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1.
Recently, successful treatment of mares with a history of persistent mating‐induced endometritis (PMIE) with dexamethasone has been reported. As systemic treatment of horses with glucocorticoids should be handled with caution, we tested the hypothesis that treatment with the non‐steroid anti‐inflammatory drug (NSAID) vedaprofen, an inhibitor of cyclooxygenase‐2, may have comparative, positive effects on fertility. Barren mares with a history of repeated PMIE were treated with vedaprofen (n = 8; initially 2 mg/kg bodyweight followed by 1 mg/kg orally twice daily) from 1 day before the first insemination to 1 day after ovulation or left untreated (n = 9). All mares received oxytocin (20 I.E. s.c.) thrice daily. Uterine swabs were collected for bacteriology and cytology. The day after ovulation, fluid accumulation was detected in three control mares and four treated mares (n.s.). The percentage of neutrophils in uterine cytology was significantly increased in comparison to the day before ovulation irrespective of treatment. Pregnancy was confirmed in two of nine mares in the control group and seven of eight mares in the treatment group (p < 0.05). NSAIDs may positively affect fertility in mares with a history of PMIE. 相似文献
2.
Camilla Dooleweerdt Rasmussen Maria Mathilde Haugaard Morten Roenn Petersen Jesper M?ller Nielsen Hanne Gervi Pedersen Anders Miki Bojesen 《Veterinary research》2013,44(1):26
Streptococcus equi subsp. zooepidemicus is the pathogen most commonly isolated from the uterus of mares. S. zooepidemicus is an opportunistic pathogen and part of the resident flora in the caudal reproductive tract. The aim of this study was to investigate whether a genotypically distinct subpopulation of S. zooepidemicus is associated with endometritis in the mare, by genotyping and comparing uterine S. zooepidemicus strains with isolates from the vagina and clitoral fossa. Mares with (n = 18) or without (n = 11) clinical symptoms of endometritis were included. Uterine samples were obtained using a guarded endometrial biopsy punch, whereas a swab was used to recover samples from the cranial vagina and the clitoral fossa. If S. zooepidemicus was present, up to three colonies were selected from each anatomical location (max. 9 isolates per mare). Bacterial isolates were characterized by pulsed-field gel electrophoresis (PFGE) and multilocus sequence typing (MLST). S. zooepidemicus was isolated from the endometrium of 12 mares. A total of 88 isolates were analyzed by PFGE: 31 from the endometrium, 26 from the cranial vagina and 31 isolates from the clitoral fossa. For MLST 21 isolates were chosen. Results demonstrated a higher genetic similarity of the isolates obtained from infectious endometritis compared to isolates obtained from the caudal reproductive tract. In conclusion, we demonstrate for the first time that a genetically distinct group of S. zooepidemicus is associated with infectious endometritis in the mare. 相似文献
3.
N J Digby 《Equine veterinary journal》1978,10(3):167-170
Experimental studies of endometrial smears from 26 normal mares showed that after a period of sexual rest exceeding 7 days smears were generally free from inflammatory cells. Smears from 9 mares showing signs of persistent endometritis contained inflammatory cells in 91 per cent while bacterial culture was positive in only 45 per cent. Smears were also taken from 242 Thoroughbred mares as a routine procedure in 1977. It was concluded that endometrial cytology provides a better guide to uterine inflammation than bacteriology. The routine clinical use of endometrial cytology is recommended to aid the interpretation of both positive and negative bacterial cultures from the cervix. 相似文献
4.
One hundred and fifty-four mares were inseminated with fresh semen either during the pre- or post-ovulatory periods at different intervals relative to ovulation: 36-24 h (n = 17) and 24-0 h (n = 30) before ovulation; 0-8 h (n = 21), 8-16 h (n = 24), 16-24 h (n = 48) and 24-32 h (n = 14) h after ovulation. All mares received the same routine post-mating treatment consisting of an intrauterine infusion with 1 litre of saline and antibiotics followed 8 h later by an intravenous administration of oxytocin. Artificial inseminations (AI) from 36 h before ovulation up to 16 h post-ovulation were performed with transported cooled semen. While there was no data available for inseminations later than 16 h, data from natural mating after 16 h post-ovulation were included. Pregnancy rate (PR) of mares inseminated 36-24 h (29.4%) was significantly lower (p < 0.05) than mares inseminated 24-0 h before ovulation (60%), 0-8 h (66.7%) and 8-16 h (70.1%) post-ovulation. Embryo loss rate (ELR) was highest in mares mated 24-32 h after ovulation (75%). PR of mares mated 16-24 h post-ovulation (54.1%) did not differ significantly from any other group (p > 0.05); however, the ELR did increased markedly (34.6%) compared with inseminations before 16 h post-ovulation (<12%). At ≥ 30 days post-ovulation, PR of mares mated 16-24 h after ovulation (35.4%) was significantly lower than mares mated 0-16 h after ovulation (62%). Good PR with acceptable ELR can result from inseminations within 16 h of ovulation, at least with this specific post-mating routine treatment. 相似文献
5.
