Minor FSH surge, minor follicular wave, and resurgence of preovulatory follicle several days before ovulation in heifers

Switching of follicle destiny so that the second largest follicle becomes dominant in monovulatory species

During an ovulatory follicular wave in the monovulatory species of heifers, mares, and women, the two largest follicles deviate in diameter at the end of a common follicle growth phase. The largest follicle before deviation becomes the future ovulatory follicle in most ovulatory waves. In 10-30% of the ovulatory waves, the destiny of the two follicles switches just before or at deviation so that the second-largest follicle becomes the future ovulatory follicle, and the largest follicle becomes a subordinate. In FSH-driven switching in heifers, mares, and women, the wave-stimulating FSH surge decreases to a low concentration before the largest follicle has developed the ability to utilize the low concentrations. The concentrations of FSH then increase (mares, women) or cease to decrease (heifers), and the next largest follicle acquires the capability of becoming the future ovulatory follicle. Luteolysis-driven switching has been reported in heifers but not in mares and women. The switching in heifers occurs during ovulatory wave 3 of three wave interovulatory intervals (IOI) when the wave of follicles is in the common growth phase in synchrony with the time of luteolysis. Regression of the CL during the common growth phase of ovulatory wave 3 is accompanied by decreased activity of follicles that are adjacent to the regressing CL but not when follicles and CL are separated or in opposite ovaries. The role of luteolysis in switching in heifers has been tested by treating with PGF2α when the largest follicle of wave 2 was near the end of the common growth phase. Switching in destiny of the largest follicle from the expected future dominant to a future subordinate occurred in most waves (10 of 17) when the largest follicle and regressing CL were in the same ovary and adjacent but not when separated in the same ovary or when in opposite ovaries (0 of 11). The newly selected future ovulatory follicle may develop in the opposite ovary. Thereby, frequency of the contralateral vs ipsilateral relationship between the preovulatory follicle and CL in heifers is greater in three-wave IOI than in two-wave IOI. In summary, the second largest predeviation follicle becomes the postdeviation dominant follicle when the decreasing FSH is out of phase with the largest predeviation follicle in heifers, mares, and women or when luteolysis and predeviation are in synchrony in heifers.

Effect of progesterone administration during growing phase of first dominant follicle on follicular wave pattern in buffalo heifers

In buffaloes, like other domestic mammals, antral follicles develop in a wave-like pattern. Factors predictive of a particular follicular wave pattern are yet to be identified. In this study, we examined the preponderance of 2- versus 3-wave patterns in 46 interovulatory intervals (IOIs) from 36 buffalo heifers, in which a subset of 10 heifers was scanned for 2 consecutive IOIs to record the repeatability of follicular wave pattern. Two-wave pattern was detected in 63.0% and 3-wave follicular pattern in 27.0% IOIs. The dominant follicles (DF) of both wave 1 as well as the ovulatory wave attained a smaller (P < 0.05) maximum diameter in 3-wave cycle as compared to 2-wave cycle. The mean duration of IOI was significantly shorter in 2-wave compared to three-wave cycles (20.5 ± 0.3 vs. 22.3 ± 0.2 days; P < 0.05). Out of 10 buffalo heifers, 7 displayed non-alternating patterns and 3 had alternating follicular wave patterns. We also tested the hypothesis that progesterone administration during early IOI results in increased preponderance of 3-wave pattern and heifers inseminated after ovulation of the third wave DF will have greater fertility. Sixteen heifers subjected to progesterone treatment from D0 (day of ovulation) in a decreasing dose until D5 were compared with control heifers (n = 10). Progesterone treatment significantly reduced the maximum diameter of DF of wave 1 (P < 0.001), whereas the mean duration of IOI remained unchanged (P > 0.05) between the two groups. Progesterone administration during early IOI significantly increased the proportion of 3-wave cycles as compared to control (P < 0.05). The hypothesis that progesterone administration during IOI results in increased preponderance of 3-wave pattern was supported. However, no change in fertility was recorded in progesterone-treated heifers (7 pregnant out of 16; 43.8%) as compared to untreated control heifers (4 out of 10 heifers; 40.0%). In summary, progesterone administration in buffalo heifers during the growing phase of wave 1 resulted in greater preponderance of 3-wave follicular patterns, with no significant effect on fertility.

