雌性小熊猫粪样中雌二醇与孕酮水平的变化与繁殖启动的关系

于1999年12月-2000年4月在成都动物园和成都大熊猫繁育研究基地,用放射免疫分析法测定了4只雌性小熊猫（Ailurus fulgens)粪样中雌二醇(E2)和孕酮(P)水平的变化,同时对其交配行为进行了观察。研究结果表明：雌性小熊猫进入发情期后,粪样中E2迅速升高,并多次出现峰值,表明小熊猫可能是季节性多发情动物。交配行为发生前E2出现峰值,P水平上升,说明E2和P是启动雌性小熊猫交配行为的重要因素;未伴随有P水平相对上升的E2峰值不能引起雌性小熊猫发生交配行为,该现象为暗发情。交配行为发生后P水平持续升高,据此推断小熊猫的排卵方式可能是诱导排卵,诱导因子是交配刺激。     

圈养马麝刻板行为表达与粪样类固醇激素的关系

2017年7月1日-8月31日及2018年6月1日-7月31日,在甘肃兴隆山保护区马麝繁育中心,采用焦点取样法和连续记录法进行了圈养马麝的刻板行为取样,采集同期粪样,并用放射免疫分析法（RIA）检测粪样中肾上腺皮质醇、睾酮及雌二醇激素的水平,分析了圈养马麝刻板行为表达与上述3种激素水平的关系。结果显示,展现刻板行为的圈养马麝的皮质醇水平（111.099 ± 16.231）ng/g略高于无刻板行为表达的马麝（95.640± 9.738） ng/g,差异未达显著（P> 0.05）;展现刻板行为雄麝的睾酮水平（135.900± 21.582）ng/g略高于无刻板行为的雄麝（108.182 ± 9.689） ng/g,差异也不显著（P> 0.05）;展现刻板行为雌麝的雌二醇水平（0.445 ± 0.116）ng/g显著低于无刻板行为雌麝（10.843 ± 1.142）ng/g（P< 0.05）。研究结果表明,圈养雄性马麝的刻板行为表达与其类固醇激素水平不相关;而雌麝的刻板行为表达与雌二醇分泌显著负相关,这与其繁殖及健康状况有关。在麝类驯养实践中,可将粪样类固醇激素水平（尤其是雌二醇）作为其受胁迫水平及行为健康的监测指标。     

小熊猫繁殖周期血清雌二醇和孕酮含量变化

为研究小熊猫繁殖周期血清雌二醇、孕酮含量变化规律,采用化学发光免疫分析法连续16 次测定了2只成体雌性小熊猫血清雌二醇和孕酮含量变化,历经发情间期、发情期和两次妊娠期;连续9次测定了7只小熊猫妊娠期的孕酮含量变化。结果:(1)发情间期,小熊猫血清雌二醇的水平一直维持在低水平(基础水平),进入发情前期,血清雌二醇水平明显升高,在发情期一直维持高水平,配种后迅速降至基础水平; (2)小熊猫血清孕酮含量在发情间期和发情期均维持在较低水平,直至发情期过后才出现升高,在妊娠期一直维持高水平,峰值出现在5 月;(3)发情的小熊猫不论妊娠与否,在妊娠期内血清孕酮含量均维持在高水平。研究表明:小熊猫血清雌二醇、孕酮含量变化能直接反映其繁殖规律,雌二醇对启动雌性小熊猫季节性繁殖起重要作用;在妊娠期内小熊猫血清孕酮含量升高不能作为判断小熊猫妊娠的标准;雌性小熊猫在妊娠期有假孕现象。     

恒河猴血清孕酮含量测定方法

目的建立恒河猴血清中孕酮含量测定方法。方法本文采用放射免疫测定技术。结果孕酮的回收率为94％,批内CV为5．1％～8．3％,批间CV为4．5％～7．7％,灵敏度为5～10Pg。说明该方法具有较高的灵敏度、特异性、准确性。分别测定了幼年组、成年组和老年组的雌性恒河猴的血清中的孕酮含量分别为：（0．20±0．04）ng／mL、（6．26±0．17）ng,mL和（0．35±0．06）ng/mL;成年雌性恒河猴月经周期孕酮的变化范围为：滤泡期为（1．10±0．12）ng／mL,排卵期（2．36±0．18）ng/mL,黄体期（6．17±0．15）ng/mL,妊娠期随着妊娠月份的增加,孕酮浓度也增加,最高可达50ng／mL。结论经实验验证,该方法灵敏、可靠、适用,可作为恒河猴血清中孕酮含量测定的一种方法。     

