Cryopreservation of poultry sperm: the enigma of glycerol

Avian Genetic Resource Banking: Can Fish Embryos Yield Any Clues for Bird Embryos?

Cryopreservation of avian germplasm is becoming better understood and more commonly practiced. However, one area that would be of great benefit for genome resource banking is the preservation of avian embryos. Little is know about the cryobiology of avian embryos, and they have never been successfully cryopreserved. However, it is likely that they share many of the challenges of other yolk-filled multicompartmental embryos. For example, the fish embryo has 1) a large overall size, resulting in a low surface-to-volume ratio, which retards water and cryoprotectant efflux/influx; 2) large-sized cells, such as the yolk, which could increase the likelihood of membrane disruption by intracellular ice formation; 3) compartments, such as the blastoderm and yolk, with differing permeability properties; and 4) susceptibility to chilling injury. Both the avian and fish systems share many physical and anatomical properties, and it is predicted that some of the same permeability barriers would exist in both as well. Although the systems are similar, some of the goals, and thus the practices, to protect the genome may be quite different. One of these major goals in avian developmental biology is to produce chicken:chicken transgenic animals, especially those with germ line transmission. Producing efficient germ line transmissions and being able to cryopreserve these transmissions would be extremely beneficial to both basic and agricultural science. This could be accomplished through the cryopreservation of embryonic gonadal tissue followed by grafting into a host. The gonadal/tail-graft system would provide an advantage for cryopreservation because it is small (in comparison with the whole embryo), has fairly uniform tissue, and contains the essential primordial germ line cells capable of recreating the genetic line of interest. Moreover, because the chicken is such a robust model for most other avian species, the cryopreservation of the gonadal/tail-graft may potentially open up similar treatments for other commercially important species.

The National Animal Germplasm Program: Challenges and Opportunities for Poultry Genetic Resources

In the United States, poultry genetic resources have consolidated because of economic pressures. Such consolidations can potentially jeopardize the poultry industry and the ability of research communities to respond to future challenges. To address the loss of genetic resources for all livestock and aquatic species, USDA established the National Animal Germplasm Program (NAGP) in 1999. Since the initiation of NAGP, population surveys have been conducted on nonindustrial chicken and turkey breeds. These surveys not only provide insight into breed status, but also serve as a benchmark for future comparisons. The survey results revealed that 20 chicken breeds and 9 turkey breeds were in various stages of being lost. The NAGP has initiated an ex situ repository for cryopreserved germplasm and tissue that already contains 59 chicken lines and 2,915 tissue samples. As the NAGP, along with its industry and university partners, continues developing the ex situ collection, there are research opportunities in cryopreserved tissue utilization and studies of genetic diversity. For cryopreserved tissues, several key research areas include improving the cryopreservation protocols for rooster and tom semen by using cryoprotectants other than glycerol and utilizing embryonic cells. Although surveys have been conducted on public research lines and rare breeds, there is a void in understanding the level of genetic diversity present in U.S. poultry populations. Therefore, an opportunity exists to perform a series of genetic diversity studies using molecular- based approaches. Such an evaluation can help clarify population differences between research lines and rare breeds and, thereby, facilitate conservation strategies. There appears to be growing consumer interest in poultry products derived from heritage breeds and/or poultry raised in nonindustrial production systems. Although the depth of such market trends is unknown, such an interest may provide an important niche for rare poultry breeds and, thereby, strengthen the genetic base.

French field results (1985–2005) on factors affecting fertility of frozen stallion semen

Results on procedures for freezing stallion semen and the subsequent fertility during 20 years are presented. The present system applied in French National Stud includes: (1) a freezing protocol (dilution in milk, centrifugation and addition of freezing extender (INRA82+egg yolk (2%, v/v)+glycerol (2.5%, v/v) at 22 degrees C, a moderate cooling rate to 4 degrees C and freezing at -60 degrees C/min in 0.5-ml straws); (2) selection of ejaculates showing post-thaw rapid motility >35%; and (3) an insemination protocol (mares examined once daily, two AI of 400 x 10(6) spermatozoa 24 h apart before ovulation, sufficient number of straws to have the possibility to perform six AI of 400 x 10(6) total spermatozoa, i.e. 2.4 x 10(9) total spermatozoa available per mare per season). This system was applied to >110 stallions per year, the average post-thaw motility of ejaculates was 50% (>1800 ejaculates) before selection. The semen freezability was defined as the number of selected ejaculates divided by the total number of ejaculates frozen. Of the stallions, 5, 4, 5, 21 and 64% had semen freezability of 0-10, 10-33, 33-60, 60-90 and over 90%, respectively. Per-cycle pregnancy rate was 45-48% (>1500 mares per year, 1.8 cycles per mare) and foaling rate 64%. In comparison, per-cycle pregnancy rate and foaling rate of mares hand-mated to stallions were 57-59% and 64%, respectively. The average number of straws used was 32-35 (1.75 x 10(9) total spermatozoa) per mare per season. According to our results and the literature, the most important factors for improving fertility of frozen equine semen include: (1) a low concentration of glycerol (2-3.5% final concentration); (2) a suitable base extender for freezing like Lactose-Glucose EDTA or INRA82; (3) a post-thaw motility >30-35%; and (4) a sufficient number of spermatozoa per mare per season (1.5-2 x 10(9) total spermatozoa for two to three cycles) divided into small units. Numbers of spermatozoa, lower than 750.10(6) total spermatozoa per cycle, could result in lower per-cycle pregnancy rate with higher additional costs for management of mares. Because there are no particular regulations on quality and quantity of equine semen in the European Community, there is a need for the uniformity of information about frozen semen. A codification is suggested, based on the number of spermatozoa available per mare per season, the post-thaw motility and the final glycerol concentration.

Amides as cryoprotectants for freezing stallion semen: A review

Stallion semen cryopreservation, despite its impact on the horse industry, is not an established technology. During the last years, a number of modifications have been proposed to the freezing process, however, a large population of stallions still have poor semen quality and fertility after frozen-thawed. Glycerol toxicity could be a reason for the variation on stallion sperm freezability. There are limited publications concerning the use of alternative cryoprotectants for equine sperm. Glycerol is contraceptive for some species and other cryoprotectors, such as amides, have been show to be a good option for freezing semen of these species. Recent reports have shown encouraging data respecting the use of amides as cryoprotectants for stallions, with more remarkable improvements for semen from stallions that freeze poorly when glycerol is used.

