new utero-tubal junction insemination device in dairy cattle

A new artificial insemination device for semen deposition near the utero-tubal junction in cattle (Ghent device) has been developed at the Ghent University (Belgium). In this study, the effect of the new insemination device on sperm quality was evaluated. Moreover, in a field trial 4064 dairy cows were inseminated by 12 inseminators to examine the efficacy of the device under field conditions. The Ghent device is a disposable plastic catheter which can easily follow the curvature of the uterine horns and thus reach the utero-tubal junction (UTJ). After expulsion of the inseminate with 0.7 or 1.7 ml of air, 19.0% of the insemination dose remained in the insemination catheter. Sperm loss can be diminished to 9.0% of the original insemination dose when the insemination catheter is flushed with 0.1 ml of air, followed by 0.6 ml of physiological saline solution. No toxic effect of the insemination catheter on sperm quality or fertilizing capacity was found. In the field trial, sperm were inseminated in dairy cattle which were divided in three groups. The first group was inseminated in the uterine body with the conventional insemination device, the second group in the uterine body with the Ghent device, and the third group in the tip of both uterine horns with the Ghent device. Each insemination was performed with 10 x 10(6) to 15 x 10(6) frozen-thawed spermatozoa. The pregnancy rates (PRs) were significantly affected by the insemination technique (P = 0.02), by the inseminator (P = 0.01), by heifer or cow (P < 0.01), and by the insemination number (P < 0.01). Pregnancy rates obtained with the conventional insemination device (57.6%) were significantly better than those obtained with the Ghent device in the uterine body (52.7%) (P < 0.01), but did not differ significantly from those obtained after deep insemination into both uterine horns (53.8%) (P = 0.27). It can be concluded that the Ghent device is suitable for utero-tubal junction insemination of dairy cattle under field conditions. Whether the Ghent device is also suitable for insemination with lower insemination doses is at present under investigation.

Advances in deep uterine insemination: a fruitful way forward to exploit new sperm technologies in cattle

After clarifying regions of the female tract wherein spermatozoa are stored and the egg is fertilised, proposals are made for a modified site of sperm deposition in cattle. A deep pre-ovulatory insemination into the ipsilateral horn of the uterus-the side of the ovulatory follicle-should improve establishment of viable spermatozoa in the caudal region of the oviduct isthmus, the so-called functional sperm reservoir. Suppressed motility within viscous secretions and binding of sperm heads to endosalpingeal microvilli are features of this phase of storage. Activation and release of such spermatozoa would be prompted by imminent ovulation and associated ovarian endocrine programming by both local and systemic routes. Potential advantages of deep insemination include: (1) raising the fertility of genetically valuable bulls whose non-return rates are sub-optimal; (2) reducing the number of spermatozoa in each insemination dose; (3) exploiting the limited numbers of sex-selected sperm cells (X- and Y-chromosome-bearing spermatozoa) available from flow cytometry; (4) breeding from valuable but oligospermic bulls. Putative disadvantages might include: (1) rectal palpation of the ovaries to identify the pre-ovulatory follicle; (2) damage to or even perforation of the uterine wall by the insemination device; (3) the risk of polyspermic fertilisation; (4) specific training in the technique for non-clinically qualified inseminators. Each of these reservations receives comment. In conclusion, a modified technique of insemination should be feasible under commercial conditions, could be coupled with new sperm technologies, and would give a boost to the artificial insemination industry.

