不同繁殖生理阶段及繁殖障碍母牛的阴道黏液电阻值变化

doi:10.12160/j.issn.1672-5190.2023.05.008

Abstract

Abstract:

[Objective] This study was conducted to measure and compare the electrical resistance of vaginal mucus （ERVM） of beef cows in different reproductive physiological periods and with different types of reproductive disorders, and to provide references for the assistant detection of estrus and gestation as well as the diagnosis of reproductive disorders in cows based on the obtained relevant basal data. Meanwhile, it also aimed to assess the applicability of animal estrus and ovulation tester, and to render technical support for improving the reproductive efficiency in cows. [Method] A total of 297 reproductive beef cows were selected from 21 cattle farms or households. According to the reproductive records and rectal examination results, the cows were subjected to reproductive physiological periods （anestrous period, estrus period, gestation period) determination or reproductive disorders diagnosis. Based on the above records and results, the 297 cows were assigned into the following four groups: an anestrous period group （n=76）, an estrus period group （n=48）, a gestation period group （n=106）, and a reproductive disorders group （n=67）. The 106 heads in the gestation period group were further classified based on the gestation days: 44 heads with ≤60 days of gestation, 24 heads with 61-120 days of gestation, 31 heads with 121-180 days of gestation, and 7 heads with >180 days of gestation. In accordance with the reproductive physiological processes, 42 heads at the luteal phase, 13 heads at the follicular phase and 24 heads at the gestation phase were selected from the cows in the anestrous, estrus, and gestation periods, respectively. The 67 heads in the reproductive disorders group were further divided based on the types of reproductive disorders: 8 heads with ovarian cysts, 57 heads with persistent corpus luteum, and 2 heads with freemartinism. The ERVM of the cows in different reproductive physiological periods and with different types of reproductive disorders was measured using a fully automated animal estrus and ovulation tester, and was statistically compared and analyzed. [Result] The lowest ERVM was observed in the cows in the estrus period, which was 17.91% （P<0.01） and 28.38% （P<0.01） lower than that in those in the anestrous and gestation periods, respectively; the ERVM in the anestrous period was 12.76% （P<0.01） lower than that in the gestation period. The highest ERVM was observed in the cows with ≤ 60 days of gestation, followed by those with 61-120 days of gestation; both were extremely significantly （P<0.01） higher than those with >180 days of gestation; the ERVM in the cows with 121-180 days of gestation was significantly （P<0.05） higher than that in those with >180 days of gestation. The ERVM in the cows at the follicular phase decreased by 35.85% and 37.05% compared with that in those at the luteal and gestation phases, respectively, reaching extremely significant （P<0.01） levels; the ERVM at the luteal phase was similar to that at the gestation phase （P>0.05）. The ERVM in the cows with freemartinism was the highest, and was 36.12% higher （P<0.01） than that in those with ovarian cysts; the ERVM of the cows with persistent corpus luteum was 22.42% higher than that in those with ovarian cysts （P>0.05）. [Conclusion] The variations in the ERVM of beef cows in different reproductive physiological periods and with different types of reproductive disorders were characterized. The average ERVM of the cow populations evidently varied among the anestrous, estrous and gestation periods as well as the different types of reproductive disorders, and also exhibited apparent individual differences. Moreover, there was partial overlap in the ERVM of cows under different reproductive physiological conditions. A ERVM less than 180 Ω was indicative for the determination of estrous period. Additional diagnostic techniques, such as rectal examination and verification of reproductive records, were necessary when using ERVM to identify gestation and anestrous periods and to diagnose reproductive disorders in cows.

Key words: cow, reproductive physiological period, gestation, reproductive disorder, electrical resistance of vaginal mucus

CLC Number:

S823.923

HE Zhanxing, ZHANG Jicai, HUANG Meifen, ZHAO Tingting, SHI Jianwei, MA Zhenming, WANG Ji, HUANG Youfa, ZHENG Shengmei, WANG Ankui. Characterization of Changes in Electrical Resistance of Vaginal Mucus of Beef Cows in Different Reproductive Physiological Periods and with Different Types of Reproductive Disorders[J]. Animal Husbandry and Feed Science, 2023, 44(5): 57-62.