An FSH booster surge for resurgence of the preovulatory follicle in heifers

Emergence of wave 1 during an interovulatory interval (IOI) in heifers is stimulated by FSH surge 1. A minor FSH surge with absence of a dominant follicle in the associated follicular wave occurs immediately before FSH surge 1. This minor surge is termed an FSH booster surge owing to its occurrence temporally during a resurgence of a preovulatory follicle that has been decreasing or lagging in growth rate for several days. The beginning nadir, peak, and ending nadir of the FSH booster surge occur at means of 7, 4, and 3 d before ovulation. The beginning nadir occurs at the beginning of a decrease in growth rate of the preovulatory follicle, and the peak occurs at the beginning of resurgence. The frequency of an FSH booster surge in 1 study was 10/17 (59%) and 4/18 (22%) in 2-wave and 3-wave IOI, respectively. The presence versus absence of a booster surge in 3-wave IOI is associated with a slower growth rate of the preovulatory follicle and a longer IOI. Most 3-wave IOI have rapid growth rate of the preovulatory follicle and do not have an FSH booster surge. Estradiol is a known FSH suppressor and begins to decrease at the beginning of the FSH booster surge and the beginning of a lag in growth rate of the preovulatory follicle. Concentration of LH increases significantly by the day of the peak of the booster surge. However, LH increases during waves with and without resurgence of the preovulatory follicle, whereas the FSH booster surge develops only in waves with resurgence in both 2-wave and 3-wave IOI. The beginning nadir of the booster surge is accompanied sometimes (eg, 6 of 10 surges) by the emergence of a minor follicular wave which does not develop a dominant follicle. Emergence of the booster wave and beginning FSH nadir occur earlier than the first progressive increase in LH indicating that the minor wave is attributable to the FSH booster surge. Based on temporality, the booster surge is used to stimulate recruitment or emergence of some of the small antral follicles (eg, 1 and 2 mm) that will become part of wave 1 of the next IOI. The primary function of the FSH booster surge as indicated by close temporality is to stimulate resurgence of a preovulatory follicle that has been lagging in growth rate. It is not known whether the booster surge and resurgence of the preovulatory follicle are essential for complete and normal maturation of the follicle and oocyte and for ovulation.

Positive effects of biostimulation on luteinizing hormone concentration and follicular development in anestrous beef heifers

The objectives of this study were to characterize the LH secretion pattern and the follicular development of anestrous beef heifers during early exposure (first 30 d of exposure) to androgenized steers (AS) and to determine if exposure to AS for 80 d (includes the first 30 d and 50 d more) advances the onset of ovarian cyclic activity. Twenty-nine anestrous Hereford heifers (20.2 ± 4.1 mo old and 257.5 ± 32.5 kg of BW) were allocated to 2 homogeneous groups according to their age and BW: 1) heifers exposed to AS (group EH; = 15) for 80 d and 2) control heifers, isolated from AS and any other male during all the course of the study (group CH; = 14). On d 0, 3 AS were joined with the EH group, which were removed and replaced with other 3 AS on Day 14. On d -10, 1, 10, 20, and 30, 8 heifers per group were housed in individual stalls and blood samples for LH were collected at 15-min intervals for 6 h. From d -10 to 30, the maximum follicle diameter (MFD) and the presence of a corpus luteum (CL) was daily recorded by ultrasound scanning and estrous behavior was detected twice daily. The emergence of follicular waves (FW), defined as the day when the dominant follicle of a wave was first observed (3-4 mm diam.), was retrospectively determined. Afterward, ultrasound scannings were performed weekly from d 32 to 60 and on d 70 and 80 to determine the presence of CL. After 10 d of male exposure, LH concentrations, either mean (1.67 vs. 0.88 ng/mL [SEM 0.09]) or basal (1.53 vs. 0.74 ng/mL [SEM 0.09]), were greater ( < 0.05) in the EH group than in the CH group. There was a treatment effect in MFD, as it was greater in EH than in CH ( = 0.05; 8.00 ± 0.16 vs. 7.52 ± 0.17 mm, respectively), but none of those follicles ovulated during the 40-d period. The MFD of the second FW was greater in EH than in CH, in coincidence with the transient increase on LH concentrations, which probably induced the greater follicular growth. Cumulative proportions of heifers that started to cycle were greater ( = 0.01) in EH than in CH on d 60 (33.3 vs. 0%), 70 (47 vs. 0%; < 0.005), and 80 (53 vs. 0%; < 0.001) of the exposure period. In conclusion, exposure of anestrous beef heifers to AS resulted in a transient increase on LH secretion after 10 d of male exposure and increased follicular diameter attained during the second FW. In addition, ovarian cyclic activity was advanced in exposed heifers.

