10 Pregnancy rates following artificial insemination or embryo transfer in lactating Holstein cows

2020 ◽  
Vol 32 (2) ◽  
pp. 130
Author(s):  
M. Oliveira ◽  
R. Santos ◽  
R. Chebel ◽  
D. Demetrio
Keyword(s):  
Embryo Transfer ◽  
Embryo Development ◽  
Artificial Insemination ◽  
Early Embryo ◽  
Pregnancy Rates ◽  
Holstein Cows ◽  
Genetic Merit ◽  
Excessive Heat ◽  
The Difference ◽  
June July

Excessive heat affects the fertility of high production lactating cows, and reduced pregnancy rates (PR) are observed during summer and early fall. Embryo production programs are used to produce more calves from high genetic merit animals, but could it also increase fertility by bypassing all the negative variables affecting the embryo development before Day 7 (oocyte development, ovulation, fertilization, early embryo development)? The data from AIs and embryo transfers (ET) between June 2017 and May 2019 were analysed. June, July, August, September, and October were called critical months (first-service AI conception rate dropped below 44%). The cows were located at Maddox Dairy in Riverdale, CA, USA, a Holstein herd that milks 3500 cows with a 305-day mature-equivalent milk production of 12 800 kg. First- and second-lactation cows were enrolled in a Presynch-Ovsynch oestrus-synchronization program and scheduled for the first AI at 86 days after calving or to receive an embryo 7 or 8 days after the expected heat. The embryos were produced invivo or invitro from Holstein donors and were transferred fresh or frozen. Blood was sampled on Day 30 after expected heat day (23 days after embryo transfer), and pregnancy was detected by the IDEXX PAG Bovine Pregnancy Test. Table 1 summarises the results, where ET PR% is the number of pregnant cows divided by the number of cows that received and embryo. All the cows synchronized for AI were bred, but only cows with the presence of a corpus luteum (CL) on ET day received an embryo. The presence of a CL was not detected in 28.7% (471/1642) of the cows (32.2% in the critical months and 25.7% in the others). Unfortunately, we could not detect the presence of a CL by ultrasonography every time we transferred embryos, so the nonovulation rate might be overestimated. The cows without a CL were considered open and used to calculate the adjusted PR (AdjPR%). Embryo transfer PR is superior to that of AI, especially during the critical months. Fresh invivo embryos have the most impact. When the cows without CLs are considered open, the difference between AI and ET is still evident for fresh invivo embryos. Besides producing animals with higher genetic merit, depending on the type of embryo used, ET can increase fertility in lactating Holstein cows, especially during the critical months. The other benefit of using ET is that cows that do not ovulate are synchronized right away, which is not the case for AI cows. Table 1.AI×embryo transfer in lactating Holstein cows1 from June 2017 to May 20192 Item Critical months (June to October) Other months (November to May) All year %PR n Adj PR% n %PR n Adj PR% n %PR n Adj PR% n Artificial insemination 41.2% 896 41.2% 896 47.7% 1767 47.7% 1767 45.5% 2663 2663 Fresh invivo embryo 62.7% 373 47.5% 493 69.5% 262 55.3% 329 65.5% 635 50.6% 822 Frozen invivo embryo 59.3% 221 44.8% 292 59.4% 256 47.3% 322 59.3% 477 46.1% 614 IVF fresh embryo 47.9% 167 36.2% 221 54.0% 363 43.0% 456 52.1% 530 40.8% 677 Total embryos 58.5% 761 44.2% 1006 60.2% 881 47.9% 1107 59.4% 1642 46.1% 2113 1Lactating Holstein cows, first and second lactation, first service, Presynch-Ovsynch, 85 DIM. 2PR%=the number of pregnant cows divided by the number of cows that received and embryo; AdjPR%=adjusted pregnancy rate.

scholarly journals Genetic merit for fertility traits in Holstein cows: VI. Oocyte developmental competence and embryo development

2019 ◽  
Vol 102 (5) ◽  
pp. 4651-4661 ◽  
Author(s):  
S.G. Moore ◽  
S.B. Cummins ◽  
S. Mamo ◽  
P. Lonergan ◽  
T. Fair ◽  
...  
Keyword(s):  
Embryo Development ◽  
Developmental Competence ◽  
Holstein Cows ◽  
Genetic Merit ◽  
Oocyte Developmental Competence ◽  
Fertility Traits