Camila Silva Costa Ferreira Rita de Cássia Lima Morais Amanda Bricio Pereira de Andrade Mário Felipe A. Balaro José Antônio Silva Ribas Gustavo Mendes Gomes Aline Emerim Pinna 《Reproduction in domestic animals》2020,55(6):747-752
The aim of this study was to evaluate whether the RI and PI values would help in choosing the best embryo recipient, and observe whether CL vascularization would influence P4 production. During the breeding season 2018/2019, the study was conducted using 35 mares, which is used for reference to collect data for the project on the day of embryo transfer. The utilized mares were divided into five groups followed by the day after ovulation, with D0 being the day of ovulation. Therefore, the five groups are as follows: D4—mares that were on the 4th post-ovulation day; D5—mares that were on the 5th post-ovulation day; and doing so successively for D6, D7 and D8. On the day of embryo transfer, the CL of the mares that selected as recipients was evaluated by B-mode and power flow mode ultrasonography and the right and left dorsal branches of the uterine arteries by spectral Doppler ultrasonography. Blood samples were taken on the day of the embryo transfer for a dosage of P4 concentration by radioimmunoassay. No statistical difference was found between the variables when the mares were separated into pregnant and non-pregnant mares, or when they were separated by age groups. When the groups of mares were compared by the day of embryo transfer, the statistical difference was found between the groups D5 × D6 (p = .0053) and D6 × D8 (p = .0036) in RI variable. In PI variable, the statistical difference was found between the groups D4 × D8 (p = .049), D5 × D6 (p = .0446) and D6 × D8 (p = .0024). We conclude that the mares with RI measurement of uterine arteries near 1.0 are correlated to mares with high CL vascularization and elevated P4 concentration. 相似文献
6.
John R. Newcombe Sandra Wilsher Juan Cuervo-Arango 《Reproduction in domestic animals》2023,58(1):141-145
Mares are seasonally polyoestrous breeders. Therefore, the first ovulation of the season, following winter anoestrus, is the only cycle in which mares ovulate without the presence of an old CL from the previous cycle. The objective of this study was to compare the length of oestrous behaviour, and plasma progesterone concentrations during the early post-ovulatory period between mares after the first and second ovulation of the breeding season. Overall, 38 mares and 167 oestrous periods were used in the study. From those, 11 mares were used during the first and subsequent oestrous period to measure and compare the post-ovulatory rise in progesterone concentration, whereas all the mares were used to compare the length of the post-ovulatory oestrous behaviour between the first and subsequent cycles of the breeding season. The persistence of the post-ovulatory oestrus was longer (p < .001) following the first ovulation of the year (median of 52 h) compared with the subsequent ovulations (median of 36 h for second and later ovulations groups; n = 38 mares). The progesterone concentration at any of the four 8 h-intervals analysed (28, 36, 76 and 84 h post-ovulation) was lower (p < .01) following the first versus the second ovulation of the year. By 36 h post-ovulation the progesterone concentration of mares at the second ovulation of the year had passed the threshold of 2 ng/ml (2.1 ± 0.33 ng/ml), whereas in the first cycle it was 1.2 ± 0.13 ng/ml. In conclusion, mares had lower progesterone concentrations in their peripheral circulation and longer persistence of oestrous behaviour following the first ovulation of the year compared with the second and subsequent ovulatory periods of the breeding season. 相似文献
7.
H. Ghasemzadeh-nava F. Ghasemi P. Tajik A. Shirazi 《Journal of Equine Veterinary Science》2004,24(5):188
One hundred eleven mares were examined and selected on the basis of some criteria (history of recent genital discharge and/or abortion, dystocia, retained placenta, rectovaginal rupture and/or failing to conceive after repeated services), rectal palpation, and ultrasound examination of genital tract. The mares were classified in 3 groups (young, middle age and old). During estrus, a specimen was taken by uterine swab and endometrial biopsy. Endometritis was diagnosed and graded on the basis of pathology results and treatment was done on the basis of culture and antibiogram tests. At the first step of treatment, uterine lavage with warm saline followed by intrauterine administration of a specific antibiotic, or povidone iodine solution, was done daily during estrus. If the mare had not responded to the first treatment, in the next steps systemic antibiotic therapy was also added to the mentioned treatment. The results showed that Escherichia coli was the most frequently isolated pathogen and response to the treatments was significantly better in the young mares with category IIA fibrosis of uterine pathology than that of two other groups. It was also found that there is no relationship among age and kind of pathogen to mare endometritis.
