Successful vitrification of equine embryos >300 microns without puncture or aspiration.

BACKGROUND: Equine embryos >300 µm require puncture before vitrification. Protocols that do not require pre-puncture would make vitrification easier and allow for its widespread use. OBJECTIVES: To design a successful vitrification protocol for embryos >300 µm without puncture as a pre-treatment. STUDY DESIGN: Experimental in vivo study. METHODS: Thirty-eight embryos were divided into 3 groups (G1: ≤300 µm, n = 11; G2: >300-500 µm, n = 20; G3: >500 µm, n = 7). Embryos were vitrified using a human vitrification kit. Following a 15 min exposure to equilibration solution (ES; 7.5% DMSO +7.5% ethylene glycol [EG] in a base medium [BM] of M199 HEPES-buffered medium [H199] + hydroxypropyl cellulose + gentamycin), embryos were exposed for ≤90 s to a vitrification solution (15% DMSO +15% EG + 0.5 M trelahose in BM), loaded onto a Cryolock and plunged into LN2. Warming was undertaken by plunging the Cryolock tip into 1 mL of H199 + 20% FBS + pen/strep +1 M sucrose at 42°C for 1 min. The embryos were then moved to a 0.5 M sucrose solution for 4 min, then placed in Vigro Hold for 4 min prior to transfer to a recipient. RESULTS: Pregnancy rates were 81.8% (9/11) for G1, 80% (16/20) for G2, and 0% (0/7) for G3. The largest embryo to survive was 480 µm. MAIN LIMITATIONS: Limited numbers and only one pregnancy was followed to term. CONCLUSIONS: Equine embryos ≤480 µm can be successfully vitrified using a protocol with a longer exposure time to the ES. This does not appear to have a negative effect on early embryonic development.

The effect of embryo reduction and transfer on luteostasis in the mare.

This study investigated the effects of embryo reduction and transfer of Day 11 embryos, with or without subsequent reduction, on luteostasis in the mare. In Experiment 1, reduction of embryos at Days 10 (n = 15), 11 (n = 47), 12 (n = 36), 13 (n = 27), 14 (n = 5) and 16 (n = 2) of pregnancy resulted in luteostasis in 13%, 47%, 78%, 89%, 80% and 100% mares. Mares undergoing > 1 embryo reduction showed consistency in when luteostasis occurred. In Experiment 2, transfer of Day 11 embryos to recipient mares 10 (n = 9), 11 (n = 8), 12 (n = 9) and 13 (n = 8) days post ovulation resulted in luteostasis in 78%, 87.5%, 78% and 37.5% of mares. Only 22%, 37%, 0% and 12%, respectively, of these mares remained pregnant. In the Day 10, 11 and 12 recipients luteostasis occurred on at least one occasion when an embryo was detected at 24 h but not at 48 h post transfer. In the Day 12 recipients luteostasis occurred on three occasions (3/9;33%) when the transferred embryo was not detected at 24 h. In Experiment 3 reduction of a Day 11 embryo 24 h after transfer to a Day 10 (n = 4), 11 (n = 6), 12 (n = 6) or 13 (n = 6) recipient resulted in luteostasis in 100%, 83%, 100%, and 83% of mares. All five Day 11 recipients that had an embryo reduced 12 h post transfer became luteostatic. These results suggest there is plasticity overall, but individual rigidity, in the timing of maternal recognition of pregnancy. Furthermore, an intact embryo need only be present in the uterus for 12 h to cause luteostasis.

Successful vitrification of manually punctured equine embryos.

BACKGROUND: Successful vitrification of equine expanded blastocysts requires collapse of the blastocoele cavity using a micromanipulator-mounted biopsy pipette on an inverted microscope. Such equipment is expensive and requires user skill. OBJECTIVES: To develop a manual method of blastocoele collapse prior to vitrification using commercial products. STUDY DESIGN: In vivo experiment. METHODS: Seventy-nine Day 7 or 8 embryos were measured and graded. Twenty were vitrified following micromanipulator-assisted puncture and aspiration before being used to validate commercial human vitrification and warming kits containing, respectively, 2-step concentrations of DMSO and ethylene glycol (7.5%-15% v:v) and decreasing concentrations of sucrose. After warming, embryos were transferred to recipient mares. Once validated, the commercial kits were used to vitrify and warm a further 39 embryos which were punctured manually using a microneedle, 2 (5%) were damaged during puncture and excluded; 20 more embryos were vitrified without puncture. Embryos were grouped as follows: non-punctured ≤ 300µm (n = 10) and >300 to ≤560 µm (n = 10), punctured small (>300 to ≤560 µm; n = 17) and large (>560 µm; n = 10) and exposed to the equilibration solution (ES) in the kit for 6min. An additional group of punctured large embryos was exposed to ES for 8min (n = 10). For the initial warming step, embryos were exposed for 1min to the thawing solution at 42°C, before being moved to a dilution solution at room temperature. RESULTS: Vitrified, manually punctured embryos ≤560 µm exposed to ES for 6min resulted in a pregnancy rate of 82% (14/17). Unpunctured embryos ≤300 µm gave an 80% (8/10) pregnancy rate. Larger unpunctured embryos, punctured embryos >560 µm and embryos exposed to ES for 8min gave significantly reduced pregnancy rates. MAIN LIMITATIONS: Limited group sizes. CONCLUSION: High pregnancy rates can be achieved by manually puncturing ≤560 µm equine embryos prior to their vitrification and subsequent warming in commercial media.

Puncture of the Equine Embryonic Capsule and Its Repair In Vivo and In Vitro.

Vitrification of embryos >300 µm in diameter requires puncture of the glycoprotein capsule, although the size of the hole compatible with embryo survival is unknown. Forty-five day-7 or -8 embryos were punctured using a 30-µm glass biopsy pipette mounted on a micromanipulator (n = 20) or manually with either an acupuncture needle (∼100-µm diameter -hole; n = 10) or a microneedle with a <1 µm tip to produce a ∼30-µm diameter hole (n = 15) before transferring to recipient mares; further 12 embryos were punctured with either the acupuncture needle or microneedle before being cultured in vitro for 48 hrs (n = 3 per puncture group) or transferred to recipient mares and recovered 48 hrs later (n = 3 per puncture group). No pregnancies resulted from the 10 embryos punctured with the acupuncture needle, whereas 15 of 20 (75%) and 10 of 15 (67%) punctured on the micromanipulator or manually with the microneedle resulted pregnancies. Neither acupunctured nor microneedle-punctured embryos repaired their capsules in vitro. The acupunctured embryos also failed to repair their capsule after 48 hrs in vivo and subsequent uterine flushing yielded numerous capsular vesicles. The microneedle-punctured embryos did repair their capsule in vivo. Puncture with the microneedle opens the way for development of a manual method to vitrify equine embryos.