Sperm cryopreservation is a fundamental process for the long-term conservation of livestock genetic resources. Yet, the packaging method has been shown, among other factors, to affect the frozen-thawed (FT) sperm quality. This study aimed to develop a new mini-straw for sperm cryopreservation. In addition, the kinematic patterns, viability, acrosome integrity, and mitochondrial membrane potential (MMP) of boar spermatozoa frozen in the developed 0.25 mL straw, 0.25 mL (minitube, Germany), or 0.5 mL (IMV technologies, France) straws were assessed. Postthaw kinematic parameters were not different (experiment 1: total motility (33.89%, 32.42%), progressive motility (19.13%, 19.09%), curvilinear velocity (42.32, 42.86), and average path velocity (33.40, 33.62) for minitube and the developed straws, respectively. Further, the viability (38.56%, 34.03%), acrosome integrity (53.38%, 48.88%), MMP (42.32%, 36.71%) of spermatozoa frozen using both straw were not differ statistically (p > 0.05). In experiment two, the quality parameters for semen frozen in the developed straw were compared with the 0.5 mL IMV straw. The total motility (41.26%, 39.1%), progressive motility (24.62%, 23.25%), curvilinear velocity (46.44, 48.25), and average path velocity (37.98, 39.12), respectively, for IMV and the developed straw, did not differ statistically. Additionally, there was no significant difference in the viability (39.60%, 33.17%), acrosome integrity (46.23%, 43.23%), and MMP (39.66, 32.51) for IMV and the developed straw, respectively. These results validate the safety and efficiency of the developed straw and highlight its great potential for clinical application. Moreover, both 0.25 mL and 0.5 mL straws fit the present protocol for cryopreservation of boar spermatozoa.

This study was conducted to find out the effect that κ-Carrageenan has on the properties of dog sperm when it was added to the cryoprotectant. Extender basically was contained 1.21 g Trizma base, 0.67 g citric acid, 0.4 g glucose, 0.03 g penicillin G, 0.05 g streptomycin sulfate. Extender1 was added with 0.1%, 0.2%, 0.3%, and 0.5% carrageenan, while extender2 was supplemented with glycerol. After freezing-thawing, the motility, viability, acrosome integrity, apoptosis, and ROS (reactive oxygen specifications) of sperm were measured to analyze the effects of the supplementation of carrageenan. Total Motile (TM), Rapid Progressive Motile (RPM), Medium Progressive Motile (MPM), and Immotile were measured through the CASA system after thawing in 37 degree water. Extender with 0.2% κ-carrageenan (64.26 ± 0.49) was significantly higher than control (40.24 ± 8.27) (p < 0.05). RPMs of extender with 0.1%, 0.2% κ-carrageenan (57.64 ± 6.34, 56.47 ± 1.35) were significantly higher than the other groups (p < 0.05). Acrosome integrity was measured by dyeing to PSA-FITC with an epifluorescence microscope. Normal acrosome ratio of extender with 0.5% κ-carrageenan (61 ± 8.03) was higher than the other groups (p < 0.05). Apoptosis was measured with a FACSCalibur flow cytometer using FITC (FITC Annexin V Apoptosis Detection Kit). Treated groups of κ-carrageenan of 0.1% (0.81 ± 0.05), 0.2% (0.85 ± 0.05) were significantly higer (p < 0.05) than control. Modified SYBR/PI staining was used for determination of viability and DCF staining was used for evaluation of ROS. Viability and ROS were not significantly different from other groups. In conclusion, adding a certain concentration of carrageenan to the extender of cryopreservation, carrageenan contributes to the improvement of the sperm motility, acrosome integrity and prevention of apoptosis.