猎豹粪样皮质醇代谢研究

采用放射性免疫法测量猎豹粪样中皮质醇代谢的含量,通过不同时间点的动态采样分析皮质醇含量的变化。在研究的6个雌性猎豹中,粪样皮质醇含量显示它们能够分成3个不同的组,高皮质醇含量的雌性猎豹组(～295.22ng/g粪样,n=2)、中等皮质醇含量雌性猎豹组(～152.29ng/g粪样,n=2)、偏低的皮质醇含量的雌性猎豹组(～94.14ng/g粪样,n=2)。外源压力影响了猎豹的繁殖性能,而皮质醇的代谢水平是反映猎豹来自外源压力的一个重要指标。本研究拟通过猎豹粪样中皮质醇的含量评估动物所处的环境压力水平,为饲养管理水平和饲养环境的改善提供有益的借鉴,进而为解决动物的繁殖问题提供新的思路和方法。     

笼养雌性黑叶猴尿中性腺激素水平变化与性行为、等级序位的关系

2003年10月30日至2004年11月21日,采集了3只笼养雌性黑叶猴妊娠期和1 只笼养雌性黑叶猴发情期的晨尿,并用放射免疫分析法检测尿液中孕酮和雌二醇浓度,同时用全事件观察法观察黑叶猴的行为,分析雌性黑叶猴的行为与其尿中的性腺激素的关系。研究结果发现:1)进入妊娠期,雌性黑叶猴尿中的雌二醇浓度逐渐上升,中后期达高峰;而尿中孕酮浓度在妊娠初期仍维持在放免法的灵敏度以下,妊娠约1 个月后才升高至灵敏度以上(13.39 ng/ mgCr);2)在妊娠中期,雌性黑叶猴仍维持着较高频率的邀配行为,但与雌激素的变化无明显的相关关;3)发情期,雌猴尿中的雌二醇浓度与其邀配行为呈正相关;4)雌性黑叶猴的性激素高低与其等级序位无关,但序位高的雌猴繁殖较早。     

大熊猫生殖生物学研究:Ⅱ.大熊猫妊娠期尿中孕酮和绒毛膜促性腺激素样物质含量的变化

本文用放射免疫法测定了四只大熊猫在妊娠期和非妊娠期尿中孕酮和CG样物质含量的变化。结果表明:在大熊猫胚胎着床前,孕酮和CG样物质含量较低;胚胎着床后,二种激素的含量显著上升并达到高峰。雌兽妊娠期尿中孕酮和CG样物质含量的变化规律可为证实大熊猫系延缓着床型动物提供一些理论依据;同时,也为大熊猫的妊娠诊断和预测分娩提供一些参考数据。     

注射LHRHa对泥鳅血清性类固醇激素变化研究

研究了注射促黄体激素类似物(LHRHa)后,泥鳅(Misgurnus anguillicaudatus)血清性类同醇激素的变化规律,并探讨在泥鳅繁殖季节时.孕酮(P)、睾酮(T)和雌二醇(E2)对性腺发育的作用及调节机制.实验共分两组,对照组和实验组;对照组只注射生理盐水;实验组注射LHRHa,雌鱼0.2 μg/g,雄鱼减半.注射前尾静脉采血,作为血液样本分析基础水平(Oh),注射药物后分别在7、24、48、72和96h尾静脉采血.测定雌鱼睾酮、雌二醇和孕酮,雄鱼孕酮和睾酬血清浓度.实验结果表明:注射LHRHa,雌鱼血清睾酮和雌二醇浓度显著高于对照组,雄鱼血清睾酮和孕酮显著高于对照组(P<0.05);24h浓度较高.雌鱼孕酬、睾酮和雌二醇分别为(0.710±0.082)ng/mL、(9.00±0.57)ng/mL和(696.4±26.2)pg/mL,雄鱼孕酮和睾酮分别为(0.527±0.121)ng/mL和(9.62±0.62)ng/mL.实验组雌鱼孕酮变化基本规律为,基础水平(0-7h)-逐渐升至最高(7-24h)-逐渐降至基础水平(24-48h)-维持基础水平(48-96h).实验组雌鱼睾酮和雌二醇与雄鱼孕酮和睾酮变化规律基本相似,其规律为,逐渐上升至最高(0-24h)-逐渐降至基础水平(24-72h)-维持基础水(72-96h).24h对照组雌鱼睾酮和雌二醇显著升高,浓度分别为:睾酮(2.20±0.18)ng/mL,雌二醇(269.1±36.6)pg/mL.对照组雄鱼血清孕酮和睾酮浓度实验期间均无显著变化.研究认为:LHRHa能够刺激泥鳅性类同醇激素分泌,特别是睾酮的分泌,显著提高雌鱼性腺指数(GSI).但刺激P的分泌调控能力有限,实验期间处于较低水平,诱导排卵效果差,泥鳅的性类固醇激素可能有特殊的调节机制.雌二醇和睾酮对性腺成熟有重要作用,孕酮对介导卵细胞最终成熟和排卵可能起重要作用,而雌二醇和睾酮无明显效果.     