Cryopreservation of human spermatozoa: Comparison of two cryopreservation methods and three cryoprotectants

OBJECTIVE

To evaluate the ability of two cryopreservation methods and three cryoprotectants to preserve sperm quality.

DESIGN

A prospective clinical study.

SETTING

Male infertility clinic at a tertiary healthcare center.

PATIENT(S)

Twenty infertile men and 10 healthy donors.

INTERVENTION(S)

In the first experiment, semen was cryopreserved by either the Irvine Scientific method (IS) or the Cleveland Clinic Foundation (CCF) method. In the second experiment, semen was cryopreserved by the IS method and one of three cryoprotectants: TES and Tris yolk buffer, Sperm Freezing Medium, or Enhance Sperm Freeze.

MAIN OUTCOME MEASURE(S)

Postthaw sperm motility, cryosurvival, and kinematics.

RESULT(S)

Percentages of postthaw sperm motility and cryosurvival were higher in the IS cryopreservation method compared with in the CCF method (15.94 +/- 9.19 vs. 12.07 +/- 7.31 and 47.42 +/- 17.44 vs. 35.76 +/- 17.56). However, the CCF method resulted in significantly better sperm kinematics. Postthaw motility in the donors and patients was highest in the samples frozen in TES and Tris yolk buffer medium.

CONCLUSION(S)

The IS method was associated with more flash freezing compared with the CCF method and resulted in better preservation of sperm motility and a higher cryosurvival rate. TES and Tris yolk buffer was most effective at protecting sperm from the negative effects of the cryopreservation process. This may be due to the presence of egg yolk along with glycerol.

An effective method for improving the fertility of glycerol-exposed poultry semen

Semen cryopreservation is necessary for banking germplasm from critical poultry stocks. To date, glycerol is the most effective cryoprotectant for poultry sperm; however, the contraceptive effects of glycerol require a significant reduction of the cryoprotectant from thawed semen before artificial insemination (AI). The effectiveness of glycerol reduction by dialysis, Percoll density gradient centrifugation, or washing through 12% (wt/vol) Accudenz was evaluated by fertility trials with highly inbred chicken research lines and commercial turkey lines. Semen was extended 1:1 and then diluted with glycerolized extender to yield a final 11% (vol/vol) glycerol concentration. Glycerolized rooster semen was aliquoted for control, Accudenz centrifugation, and dialysis treatments. A total of 90 pure line and 85 F1 hybrid chicken hens were each inseminated with 100 x 10(6) sperm at 7-d intervals for 4 to 6 wk. All eggs from the glycerolized control semen treatments were infertile, and fertility rates from dialyzed semen decreased steadily from 26.4 to 0% within the first 4 wk for the pure lines. In contrast, fertility rates for Accudenz-processed semen increased from 17.9 to 37.17% during the first 4 wk. Similar fertility rates occurred with the F1 hybrid cross lines. For turkey fertility trials, the dialysis treatment was not used; glycerolized turkey semen was processed by Accudenz or Percoll centrifugation to reduce glycerol. A total of 36 hens were inseminated with 150 x 10(6) sperm at 7-d intervals for 6 wk. Similar to the chicken trials, fertility rates of Accudenz-processed semen steadily increased to 49.4% by the sixth week of insemination. The average fertility of Percoll-processed semen was only 19.1%. These data demonstrate that Accudenz centrifugation is an acceptable glycerol reduction method for nonfrozen poultry semen.

Evaluation of alternative cryoprotectants for preserving stallion spermatozoa

Although use of cryopreserved stallion spermatozoa is currently accepted by many breed registries, utilization of this technique remains limited due to poor fertility for some stallions. One reason for these results is osmotic stress that spermatozoa experiences when the cryoprotectant (glycerol) is added to the cells prior to freezing and removal from the cells after thawing. In an effort to minimize osmotic damage, alternative cryoprotectants, having lower molecular weights and greater membrane permeability than glycerol, were evaluated to determine their effectiveness for cryopreserving stallion spermatozoa. In the first experiment, equal molar concentrations of several amides were compared to determine if they could preserve the motility of sperm as well as glycerol. At 0.55 M concentration, addition of glycerol to a skim milk-egg yolk (SMEY) diluent resulted in higher percentages of motile sperm (61%) than methyl formamide (40%) or dimethyl formamide (38%, P<0.05), while formamide, acetamide, and methyl acetamide resulted in recovery of less than 20% motile cells (P<0.05). When methyl formamide or dimethyl formamide were increased to 0.6 or 0.9 M they resulted in percentages of motile cells (48-54%) similar to that achieved with glycerol (52%). Similarly, 0.9 M ethylene glycol also resulted in similar percentages of motile cells (43%). Replacing the glucose and fructose in the SMEY diluent with either raffinose or trehalose did not result in higher percentages of motile sperm (65 and 66%, respectively) than the control SMEY (63%). Similarly, addition of methyl cellulose also did not increase the percentages of motile spermatozoa in the samples, after cryopreservation (P>0.05). In conclusion, both methyl formamide and dimethyl formamide protected stallion spermatozoa from cryodamage as effectively as glycerol. Since these compounds permeate the plasma membrane more effectively than glycerol, they should cause less osmotic damage to stallion spermatozoa than glycerol. Therefore, these compounds may prove very effective in the cryopreservation of stallion spermatozoa, and may be particularly useful for spermatozoa from stallions that produce spermatozoa that have poor post-thaw characteristics when glycerol is used as the cryoprotectant.

A cryopreservation procedure for the rumen protozoon Entodinium caudatum: estimation of its viability by fluorescence microscopy

AIMS

To study the viability of a culture of the rumen protozoon Entodinium caudatum after a cryopreservation procedure by a fluorescence microscopy staining method.

METHODS AND RESULTS

Fluorescence method is based on the different colour of cells depending on their membrane integrity. When the temperature effect was studied either by fluorescence or motility, the techniques were correlated (r = 0.727) and their slopes and intercepts were not different (P > 0.05). However, motility showed a higher variation coefficient (0.40 vs 0.12). There were no differences between cooling rates at cryopreservation (1 and 4 degrees C min-1) at 38, 15 or 5 degrees C, nor after thawing.

CONCLUSIONS

Fluorescence staining is more accurate than motility for assessing protozoal viability. Viability after thawing was 0.50, and the number of viable cells per 250 microl straw was 320 and 420 for 1 and 4 degrees C min-1.