Fixed time deep intracornual insemination of heifers at synchronized estrus

The aim of the study was to determine the efficiency of single fixed time deep intracornual insemination using 2 x 10(6) spermatozoa compared with single standard dose deep intracornual insemination and single and dual standard dose (40 x 10(6)) uterine body (conventional) insemination in heifers at synchronized estrus. Estrus was synchronized in 275 virgin heifers by administration of two doses of PGF(2)alpha 14 days apart. Deep intracornual inseminations with low (ICI-LD1, n=102) and standard (ICI-SD1, n=56) dose of semen and the single standard dose conventional inseminations (AI-SD1, n=66) were performed 80-82 h after the second PGF(2)alpha treatment. Ultrasonography was used to identify the first dominant (presumed ovulatory) follicle, and semen was deposited either close to the utero-tubal junction (n=69 in ICI-LD1 and n=23 in ICI-SD1) or in the middle part of the uterine horn (n=28 in ICI-LD1 and n=28 in ICI-SD1) ipsilateral to the ovary bearing the first dominant follicle. The dual standard dose conventional inseminations were performed 72 and 96 h after the second PGF(2)alpha treatment (AI-SD2, n=51). The pregnancy rate in the ICI-LD1 group (68.0%) did not differ significantly (P>0.05) from the ICI-SD1 group (56.9%) or the AI-SD2 group (65.9%) and was significantly higher (P<0.05) than in the AI-SD1 group (54.2%). The site of intacornual deposition of semen, near the utero-tubal junction or in the middle of the horn, had no effect on the pregnancy rate. The pregnancy rate in all the groups was not affected by the intensity of expression of estrous signs.

An overview of low dose insemination in the mare

The need for relatively high numbers of spermatozoa for artificial insemination limits our application of recently available technologies such as sex-sorted semen. The fertility of two different methods of low dose insemination using fresh, frozen and sex-sorted semen are compared in this overview. Satisfactory conception rates are described using very low doses of spermatozoa inseminated by either hysteroscopic or deep uterine insemination methods, proving the stallion is fully fertile. The hysteroscopic method appears to give higher conception rates when inseminating fewer than 5 x 10(6) spermatozoa and is therefore, the preferred method of insemination for sex-sorted spermatozoa. However, hysteroscopic deposition of low numbers of spermatozoa from infertile stallions does not appear to improve their fertility.

Site of semen deposition in cattle: a review

The breeding of cattle using conventional artificial insemination methods involves the deposition of semen in the uterine body. However, it has been recently proposed by several authors that the site of semen deposition be changed to the uterine horns. This suggestion is based on 2 facts: the acceptance that the major preovulatory sperm reservoir may be the uterotubal junction rather than the cervical canal, and the lack of accuracy by inseminators in depositing semen. In over 50% of cases, inseminators were not sufficiently trained to deposit semen into the uterine body, so that intracervical insemination was often performed resulting in reduced fertility. The advantage of deep uterine insemination, whether bicornual or unicornual, is that it favors the deposition of semen nearer to the uterotubal junction and thus reduces the incidence of cervical deposition. This review updates the literature on the ideal site of semen deposition, including cervical, uterine body, cornual and intraperitoneal. Also analyzed are the effects of right vs. left side activity of the female reproductive tract on the optimum site of semen deposition as it affects fertilization. Finally, the question of whether the clinical training of inseminators should be reevaluated is discussed.

Insemination of heifers with sexed sperm

Data from inseminating 1,000 heifers consecutively with sexed sperm and 370 heifers with control sperm in 11 small field trials are summarized. Semen was from 22 bulls of unknown fertility of various beef and dairy breeds, and 6 inseminators participated. Freshly collected sperm were sexed using a MoFlo flow cytometer/cell sorter after staining sperm with the DNA-binding dye Hoechst 33342; the principle is that the bovine X chromosome has 3.8% more DNA than the Y chromosome. Accuracy approaching 90% males or females was achieved. There was little difference in pregnancy rates between sexed, unfrozen and sexed, frozen sperm. In 5 of 6 field trials, there was little difference in pregnancy rates between insemination doses of 1.0 to 1.5 x 10(6) versus 3.0 x 10(6) sexed, frozen sperm. In the most recent trials, pregnancy rates with sexed, frozen sperm were within 90% of unsexed, frozen controls that had 7 to 20 times more sperm/insemination dose; however, in a few trials, control pregnancy rates were substantially higher than with low doses of sexed sperm. There were too few inseminations per bull to test bull differences in pregnancy rates rigorously. Insemination of sexed, frozen sperm bilaterally into the uterine horns produced pregnancy rates similar to insemination into the uterine body in 4 of 5 field trials. Pregnancy rates among inseminators did not differ significantly. There was no excess embryonic death between 1 and 2 months of gestation with pregnancies from sexed sperm, and very few abortions occurred between 2 months of gestation and term. Although rigorous epidemiological studies remain to be done, calves resulting from sexed sperm appear to exhibit no more abnormalities than controls.