抗血小板制剂对射频消融术前后vWF、血小板和凝血纤溶活性的影响

目的：探讨消融技术后血栓栓塞的机制和预防的方法,为临床提供血栓栓塞并发症的防治方法。方法：在我科行射频消融术的室上速患者158名,年龄15-61岁,其中右侧旁道12例,双径路62例,左侧旁道84例。随机分为五组,组Ⅰ（n=31）术前未服抗血小板制剂,术后立即服用阿斯匹林0.3g,1／日;组Ⅱ（n=32）术前3天始服用阿斯匹林0.3g,1／日;组Ⅲ（n=30）术前3天始服用氯吡格雷75mg1／日;组Ⅳ（n=32）术前3天服用阿斯匹林0．3g＋氯吡格雷75mg 1／日;组V（n=33）术前3天始服用阿斯匹林0.3g,1／日,术后皮下注射速避凝0．4ml 1／日。分别于入院后、电生理检查前即成功放置鞘管后、消融前即静推肝素前、消融后即刻、消融后24h采血。测定血浆血小板仪颗粒膜蛋白（GMP-140）水平、D-二聚体、血管性假血友病因子（vWF）。结果：①组IGMP-140水平自穿刺后即开始上升,射频消融术后24小时仍处于较高水平,血管穿刺后电生理检查前明显升高为30．41&#177;5．67ng／ml（P〈0．05）,而射频消融术后升高为60．4&#177;12．79ng／ml（P〈0．05）,但组Ⅱ、Ⅲ、Ⅳ、Ⅴ尤其是组IVGMP-140水平始终处于相对较低的水平（P〈0．05）。②组ID-二聚体水平自穿刺后即开始上升,射频消融术后24小时仍处于较高水平,血管穿刺后电生理检查前明显升高为0．58&#177;0．22mg／L（P〈0．05）,而射频消融术后升高为1．50&#177;0．56mg／L（P〈0．05）。组Ⅱ、Ⅲ、Ⅳ、Ⅴ尤其是组ⅣD-二聚体水平与组Ⅰ相比始终处于较低水平（P〈0．05）。③血浆vWF的水平：各组vWF水平自血管穿刺结束后即明显升高（P〈0．05）,射频消融术后组Ⅰ、Ⅲ升高明显,而组Ⅱ、Ⅳ、VvWF水平只有轻度升高（P〈0．05）,各组vWF水平在术后24小时仍维持相对较高的水平。④血浆GMP-140、D-二聚体、vWF在射频消融前后的改变与累及放电量、放电时间、放电次数、消融时间及肌钙蛋白Ⅰ等无关（P〈0．05）。结论：射频消融对内皮细胞有损伤作用,可导致GMP-140、D-二聚体的明显升高呈血栓前状态。不同的抗血小板制剂对其有改善作用。阿斯匹林可能降低血浆中vWF水平。     