SIGNIFICANCE AND IMPACT OF THE STUDY

This cryopreservation procedure seems to ensure culture recovery for E. caudatum.

Field and in vitro assay of three methods for freezing ram semen

Glycerol has been the most widely used cryopreservation agent for spermatozoa and a wide range of factors affect its action on sperm viability and fertilizing capacity. We tested three methods for freezing ram semen packed in 0.25 ml straws (final cellular concentration: 100 x 10(6) spz/ml). Method M1: Two-thirds of the final volume of diluent was added as solution A (without glycerol) to the pure semen at 35 degrees C. The sample was cooled to 5 degrees C (-0.30 degrees C/min), one-third of final diluent volume was added as solution B (final concentration of glycerol 4%) and the sample was maintained at 5 degrees C for 2h. It was then frozen in a programmable biofreezer (-20 degrees C/min down to -100 degrees C). Method M2: The sample was diluted with a specific solution at 35 degrees C (final concentration of glycerol 3%), cooled to 5 degrees C (-0.20 degrees C/min) and left for 2h. After that, it was frozen in nitrogen vapours. Method M3: Semen was diluted 1:1 in a specific solution (concentration of glycerol 2%) and cooled to 5 degrees C (-0.25 degrees C/min). The sample was then diluted again in the same solution to the final cellular concentration (final concentration of glycerol 4%). It was left for 1h at 5 degrees C and then frozen in a programmable biofreezer (-20 degrees C/min down to -100 degrees C). Best total motility (TM) and progressive motility (PM) (75.8 and 55.18%) were obtained using Method M3. Methods M1 and M3 gave significantly higher values (P<0.05) for kinetic parameters: average path velocity (VAP) (81.3 and 85.2 microm/s), straight-line velocity (VSL) (72.8 and 77.3 microm/s) and linearity (LIN) (66.6 and 68.8%). Method M2 showed the lowest kinetic parameters of motility (VAP 74.4, VSL 67.3 and LIN 62.5) and the highest percentage of cells with damaged plasma membrane (53.8%). Method M1 gave the worst results in viability and acrosome status assessed using fluorescence probes (31.3%-dead cells with damaged acrosomes-versus 25.4% in M2 and 23.3% in M3). A field trial carried out on fertility showed a significantly higher percentage of pregnant or lambing ewes (P<0.05) with Method M3 (67.3% versus 51.1% for M1 and 58.8% for M2). We concluded that the use of a simple dilution medium (test-fructose-glycerol-egg yolk) with the addition of glycerol (to 2% at 35 degrees C and to 4% at 5 degrees C) in two steps together with a programmable biofreezer was a productive method for freezing ram semen.

Cryopreservation of canine semen using a coconut water extender with egg yolk and three different glycerol concentrations

Semen was collected by digital manipulation from six adult dogs. The second fraction of the ejaculate was used in this study. The semen was assessed by macroscopic and microscopic criteria 1 min after collection, first dilution, cooling, glycerol addition and thawing. Experiments were conducted to compare the effect of three different concentrations of glycerol in coconut water extender. The freezing method employed was that one described for caprine semen with slight changes. Semen was thawed at 37 degrees C for 1 min. Spermatozoal motility after thawing was 49.2+/-26, 44.2+/-18.3 and 35.8+/-26.8% for groups with 4, 6 and 8% glycerol, respectively. The vigor after thawing was 2.6+/-1.1, 2.7+/-1.0 and 2.1+/-1.2 for these groups, respectively. There was no difference among groups in motility and vigor. However, a smaller percentage of total and secondary abnormalities was observed using 6% glycerol in coconut water extender. In conclusion, the three glycerol concentrations (4, 6 or 8%) can be used successfully in cryopreservation of canine semen using a coconut water extender.

Isolation and unique composition of purified head plasma membrane from rooster sperm

The structure, composition, and function of membranes from organelles of mammalian spermatozoa differ from each other and from the sperm's plasma membrane. Avian sperm studies have suffered from the lack of a technique to isolate these various membranes, which the current study now provides. Nitrogen cavitation and differential centrifugation separated head plasma membranes (HPM) of rooster sperm from sperm debris, acrosomal membranes, and mitochondrial membranes and characterized these membranes enzymatically and microscopically. The HPM was enriched in acid phosphatase (marker enzyme for HPM; 1,814.81 +/- 470.43 micromol phosphate released/microg protein vs. 868.53 +/- 75.55 for whole semen; a 202.5 +/- 37.8% enrichment, mean +/- SE, P < 0.001), with less (P < 0.001) mitochondrial and acrosomal enzyme activity. The mitochondrial fraction had 515.1 +/- 167.6% more succinate dehydrogenase activity (marker for mitochondria, P < 0.001) and the acrosomal fraction had 315.4 +/- 61.2% more acetylglucosaminidase activity (marker for acrosome, P < 0.0001) than whole semen. Thin layer and gas chromatography showed that HPM lipids had more (P < 0.05) sphingomyelin and phosphatidylserine, and less phosphatidylcholine and phosphatidylethanolamine than did the sperm body membranes (SBM). Overall, HPM had less polyunsaturated fatty acids than SBM (36.8 +/- 3.4 vs. 44.5 +/- 1.7% of total phospholipids, P < 0.05). HPM had slightly more n3 (3.2 +/- 0.5 vs. 1.3 +/- 0.2%, P < 0.01) but much less n6 (33.6 +/- 3.3 vs. 43.3 +/- 1.9%, P < 0.01), specifically less C22:4n6. Future study of avian sperm will be able to reliably characterize the structure-function relationships of specific sperm membranes.