Introduction
Bacterial endometritis is the most common cause of subfertility.[1, 2, 3 and 4] In 1992, Kenney argued against the general use of the term “endometritis” to describe the two often quite separate conditions of endometrium: the degenerative changes often associated with age and parity. He suggested the use of the term “endometriosis” instead of the term “chronic degenerative endometritis” (CDE): the inflammatory infection that is divided to “acute endometritis” and “chronic infiltrative endometritis” (CIE). [5]In some mares, the bacteria becomes established and uterine infection develops in which the sources of uterine contamination include coitus, parturition, and reproductive examination.[2, 4 and 6] These mares remain persistently infected and are termed “susceptible” mares, which may have conformation defects such as pneumovagina, uterine pooling, and foaling injuries, which predispose them to endometritis. [7] There are some data indicating that age, parity, and barren years may have important bearing on the breeding prognosis of the mare. [8 and 9] In general, loss of resistance to infection is associated with advancing age and multiparity, factors that are frequently associated with increasing value of mares. [10] By far, Streptococcus zooepidemicus followed by E coli, Pseudomonas aeruginosa, and Klebsiella pneumoniae are the most frequently isolated pathogens,[7 and 10] but there are a few reports that E coli, K pneumoniae, and Corynebacterium spp. are the most frequent isolates.[4 and 11] Endometrial cytology and culture samples often reveal evidence of inflammation and infection. To improve reproductive management of mares in Iran, this study was conducted to assess main causes of mare endometritis and also the relation of age and kind of pathogen to mare endometritis, plus the efficacy of treatment methods in problem mares.Materials and methods
One hundred eleven mares of different breeds (Thoroughbred, Arab, cross-bred, and two native breeds including Kord and Turkaman) from 4 to 26 years of age were examined and selected during April 1996 to June 2001. They had a history of recent genital discharge and/or abortion, dystocia, retained placenta, rectovaginal rupture, and/or failing to conceive after repeated services. The sanitary condition of the foaling boxes was also noted. The mares were classified in three groups according to the age: (1) young (4-9 years old), (2) middle age (10-14 years old), and (3) old age (≥15 years old).Each mare was restrained in a stock. The vulvar discharge and pneuomovagina were recorded if present. Rectal palpation and ultrasound examination of genital tract were done to determine uterine tone and presence of uterine fluid. During the estrus, a double-guarded swab was passed per vagina into the uterus. The swab was kept in contact with the endometrium for a minimum of 20 seconds and was placed in transport media. In the laboratory the swab was cultured as described by Rickets.[12] An endometrial biopsy specimen was also taken, fixed, and processed as described by Rickets. [13] Endometritis was graded as described by Kenny and Doig. [14] Briefly, they are Grade I (Absent), Grade IIA (Mild), Grade IIB (Moderate), and Grade III (Severe). After specifying the causal organism of endometritis, treatment was done on the basis of culture and antibiogram tests as described by Asbury et al, [10] the antibiotics used for treatment were: gentamicin (intrauterine administration, 2-3 g), amikacin (2 g, intrauterine administration), potassium penicillin G (5 million units, intrauterine administration), and chloramphenicol (3 g, intrauterine administration). [10 and 15] A diluted solution of povidone iodine (0.2%) as uterine lavage was also used in cases whose uterine culture results were yeasts. The following protocol was carried out to treat bacterial endometritis at the first step:Uterine lavage with warm saline followed by intrauterine administration of specific antibiotic or povidone iodine (on the basis of uterine culture and antibiotic sensitivity test results) was done daily during estrus. Casslick operation was done in pneuomovaginal cases. In the next estrus, the uteri were examined by rectal palpation and ultrasonography procedure. If they were involuted, had enough tone and had no fluid, the mares were clinically defined to be treated and bred artificially with fresh semen collected from an approved fertile stallion (about 500 million progressive motile sperm) in Kenney's extender. If there was recurrent endometritis or the uterus was not involuted and/or had not enough tone or had some fluid in it, another specimen was taken by a double-guarded swab. On the basis of culture and antibiotic sensitivity test results, mares that had not responded to the first treatment were treated again with the first step protocol plus systemic antibiotic therapy (gentamicin, amikacin, or procaine penicillin G in bacterial-caused endometritis) or just flushed the uterus with saline and 0.2% povidone iodine solution (in yeast-caused endometritis and/or endometriosis). This treatment was also carried out daily during the estrus. Some of the mares that had not responded to the second treatment protocol were treated again (based on uterine culture and antibiotic sensitivity test results) for one to two times more in the next estrus phases as in the second step. The data were analyzed by χ2 test.Results
Table 1 shows the pathogens isolated in three successive cultures from the uteri of the mares. Among 197 swabs were taken from the uteri of 111 mares, the cultures were positive in 175 instances in which the mixed organisms were isolated in 20 cases. The interesting point in these 3 successive cultures was the persistence of one Klebsiella infection detected in a mare belonging to the second group, in the all-performed treatments. The isolated P aeruginosa in a mare belonging to the third group had the same result. The combination of Candia albicans with E coli and/or E coli with Enterobacteriaceae were the most common feature of mixed micro-organisms isolated in the culture plates. 相似文献8.
Persistent purulent endometritis in a mare was attributed to an unclassified species of Corynebacterium. Following intrauterine infusions of 20% betadine for 5 days the purulent vulval discharge ceased and the mare appeared clinically normal. Based on histological examination of endometrial biopsy samples, the severe acute inflammatory reaction had largely resolved 2 days after therapy. Three maiden mares considered resistant to bacterial endometritis received single intrauterine inoculations of 1.8 X 10(9) colony-forming units of the Corynebacterium species. The uterine response was followed by vaginal speculum examinations, uterine cultures and cytology, and endometrial histology. After an acute inflammatory reaction, each mare had recovered completely within 2 weeks. Most rapid recovery occurred in the mare in estrus at the time of inoculation. Subsequent secondary infections were detected in two mares. The uncertainty of correlations between results obtained by various diagnostic techniques emphasized the problems associated with each. This report illustrates the concept that endometritis in individual mares may relate more to as yet unidentified "mare factors" controlling uterine defense than to primary invasion by bacteria. 相似文献
9.