秦岭野生雌性川金丝猴粪便睾酮水平与邀配频次的季节性变化

为研究野生雌性川金丝猴(Rhinopithecus roxellana)不同季节体内睾酮水平与性行为频次的变化及二者的关系,我们以秦岭一野生川金丝猴种群为研究对象,通过长时间连续跟踪观察,完成了该种群中所有87只金丝猴的个体识别。用无损伤取样法采集了三只成年雌性川金丝猴不同季节的粪样,对粪样中的睾酮进行抽提测定,同时对采样个体的性行为进行记录。结果显示:1)成年雌猴在交配盛期与非交配盛期,粪样中睾酮水平均呈明显的周期性波动,交配盛期时睾酮水平的变化周期为24.56 d±4.07 d,非交配盛期时为43.67 d±2.89 d,显著长于交配盛期;2)成年雌猴在交配盛期的粪样睾酮水平为2.85 ng±1.12 ng/g,邀配频次为0.98±1.04次/d,非交配盛期时睾酮水平为1.71 ng±0.77 ng/g,邀配频次为0.28±0.53次/d,与交配盛期相比,非交配盛期的睾酮水平和邀配频次均明显降低;3)交配盛期各成年雌猴的粪样睾酮水平与邀配频次均有较显著的正相关关系(相关系数分别为0.631、0.683和0.659),而在非交配盛期这种相关关系并不存在(相关系数分别为0.091、0.493和0.205)。本研究表明,成年雌性川金丝猴体内睾酮水平、睾酮水平变化周期及邀配行为频次均具有明显的季节性差异,这种季节性差异可能是川金丝猴行季节性繁殖的内在原因和外在表现之一。本研究亦表明交配盛期雌猴的性行为频次在一定程度上可能受体内睾酮水平的控制,而在非交配盛期这种控制作用较弱。     

Serum and fecal steroid analysis of ovulation,pregnancy, and parturition in the black rhinoceros (Diceros bicornis)

Studies were conducted to determine: (1) if fecal hormone metabolite concentrations correlated with serum estrogen and progesterone concentrations, follicular activity and reproductive behavior in the black rhinoceros (Diceros bicornis) and (2) if threshold values of respective fecal metabolite concentrations correlated with pregnancy. Blood and fecal samples were collected, in conjunction with transrectal ultrasound and behavior observations, for an 18-month period from one black rhinoceros female. Subsequently, serial fecal samples were collected from 13 females in 10 zoos. Quantitative analysis of serum progesterone (P₄) and estradiol (E₂) was performed by radioimmunoassay (RIA): analysis of fecal estrogen metabolites (E) and fecal progesterone metabolites (P) were performed by enzyme immunoassay (EIA). Serum P₂ concentrations identified two luteal phase patterns and two nadirs which corresponded with behavioral estrus. Fecal E patterns indicated a sharp peak which corresponded with breeding. concentrations of fecal P illustrated identifiable nadirs and several peaks which corresponded to serum P₄ nadirs and luteal phases. Serum P₄ concentrations were not different between the luteal phase and pregnancy. Fecal P concentrations started to rise above luteal phase concentrations approximately 150 days postbreeding and remained elevated until immediately before parturition. Serum E₂ and fecal E concentrations rose and subsequently declined after parturition. In the fecal samples from seven pregnant females, fecal P concentrations were similarly elevated compared to six nonpregnant females. Results indicated that fecal steroid metabolites accurately reflected serum steroid hormone concentrations and that the measurement of P and E concentrations permitted the characterization of the estrous cycle, the diagnosis of pregnancy, and the onset of parturition. Zoo Biol 16:121–132, 1997. © 1997 Wiley-Liss, Inc.     

雄性小熊猫粪便中睾酮水平的变化与繁殖周期的关系

1999 年12 月至2000 年9 月, 使用放射免疫分析法, 测定了成都动物园和成都大熊猫繁育研究基地的4 只雄性小熊猫粪样中睾酮水平变化情况, 同时对其行为进行了观察。研究结果表明, 雄性粪样中睾酮水平在繁殖期(12 月～3 月) 显著高于非繁殖期(4 月～9 月) (P < 0.01) , 且睾酮水平变化与繁殖行为密切相关。在非繁殖期,雄性小熊猫的睾酮水平处于基础的较低水平时, 其繁殖行为如蹭阴、舔阴、舔标记物和咩叫等几乎没有发生或很少发生; 而在繁殖期, 雄性小熊猫的睾酮水平明显升高, 这些繁殖行为频繁发生。以上结果说明, 睾酮是调节雄性小熊猫繁殖行为季节性变化的生理因子。     