Artificial insemination of farmed red deer (Cervus elaphus)

1990 ◽  
Vol 51 (3) ◽  
pp. 613-621 ◽  
Author(s):  
P. F. Fennessy ◽  
C. G. Mackintosh ◽  
G. H. Shackell
Keyword(s):  
Pregnancy Rate ◽  
Cervus Elaphus ◽  
Artificial Insemination ◽  
Red Deer ◽  
Pregnancy Rates ◽  
Progesterone Treatment ◽  
Serum Gonadotropin ◽  
The Difference ◽  
Fixed Times ◽  
In Pregnancy

ABSTRACTSix experiments involving the artificial insemination (AI) of a total of 300 female red deer (hinds) with frozen-thawed red deer semen (collected by electro-ejaculation) were conducted over 3 years. Insemination took place at fixed times following various oestrous synchronization procedures using progesterone withdrawal and treatment with pregnant mare's serum gonadotropin (PMSG). In the 1st year, the experiments evaluated basic AI techniques in which pregnancy rates were 45% in 20 hinds receiving two inseminations per vaginam (PV) and 56% in 27 hinds inseminated by the laparoscopic intrauterine method (IU). In the 2nd year, the experiments involved comparisons of the progesterone regime, one or two PV inseminations, and the timing of a single PV insemination. There was no effect of replacement of the progesterone device after 9 days and withdrawal 3 days later compared with the use of one device for the whole period in two experiments. The pregnancy rate for a double PV insemination was significantly higher than for a single PV insemination (58 and 34%; P < 0·05) and there was also a small effect of timing of insemination relative to the synchronization treatment. In the 3rd year all hinds were inseminated by the IU method. The experiments involved a comparison of various times of AI following progesterone withdrawal and a comparison of the progesterone regime. The overall pregnancy rate for 63 hinds inseminated was 56% with no difference between three times of insemination (48, 52 and 55 h). In the second experiment, the difference in pregnancy rate between treatment with progesterone for 15 days and 12 days (44 and 72% for 18 hinds per group) was not significant, but the interaction between the length of progesterone treatment and insemination time was significant (P < 0·05), with the 12-day progesterone/55 h insemination giving a much higher pregnancy rate than the 15-day/55 h insemination (89 and 20% respectively). Although no experiments involved direct comparisons of the routes of insemination, overall pregnancy rates were 56% for IU, 53% for double PV and 35% for single PV inseminations.

scholarly journals The incompletely fulfilled promise of embryo transfer in cattle—why aren’t pregnancy rates greater and what can we do about it?

2020 ◽  
Vol 98 (11) ◽  
Author(s):  
Peter J Hansen
Keyword(s):  
Embryo Transfer ◽  
Artificial Insemination ◽  
Blastocyst Stage ◽  
Pregnancy Rates ◽  
Bovine Embryos ◽  
Uterine Receptivity ◽  
Stage Of Development ◽  
Stage Embryo ◽  
Repeat Breeder ◽  
In Pregnancy

Abstract Typically, bovine embryos are transferred into recipient females about day 7 after estrus or anticipated ovulation, when the embryo has reached the blastocyst stage of development. All the biological and technical causes for failure of a female to produce a blastocyst 7 d after natural or artificial insemination (AI) are avoided when a blastocyst-stage embryo is transferred into the female. It is reasonable to expect, therefore, that pregnancy success would be higher for embryo transfer (ET) recipients than for inseminated females. This expectation is not usually met unless the recipient is exposed to heat stress or is classified as a repeat-breeder female. Rather, pregnancy success is generally similar for ET and AI. The implication is that either one or more of the technical aspects of ET have not yet been optimized or that underlying female fertility that causes an embryo to die before day 7 also causes it to die later in pregnancy. Improvements in pregnancy success after ET will depend upon making a better embryo, improving uterine receptivity, and forging new tools for production and transfer of embryos. Key to accelerating progress in improving pregnancy rates will be the identification of phenotypes or phenomes that allow the prediction of embryo competence for survival and maternal capacity to support embryonic development.