An effective method for freezing White Italian gander semen

Efficiency of freezing method, worked out for the White Italian gander semen was evaluated by comparing motility, morphology and fertilizing ability of spermatozoa in fresh and frozen-thawed semen. A part of pooled semen, collected from 25 White Italian ganders by dorso-abdominal massage was used immediately for artificial insemination of 10 geese (the control group) with a dose of 80 microl. This insemination was performed six times at weekly intervals. The remainder of the semen was diluted 1:0.5 (v/v) with EK diluent, equilibrated for 15 min at +4 degrees C, mixed with 6% (v/v) of dimethylformamide (DMF) and frozen to -140 degrees C at a rate of 60 degrees C/min. Frozen semen was thawed in a 60 degrees C water-bath and inseminated twice weekly in a dose of 100 microl (10 females of the experimental group, 12 inseminations were made). The freezing process affected spermatozoa motility and morphology, but had no effect on their fertilizing ability. Positive movement was observed in 50-60% of the spermatozoa in fresh semen and about 40% of the frozen-thawed cells. The average percentage of total live and live normal spermatozoa decreased due to freezing from 92.2 to 68.4% and from 34.7 to 14.1%, respectively. After the fresh semen insemination with average 12 million of the live normal spermatozoa per week average fertility was 88.24%; hatchability of set eggs was 80.88% and hatchability of fertile eggs was 91.67%. For frozen-thawed semen inseminated with average 9.5 million of the undamaged spermatozoa per week, the average fertility and hatchability rate was 83.78, 73.87, and 88.17%, respectively. Fecundity rates obtained after insemination with the frozen-thawed gander semen allow for the application of the freezing technique into breeding practice, in place of natural mating or to assist natural mating in periods of lowered fertility level.

DMF effects on frozen gander semen

1. The objective of the present study was to determine if the age of semen donors affects the susceptibility of spermatozoa to freezing and whether DMF (dimethyl formamide) inseminated with freeze-thawed gander semen decreases fertility. 2. Semen was collected 3 times a week by dorsal-abdominal massage from two groups of White Italian ganders: 3 and 2 years-old. Both samples were diluted, mixed with DMF to a final concentration of 6% (v/v), pre-frozen and transferred into LN2. 3. Twice a week, the freeze-thawed semen was used for insemination of two groups of geese at a dose of 4 to 16 million live morphologically normal spermatozoa. One group was inseminated immediately after thawing, the 2nd with semen from which the DMF was removed. 4. Donor age had no effect on the spermatozoa's aptitude for freezing. The differences in quality and quantity of fresh and freeze-thawed semen produced by 3 or 2 year-old ganders were not significant. 5. The presence of DMF in the inseminated freeze-thawed semen did not affect the reproductive efficiency of spermatozoa. The fertility rate obtained with semen inseminated either with or without the cryoprotectant averaged 92.9% and 87.2% respectively. The hatchability of set eggs was 81.1% and 79.9% and, the hatchability of fertile eggs amounted to 87.3% and 89.4%.

Glycerol: a neglected variable in metabolic processes?

Glycerol is a small and simple molecule produced in the breakdown of glucose, proteins, pyruvate, triacylglycerols and other glycerolipid, as well as release from dietary fats. An increasing number of observations show that glycerol is probably involved in a surprising variety of physiopathologic mechanisms. Glycerol has long been known to play fundamental roles in several vital physiological processes, in prokaryotes and eukaryotes, and is an important intermediate of energy metabolism. Despite some differences in the details of their operation, many of these mechanisms have been preserved throughout evolution, demonstrating their fundamental importance. In particular, glycerol can control osmotic activity and crystal formation and then act as a cryoprotective agent. Furthermore, its properties make it useful in numerous industrial, therapeutic and diagnostic applications. Few studies have focussed directly on glycerol, however, and while its metabolism is increasingly well documented, much of the details remain unknown. Considering the importance of glycerol in multiple vital physiological processes, its study could help unlock important physiopathological mechanisms.

Comparison of permeating and nonpermeating cryoprotectants for mouse sperm cryopreservation

Mouse sperm has proven to be more difficult to cryopreserve than sperm of other mammalian species. Published reports show that only three cryoprotectant agents (CPAs), alone or combined, have been studied: glycerol and dimethyl sulfoxide (DMSO), as permeating agents, and raffinose, as a nonpermeating agent. To date, the most consistent results for mouse sperm cryopreservation have been achieved by use of raffinose/skim milk as cryoprotectant with rapid cooling at 20 degrees C per minute. In this study, we compared the cryoprotection provided by permeating (glycerol, formamide, propanediol, DMSO, adonitol) or nonpermeating (lactose, raffinose, sucrose, trehalose, d-mannitol) compounds for freezing mouse sperm. Different solutions were made using 3% skim milk solution as the buffer or extender in which all different cryoprotectant agents were dissolved at a concentration of 0.3 M, with a final osmolality of approx. 400 mOsm. Sperm samples from CB6F1 (hybrid) and C57BL/6J (inbred) mice collected directly into each CPA were frozen/thawed under identical conditions. After thawing and CPA elimination (centrifugation) raffinose (59%), trehalose (61%), and sucrose (61%) sustained the best motility (P = < 0.1) of the nonpermeating agents, whereas the best of the permeating agents was DMSO (42%). Membrane integrity was analyzed and showed that the simple exposure (prefreeze) to sugars was less harmful than the exposure to glycols. Coincidentally, sperm frozen in trehalose (41%), raffinose (40.5%), and sucrose (37.5%) were the samples less injured among all different postthawed CPA tested. The in vitro fertilization results demonstrated that hybrid mouse spermatozoa frozen with sugars (lactose 80%, raffinose 80%, trehalose 79% of two-cell embryos production) were more fertile than those frozen with glycols (glycerol 11%).

Acrosomal ultrastructure of stallion spermatozoa cryopreserved with ethylene glycol using two packaging systems

The present experiments aimed to examine the substitution of glycerol (G) by ethylene glycol (E) as a cryoprotective agent for stallion spermatozoa. Two different ethylene glycol concentrations (5% and 10%) and also the association of glycerol (2%) and ethylene glycol (3%) (E/G) were studied (Experiment 1). In Experiment 2, two packing systems (0.5 x 4.0 ml) were evaluated using both cryoprotectors. In both experiments, the sperm membrane integrity after freezing was evaluated using transmission electron microscopy. The mean post-thaw motility was 34.25, 36.5, 29.25 and 34.75% for G5%, E5%, E10% and E/G, respectively. It was observed that the percentage of motile spermatozoa was significantly smaller (P<0.05) when semen was processed with E10%. A decrease in the acrosome integrity was observed in frozen thawed spermatozoa from all treated groups. It was observed that 28.0, 22.5, 25.5 and 22.5% of the sperm cells had a normal acrosome following freezing with G5%, E5%, E10% and E/G, respectively. Undulation of the outer acrosomal membrane, acrosomal swelling and loss of acrosomal content density and homogeneity were the most evident ultrastructural alterations observed. In Experiment 2, the post-thaw motility was higher (P<0.05) for sperm frozen in 0.5 ml straws than in 4.0 ml straws, regardless of the cryoprotector used. The ultrastructural evaluation showed 26.7 and 16.0% of intact acrosomes for sperm frozen in 0.5 ml and 4.0 ml straws, respectively. We concluded that ethylene glycol has similar cryoprotective properties to glycerol and that utilisation of 0.5 ml straws improved the ability of horse sperm cells to withstand damage after the cryopreservation process.

