Ultrasonic imaging of equine ovarian follicles and corpora lutea.

One of the most profound theriogenology applications of transrectal diagnostic ultrasonography in mares involves the imaging of ovarian follicles and corpora lutea. The resolving capabilities (frequency) and quality of the scanner directly affect the minimal size of a structure that can be imaged and the quality of the image. High-frequency scanners (5 or 7.5 MHz) of good quality can image a 2-mm follicle and the corpus luteum throughout its functional life. A low-frequency scanner (3 or 3.5 MHz) can image a 6-mm follicle and the corpus luteum for several days after ovulation. Equine follicles are excellent subjects for transrectal imaging because they are large, filled with fluid, and readily accessible. Event the small follicles (less than 10 mm) can be diagnostically important in evaluating whether ovarian infertility has occurred and whether the follicles are responding to treatment for follicular stimulation. The large, preovulatory follicles are of special interest. Averaged over a group of 79 periods, the following significant changes were found in the preovulatory follicle: increasing diameter, shape change from spherical to pear-shaped or conical, and increasing thickness of the follicular wall. No significant changes were found in the echogenicity (gray-scale value) of the wall or fluid. In retrospect, the diameter of the follicle seemed as useful for predicting impending ovulation as any of the other ultrasound criteria. The occurrence of ovulation is readily detected by the disappearance of a large follicle that was present at a recent previous examination. In addition, the ovulation site on the day of ovulation is detectable. In one study, the site was correctly identified in 24 of 24 mares. A small amount of residual follicular fluid can sometimes (7 of 10 in one study) be detected at the site of ovulation. The residual fluid usually disappears over a period of 0.5 to 20 hours. Subsequently, the developing corpus luteum may form a central nonechogenic area with peripheral luteinization or may remain uniformly luteinized. The central areas are of apparently vascular origin (blood or a component of blood) and become clotted and organized. In one study, approximately 50 per cent of the glands developed central areas exceeding 10 per cent of the size of the gland. The central areas began to develop on Day 0 or 1 and continued to enlarge until Day 2 or 3. The relative proportion of the gland containing a central clot decreases after Day 3, but the central area usually remains visible throughout diestrus.(ABSTRACT TRUNCATED AT 400 WORDS)