Influences of mating groups on the reproductive success of the Southern Sichuan Red Panda (Ailurus fulgens styani)

The reproduction of female red pandas under three different husbandry conditions (monogamy, polygamy, and polyandry) was studied at the Chengdu Research Base for Giant Panda Breeding, and Chengdu Zoological Park, China. We monitored the fecal steroid profiles of seven females by radioimmunoassay in order to understand how the different mating groupings affect the animals' reproductive success. Of the seven females studied, all gave birth except the one that was kept in the polyandrous group. Although fecal estradiol metabolites exhibited several peaks during estrus, only one coincided with mating behavior. Fecal progesterone metabolites did not display a sustained rise in the absence of mating behavior, even though estradiol displayed a peak of secretion. This suggests that the red panda may be an induced ovulator. During gestation, fecal progesterone metabolites were maintained at a comparatively high level, and were much higher than those of nonpregnant females. The female in the polyandrous group showed an abnormal estradiol metabolite profile, with a level that was four to five times higher than those of the females in the polygynous groupings. It was observed that this female always escaped and hid in the trees to avoid courtships with males, and did not give birth. This phenomenon suggests that polyandrous groupings may be unsuitable for successful reproduction in captivity. Zoo Biol 24:169–176, 2005. © 2005 Wiley‐Liss, Inc.     

Characterization of seasonal reproduction patterns in female pichis Zaedyus pichiy (Xenarthra: Dasypodidae) estimated by fecal sex steroid metabolites and ovarian histology

Reproductive strategies vary considerably among species, but most studies have focused on a very limited number of mammalian species. Knowledge of the reproductive cycle and behavior is essential for developing and implementing in situ and ex situ conservation strategies for threatened and endangered species. This study aimed at characterizing the seasonal reproductive pattern of female pichis Zaedyus pichiy, a threatened small armadillo native to arid regions of Argentina and Chile, through direct observations, histological studies, and by measuring fecal immunoreactive estrogens, progestagens and glucocorticoids in 10 wild-born, captive pichis and in free-ranging individuals. Results suggest that pichis are seasonal breeders that give birth to one yearly litter of 1–2 offspring, which do not leave the burrow until they are weaned at approximately 37 days. Ovarian follicular growth seems to occur throughout the year. Fecal progestagen, estrogen and glucocorticoid concentrations were minimal during the first half of pregnancy, increased to peak concentrations of up to 3500, 200 and 200 ng/g dry feces, respectively, and decreased before parturition. Postpartum progestagen concentrations were greater in lactating females than females that aborted or did not raise their offspring (p < 0.0001), which is probably related to an elevated corticosteroid synthesis that contributes to maintain lactation, given that fecal glucocorticoid concentrations were of similar pattern. Observations of a second pregnancy after late abortion or death of the newborn litter and sustained follicular growth during pregnancy and lactation suggest that female pichis can become receptive briefly after having lost their litter. Fecal estrogen and progestagen concentrations of non-pregnant, non-lactating females did not have a well-defined hormonal cyclic pattern, and corpora lutea were only observed in pregnant females.     

Fecal endocrine monitoring of reproduction in female snow leopards (Uncia uncia)

Although the snow leopard (Uncia uncia) is a common endangered felid species in zoos, little is known about the complex endocrine interactions controlling ovarian function and conception in this species. The goal of this work was to characterize ovarian activity throughout the estrous cycle, nonpregnant luteal phase (pseudopregnancy), and gestation in female snow leopards. This goal was accomplished using an enzyme immunoassay to measure fecal concentrations of estrogen metabolites (E) and progesterone metabolites (P). Fecal samples were collected from 12 female snow leopards (ages 18 months to 18 years) during one to three breeding seasons. In each breeding season, the majority of females (78%, 88%, and 100%, respectively) began to exhibit ovarian activity in December or January. The estrous cycle, defined by the first day of estrus (E ≥ 2 × basal concentration) to the first day of the subsequent estrus, was 12.7 ± 0.6 days (n = 145 cycles). Estrus lasted 4.3 ± 0.4 days with mean concentrations of fecal E during the follicular phase (1661 ± 139 ng/g feces) increasing 3.2-fold above basal concentrations (515 ± 32 ng/g feces). No spontaneous ovulations were observed in any of the cycling females. Nonpregnant luteal phases were observed in eight females that bred but did not become pregnant. The length of the nonpregnant luteal phase ranged from 11 to 72 days (45.7 ± 5.7 days; n = 10) with mean concentrations of fecal P during the luteal phase (12.46 ± 1.7 μg/g feces) increasing 6.2-fold above basal concentrations of P (2.01 ± 0.2 μg/g feces). Three of the females in the study became pregnant and gave birth after a gestation of 93 (n = 2) and 95 (n = 1) days. Fecal P concentrations during pregnancy increased to 11.64 ± 1.3 μg/g feces, or 5.8-fold above basal concentrations. The results of this study provide a comprehensive characterization of reproductive endocrinology in snow leopards, and confirm that fecal hormone monitoring is an effective way to monitor female snow leopards throughout the breeding season.     