EM Woodward M Christoffersen J Campos DW Horohov KE Scoggin E Squires MHT Troedsson 《Reproduction in domestic animals》2013,48(4):554-561
The first objective of this study was to evaluate intrauterine nitric oxide (NO) and endometrial inducible NO synthase (iNOS) in mares susceptible or resistant to persistent breeding‐induced endometritis (PBIE) within 24 h after breeding. Mares susceptible (n = 6) or resistant (n = 6) to PBIE were inseminated over five cycles, and uterine secretions and endometrial biopsies were collected before and 2, 6, 12 and 24 h after insemination. Uterine secretions were analysed for NO and biopsies were analyzed for iNOS expression. A second experiment evaluated the effect of treatment with dexamethasone or mycobacterial cell wall extract (MCWE) on uterine NO production and endometrial iNOS mRNA expression. Six susceptible mares were inseminated over three cycles with (i) killed spermatozoa without treatment (control), (ii) killed spermatozoa with 50 mg of dexamethasone IV or (iii) MCWE IV 24 h prior to insemination with killed spermatozoa. Six resistant mares were inseminated with killed spermatozoa as a control. Six hours after breeding, uterine biopsies and secretions were collected and evaluated for NO and iNOS mRNA. In Experiment 1, resistant mares had an increase in iNOS mRNA expression 2 h post‐breeding compared to baseline (p = 0.045), 12 h (p = 0.014) and 24 h (p = 0.001). Susceptible mares had higher expression 2 h compared to 6 h (p = 0.046). No differences were observed in mRNA or protein expression of iNOS between resistant and susceptible mares. Resistant mares had a relatively steady amount of total intrauterine NO over 24 h, while susceptible mares had an increase over time, with a significantly higher increase in total NO than resistant mares at 6 (p = 0.04) and 12 h (p = 0.032). In Experiment 2, no differences were observed for iNOS mRNA expression. Susceptible mares had increased NO when compared to resistant mares (p = 0.008) and MCWE decreased NO (p = 0.047). 相似文献
10.
K. Pool-Anderson MS J.M. Wilson PhD G.W. Webb PhD D.C. Kraemer PhD DVM G.D. Potter PhD J.W. Evans PhD 《Journal of Equine Veterinary Science》1988,8(2)
Estradiol and progesterone concentrations were evaluated from diestrous embryo transfer recipient mares (5 to 14 days post-ovulation) which were treated with an exogenous hormone regimen. Upon detection of the donor mare's ovulation (0 hours), 10 mg PGF2α was given to the recipient mare; at 12, 24 and 36 hours 20 mg estradiol cypionate; at 48 hours, 500 mg progesterone in oil and then 22 mg altrenogest at 60, 72 and 96 hours. Altrenogest (22 mg/day) was continued until end of the trial (detection of a fetal heart beat). Embryos were transferred non-surgically 6 or 7 days after the start of treatment.Plasma samples were evaluated over three periods; period 1-between recipient mare ovulation and prior to PGF2α period 2-between PGF and embryo transfer and period 3-post-transfer. During periods 2 and 3, estradiol was higher (P<.05) for mares which were 10 to 14 days post-ovulation (late diestrous) as compared to mares which were 5 to 9 days post ovulation (mid-diestrous) when treatment began. Progesterone concentrations were higher (P<.05) for the mid-diestrous mares in the same periods. The pregnancy rate was higher for the late diestrous mares than the mid-diestrous mares (58% (7/12) vs 10% (1/10)). However, no difference (P>.05) was detected in estradiol or progesterone in the late diestrous mares which were pregnant or open. During period 2, estradiol was higher (P<.05) in the pregnant than open mares. Whereas, during period 3, progesterone was higher (P<.05) in the open mares.These data suggest that estradiol is important for the establishment of pregnancy in the mare. Furthermore, hormone treatment developed in this study appears to have some potential in synchronization of diestrus mares to be used as embryo recipients. 相似文献
11.
Efficiency of uterine fluid cytology in the diagnosis of subclinical endometritis in the water buffalo (Bubalus bubalis) 
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下载免费PDF全文 SC Gahlot S Kumar A Kumaresan S Chand RK Baithalu S Lathika TK Patbandha SS Lathwal TK Mohanty 《Reproduction in domestic animals》2017,52(3):513-516
This study compared endometrial cytology vis‐a‐vis uterine fluid cytology for assessment of uterine health in clinically normal and subclinical endometritis (SE)‐affected buffaloes. Uterine fluid samples and endometrial samples were collected from the buffaloes (n = 38) at oestrus using blue sheath and cytobrush, respectively. The smears were stained with Field stain for 3 minutes, and a minimum of 400 cells were counted in each smear for determination of the percentage of polymorphonuclear (PMN) leucocyte. The incidence of subclinical endometritis, based on the cytobrush cytology, was 23.08%. The correlation between cytobrush cytology with uterine fluid cytology was positive and significant (r = .37; p = .02). The ratio of PMN leucocyte in cytobrush cytology to uterine fluid cytology was 1:2.4. ROC analysis revealed that the threshold value of 6.16% PMN leucocyte in uterine fluid cytology showed a diagnostic sensitivity and specificity of 100% in differentiating normal from SE‐affected buffaloes. In conclusion, collection of uterine fluid was easier compared to collection of endometrial samples using cytobrush and the percentage of PMN leucocyte in uterine fluid cytology can be used as a tool for diagnosis of subclinical endometritis in buffaloes. 相似文献
12.