Species variation in osmotic, cryoprotectant, and cooling rate tolerance in poultry, eagle, and peregrine falcon spermatozoa

Potential factors influencing spermatozoa survival to cryopreservation and thawing were analyzed across a range of the following avian species: domestic chicken (Gallus domesticus), domestic turkey (Meleagris gallopavo), golden eagle (Aquila chrysaetos), Bonelli's eagle (Hieraaetus fasciatus), imperial eagle (Aquila adalberti), and peregrine falcon (Falco peregrinus). Studies focused on spermatozoa tolerance to the following: 1) osmotic stress, 2) different extracellular concentrations of the cryoprotectant dimethylacetamide (DMA), 3) equilibration times of 1 versus 4 h, 4) equilibration temperature of 4 versus 21 degrees C, and 5) rapid versus slow cooling before cryopreservation and standard thawing. Sperm viability was assessed with the live/dead stain (SYBR-14/propidium iodine). Sperm viability at osmolalities >/=800 mOsm was higher (P: < 0.05) in raptor than poultry semen. Return to isotonicity after exposure to hypertonicity (3000 mOsm) decreased (P: < 0.05) number of viable spermatozoa in chicken, turkey, and golden and Bonelli's eagle spermatozoa but not in imperial eagle or peregrine falcon spermatozoa. Differences were found in spermatozoa resistance to hypotonic conditions, with eagle species demonstrating the most tolerance. Semen, equilibrated for 1 h (4 degrees C) in diluent containing DMA (> or =2.06 M), experienced decreased (P: < 0. 05) spermatozoa survival in all species, except the golden eagle and peregrine falcon. Number of surviving spermatozoa diminished progressively with increasing DMA concentrations in all species. Increased equilibration temperature (from 4 to 21 degrees C) markedly reduced (P: < 0.05) spermatozoa survival in all species except the Bonelli's eagle and turkey. Rapid cooling was detrimental (P: < 0.05) to spermatozoa from all species except the imperial eagle and the chicken. These results demonstrate that avian spermatozoa differ remarkably in response to osmotic changes, DMA concentrations, equilibration time, temperature, and survival after fast or slow freezing. These differences emphasize the need for species-specific studies in the development and enhancement of assisted breeding for poultry and endangered species.

Centrifugation and addition of glycerol at 22 degres C instead of 4 degrees C improve post-thaw motility and fertility of stallion spermatozoa

The aims of this study were to evaluate the effects of cooling rate to 4 degrees C and temperature at the time of centrifugation/glycerol-addition (freezing extender: INRA82 + 2% egg yolk + 2.5% glycerol) on postcentrifugation recovery rate, post-thaw motility and per-cycle fertility. When centrifugation/glycerol-addition was performed at 4 degrees C (14 ejaculates), a moderate cooling rate (37 degrees C to 4 degrees C in I h) resulted in higher post-thaw motility (45%) than when using a slow cooling rate (37 degrees C to 4 degrees C in 4 h) (39%; P<0.05). When centrifugation/glycerol-addition was performed at 22 degrees C (37 degrees C to 22 degrees C in 10 min) (10 ejaculates), post-thaw motility was lower when spermatozoa were frozen directly from 22 degrees C (23%) than when spermatozoa were cooled to 4 degrees C (22 degrees C to 4 degrees C in 1 h) before freezing (47%; P<0.0001). When centrifugation/glycerol-addition was performed at 22 degrees C (before cooling at a moderate rate), as opposed to 4 degrees C (after cooling at a moderate rate), a significant improvement of 1) recovery of spermatozoa after centrifugation (P<0,0001), 2) post-thaw motility of spermatozoa at thawing (40% vs 36% (n < or = 291 ejaculates/group), P<0.0001) and 3) per-cycle fertility (56% vs 42% (n > or = 190 cycles/group), P<0.01) was observed. In conclusion, centrifugation/glycerol-addition at 22 degrees C followed by cooling to 4 degrees C at a moderate rate results in an improvement of post-thaw motility, spermatozoa recovery rate and per cycle fertility.

Storage of poultry semen

Methods of semen collection and artificial insemination (AI) in poultry, requirement for diluents, methods of liquid and frozen storage of avian semen and evaluation of spermatozoa after storage for fertilizing ability are reviewed. Frozen storage of semen from non-domestic birds is also briefly discussed.

Basic aspects of frozen storage of semen

Basic concepts of cryopreservation and the causes of cryoinjury are reviewed. The possible roles of cryoprotectants and additives are considered in the context of their putative interactions with the sperm plasma membrane. Modern approaches to the laboratory assessment of spermatozoa after freeze-thawing are also briefly discussed.

Effect of differential addition of glycerol and pyruvate to extender on cryopreservation of Mediterranean buffalo (B.bubalis) spermatozoa

The composition of the extender in which semen is diluted before freezing plays a major role in successful cryopreservation of spermatozoa. Substances of high osmolarity, like glycerol, protect sperm cells during the freezing process and energy-rich compounds, like pyruvate provide extra energy during capacitation and fertilization. Since cryopreservation procedures for Buffalo spermatozoa have not been adequately defined, the aim of the study was to improve the survival rate of buffalo (Bubalus bubalis) spermatozoa after cryopreservation by optimizing the timing for adding glycerol and by enriching the cryoprotectant extender with an energy source substrate. Semen was collected with an artificial vagina from 5 bulls and the ejaculates were immediately evaluated for motility, forward progressive motility and for viability, pooled and held at room temperature (28 degrees C) for 1 h. Then aliquots of pooled semen were subjected to dilution and equilibration in triplicate as follows: Experiment 1. Glycerol (3%) in a commercial extender was added to the semen at 28 degrees C and cooled to 5 degrees C for 1 h; then extender with 11% glycerol was added before further equilibration (initial glycerol addition; IGA) and the samples held at 5 degrees C for 1, 3 or 5 additional hours (IGA 1, n = 24; IGA 3, n = 24; IGA 5, n = 24) before freezing. Experiment 2. Glycerol (3%) was added and the mixture brought to 5 degrees C as described above. Then extender with 11% glycerol was added (late glycerol addition; LGA) and after equilibration for 1, 3 and 5 h (LGA 1, n= 24; LGA 3, n = 24; LGA 5, n = 24) the samples were frozen. In Experiments 3 and 4 Na pyruvate (1.25 mM) was added to the extender as described for IGA and LGA above (IPA and LPA samples). The effect of addition time (initial vs late) of glycerol and pyruvate was evaluated by measuring sperm motility, progressively forward motility and viability. After freezing-thawing the percentage of motile spermatozoa was significantly higher (0.001<P<0.01) after a late addition of glycerol and pyruvate (LGA 5 and LPA 5). The optimizing of the timing of the glycerol addition and the presence in the extender of an energy source rendered a higher efficiency in thawed spermatozoa.