Non-invasive monitoring of the estrous cycle in captive crab-eating foxes (Cerdocyon thous)

In this study, four crab-eating fox females (Cerdocyon thous) maintained at the Federal University of Mato Grosso Zoo, Cuiabá, Brazil, were investigated for 16 mo, using transabdominal ultrasonography and measurement of estradiol and progesterone concentrations in blood plasma and feces. Blood collection and ultrasonography were performed once a month, whereas fecal collections were performed three times a week. During the experimental period, there was an annual estrous cycle in all females, with the reproductive season lasting from winter to spring, and three became pregnant. Transabdominal ultrasonography was inconclusive for characterization of estrus cycles phase, but was effective for early detection of pregnancy, pregnancy monitoring, and for evaluating postpartum uterine involution. There were similarities between C. thous female's reproductive aspect and bitches, with similar pregnancy data, although uterine involution was faster in C. thous. Peak serum concentrations of P4 and E2 were (mean ± SD) 14.58 ± 5.8 ng/ml and 31.62 ± 53.54 pg/ml, respectively, whereas mean fecal peaks of P4 and E2 were 2.37 ± 1.42 ng/g and 157.95 ± 82.63 pg/g, respectively. All pregnant females had serum and fecal P4 concentrations reaching maximum values (16.5 ± 4.0 ng/ml and 2.7 ± 0.4 ng/g, respectively) from 10 to 30 d of gestation; those values subsequently declined, reaching baseline at parturition (5.0 ± 4.0 and 0.7 ± 0.4 ng/g, respectively). Peaks of E2 occurred throughout the year, and were absent only during apparent lactational anestrus.     

Reproductive endocrine responses to photoperiod and exogenous gonadotropins in the pallas' cat (Otocolobus manul)

Fecal samples were collected for 14–26 months from three male and six female Pallas' cats (Otocolobus manul) to examine gonadal steroidogenic activity in response to changes in photoperiod and treatment with exogenous gonadotropins. Females exhibited a seasonal anestrus from May–December, excreting consistently low concentrations of fecal estrogens (overall mean, 50.2±8.5 ng/g). During the breeding season (January–April), baseline fecal estrogen concentrations were higher, averaging 128.4±18.9 ng/g, with peak concentrations ranging from 455.8–909.6 ng/g. Interpeak intervals in estrogen excretion ranged between 7 and 21 days, with an average estrous cycle length of 14.3±1.7 days. Two females became pregnant after natural mating, with overall luteal progestogen concentrations averaging ～40 μg/g throughout gestation. Fecal estrogens increased in mid‐gestation, peaking just before birth. Induction of follicular development with eCG (100–300 IU, i.m.) resulted in an increase in fecal estrogens (peak range, 263.1–1198.1 ng/g), followed by a postovulatory increase in fecal progestogens (overall mean, 41.1±11.9 μg/g) after hCG (75–150 IU, i.m.). Despite apparently normal ovarian responses, none of the females conceived after artificial insemination (AI). The gonadotropin‐induced nonpregnant luteal phase lasted 49.8±5.3 days (range, 30–60 days), whereas gestation lasted ～70 days. In the male Pallas' cat, fecal androgens were elevated from November–April (overall mean, 352.3±30.3 ng/g) compared with nadir concentrations during the rest of the year (82.1±3.3 ng/g). Entrainment of seasonality to photoperiod was demonstrated by stimulation of gonadal steroidogenic activity in cats exposed to increasing artificial light during natural (nonbreeding season) and artificially induced short‐day photoperiods. In summary, reproduction in Pallas' cats is highly seasonal and photoperiod‐dependent. Females exhibit elevated baseline and peak fecal estrogen concentrations for 3–4 months during late winter/early spring. Testicular steroidogenic activity precedes the rise in female estrogen excretion by about 2 months, presumably to ensure maximal sperm production during the breeding season. Zoo Biol 21:347–364, 2002. Published 2002 Wiley‐Liss, Inc.     