Endometritis is accepted as a major hindrance to achieve optimal reproductive efficiency in mares. The objective of the present study was to evaluate the therapeutic efficacy of combined therapy of immunomodulator and ecbolic as an alternative stand-alone therapy for mares with persistent endometritis. On the basis of history, culture, endometrial cytology, and per rectal and/or ultrasonographic genital examinations, 76 subfertile mares were selected and assigned to three age groups and four treatment (G-1, 2, 3) and control (G-4) groups. At estrus, all the mares were bred once naturally. Thereafter, the mares of G-1 (n = 28) were aseptically treated at 6-hours after natural service with intrauterine infusion (in 50 mL normal saline solution) of 100 μg of Escherichia coli lipopolysaccharide (LPS). Additionally, these mares received two injections of 20 IU of oxytocin (IV) at 12 and 24-hours after infusion. Mares in group G-2 (n = 11) were treated with LPS as mares of G-1, whereas mares in G-3 (n = 12) received oxytocin injections only. The mares of G-4 (n = 23) did not receive any treatment. Pregnancy rates at day 21 and foaling rates were higher (P < .001) in group G-1 than in G-4. In G-1, higher percentage of mares at ages 6–10 years conceived and foaled than mares aged ≥16 years. On re-swabbing of mares that remained nonpregnant, the majority of G-1 and G-2 mares demonstrated sterile cultures and negative cytology, whereas uterine inflammation persisted in mares of G-3 and G-4. In conclusion, the combined therapy was effective for the elimination of persistent endometritis and improved reproductive performance of subfertile mares. 相似文献
13.
Abstract AIM: To compare the efficacy of oxytocin given once daily, either I/V or I/M, on Days 7–14 post-ovulation, on the expression of oestrus in mares through to 65 days post-ovulation. METHODS: Eighteen mares of various breeds that were displaying normal oestrous cycles were randomly assigned to one of three treatment groups on the day of ovulation (Day 0), detected using transrectal ultrasonography. Mares in the control group (n = 6) were given 1 mL saline I/V; mares in the I/V and I/M groups (n = 6 per group) were injected with 10 IU oxytocin I/V and I/M, respectively. All treatments were given once daily on Days 7–14. Mares were teased by a stallion three times per week, up to 65 days post-ovulation, to detect oestrous or dioestrous behaviour. Ovarian follicular and luteal activity were monitored using transrectal ultrasonography three times weekly, and daily when a follicle >30 mm diameter was present until ovulation. Blood samples were collected weekly for analysis of concentrations of progesterone in serum. Prolonged dioestrus was defined as a period of >30 days of dioestrous behaviour after Day 0, confirmed by detection of corpora lutea and concentrations of progesterone in serum >4 nmol/L. RESULTS: Overall, 8/18 (44%) mares showed prolonged dioestrus. These included 2/6 (33%) mares in the control group, compared with 5/6 (83%) and 1/6 (16%) mares in the I/V and I/M groups, respectively (p = 0.11). The median duration of the first dioestrus was longer for the I/V group (64 (min 16, max 66) days) compared with the control group (18 (min 12, max 64) days) (p = 0.05), but was not different between the control group and the I/M group (16 (min 13, max 65) days) (p = 0.57). For all mares there was strong agreement between teasing behaviours, ultrasonographic assessment of ovarian activity, and concentration of progesterone in serum. CONCLUSIONS AND CLINICAL RELEVANCE: This study found that low doses of oxytocin did not increase the proportion of mares with prolonged dioestrus, compared with controls, although I/V oxytocin did increase the median duration of dioestrus. The results must be interpreted with some caution as group numbers were small, and a variety of breeds were used. Further investigation of oxytocin given I/V may be warranted as a potential method of oestrus suppression in mares exhibiting oestrous cycles that is low cost, safe and well-tolerated, and potentially reversible with prostaglandin. 相似文献
14.