Fundamental aspects of sperm cryobiology: the importance of species and individual differences

While semen cryopreservation is successfully used for a few species, application to other species can be problematic. Here, I argue that species differences in female tract anatomy, subtle differences in sperm transport mechanisms, ability to time inseminations and deliver spermatozoa effectively are powerful determinants of fertility with cryopreserved spermatozoa. Poor sperm survival represents one major aspects of the problem and determining biophysical characteristics of the sperm plasma membrane is an established approach to solving it. However, this approach is unable to account for the consistent differences in post-cryopreservation sperm quality between individual males, an effect that is recognized is many species although only documented in a few. Searching for genetic differences between these individuals might offer a genomically-based direction in semen cryopreservation research. Cryopreservation of spermatozoa and spermatogenic cells for intracytoplasmic sperm injection has been developed primarily to deliver an intact genome and presents a very different set of technical problems.

Organelle-specific probe JC-1 identifies membrane potential differences in the mitochondrial function of bovine sperm

The mitochondrial probe 5,5',6,6'-tetrachloro-1,1',3,3'-tetraethylbenzimidazolyl-carbocyan ine iodide (JC-1) not only identifies mitochondria exhibiting low membrane potentials by the emission of green fluorescence (range, 510-520 nm) but also differentiates these from mitochondria exhibiting relatively high membrane potentials. This discrimination occurs because JC-1 forms aggregates at high membrane potentials. These J-aggregates emit a bright red-orange fluorescence at 590 nm. In this study, JC-1 was combined with the classical dead cell stain, propidium iodide (PI), to identify a spectrum of functional sperm along with degenerate sperm. Flow cytometric analysis of bull sperm showed that the aggregate:monomer ratio differed among bulls before cryopreservation (P < 0.001) but not afterwards (P > 0.05). The effects of stain equilibration time, sperm concentration, and live:dead ratios were examined. The addition of SYBR-14 to the JC-1 and PI combination enhanced the distinction between the red PI-stained and red-orange JC-1-stained populations. This discrimination between J-aggregates and the PI-stained sperm was affected by sperm concentration. These studies show that JC-1 can be useful in monitoring mitochondrial function in bovine sperm.

Comparison of cryoprotectants and methods of cryopreservation of fowl spermatozoa

The deleterious effects of three cryoprotectants, glycerol, dimethylsulfoxide (DMSO), and dimethylacetamide (DMA), were compared on fowl spermatozoa. The viability and integrity of spermatozoa were measured with eosin-nigrosin smears. Glycerol was the least deleterious cryoprotectant, followed by DMA, and DMSO was the most toxic. Methods employing either glycerol or DMA were then compared for the cryopreservation of semen in either straws or pellets. Fertility was measured following artificial insemination. The highest fertility rates were obtained with semen frozen with DMA in pellets directly plunged in liquid nitrogen, DMA being added at -6 C (92.7%) or 5 C (84.7%). When semen was frozen in straws, glycerol equilibrated for 1 or 30 min gave the highest fertility results, but the fertility rates were lower (53.7 and 63.9%) than with DMA in pellets. The lowest results (26.7%) were obtained when semen was frozen in straws with DMA. When semen was frozen in pellets at very high cooling rates, DMA was superior to glycerol as a cryoprotectant, as evidenced by fertility. In contrast, when straws and low freezing rates were used, glycerol gave better results; however these results were never as high as those obtained with DMA and pellets. In conclusion, under our experimental conditions, the highest fertility rates were achieved with DMA and pellets. However, for gene banking, which requires high levels of safety and clear identification, glycerol and straws are more convenient.

Successful recovery of motility and fertility of cryopreserved cane toad (Bufo marinus) sperm

The recent decline and extinction of amphibian species is a worldwide phenomenon without an identified cause or solution. Assisted reproductive technologies, including sperm cryopreservation, are required to manage endangered amphibian species and preserve their genetic diversity. This study on the Anuran amphibian (Bufo marinus) was undertaken to determine the feasibility of cryopreservation of amphibian sperm. Sperm suspensions for cryopreservation were prepared by macerating testes in cryoprotective additives of 10% (w/v) sucrose or 10% (w/v) sucrose containing either 10, 15, or 20% (v/v) glycerol or 10, 15, or 20% (v/v) dimethyl sulfoxide (Me2SO). Suspensions were then cooled to -85 degreesC using a controlled rate cooler, stored in LN2, and thawed in air. The motility and fertilization rate of cryopreserved suspensions and unfrozen control suspensions in Simplified Amphibian Ringer were compared. Sucrose alone had no cryoprotective effect. All other treatments showed varying degrees of recovery of motility and fertilizing capacity. High rates of recovery of motility and fertilizing capacity were observed with 15% Me2SO (68.9 +/- 3.8 and 60.5 +/- 4.7%) and 20% glycerol (58.0 +/- 5.9 and 81.4 +/- 4.3%), respectively. Motility and fertilization rates were similar with Me2SO but diverged with glycerol as cryoprotectant. The data demonstrate the feasibility of using sperm cryopreservation with amphibian species. Copyright 1998 Academic Press.

