Vitrification of equine expanded blastocysts following puncture with or without aspiration of the blastocoele fluid

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.

Effect of different manual puncture methods on donkey embryo before vitrification

The application of embryo recovery and transfer technology in the donkey industry is far lower than that of horses and cattle. Sometimes the recovered embryos could not be transferred in time, which required embryo cryopreservation. The embryo cryopreservation technology is more conducive to the preservation and transportation of recovered embryos with excellent genetic traits. However, this technique for donkey embryos is not efficient and needs further optimization. The objective of this study was to evaluate the effect of different manual puncture methods on the viability and pregnancy rates of vitrified-thawed donkey embryos. A total of 117 donkey embryos were recovered on day 7-8 post-ovulation and were divided into four groups by random assortment. There were 28 embryos without puncture or cryopreservation (Control). 58 embryos were manually punctured using a 29G needle (VG, n = 29) or microneedle with a sharp tip of <10 μm (VM, n = 29), then vitrified in 15% EG + 15% DMSO + 0.5 M sucrose. Another 31 embryos were punctured with a microneedle and vitrified with 10% EG + 10% DMSO +0.5 M sucrose +2 mol/L proline (VMP). Both fresh embryos and vitrified-thawed embryos were incubated for 3 h (38.5 °C, 5% CO2 in air) before embryo transfer. The results showed that the embryo recovery rates on day 7.5 and 8 were higher than day 7 (P < 0.05). After incubation, dead cells were assessed and the percentages of dead cells in VM and VMP were lower than that in VG (P < 0.05), although both were higher than those in Control (P < 0.05). The pregnancy rates after 23 days post transfer were assessed and the results showed that the pregnancy rate in VG (8.0%) was lower than that in Control (41.7%), VM (24.0%) and VMP (29.6%) (P < 0.05). No pregnancies resulted from the 10 embryos with diameters ≤650 μm in VG, which lower than either VM (33.3%) or VMP (38.9%) (P < 0.05). While, there was no difference in pregnancy rates among all vitrification groups when embryos were >650 μm in diameter (P > 0.05). In conclusion, the embryo recovery rate on day 7 after ovulation was relatively low, and it was more appropriate to extend it to day 8. Microneedle puncture could reduce embryo damage and achieve a higher pregnancy rate compared with 29G needles. Proline has the potential to improve donkey embryo cryopreservation.

Vitrifying expanded equine embryos collapsed by blastocoel aspiration is less damaging than slow-freezing

The cryotolerance of equine blastocysts larger than 300 μm can be improved by aspirating blastocoele fluid prior to vitrification; however, it is not known whether blastocoele aspiration also enables successful slow-freezing. The aim of this study was therefore to determine whether slow-freezing of expanded equine embryos following blastocoele collapse was more or less damaging than vitrification. Grade 1 blastocysts recovered on day 7 or 8 after ovulation were measured (>300-550 μm, n = 14 and > 550 μm, n = 19) and blastocoele fluid was aspirated prior to slow-freezing in 10% glycerol (n = 14), or vitrification (n = 13) in 16.5% ethylene glycol/16.5% DMSO/0.5 M sucrose. Immediately after thawing or warming, embryos were cultured for 24 h at 38 °C and then graded and measured to assess re-expansion. Control embryos (n = 6) were cultured for 24 h following aspiration of blastocoel fluid, without cryopreservation or exposure to cryoprotectants. Subsequently, embryos were stained to assess live/dead cell proportion (DAPI/TOPRO-3), cytoskeleton quality (Phalloidin) and capsule integrity (WGA). For 300-550 μm embryos, quality grade and re-expansion were impaired after slow-freezing but not affected by vitrification. Slow-freezing embryos >550 μm induced additional cell damage as indicated by a significant increase in dead cell proportion and disruption of the cytoskeleton; neither of these changes were observed in vitrified embryos. Capsule loss was not a significant consequence of either freezing method. In conclusion, slow-freezing of expanded equine blastocysts collapsed by blastocoel aspiration compromises post-thaw embryo quality more than vitrification.

"Comparison of two closed vitrification methods for vitrifying dromedary camel (Camelus dromedarius) embryos"

A total of 184 dromedary camel embryos were vitrified using a novel vitrification kit specifically developed for camel embryos. These embryos were vitrified using a 3-step process by exposing them to vitrification solutions (VS) containing 20% foetal calf serum (FCS) with (+) or without (-) the addition of bovine serum albumin (BSA). Embryos were then further divided into two groups (<or ≥ 500 μm), vitrified using a closed vitrification system and stored on a Cryolock® embryo storage device or vitrified using solid surface vitrification of the Cryologic Vitrification Method (CVM)™ and stored on a Fibreplug™ embryo storage device. Embryos were then warmed and transferred in pairs, of approximately equal size, into recipient camels on Day 6 after ovulation. A total of 92 embryos were vitrified using the Cryolock; 86 embryos (C-BSA, n = 46; C + BSA, n = 40) survived warming, and were then transferred into 43 recipients. The pregnancy rate (PR) per recipient was 17% (C-BSA: 4/23) and 45% (C + BSA: 9/20) at 20 days after transfer but reduced to 9% and 30% at 60 days of gestation, respectively. For the Fibreplug group, a total of 92 embryos were vitrified, 86 embryos (F-BSA, n = 44; F + BSA, n = 42) survived warming, and were transferred into 43 recipients. The PR per recipient was 73% (F-BSA: 16/22) and 48% (F + BSA: 10/21) at 20 days after transfer but reduced to 50% (11/22) and 33% (7/21) at 60 days of gestation, respectively. Of the 39 pregnancies at 20 days after transfer, 77% (30/39) resulted from embryos with a diameter of 300-450 μm and 23% (9/39) were from embryos with a diameter of 500-850 μm. In conclusion, 1) significantly higher pregnancy rates were achieved when embryos were vitrified using the Fibreplug than using the Cryolock; 2) the effect of BSA on embryo vitrification is dependent on embryo storage device type and embryo diameter; 3) smaller vitrified embryos (<500 μm) tend to produce higher pregnancy rates than larger embryos (≥500 μm), however, the negative effect of embryo size on embryo vitrification is reduced when embryos are frozen using the original novel vitrification kit (no BSA) solid surface vitrification using the CVM.

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.