S. Barbacini DVM D. Necchi DVM G. Zavaglia DVM E. L. Squires PhD 《Journal of Equine Veterinary Science》2003,23(11):493-496
Uterine fluid accumulation has been reported after insemination or natural breeding of mares. This retrospective study examined the factors affecting the incidence of uterine fluid after insemination of frozen semen. Specifically, this study determined the association between mare age, reproductive status, fluid accumulation, and pregnancy rates in mares. Records were available from 283 warmblood mares throughout 496 cycles. Mares were divided into maiden, foaling, and barren and age groups of 3 to 9, 10 to 16, and more than 16 years. Mares were inseminated only once with frozen semen within 4 to 8 hours before or after ovulation. Ultrasound examinations were performed 12 to 18 hours after insemination. A depth of at least 20 mm of fluid was considered significant. Mares with less than 20 mm were treated with oxytocin, and those with more than 20mm of fluid were given oxytocin and uterine lavage. Pregnancy determination was performed at 14 to 16 and 30 to 50 days after ovulation. Fluid level of more than 20 mm was recorded in 25% of the cycles. Barren mares and aged mares (10-16 and > 16 years) had a higher incidence of uterine fluid accumulations. Per-cycle pregnancy rate was lower (45%) in mares with uterine fluid than in mares without uterine fluid (51%). This difference was primarily due to the reduction in fertility of mares who were older than 16 years and retained fluid after insemination. Apparently, oxytocin and lavage treatments provided acceptable fertility in the other groups of mares that had uterine fluid.
Introduction
Use of equine frozen semen is accepted by the majority of horse registries. According to several field studies,[1, 2, 3, 4 and 5] insemination of frozen semen has resulted in acceptable pregnancy rates. Postbreeding fluid accumulation is a physiologic inflammation that clears the uterus of foreign material such as excess spermatozoa, seminal plasma, bacteria, and extenders. [6, 7, 8, 9 and 10] Uterine fluid can be easily diagnosed with ultrasonography. [10, 11 and 12] Persistent postbreeding uterine fluid has been associated with a decrease in fertility after natural mating or artificial insemination (AI) of fresh semen. [11, 12 and 13] Predisposing factors to persistent fluid accumulations are reduced myometrial contractions, poor lymphatic drainage, large overstretched uterus, and cervical incompetence. [7, 14 and 15] Normal mares are able to expel uterine fluid quickly after inseminations, whereas susceptible mares accumulate fluid in their uterine lumen for more than 12 hours after breeding or insemination. [10]It is commonly stated that insemination with frozen semen leads to greater post-AI fluid accumulation than insemination with fresh or cooled semen or after natural mating. Apparently, there is only 1 controlled study on this comparison.[7] The authors reported that infusion of frozen semen resulted in a greater inflammatory response than natural breeding. In a field study, [16] 16% of mares naturally mated had persistent postbreeding fluid accumulations compared with a 30% rate reported for mares inseminated with frozen semen. [1 and 2] More recently, Watson et al. [17] reported a postbreeding fluid accumulation rate of 16%, which is identical to that reported for natural mating. [16] It is difficult to compare studies because details of mare selection and insemination or breeding frequencies are not always reported. Obviously, a higher proportion of barren and aged mares in a study would increase the incidence of postbreeding fluid accumulation. [1 and 2]The study presented herein was a retrospective study designed to determine the incidence of postbreeding fluid accumulation in a large number of mares inseminated with frozen semen. Associations were determined between mare age, reproductive status and fluid accumulation, and pregnancy rate in mares with and without uterine fluid accumulation.Materials and methods
Mares
Records were available from 283 warmblood mares inseminated with frozen semen at the Cristella Veterinary Clinic in Italy during 1998 to 2001. Mares ranging in age from 3 to 20 years were inseminated with semen that was frozen in 10 centers and was from 34 stallions. The broodmare population was subdivided into 3 reproductive groups: 89 maiden mares (mean age, 7.2 years), 106 foaling mares (mean age, 9.4 years), and 87 barren mares (mean age, 11.9 years). Maiden mares older than 7 years were selected with biopsy scores of 1 or 2 only. Barren mares were open for no more than 2 consecutive seasons and had negative cytology and bacteriology scores. Age groups were divided as follows: 3 to 9 years (n = 132), 10 to 16 years (n = 137) and older than 16 years (n = 14). Data from 496 cycles were used. Distribution of the estrous cycles was 172, 157, and 167 in the maiden, foaling, and barren groups, respectively; and 224, 244, and 28 in the youngest, intermediate, and oldest groups, respectively.Mare reproductive management and artificial insemination protocol
During estrus, all mares underwent a daily ultrasound examination with a 5-mHz transrectal probe (SA 600 Vet; Medison Inc., Seoul, South Korea) until 1 or more 35-mm ovarian follicles were detected. Ovulation was then induced by the intravenous administration of 2000 IU of human chorionic gonadotropin (hCG). Ultrasound examination was performed 12 hours after hCG treatment and then every 4 to 8 hours until ovulation occurred. Mares were inseminated only once within a period of 4 to 8 hours before or after ovulation. The semen used was thawed according to the distribution center's instructions and had the following minimum post-thaw quality requirements: not less than 200 × 106 progressively motile spermatozoa per dose and a minimum of 30% progressive spermatozoal motility. Foaling mares were not inseminated at their first postpartum (“foal heat”) estrous period, because pregnancy rates are recognized to be lower than during the subsequent estrous periods.[18] During the first postpartum estrus, ovarian ultrasound scan examinations were performed every 2 to 3 days until an ovulation was detected. A prostaglandin F2α injection was given 5 days later to short-cycle the mare.Postinsemination monitoring