Loss of plasma membrane proteins of bull spermatozoa through the freezing-thawing process

The widespread application of A. I. and realization of its full potential depends largely on the use of frozen semen. However, fertility resulting from A. I. is poorer than that from fresh semen in most species. The objective of this study was to compare the protein composition of fresh and frozen-thawed bull sperm plasma membrane surface. The effect of Tween 20 on protein removal from fresh and frozen sperm plasma membrane surface was studied and compared. The effect of incubation with different detergent concentrations on sperm motility and viability was examined. Approximately 2 x 10(8) frozen-thawed bull spermatozoa washed through a discontinuous Percoll gradient were incubated for 15 min at 20 degrees C with 0.01, 0.03 and 0.05% Tween 20. Sperm motility was completely eliminated at all 3 assayed detergent concentrations, while the initial sperm viability of 52% was decreased to 26, 10 and 5%, respectively, at the 3 concentrations. The removal of sperm plasma membrane proteins also increased from 0.72 mg to 2 mg with 0.05% Tween 20. Similar results were found with fresh semen samples. Although the amount of extracted proteins was significantly lower than that obtained with frozen spermatozoa, fresh sperm motility was likewise eliminated by the detergent treatment, and sperm viability was decreased. A semen sample with an initial sperm viability of 59% had a value of only 8% after treatment with 0.05% Tween 20. Comparative SDS-PAGE analysis of the extracted fractions from fresh and frozen-thawed semen treated with Tween 20 showed that the higher amount of extracted proteins in the frozen semen samples corresponded to the egg yolk lipoproteins in the cryoprotectant medium. However, it is worth noting that 4 more bands were found in the sample obtained from fresh semen than from frozen semen. These results indicate that some cell membrane proteins are lost through the freezing-thawing process.

Cryopreservation of rabbit spermatozoa using acetamide in combination with trehalose and methyl cellulose

Glycerol is not an effective cryoprotectant for rabbit spermatozoa; therefore, rabbit spermatozoa were used as a model for developing cryopreservation procedures for other cell types which also freeze poorly when glycerol is used as the cryoprotectant. Experiments were conducted to 1) compare several published protocols for cryopreserving rabbit spermatozoa; 2) determine if removal of seminal granules, required for flow cytometry analysis, affects the motility of rabbit spermatozoa; and 3) determine if using a combination of cell permeating cryoprotectants (acetamide) with cell nonpermeating cryoprotectants (trehalose and methyl cellulose; MC), can increase the recovery of viable rabbit spermatozoa after cryopreservation. Media containing acetamide as a cryoprotectant were found to be most effective for rabbit spermatozoa. The cryoprotectants ethylene glycol, dimethylsulfoxide and glycerol were not effective for cryopreserving rabbit spermatozoa. Second, rabbit spermatozoa could be centrifuged through a Percoll gradient composed of equal volumes of Prcoll and a HEPES-buffered sperm medium. This centrifugation removed all seminal granules without affecting the percentage of motile spermatozoa after initial sperm dilution (85 vs 74%) or after cryopreservation (35 vs 30%), when sperm were either centrifuged or not centrifuged, respectively. The substitution of trehalose in the cryopreservation medium for raffinose did not improve recovery of motile cells following cryopreservation (P > 0.05). However, addition of MC resulted in higher percentages of motile sperm after cryopreservation (43 vs 31%; P < 0.05). In addition, sperm viability and acrosomal integrity were simultaneously evaluated using flow cytometry. The addition of both trehalose and MC to media containing acetamide resulted in higher percentages of live acrosome-intact cells than acetamide alone (53 vs 37%; P < 0.05). These results indicate that a combination of permeating and nonpermeating cryoprotectants (acetamide, trehalose and MC) were more effective in preserving rabbit spermatozoa than acetamide alone and that analyzing multiple sperm characteristics, by flow cytometry, can assess sperm damage not detected by analyzing sperm motion characteristics.

Cryopreservation of rooster sperm using methyl cellulose

Experiments were designed to determine when, during the cryopreservation process, sperm lose fertilizing capacity and whether the cryoprotectant, methyl cellulose (MC), could be used in combination with glycerol to cryopreserve sperm and remain in the inseminate without reducing fertility. Semen diluted in Minnesota Avian extender (MNA) and inseminated immediately had greater fertility (75%) than semen processed for cryopreservation (12 to 60%). The largest decreases in fertility were due to addition of glycerol to sperm and to cryopreservation. In another experiment, fertility of inseminates containing 0, 1, and 2% glycerol were 82, 29, and 21%, respectively, for eggs collected 2 to 5 d after insemination. When 0.5% MC was added to the same three treatments, fertility rates were 88, 63, and 69%, respectively. Semen cryopreserved in MNA containing 9% glycerol; MC + 3% glycerol; MC + 4% glycerol; MC + 9% glycerol; or 9% glycerol with the cryoprotectant removed post-thaw by dilution and subsequent centrifugation exhibited 59, 30, 35, 60, and 69% viable cells, respectively; and 65, 38, 46, 69, and 65% motile sperm, respectively. Sperm cryopreserved with MC and either 4 or 9% glycerol exhibited similar numbers of sperm binding to chicken perivitelline layers in vitro as did fresh sperm, whereas sperm frozen with MC and 3% glycerol bound oocytes with only 31% efficiency (P < 0.05). The extent to which cryopreserved sperm penetrated the perivitelline layer in vitro was independent of glycerol concentration, but was four times more efficient than that of fresh sperm (P < 0.05). The fertility rates of fresh semen, semen frozen in 9% glycerol with the cryoprotectant removed after thawing, and semen frozen in MC with either 3 or 4% glycerol were 87.4, 27.6, 0.8, and 0.5%, respectively (P < 0.05). The MC reduces the contraceptive effects of glycerol when inseminated with fresh sperm, but does not maintain fertilizing capacity in frozen-thawed sperm when used in combination with 3 or 4% glycerol.

Cryopreservation of stallion spermatozoa

The main advantage to using frozen semen in any breeding program is faster genetic gain for the inherited trait desired. Milk production of dairy cows doubled (from 26,000 to 52,000 kg of milk/cow per year) between 1950 and 1980, because the dairy industry was using semen only from bulls with the greatest genetic potential for milk production. This genetic gain could have been achieved without the use of frozen semen; however, the time required to achieve that same genetic progress would have been lengthened exceedingly. Fertility rates using frozen stallion spermatozoa are not equal to that of fresh semen, but with careful management of both the stallion and the mare fertility rates of 40% to 60% can be achieved for a single mare reproductive cycle and fertility rates of 60% to 75% during the course of a breeding season can be expected for a number of stallions. Because pregnancy rates have increased and because many breed registries now condone the use of frozen stallion semen, more people in the equine industry are using frozen semen. It has been the attempt of this article to make the practitioner aware of some of the problems that can occur when processing, freezing, storing, and using frozen semen, and how to control those problems. The practitioner also should be aware that there is large variation in semen quality from stallions, and that spermatozoa from some of the problem stallions can be improved by altering a "standard protocol," but that semen from some stallions will not cryopreserve effectively, regardless of the efforts put forth.