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[1]	RORIE R W, BILBY T R, LESTER T D. Application of electronic estrus detection technologies to reproductive management of cattle[J]. Theriogenology, 2002, 57(1): 137-148. pmid: 11775966
[2]	GONCU S, ANITAS O, GUNGOR C, et al. New technology usage for sustaniable dairy cow reproductive perfomances[J]. Journal of Environmental Science and Engineering B, 2017, 6(7): 370-379.
[3]	CARTER P D, DUFTY J H. Assessment of vaginal impedance measurements as an indicator of oestrus in cattle[J]. Australian Veterinary Journal, 1980, 56(7): 321-323. pmid: 7436937
[4]	CANFIELD R W, BUTLER W R. Accuracy of predicting the LH surge and optimal insemination time in Holstein heifers using a vaginal resistance probe[J]. Theriogenology, 1989, 31(4): 835-842. pmid: 16726598
[5]	LEWIS G S, AIZINBUD E, LEHRER A R. Changes in electrical resistance of vulvar tissue in Holstein cows during ovarian cycles and after treatment with prostaglandin F2α[J]. Animal Reproduction Science, 1989, 18(1/2/3): 183-197. doi: 10.1016/0378-4320(89)90020-1
[6]	MEENA R S, SHARMA S S, PUROHIT G N. Efficiency of vaginal electrical resistance measurements for oestrous detection and insemination in Rathi cows[J]. Animal Science, 2003, 76(3): 433-437. doi: 10.1017/S1357729800058665
[7]	PUROHIT G N, GUPTA K A. Efficiency of vaginal electrical resistance for insemination of cattle[J]. Livestock International, 2000, 12:12-14.
[8]	TADESSE M, THIENGTHAM J, PINYOPUMMIN A, et al. The use of vaginal electrical resistance to diagnose estrus and early pregnancy and its relation with size of the dominant follicle in dairy cattle[J]. Kasetsart Journal(Natural Science), 2011, 45(3): 435-443.
[9]	GUPTA K A, PUROHIT G N. Use of vaginal electrical resistance(VER) to predict estrus and ovarian activity, its relationship with plasma progesterone and its use for insemination in buffaloes[J]. Theriogenology, 2001, 56(2): 235-245. doi: 10.1016/S0093-691X(01)00559-3
[10]	GUPTA K A, PUROHIT G N. Pregnancy rates in buffaloes inseminated on the basis of vaginal electrical resistance(VER)[J]. Indian Journal of Animal Sciences, 2001, 71(10): 908-909.
[11]	JUYENA N, HASSAN M, MOLLAH H, et al. Monitoring vaginal electrical impedance in Bangladeshi water buffaloes during postpartum period[J]. Journal of Buffalo Science, 2015, 4(2): 46-51. doi: 10.6000/1927-520X.2015.04.02.3
[12]	KITWOOD S E, PHILLIPS C J C, WEISE M. Use of a vaginal mucus impedance meter to detect estrus in the cow[J]. Theriogenology, 1993, 40(3): 559-569. pmid: 16727339
[13]	HULSURE M S, PARGAONKAR D R, BAKSHI S A. Studies on use of electronic probe estrone to detect heat in cows and to monitor optimum time for insemination[J]. Indian Journal of Animal Reproduction, 1995, 16(2): 107-108.
[14]	LEIDL W, STOLLA R. Measurement of electric resistance of the vaginal mucus as an aid for heat detection[J]. Theriogenology, 1976, 6(2/3): 237-249. doi: 10.1016/0093-691X(76)90017-0
[15]	PUROHIT G N, KUMAR S, KUMAR D. Electronic measurements of vaginal electric resistance(VER) : Current status for estrus detection, timing insemination and pregnancy diagnosis in cattle and buffalo[J]. Ruminant Science, 2019, 8(2): 145-152.
[16]	寇红祥, 李蓝祁, 王振玲, 等. 牛发情期活动量与阴道黏液电阻值变化规律的研究[J]. 畜牧兽医学报, 2017, 48(7): 1221-1228.
[17]	SCHAMS D, SCHALLENBERGER E, HOFFMANN B, et al. The oestrous cycle of the cow: Hormonal parameters and time relationships concerning oestrus, ovulation, and electrical resistance of the vaginal mucus[J]. Acta Endocrinologica, 1977, 86(1): 180-192. pmid: 578608
[18]	FIRK R, STAMER E, JUNGE W, et al. Automation of oestrus detection in dairy cows: A review[J]. Livestock Production Science, 2002, 75(3): 219-232. doi: 10.1016/S0301-6226(01)00323-2
[19]	HOCKEY C D, NORMAN S T, MORTON J M, et al. Use of vaginal electrical resistance to diagnose oestrus, dioestrus and early pregnancy in synchronized tropically adapted beef heifers[J]. Reproduction in Domestic Animals, 2010, 45(4): 629-636. doi: 10.1111/j.1439-0531.2008.01320.x pmid: 19144030
[20]	王必强, 马风宝. 可视输精枪和排卵测定仪在母牛同期发情中的应用[J]. 基层农技推广, 2020, 8(10): 33-34.
[21]	JOTANOVIC S, ŠAHINOVIC R, STANCIC I, et al. Relationship between electrical resistance of vaginal mucus in the moment of insemination and cow′s pregnancy rate[J]. Contemporary Agriculture, 2011, 60(1/2): 104-109.
[22]	AHMED M, CHOWDHURY M K, RAHMAN M M, et al. Relationship of electrical resistance of vaginal mucus during oestrus with post-ai pregnancy in cows[J]. Bangladesh Journal of Veterinary Medicine, 2017, 15(2): 113-117. doi: 10.3329/bjvm.v15i2.35520
[23]	吴元昌, 郑羽, 高建新. 发情鉴定仪测定母牛适宜配种时机[J]. 畜牧兽医杂志, 2008, 27(2): 92-93.
[24]	ZULUAGA J F, SALDARRIAGA J P, COOPER D A, et al. Evaluation of vaginal electrical resistance as an indicator of follicular maturity and suitability for timed artificial insemination in beef cows subjected to a synchronization of ovulation protocol[J]. Animal Reproduction Science, 2008, 109(1/2/3/4): 17-26. doi: 10.1016/j.anireprosci.2007.10.002
[25]	TASAL I, ATAMAN M, AKSOY M, et al. Estimation of early pregnancy by electrical resistance values of vaginal mucosa in cows and heifers[J]. Revue De Medecine Veterinai, 2005, 156(2): 91-94.

Characterization of Changes in Electrical Resistance of Vaginal Mucus of Beef Cows in Different Reproductive Physiological Periods and with Different Types of Reproductive Disorders

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