An ultrasound examination of the reproductive tract was performed 12 to 18 hours after insemination to detect any intrauterine fluid accumulation. The presence and depth of intrauterine fluid was recorded. Twenty millimeters or more of grade II or III intrauterine fluid[19] was recorded as a significant amount of fluid. Mares with less than 20 mm of fluid were treated with an intravenous injection of 20 IU oxytocin. For mares with more than 20 mm of fluid, oxytocin was administered, and the uterus was flushed daily with buffered saline solution: 1-L aliquots were infused and recovered until the recovered fluid was clear. In these mares, oxytocin treatment was repeated up to 3 times daily. Post insemination treatments were performed for no more than 4 days after ovulation had occurred.Pregnancy diagnosis was performed with ultrasound at 14 to 16 days after ovulation. Scans were then repeated at 30 and 50 days of gestation to confirm the presence in the uterus of an apparently healthy developing conceptus.Statistical analysis
χ2 Analysis was used to determine the effect of reproductive status and age on the incidence of fluid accumulation. In addition, the influence of persistent uterine fluid accumulation on pregnancy rates per cycle was determined for each reproductive class and age by using χ2 analysis.Results
The per-cycle pregnancy rate at 14-16 days after ovulation was 49.3% (245/496 cycles). By the end of the season, 245 of 283 mares (86.5%) were confirmed pregnant. Fluid level of at least 20 mm (grade II or III) was recorded in 126 of the 496 cycles (25.4%). Barren mares had a higher (P < .05) incidence of postbreeding fluid accumulation (64/167; 38.3%) than maiden (34/172; 19.7%) and foaling (28/157, 17.8%; Table 1) mares. The incidence of fluid accumulation was also higher in mares older than 16 years (19/28; 67.8%) than those aged 10 to 16 years (69/244; 28.2%) and 3 to 9 years (38/224; 17%). The incidence of uterine fluid was also higher (P < .05) for mares aged 10 to 16 years than those aged 3 to 9 years (Table 2). Overall, the per-cycle pregnancy rate was lower (P < .05) for mares with post-AI fluid accumulations than for those with no uterine fluid or only a small quantity of fluid (57/126, 41.9% vs 188/360, 56.2%). Pregnancy rates were similar (P > .05) for mares with or without uterine fluid when comparisons were made within maiden and barren mare groups. However, more foaling mares became pregnant when no fluid was detected after insemination. Pregnancy rate for this group (68.1%) was higher than that for maiden (44.2%) and barren (44.6%) mares (Table 3). Older mares with uterine fluid accumulations had a lower per-cycle pregnancy rate (36.8%) than mares in the same group but without fluid. Surprisingly, if no fluid was detected, the highest pregnancy rates were in mares older than 16 years ( Table 4). 相似文献15.
Marcelo A. Couto Med. Vet. John P. Hughes DVM 《Journal of Equine Veterinary Science》1984,4(6):265-273
This paper illustrates and describes the findings obtained from cervical and uterine cytology smears in the mare. Cervical/endometrial cytology is a simple technique that provides valuable information to the clinician regarding the existence of an acute or active endometritis. The most frequent observation is the presence of neutrophils. Chronically infected/inflamed mares with some degree of inflammatory cellular infiltration can also be identified on the cytology smear by the presence of neutrophils, macrophages and lymphocytes. Microorganisms are sometimes found with either acute or chronic endometritis.
This technique is not a substitute for uterine culture and biopsy. The correct identification of bacteria should be based on the cultural characteristics of the microorganisms. 相似文献
16.
Ryan A. Ferris Julia K. VeirMichael R. Lappin DVM PhD DACVIM Patrick M. McCue DVM PhD DACT 《Journal of Equine Veterinary Science》2014
Microbial culture from a double-guarded culture swab is commonly used to diagnose infectious endometritis. The objective of this study was to develop a quantitative polymerase chain reaction (qPCR) assay to detect a broad range of bacteria from equine uterine samples. Twenty-seven mares with a clinical history of endometritis had a double-guarded culture swab collected for analysis by qPCR and microbial cultures. An additional 12 mares had a uterine biopsy sample collected for qPCR analysis, microbial culture, and histopathology. Subsequently, a double-guarded culture swab for microbial culture and a cytology brush sample were also collected. The qPCR assay detected bacterial DNA in nine of 27 mares from a double-guarded swab and six of 12 mares from an endometrial biopsy. Positive microbial growth was detected in nine of 27 mares and four of 12 mares from a double-guarded culture swab. Bacterial DNA was detected in two of 27 mares and two of 12 mares without subsequent microbial growth. The simple presence of an organism's DNA allows for detection by nonculture-based systems, both live and dead organisms can be identified. In conclusion, the qPCR assay was determined to be a sensitive diagnostic technique for identifying pathogens associated with infectious endometritis. The primary application of the qPCR assay is detection of potential pathogenic bacteria in the uterus of a mare suspected of having infectious endometritis when a traditional microbial culture is negative. Further work is warranted to determine if mares positive for bacterial DNA and negative for microbial culture are affected clinically. 相似文献
17.