Cryopreservation of rooster semen in thirteen and sixteen percent glycerol

Semen from Barred Plymouth Rock roosters was cryopreserved with glycerol concentrations of 13 and 16% in a microprocessor-controlled freezer. Thawing and deglycerolation were facilitated by the use of an improved microprocessor-controlled thawing device and high speed dialyzer. Deglycerolated semen (100 mu L; 192 and 154 million sperm, respectively, for the 13 and 16% glycerol concentration) was inseminated into Single Comb white Leghorn hens. Three inseminations were done at 4-d intervals. Eggs were collected for 10 d starting 1 d after the first insemination, and incubated for 4th d. Fertility was determined by candling after the 4th d. Fertility measurements of 62.4 and 65% were obtained from the sperm frozen in 13 and 16% glycerol concentrations, respectively, for the 10-d period.

Frozen-thawed bovine spermatozoa diluted by slow or rapid dilution method: Measurements on occurrence of osmotic shock and sperm viability

This study was undertaken to investigate the occurrence of osmotic shock, sperm viability and membrane functional status of frozen-thawed bovine spermatozoa during a short-term incubation period (2 h) in vitro after dilution by 2 methods. Frozen semen from 10 bulls (0.5-ml plastic straws, 7% glycerol) was thawed and diluted by slow or rapid dilution method with Ham's F-10 medium containing 0 or 7% glycerol and assessed for sperm motion parameters, percentage of spermatozoa with coiled tails and reactivity to the hypoosmotic swelling (HOS; percentage of spermatozoa swelling) test at 60 min intervals during a 2 h incubation period (37 degrees C). Post-thaw sperm viability, as reflected by percentage and grade of motility (0 to 4) did not differ between the 2 dilution methods (P > 0.05) at the beginning of incubation (Time 0). However, differences were apparent (P < 0.05) as the incubation time increased. Slow dilution with medium containing 0% glycerol caused less increase (P < 0.05) in percentage of spermatozoa with coiled tails; Moreover, these spermatozoa showed greater reactivity to the HOS test. When contrasting slow vs rapid dilution methods, the occurrence of osmotic shock was less frequent, and response to the HOS test was greater for spermatozoa diluted slowly, regardless of the glycerol content of the incubation medium. Rapid deglycerolization of frozen-thawed bovine spermatozoa in a single step, induces damage which is not detected on the basis of spennatozoal motility but is clearly evident after several hours of incubation by using the HOS test to detect damage.

Fertility rate of daily collected and cryopreserved fowl semen

Semen was collected for 4 consecutive d individually from experimental broiler breeder males that had not been massaged for 7 d. The semen was mixed and diluted with the Beltsville Poultry Semen Extender with dimethylsulfoxide (DMSO) as cryoprotectant and cryopreserved. After thawing of the semen, hens were inseminated and fertility over 1 wk after a single insemination with the cryopreserved semen was determined. The overall fertility rate in this experiment (83 to 93%) was high, compared with the generally reported fertility rate of frozen-thawed fowl semen. The fertility rate of the semen collected on Days 3 and 4 was significantly higher than that of semen collected on Day 1 or 2, indicating that frequent collection over the 4-d period enhances the fertility rate of the semen.

Human spermatozoa glycerol permeability and activation energy determined by electron paramagnetic resonance

The permeability of human spermatozoa to glycerol and its activation energy were determined using electron paramagnetic resonance (EPR) techniques. EPR was used to monitor the aqueous cell volume change vs. time during the glycerol permeation process using the aqueous spin label 15N-tempone and the membrane impermeable broadening agent potassium trioxalatochromiate (chromium oxalate). The permeation process was completed in tens of seconds, requiring the use of a stopped-flow methodology. The glycerol permeability coefficient (Pg) was determined by fitting a simple theoretical model to the experimental data. The permeabilities of human spermatozoa in 1 molar and 2 molar glycerol at 20 degrees C are (10.3 +/- 0.3).10(-4) cm/min (mean +/- S.D.) and (6.0 +/- 1.4).10(-4) cm/min, respectively. The permeabilities of human spermatozoa in 2 molar glycerol at 30, 20, 10, and 0 degrees C are (8.3 +/- 1.3).10(-4) cm/min, (6.0 +/- 1.4).10(-4) cm/min, (2.1 +/- 0.4).10(-4) cm/min, and (1.1 +/- 0.3).10(-4) cm/min, respectively. The activation energy (Ea) for glycerol permeation between 30 degrees C and 0 degrees C was found to be 11.6 kcal/mol.

Cryopreservation of rooster sperm

Successful cryopreservation of sperm requires: 1) selection of proper diluent; 2) selection of the best cryoprotectant; 3) determination of freezing and thawing rates for optimum retention of fertilization potential; and 4) removal of any materials deleterious to fertility (e.g., glycerol) before insemination. An economically useful process must allow recovery of sperm with sufficient fertilization capacity to enable maximum use of any given superior male. A series of experiments tested a novel semen freezing container (BioPore CryoCell container) having physical characteristics that permit reproducible freezing and thawing plus facile removal of glycerol from the sample after processing. Experiments tested the effect of: a) residual glycerol; b) initial glycerol concentrations on retention of fertility when samples were frozen and thawed at 6 C/min; c) Beltsville Poultry Semen Extender and Minnesota A buffers used during the dialysis procedure; and d) dialysis time. Respectively, the results were: a) .8% (vol/vol) reduced fertility by 5 to 10%; b) 12% glycerol was superior to 10% and 8% glycerol; c) no difference was observed between the two buffers; and d) 90 and 120 min were both superior to 60 min. Numerous pools of rooster sperm cryopreserved in CryoCell containers and dialyzed after thawing in a prototype BioStore environmental control chamber for 90 or 120 min resulted in a mean fertility of 55.6%. This mean fertility of frozen-thawed sperm was based on 3,263 eggs laid by 400 hens on Days +1 through 9 after inseminations on Days -1, 2, and 5. It is likely that broiler stocks might have lower fertility than that obtained from the Barred Plymouth Rock males and the Single Comb White Leghorn females used in these studies. Nevertheless, the procedure described is the first to consistently result in > 50% fertilized eggs as a result of conventional intravaginal insemination (< 200 x 10(6) sperm in 100 microL extender) of sperm processed after thawing by a procedure amenable to the scaleup required for commercial applications.