11 Invivo-derived embryo pregnancy rates at Maddox Dairy from 2008 to 2018

2020 ◽  
Vol 32 (2) ◽  
pp. 130
Author(s):  
D. Demetrio ◽  
A. Magalhaes ◽  
M. Oliveira ◽  
R. Santos ◽  
R. Chebel
Keyword(s):  
Pregnancy Rate ◽  
Embryo Transfer ◽  
Milk Production ◽  
Pregnancy Rates ◽  
The Other ◽  
Lactating Cows ◽  
June July August ◽  
June July ◽  
Management Changes ◽  
July August September

Maddox Dairy, located in Riverdale, CA, USA, is a Holstein herd that milks 3500 cows with a 305-day mature-equivalent milk production of 12 800 kg, and they have been producing high genetic animals by embryo transfer (ET) since the early 1980s. Invivo-derived embryos from Holstein donors were transferred fresh (grade 1 or 2) or frozen (grade 1), at morula (4), early blastocyst (5), or blastocyst (6) stage, to virgin heifers (VH, natural oestrus, 13-15 months old) or lactating cows (LC, Presynch-Ovsynch, 86 days in milk, first or second lactation) 6 to 9 days after oestrus. Pregnancy diagnosis was done by transrectal ultrasonography at 32-46 days in VH and by the IDEXX PAG test at 30 days in LC. June, July, August, September, and October were called critical months (first service AI conception rate drops below 44%) and compared with the other months. The data from 32 503 ETs between January 2008 and December 2018 are summarised on Table 1. Pregnancy rates (PR) are lower for LC recipients than for VH. Embryo transfers performed 7 or 8 days after oestrus had higher PR in both types of recipients and embryos, but Day 6 and 9 oestrus are also used with fair results. The season does not seem to affect PR. There is not enough difference in the combination of stage and days from oestrus for invivo-derived embryos. These numbers do not belong to a planned experiment. Several management changes during the years were made, which make it very difficult to apply statistical methods to analyse the data correctly. They are used as a tool to make decisions in an attempt to improve future results. Table 1.Pregnancy rate (PR) of virgin heifers (top) and lactating cows (bottom)-fresh (SH) and frozen (OZ) invivo-derived embryo transfer1 Heat-months SH-ST4 SH-ST5 SH-ST6 SH-All OZ-ST4 OZ-ST5 OZ-ST6 OZ-All PR% n PR% n PR% n PR% n PR% n PR% n PR% n PR% n Heifers 6 d-CM 62 934 66 243 68 69 63 1246 56 473 58 219 62 42 57 734 6 d-OM 62 1623 67 489 69 211 64 2323 56 600 55 296 48 137 55 1033 6 d-T 62 2557 67 732 69 280 63 3569 56 1073 57 515 51 179 56 1767 7 d-CM 64 1506 68 495 67 221 65 2222 60 822 62 340 63 156 61 1318 7 d-OM 66 2723 68 1021 69 510 67 4254 57 1120 59 581 57 231 58 1932 7 d-T 66 4229 68 1516 69 731 67 6476 58 1942 60 921 60 387 59 3250 8 d-CM 65 1348 64 518 67 322 65 2188 59 595 64 258 63 108 61 961 8 d-OM 66 2166 68 886 70 510 67 3562 61 770 60 364 51 130 60 1264 8 d-T 66 3514 67 1404 69 832 66 5750 60 1365 62 622 56 238 60 2225 9 d-CM 60 109 56 43 70 20 60 172 60 5 33 6 50 4 47 15 9 d-OM 58 129 63 57 60 40 60 226 63 16 50 18 75 4 58 38 9 d-T 59 238 60 100 63 60 60 398 62 21 46 24 63 8 55 53 All-CM 64 3897 66 1299 67 632 65 5828 58 1895 61 823 63 310 60 3028 All-OM 65 6641 67 2453 69 1271 66 10 365 58 2506 58 1259 53 502 58 4267 All-T 65 10 538 67 3752 69 1903 66 16 193 58 4401 60 2082 57 812 59 7295 Lactating cows 6 d-CM 54 265 48 86 50 12 53 363 38 141 31 77 50 10 36 228 6 d-OM 49 463 52 203 45 56 50 723 46 101 48 54 59 27 48 182 6 d-T 51 728 51 289 46 68 51 1086 41 242 38 131 57 37 42 410 7 d-CM 54 755 59 274 56 103 55 1137 43 928 48 450 43 192 45 1570 7 d-OM 55 914 66 367 54 109 58 1393 46 1052 45 564 47 353 46 1969 7 d-T 55 1669 63 641 55 212 57 2530 45 1980 46 1014 46 545 45 3539 8 d-CM 63 252 68 82 76 33 65 368 48 219 56 80 42 33 50 332 8 d-OM 61 257 64 161 53 47 61 466 50 191 53 77 56 16 51 284 8 d-T 62 509 65 243 63 80 63 834 49 410 55 157 47 49 50 616 All-CM 56 1272 58 442 60 148 57 1868 44 1288 47 607 43 235 45 2130 All-OM 55 1634 62 731 51 212 56 2582 47 1344 46 695 48 396 47 2435 All-T 55 2906 60 1173 55 360 57 4450 45 2632 47 1302 46 631 46 4565 1ST=stage; CM=critical months (June, July, August, September, and October); OM=other months.