Kalpokas I Perdigón F Rivero R Talmon M Sartore I Viñoles C 《Acta veterinaria Scandinavica》2010,52(1):66
Background
Intrauterine infusions have been widely used for the treatment of endometritis in the mare. Nevertheless, their consequences on endocrine and endometrial molecular aspects are unknown. We studied the effect of a 1% povidone-iodine solution intrauterine infusion on progesterone levels, endometrial histology and estrogen (ERα) and progesterone (PR) receptor distribution by immunohistochemistry.Methods
Fourteen healthy mares were used in this study. Estruses were synchronized and seven mares were treated with intrauterine infusions at days 0 and 2 post ovulation of two consecutive estrous cycles. Uterine biopsy samples were taken on days 6 and 15 post ovulation.Results
The treatment did not induce an inflammatory response indicating endometritis, neither affected the ERα. However, it reduced the percentage of PR positive cells (PPC) on day 6 (deep glandular epithelium, control: 95.7 vs. infused: 61.5, P < 0.05). Treated mares tended to have lower progesterone levels on day 2 (3.9 ng/ml vs. 6.6 ng/ml, P = 0.07), and higher levels on day 15 compared with controls (4.4 ng/ml vs. 1.3 ng/ml, P = 0.07).Conclusion
a 1% povidone-iodine infusion during days 0 and 2 post ovulation in healthy mares did not induce histological changes indicating endometritis, but altered progesterone concentrations and reduced the expression of endometrial PR at day 6 without affecting the ERα. These changes could reduce embryo survival. 相似文献18.
Reasons for performing study: Persistent mating induced endometritis is among the most common causes of infertility in the mare. Recently, improved pregnancy rates have been reported when corticosteroids were administered to ‘problem mares’ specifically, to modulate the post mating inflammatory response; however, the effect of treatment on pituitary and ovarian function requires further study. Objectives: To evaluate the effects of prolonged treatment with glucocorticoids on pituitary and ovarian function. Methods: Eighteen cycling Quarter Horse mares in early oestrus were assigned randomly to one of 3 treatment groups: dexamethasone 0.05 mg/kg bwt i.v. twice a day, prednisolone 0.5 mg/kg per os twice a day, or placebo for 5 days. Mares were examined by ultrasound daily to evaluate reproductive function. Blood samples were collected daily to measure luteinising hormone (LH), progesterone and cortisol levels. Results: Dexamethasone treatment caused greater (P<0.05) suppression of endogenous cortisol concentration (9.4 ± 1.1 ng/ml) compared to prednisolone‐ (41.9 ± 4.0 ng/ml) or placebo‐treated mares (32.4 ± 3.8 ng/ml). After 24 h, mares treated with dexamethasone exhibited lower uterine oedema scores than prednisolone‐ or placebo‐treated mares. An ovulation rate of 40% was observed in dexamethasone‐treated mares (2/5) compared to 83% for prednisolone (5/6) and 100% for placebo‐treated (6/6) mares. An absence of a LH surge was noted in 3 of 5 dexamethasone‐treated mares and one of 6 prednisolone‐treated mares. Conclusions: Repeated administration of dexamethasone to mares in oestrus is associated with decreased uterine oedema, suppression of LH and a high rate of ovulation failure. It is recommended that dexamethasone treatment is limited to only 1 or 2 days and that a lower dose is considered in the management of persistent mating induced endometritis to avoid potential adverse affects on reproductive function. 相似文献
19.
Fumuso E Giguère S Wade J Rogan D Videla-Dorna I Bowden RA 《Veterinary immunology and immunopathology》2003,96(1-2):31-41
20.
Endometritis is the most common cause of infertility in mares; however, many mares fail to be diagnosed despite availability of many diagnostic tests. Our objective was to compare different diagnostic methods and establish a cutoff value for the number of polymorphonuclear cells in cytology samples. Fifty-four mares were classified positive for endometritis based on endometrial biopsy (“gold standard”), and in a later analysis, the mare was reclassified as positive for endometritis if two or more of the following five criteria on a checklist were present (“new gold standard” [NGS]): (1) abnormal clinical findings, (2) abnormal gross character of low-volume lavage (LVL) fluid, (3) positive endometrial cytology, (4) bacterial growth on culture of the LVL pellet, and (5) histologic evidence of inflammation on endometrial biopsy. Kappa (κ) coefficient and percentages were calculated for sensitivity and positive predictive value (PPV) using SAS 9.3 software. Endometritis was diagnosed in 35/44 (79.5%) mares by biopsy. Based on the endometritis checklist, 33/51 (64.7%) mares were positive for endometritis. The character of LVL was 45% sensitive, whereas culture was 22% sensitive, when compared with endometrial biopsy. One percent of neutrophil-to-epithelial cell ratio was the most sensitive cutoff value (93.3%) when using a guarded swab (κ = 0.64). Endometrial biopsy was the most sensitive diagnostic method when compared against the NGS (sensitivity = 86%). Abnormal clinical findings and positive cytology showed moderate agreement with the NGS (κ = 0.41 and κ = 0.38, respectively). These studies demonstrate the importance of combining clinical findings and laboratory data when evaluating mares for endometritis. 相似文献