The objective of this study was to develop of semen transport system for cryopreservation and fertility in bull sperm. The ejaculated semen were diluted with Triladyl containing 20% egg-yolk for transportation. Diluted semen was transported by three methods that there were wrapping tissue (Tissue), sinking under 30℃ water (Water) and sinking between warm water and air (Air) methods. Semen was transported within 2 hours in 0.3℃. For this study, the freezing of diluted semen were added with Triladyl containing 20% egg-yolk. And frozen-thawed sperm were estimated with SYBR14/PI double stain for viability, FITC-PNA/PI double stain for acrosome reaction analysis and Rhodamine123 double stain for mitochondrial intact assessment. In results, live sperm (SYBR+/PI-) in Air treatment group (43.3±4.7%) was significantly (p<0.05) higher than other treatment groups (Tissue: 16.3±2.7% and Water: 27.5± 3.1%), dying sperm (SYBR+/PI+) in Air treatment group (55.6±4.7%) was significantly lower than other treatment groups (Tissue: 77.6±3.2% and Water: 67.6±3.3%) (p<0.05). Acrosome reaction in Air treatment group (0.2±0.1%) within live sperm (PI negative region) was significantly (p<0.05) lower than other treatment groups (Tissue: 0.7±0.2% and Water: 0.5±0.1%), the acrosome reaction in Air treatment group (28.6±2.8%) within all sperm also was significantly lower than other treatment groups (Tissue: 44.2±1.8% and Water: 36.2±2.0%) (p<0.05). And mitochondrial intact in Air treatment group within live (97.1±0.4%) and all (61.9±3.3%) sperm were significantly higher than other treatment groups (Tissue: 85.2±3.3%, Water: 87.8±2.9% within live sperm and Tissue: 49.28±3.7%, Water: 42.0±3.1% within all sperm) (p<0.05). Therefore, we suggest that transportation by sinking method between warm water and air was beneficial to improvement of fertility in frozen-thawed in bull semen.

The aim of this study was to evaluate the post-thawed characteristics of leopard cat semen. In this experiment, semen was collected from two leopard cats (A and B) at wild animal center in Seoul Grand Park in Korea. After collection, the sperms were washed with D-PBS and diluted by the freezing medium (Irvine science, USA) and stored in liquid nitrogen. The post-thawed concentration was for A and for B. The viability of post-thawed sperm from A and B individual was 24.0% and 19.0%, respectively. Pre-freezing motility of A and B individual semen was 68.54% and 56.65. Leopard cat A had more normal sperm than that of B (69.5% vs. 54.5%). Acrosome integrity analysis detected live (14.5% vs. 9.0%), damage (39.0% vs. 44.0%) and dead (46.0% vs. 47.0%) in leopard cat A and B, respectively. The present results concluded that leopard cat semen can be collected successfully by electro-ejaculation method and cryopreserved successfullyfor future use in different assisted reproductive technologies. The cryopreservation protocol needs to be modified for increasing post-thawed viability of leopard cat spermatozoa.

희소 한우인 칡소의 정액 동결을 위해서 레시딘을 기본 희석제로 하는 AndroMed와 Tris-egg yolk extender를 사용하여 정자의 생존율과 활력 조사를 위해서 본 연구를 수행하였다. AndroMed 희석제를 사용하였을 때 생존율과 활력은 와 의 결과를 보였다. 그리고 Tris-egg yolk extender의 경우는 각각 와 결과를 보여 생존율에서는 Tris-egg yolk 희석제가 AndroMed 희석제를 사용하였을 때보다 유의적으로(p

The aim of this study was to evaluate the effects of orvus es paste(OEP) on the sperm characteristics during freezing in boar semen. Semen quality was evaluated the motility, membrane integrity, mitochondria function, acrosome status, viability and abnormality. Boar semen were frozen until 5℃ for 2 hours using cell freezer and making the straws, and then freezing by lowing the straws into styrofoam box on the 8cm above the LN2 and plunged into LN2 for cryopreservation. In different concentration of OEP (0, 0.25, 0.5 and 1.0%) into cryo-extender, sperm motility, membrane integrity, acrosome status, viability and mitochondria function were significantly higher in 0.5% OEP than those of any other groups, but sperm abnormality were highest in 1.0% OEP group among all treatment groups (P<0.05). In the relationships of the evaluation methods for sperm viability, CBB vs membrane integrity, CBB vs HO/PI and CBB vs mitocondria function were positively correlated (0.67~0.92). Among the evaluation methods, CBB vs membrane integrity, CBB vs HO/PI and CBB vs mitocondria function were significantly correlated (P<0.001). These results of this study indicate that supplementation of 0.5% OEP in boar semen cryo-extender can improve the semen quality.