Biological factors affecting subzonal sperm microinjection results

1994 ◽  
Vol 6 (1) ◽  
pp. 63
Author(s):  
L Gianaroli ◽  
MC Magli ◽  
AP Ferraretti ◽  
D Fortini ◽  
E Feliciani ◽  
...  
Keyword(s):  
Embryo Transfer ◽  
Embryo Development ◽  
Fertilization Rate ◽  
Early Embryo ◽  
Male Factor Infertility ◽  
Biological Factors ◽  
Male Factor ◽  
Cleavage Rate ◽  
Early Embryo Development ◽  
Factors Affecting

One hundred and sixteen couples with severe male factor infertility underwent 139 subzonal sperm microinjection cycles. In total, 1343 oocytes were microinjected, resulting in a fertilization rate of 24%, followed by a cleavage rate of 65%. In 26% of the zygotes, fertilization was delayed and embryos derived from these zygotes demonstrated a poor capacity for further growth and implantation. In 102 of 139 cycles (73%) embryo transfer was performed, resulting in 9 pregnancies. This study followed the fate of injected oocytes and early embryo development to investigate biological factors that influence the results of subzonal injection.

87 Effect of Treatment with Nonsteroidal Anti-Inflammatory Drugs (NSAIDs) on Pregnancy Rates of Recipient Alpacas Post-Embryo Transfer

2018 ◽  
Vol 30 (1) ◽  
pp. 183
Author(s):  
H. W. Vivanco-Mackie ◽  
M. D. P. Salazar ◽  
M. Miguel-Gonzales ◽  
C. R. Youngs ◽  
M. Asparrin
Keyword(s):  
Body Weight ◽  
Pregnancy Rate ◽  
Embryo Transfer ◽  
Tolfenamic Acid ◽  
Pregnancy Rates ◽  
Control Group ◽  
Chi Squared ◽  
Effect Of Treatment ◽  
The Difference ◽  
Live Fetus