Characteristics and functions of a minor FSH surge near the end of an interovulatory interval in Bos taurus heifers

The apparent function of a minor FSH surge based on temporality with follicular events was studied in 10 heifers with 2 follicular waves per interovulatory interval. Individual follicles were tracked from their emergence at 2 mm until their outcome was known, and a blood sample was collected for FSH and LH assay every 12 h from day -14 (day 0 = ovulation) to day 4. A minor FSH surge occurred in each heifer (peak, day -4.6 ± 0.2). Concentration of LH increased (P < 0.05) during the FSH increase of the minor surge but did not decrease during the FSH decrease. A minor follicular wave with 8.2 ± 2.0 follicles occurred in 6 of 10 heifers. The maximal diameter (mean, 3.4 ± 0.9 mm) of 77% of the minor-wave follicles occurred in synchrony on day -4.4 ± 0.4. Most (59%) of minor-wave follicles regressed before ovulation and 41% decreased and then increased in diameter (recovered) on day -1.9 ± 0.3 to become part of the subsequent wave 1. A mean of 3.7 ± 0.9 regressing subordinate follicles from wave 2 recovered on the day before or at the peak of the minor FSH surge. The growth rate of the preovulatory follicle decreased (P < 0.02) for 3 d before the peak of the minor FSH surge and then increased (P < 0.03). Concentration of LH increased slightly but significantly temporally with the resurgence in growth rate of the preovulatory follicle. A minor LH surge peaked (P < 0.0002) on day 3 at the expected deviation in growth rates between the future dominant and subordinate follicles. Results indicated on a temporal basis that the recovery of some regressing subordinate follicles of wave 2 was attributable to the minor FSH surge. The hypothesis was supported that some regressing follicles from the minor follicular wave recover to become part of wave 1.

Associations Between Antral Ovarian Follicle Dynamics and Hormone Production Throughout the Menstrual Cycle as Women Age

BACKGROUND

The physiological origins of age-related changes in hormone production during the menstrual cycle are uncertain.

OBJECTIVE

The objective of the study was to test the hypothesis that changes in antral follicle dynamics are associated with changes in hormone production as women age.

METHODS

A prospective, observational study was conducted in ovulatory women of midreproductive age (MRA; 18-35 y; n = 10) and advanced reproductive age (ARA; 45-55 y; n = 20). The numbers and diameters of all follicles of 2 mm or greater were quantified ultrasonographically every 1-3 days for one interovulatory interval; the growth profiles of individually identified follicles of 4 mm or greater were tabulated. Blood samples were assayed for FSH, LH, estradiol, progesterone, inhibin A and B, and anti-Mullerian hormone.

RESULTS

Fifty percent of women in both the MRA and ARA groups developed one to two luteal-phase dominant follicles (LPDFs). MRA women with typical LPDFs had greater luteal-phase inhibin B (44.2 vs 17.0 ng/L) and estradiol (91.3 vs 51.7 ng/L) compared with those without LPDFs (P < .05). Luteal-phase estradiol was greater (184 vs 79 ng/L), inhibin B was greater (25.3 vs 12.7 ng/L), and progesterone was lower (6.98 vs 13.8 μg/L) in ARA women with atypical vs no LPDFs (P < .01).

CONCLUSION

Changes in antral follicle dynamics are associated with changes in hormone production as women age. The development of LPDFs in women of MRA was associated with elevated luteal-phase estradiol. A similar but exaggerated elevation in late luteal-early follicular-phase estradiol, accompanied by lower progesterone, was observed in ARA women with atypically large and persistent LPDFs.