Breed differences in circulating equine relaxin.

Equine relaxin has been previously determined in a small number of pregnant Thoroughbred mares. To better define the normal pregnancy pattern of relaxin, the current study reports on a much larger number of mares. It also was designed to determine if all equids have the same gestational pattern of relaxin secretion. Plasma samples were collected weekly in 24 Standardbred mares, every 7-10 days in 10 pony mares, and daily in late pregnancy from 16 burros. Standardbreds had higher concentrations of relaxin than that reported for Thoroughbreds during most of gestation and did not exhibit the midpregnancy nadir in relaxin concentrations observed in Thoroughbreds. Relaxin concentrations in Standardbreds showed a small but steady decline from Day 150 until delivery. Pony mares had lower relaxin concentrations throughout pregnancy than other mares and had continuously increasing concentrations during gestation. Burros had relaxin concentrations intermediate to ponies and other mares in late gestation. Burros induced to foal with oxytocin showed a sharp increase in relaxin concentrations. No effect of the sex of the offspring was observed in relaxin profiles in Standardbred mares. Each of three Standardbreds with abnormal termination of pregnancy exhibited abnormally low relaxin concentrations at some point in the gestation prior to termination of the pregnancy. Thus, relaxin may be an indicator of placental functioning and used to assess at-risk pregnancies in mares.

Relationship of serum estradiol and progesterone concentrations to the excretion profiles of their major urinary metabolites as measured by enzyme immunoassay and radioimmunoassay.

Paired daily blood and urine samples were collected from 10 apparently healthy premenopausal women to compare the hormone profiles of estradiol (E2) and progesterone in serum with those of estrone conjugates (E1Conj) and pregnanediol-3-glucuronide (PdG) in urine. Serum hormones were measured by radioimmunoassay (RIA) kits, whereas the urinary steroid metabolites were assessed by both RIA and enzyme immunoassay (EIA). RIA and EIA values for urinary E1Conj and PdG were not different, and both methods produced urinary profiles that paralleled the profile of the parent steroid in serum. However, the simplicity, flexibility, and economy of EIA will make this method more widely applicable. Mean E1Conj values lagged behind concentrations of serum E2 by one day or less, whereas daily urinary PdG profiles lagged behind serum progesterone by one to two days. Mean urinary profiles of E1Conj were similar whether or not creatinine was used to adjust for urine volume; however, creatinine indexing was beneficial when urinary profiles in individual cycles were compared with changes of serum E2.

Determination of the source of immunoreactive relaxin in the cat.

We have recently reported the secretory profile of relaxin throughout gestation in the cat. Because the appearance of relaxin begins at about Day 20 (Day O = ovulation) and because implantation begins shortly before this at Days 13-14, we hypothesized that relaxin was of feto-placental origin. To test this hypothesis, we used 4 experimental groups: 1) Control (laparotomy-only at Day 23 or 42, n = 4); 2) Early Ovariectomy (Ovx, bilateral ovariectomy between Days 23 and 26, n = 4); 3) Late Ovx (bilateral ovariectomy between Days 40 and 44, n = 4); 4) Tissue Removal (removal of feto-placental units, uterus, and one ovary on Days 16, 21, 28 and 35, n = 1 per day). Pregnancies were maintained in both Ovx groups by progesterone administration. Relaxin secretory patterns in Ovx groups were similar to the Control data. Relaxin was detectable in plasma beginning at about Day 20, with maximum concentrations reached by Day 30. Relaxin concentrations were highest (immunoactivity per mg tissue) in homogenates of placental tissues as compared to luteal, fetal, or uterine tissues. Altogether, these data indicate that the feto-placental unit is the source of relaxin in the cat.

Comparison of aqueous porcine ACTH with synthetic ACTH in adrenal stimulation tests of the female dog.

The adrenocortical (plasma corticosteroid) responses in female dogs given porcine ACTH in gelatin (1-39 amino acid sequence) and synthetic ACTH (1-24 amino acid sequence) were compared. Sixteen dogs were used. Each dog underwent 4 different ACTH stimulation studies, these being done with a 4- to 8-week interval. The studies in each dog included injections of 2 doses of porcine ACTH--2.2 IU and 4.4 IU/kg of body weight--and of 2 doses of synthetic ACTH--0.25 mg/dog and 0.50 mg/dog. The dogs were arbitrarily allotted to 4 groups, each group being subjected to a given sequence of stimulation studies. The purpose in this project was to determine whether the established methods for synthetic and porcine ACTH stimulation tests had similar results. Statistical analysis of the 4 stimulation methods revealed no significance (P greater than 0.05) in the resting or poststimulation plasma corticosteroid concentrations. Thus, it was concluded that either recommended method using ACTH (porcine ACTH at 2.2 IU/kg or synthetic ACTH at 0.25 mg/dog) causes maximal secretion of adrenocortical reserve. Either ACTH preparation, using the established method, can be used interchangeably.