The aim of the study was to improve the pregnancy rate in recipient alpacas using nonsteroidal anti-inflammatpry druds (NSAIDs) at time of embryo transfer. Because most NSAIDs are non-selective inhibitors of cyclooxygenases, which are the rate-limiting enzymes in the formation of prostaglandins, such treatment could temporarily block the production of prositaglandin F2α (PGF2α) and hence maintain corpus luetum (CL) activity long enough to support embryo development and pregnancy. The experiment was carried out in the Peruvian southern highlands (4,100 m elevation). Thirty-one adult alpaca donors were subjected to superovulation and embryo flushing as described previously (Vivanco-Mackie 2013 Proc. 29th Annu. Mtg. AETE, Istanbul, pp. 43-74; http://www.aete.eu/index.php/publications-aete/proceedings/2013/file). From the collected embryos, 20 grade A embryos were selected and transferred fresh into the recipients of the 2 experimental groups. All embryos were collected and transferred at 6.5 days post-mating of the donors with one embryo transferred per recipient. Recipient alpacas (n = 20) were synchronized and induced to ovulate after a selection made by ultrasonography, selecting as recipients the alpacas with follicles >8 mm and then exposing them to vasectomized males followed by IM injection of gonadotropin-releasing hormone (GnRH, 0.0084 mg of acetate of buserelin). Embryo transfers were made by laparoscopically aided laparotomy 6.5 days after ovulation induction as this method has been demonstrated to be more effective in previous trials compared with transcervical non-surgical transfers. At the time of embryo transfer, the recipients were randomly assigned to 1 of the 2 treatments according to the NSAID injected immediately after embryo transfer: Treatment 1 (10 alpacas) was an IM injection of meloxicam at 0.5 mg/kg of body weight; treatment 2 (10 alpacas) was an IM injection of tolfenamic acid at 3 mg/kg of body weight. At the pregnancy test by ultrasound scanning on Day 58 post-transfer, 30% (3/10) of the recipients had a live fetus in treatment 1, whereas treatment 2 had only 10% (1/10).The difference was not significant (P > 0.05) based on Chi-squared analysis. Th historical pregnancy rate obtained with fresh embryos transferred using the same technique and on the same farm where the comparison between NSAIDs was performed was 28.6% at 58 days post-transfer (Vivanco-Mackie et al. 2015 Reprod. Fertil. Dev. 27, 173 abst). Results suggest that there is no difference between tolfenamic acid and meloxicam in their effect on pregnancy rates in alpacas receiving fresh embryo transfers. Compared with historical data of nontreated recipients, results of the present experiment may indicate that the use of NSAIDs at the time of embryo transfer does not improve pregnancy rates in alpaca fresh embryo recipients. However, additional research studies with greater numbers of recipients and an untreated control group are necessary to confirm the preliminary results of the present study. The study was funded by the ‘INNOVATE PERU’ program of the Peruvian Government.

scholarly journals Effect of estrous detection strategy on pregnancy outcomes of lactating Holstein cows receiving artificial insemination and embryo transfer

2020 ◽  
Vol 103 (7) ◽  
pp. 6635-6646 ◽  
Author(s):  
Odinei Marques ◽  
Anderson Veronese ◽  
Victória R. Merenda ◽  
Rafael S. Bisinotto ◽  
Ricardo C. Chebel
Keyword(s):  
Embryo Transfer ◽  
Artificial Insemination ◽  
Pregnancy Outcomes ◽  
Holstein Cows ◽  
Detection Strategy

scholarly journals Successful transfer of day 10 horse embryos: influence of donor–recipient asynchrony on embryo development

Reproduction ◽  
2010 ◽  
Vol 139 (3) ◽  
pp. 575-585 ◽  
Author(s):  
Sandra Wilsher ◽  
Amber Clutton-Brock ◽  
W R Allen
Keyword(s):  
Embryonic Development ◽  
Embryo Transfer ◽  
Embryo Development ◽  
Growth And Development ◽  
Pregnancy Rates ◽  
Uterine Horn ◽  
Embryo Survival ◽  
Successful Transfer

A total of 78 day 10 horse embryos were transferred non-surgically to recipient mares that had ovulated 9, 7, 6, 5, 4, 3, 2 or 1 day after (negative asynchrony), on the same day (synchronous), or 2 or 4 days before (positive asynchrony) the donor (n=6 or 8 mares per group). Pregnancy rates between 100% (6/6) and 63% (5/8) were seen in recipient mares that were between +2 and −6 days asynchronous. Embryo survival to the heartbeat stage declined in recipients that were −7 days asynchronous and no embryos survived in recipients that were −9 days asynchronous. Irrespective of uterine asynchrony, cessation of embryo mobility and fixation at the base of a uterine horn occurred when the conceptus was ∼17 days old. Conceptus growth and development was slowed when embryos were placed in negatively asynchronous uteri. At the greatest degree of negative asynchrony at which embryos survived to the heartbeat stage, i.e. −7 and −6 days, development of the embryo proper and allantois was retarded. Luteostasis was achieved in recipient mares when day 10 embryos were transferred to recipient mares at any stage of asynchrony between −9 and +2 days with respect to the donor. These results indicate that in the horse, there is a wide window for establishment of pregnancy following embryo transfer to asynchronous recipients. Although progesterone priming of the uterus to a stage equivalent to that of the transferred embryo does not appear to be a prerequisite for embryo survival, it does nonetheless influence embryonic development.

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