The aim of this study was to evaluate the effects of different straw volume (0.5 and 5.0 ㎖) on cryopreservation in boar semen. Semen quality was evaluated the motility, viability, abnormality, acrosome intactness and membrane integrity. And there were also examined the development rates of IVM/IVF embryos using frozen-thawed boar semen. Boar semen were frozen until 5℃ for 3 hours using cell freezer and making the straws, and then freezing by lowing the straws into styrofoam box on the 8 cm above the LN2. In different straw volume (0.5 and 5.0 ㎖), sperm viability and abnormality were not differ in 0.5 and 5.0 ㎖ straws, but sperm motility were significantly higher in 0.5 ㎖ straws (61.3%) than in 5.0 ㎖ straws (56.3%) (p<0.05). In the Coomassie Brillient Blue (CBB), Hoechst 33258/Propidium Iodide (H258/PI) staining and Hypoosmotic Swelling Test (HOST), the acrosome intactness and sperm membrane integrity were not differ in 0.5 and 5.0 ㎖ straws, but sperm survival rate was significantly higher in 0.5 ㎖ straw (65.0%) than in 5.0 ㎖l straw (55.0%) (p<0.05). Employing the Chlortetracycline (CTC)/Hoechst33258 (H258), all treatment group were not differ in characteristic of uncapacitated acrosome-intact sperm (F), capacitated and acrosome-intact sperm (B-type) and acrosomereaction seprm (AR-type). In the developmental rate of IVM/IVF embryos using frozen-thawed boar semen in different straw volumes, the developmental rate of morula plus blastocysts were 19.9% in 0.5 ㎖ straw and 18.8% in 5.0 ㎖ straw, respectively. These results indicated that straw volume affects the semen motility and sperm survival rate, but not other semen characteristic and developmental rate of IVM/IVF embryos.

This study was carried out to investigate the general characteristics and viability of sperm after freezing and thawing and the pregnancy rates after artificial insemination with thawed semen. The rates of viable sperm after slow and rapid freezing were 87.4±3.85% and 70.8±4.45%, respectively which were significantly lower than that of fresh semen control (91.7±3.45%). The mean concentration of epididymal sperm after dilution in 1.0 ml saline and. 3.0 ml extender in a various concentrations of cryoprotectants was 124.5±48.3 x 10/sup 6/ (range of 45 x 10/sup 6/ to 280 X 10/sup 6/ /ml). There was a significant difference not in the percentage of acrosome-reacted sperm, but in the percentage of capacitated sperm, between fresh and frozen-thawed epididymal semen. When frozen-thawed after diluting with tris-buffer extender containing glycerol, DMSO and ethylene glycol with concentration of 2 to 6%, the rates of epididymal sperm exposed to different cryoprotectants ranged from 14.4±4.7% to 20.7±5.8%, 17.8±5.2% to 36.5±4.9%, and 14.4±4.6% to 18.5±5.3%, respectively which were lower compare to fresh semen control. The pregnancy rate after artificial insemination with frozen semen was 70.6%, whereas that with fresh semen was 90.0% in dogs with naturally induced estrus.

The objective of this study was to optimize the selection of sperm sources, optimal culture systems and vitrification method depends on sperm sources. The oocytes were inseminated with either KPN 105, 114, 191, SNU 101, 102, 103 or epididymis and then embryos inseminated were cultured in oviductal cell co-culture or HECM-6 as defined me dium. The blastocysts produced were pooled according to sperm sources as KPN, SNU or epididymis and then vitrified by OPP vitrification method. The results obtained were as follows: 1. The cleavage(86.2 or 84.7%) and development rates to blastocyst (30.6 or 32.0%) were not significantly different between oviductal cell co-culture or HECM-6 culture systems(P<0.05). 2. To determine the optimal sperm sources for using IVF in this system, cleavage rates in KPN 191 and SNU 101 (74.2, 55.8%) were significantly lower rather than those in KPN 105, 114, SNU 102, 103 or epididymis (86.7, 85.1, 89.8, 85.5 or 81.2%), but development rates to blastocyst in KPN 114, SNU 103 or epididymis sperm (30.0, 33.0 or 28.6%) were significantly higher rater than those in KPN 105, 191, SNU 101, 102(21.4, 15.4, 14.9 or 25.4%), respectively (P<0.05). 3. The blastocysts produced were pooled according to sperm sources as KPN, SNU or epididymis and then vitrified by OPP vitrification method. The survival rates were not significantly different among sperm sources (89.6%: 43/48 ; 90.1%: 46/51 ; 83.3% : 20/24). These results obtained indicate that the defined medium, HECM-6, could be use to produce of IVP bovine embryos. Since the frozen semen must be required to maintain of unvariation data in IVP embryo production system, KPN 114 and SNU 103 produced in our laboratory were useful for this purpose. The blastocysts produced by different sperm sources as KPN, SNU or epididymis were vitrified by OPP vitrification method and survived very high rates. The OPP vitrification method could be susceptibility to use of IVP bovine blastocyst embryos.