Fecal estradiol-17β and testosterone in prepubertal domestic cats

The aim of this article was to describe the time course of prepubertal sexual steroids in domestic cats. Fourteen newborn kittens were followed up until puberty (physical, behavioral, and hormonal changes). Fecal testosterone [T; males] and E estradiol 17-β [E2; females] concentrations were analyzed by repeated measures ANOVA and two consecutive time windows (TWs) were used to compare changes in both male (postnatal weeks 1–4 vs. 5–14) and females (postnatal weeks 1–5 vs. 6–13). Puberty was achieved 14.3 ± 0.3 and 13.3 ± 0.4 weeks after birth in male and female cats, respectively. In both genders, during TW-1 fecal steroids concentrations were similar (males) or even higher (females) to that previously described for mature cats. Fecal T (P < 0.01) and E2 (P < 0.01) varied throughout the weeks. Differences were found when hormonal concentrations of TW-1 were compared with those of TW-2 both for male (61.4 ± 7.9 vs. 16.9 ± 2.2 ng/g; P < 0.01) and female (78.2 ± 12.5 vs. 11.2 ± 4.0 ng/g; P < 0.01) cats. It is concluded that in domestic cats there is a sexual steroid surge during the first 4 and 5 postnatal weeks in male and female animals, respectively.     

Pregnancy-specific elevations in fecal concentrations of estradiol, testosterone and progesterone in the domestic dog (Canis familiaris)

Estradiol (E2), testosterone (T) and progesterone (P4) concentrations were determined by enzyme-immunoassay in aqueous extracts of fecal samples obtained during anestrus, proestrus, estrus and metestrus of 11 nonpregnant and 11 pregnant bitches. Fecal hormone concentrations (ng/g) changed in relation to stage of cycle. Mean fecal steroid concentrations in 22 anestrous bitches and 3 ovariectomized bitches were low and similar for E2 (53 +/- 5 and 27 +/- 2), T (60 +/- 7 and 36 +/- 6), and P4 (62 +/- 6 and 86 +/- 15). Within 0 to 3 d of the ovulatory LH surge fecal E2 reached peak concentrations (301 +/- 38). The T peaks (281 +/- 41) were coincident or 1 to 3 d later. Fecal P4 was then elevated for approximately 2 m.o. Between Days 26 and 45 after ovulation, mean fecal P4 concentrations were higher (P < 0.05) in pregnant (401 +/- 60) than in nonpregnant bitches (164 +/- 23) and peak fecal P4 concentrations in individual animals were higher (P < 0.01) in pregnant (812 +/- 121) than in nonpregnant bitches (425 +/- 97). In the same period mean concentrations of E2 (117 +/- 13 vs 61 +/- 5) and T (102 +/- 10 vs 70 +/- 6) were also higher (P < or = 0.05) in pregnant than in nonpregnant bitches. Serum E2, T and P4 concentration were positively correlated (P = 0.1) with concentration in fecal samples obtained one day after serum collection. Although serial fecal ovarian steroid concentrations demonstrate the time course of ovulatory cycles, the diagnostic value of individual fecal samples appears limited. The ratios of peak to basal values were approximately 6, 5 and 7 for E2, T and P4, respectively, and were considerably lower than ratios of 12 to 50 previously reported for serum or plasma concentrations. The results demonstrate that there are pregnancy-specific increases in P4, E2 and T production reflected in fecal concentrations. While such increases are reflected in fecal samples, they are generally not evident in serum or plasma concentrations because of increased hemodilution, metabolism and clearance in pregnant bitches. The physiological stimulus for these increases, presumably ovarian in origin, or the potential role of prolactin is not known.