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Viability of vitrified mouse embryos using various cryoprotectant mixtures
THERIOGENOLOGY
VIABILITY OF VITRIFIED MOUSE USING VARIOUS CRYOPROTECTANT H. Ishimorit
Y. Takahashi
EMBRYOS MIXTURES
and H. Kanagawa
Department of Theriogenology Faculty of Veterinary Medicine Hokkaido University, Sapporo 060, Japan Received
for
publication:
Accepted:
February 27, 1991 October 29, 1991
ABSTRACT Mouse morulae and blastocysts were cryopreserved by vitrification using six types of solutions. Each solution was composed of two types of cryoprotectants. glycerol(GL) + ethylene GL + dimethyl sulfoxide(DMSO), glycol(EG). GL + propylene glycol(PG), EG + PG. EG + DMSO, and PG + DMSO at an each cryoprotectant concentration of 25% v/v. Embryos were exposed to each type of vitrification solutions, which had been diluted 50% in PBS, for 5 then for another 5 minutes at 4 "C. minutes at room temperature, The embryos were loaded into straws containing vitrification solution at 4°C and plunged into liquid nitrogen within 30 seconds. After warming in water at OC and following one-step dilution of the cryoprotectant in 0.5 M sucrose+PBS, the embryos were cultured in vitro. The survival rates of morulae were 51, 16, 78, 44, 79 and 50%. respectively, for the six solutions. The survival rates of the morulae using GL + DMSO and EG + DMSO were significantly higher than those of the other solutions (P
words:
mouse
embryo,
vitrification,
cryoprotectant
mixture
INTRODUCTION Rall
and
Fahy
(1)
first
reported
vitrification
Acknowledgments The authors thank Drs, Conrad0 A. Valdez reviewing this manuscript. 1 Present address : Embryo Transplantation Milk Products Co., Ltd., Uenae Tomakomai,
FEBRUARY 1992 VOL. 37 NO. 2
and Antonio
as
a new
A. Rayos
for
Laboratory, Snow Brand Hokkaido 059-13. Japan.
481
THERIOGENOLOGY approach for the preservation of embryos. Since then, many researchers have studied cryopreservation of embryos by vitrification. Some effective vitrification solutions such as mixtures of glycerol and propylene glycol (2). polyethylene glycol and glycerol or propylene glycol (3), and ethylene glycol, ficoll and sucrose (4) have been reported. Scheffen et a1.(2) showed high in vitro survival rates of compacted mouse morulae and early blastocysts vitrified in a mixture of glycerol and propylene glycol. Massip et al.(S) reported the solution to be effective for bovine morulae and early blastocysts. Both their vitrification solution and method were simple; however, the survival rates for mouse and bovine blastocysts were lower in comparison with those for morulae. Other researchers also have reported similar findings using the same solution (6) and another vitrification solution (7, 8). Embryos at the morula and blastocyst stages are used most A vitrification solution frequently in bovine embryo transfer. same equilibration and applicable at both stages using the vitrification conditions is therefore desirable. There have been no reports regarding the comparison of different cryoprotectant mixtures used for the vitrification of embryos. This study was the in vitro viability of undertaken to investigate and compare morula and blastocyst stage embryos using different cryoprotectant mixtures. MATERIALS
AND
METHODS
Embryos Female ICR mice (4 to 7 weeks old) were induced to superovulate by intraperitoneal injections of 5 IU PMSG and 5 Ill hCG 48 hours apart. They were mated with male ICR mice except in the embryo transfer experiment, for which C57BL/6 males were used. Morulae or blastocysts were flushed from the oviducts and uteri at 70 to 72 hours or 90 to 92 hours after hCG treatment using Dulbecco's with 0.4mg/ml bovine phosphate buffered saline (PBS) supplemented serum albumin. Vitrification
Solution
Six types of vitrification solutions were used, each consisting of a mixture of two types of permeating cryoprotectants in PBS: glycerol(GL) + ethylene glycol(EG), GL + propylene glycol(PG), GL + dimethyl sulfoxide(DMSO), EG + PG, EG + DMSO, and PG + DMSO. The concentration of each cryoprotectant was 25% v/v. All solutions in the straws remained transparent during cooling and warming, which is one indication that the solutions vitrified (4). Equilibration Each
482
type
and
Cooling
of vitrification
solution
was
diluted
by 50%
in PBS
FEBRUARY 1992 VOL. 37 NO. 2
THERIOGENOLOGY and was prepared for equilibration before vitrification. Embryos were equilibrated in a 50% diluted vitrification solution for 5 minutes at room temperature (22 to 24 "C) and for another 5 minutes 20-k 1 at 4°C , at which time they were pipetted into a vitrification solution column into 0.25 ml French straws (IMV, Within 30 seconds the straws were heat-sealed and L'Aigle. France). They were stored for periods between immersed into liquid nitrogen. 1 hour and 1 week. Warming,
Dilution
and
In Vitro
Culture
The vitrified samples were warmed in water at 0°C seconds. The contents of each straw were expelled into M sucrose+PBS. The embryos were held for 5 minutes then were transferred to fresh PBS. Recovered embryos in Ml6 solution (9) and were cultured in 0.1-1111 drops paraffin oil in 5% CO, in air at 37 "C. The survival embryos was assessed by their ability to develop to blastocyst stage following 48 hours (morula) (blastocyst) of culture. In Vivo
for 15 to 20 2.5 ml of 0.5 at 37 "C and were washed of Ml6 under rate of the the expanded or 24 hours
Survival
Morulae and blastocysts vitrified in a mixture of EG and DMSO were transferred to Day-3 pseudopregnant recipient females immediately after warming and dilution. Five to seven embryos were transferred to each uterine horn. In addition, fresh embryos were transferred as controls. The recipients were autopsied and examined on Day 18 of pregnancy to record the number of live fetuses. Statistical Data
Analyses were
analyzed
by the
x'
test.
RESULTS The survival rates of morulae vitrified in GL + DMSO and in EG + DMSO were significantly higher than those of the other solutions (PCO.01). On the other hand, the survival rates of blastocysts using GL + EG and EG + DMSO were significantly higher than those of the other solutions (PcO.05). The mixture of EG and DMSO gave the highest in vitro survival rates (79%) for both morulae and blastocysts, as shown in Table 1. Results after the transfer of vitrified embryos are shown in Table 2. The in viva development rates of vitrified morulae and blastocysts were 34 and 50%. respectively. These rates were not significantly different from those of the fresh control embryos (36 and 49%). DISCUSSION
The
FEBRUARY
primary
advantages
1992 VOL. 37 NO. 2
of
the
vitrification
method
for
the
483
THERIOGENOLOGY Table
1. In vitro survival after vitrification
Type of solution
GL GL GL EG EG PG
+ + + + + +
of mouse morulae and blastocysts in six types of vitrification solutions
No.(%) of morulae vitrified developed
EG PG DMSO PG DMSO DMSO
59 6'2 60 61 63 60
No.(%) of blastocysts vitrified developed
30(5$ lO(16) 47(78)c 27(44)a 50(79)c 30c50ia
a5 85 85 a4 89 89
61(72)d 25(29); 47(55)f 39(46)d 70179)f 41(46)
GL : Glycerol, EG : Ethylene gtycol. PG : Propylene glycol. DMSO : Dimethyl sulfoxide. Data were pooled for 7-10 replicates. Values with different superscripts within the same columns significantly different (a, b, c: P~0.01; d, e. f: P~0.05).
Table
2.
In viva development of mouse morulae and blastocysts vitrified in a mixture of ethylene glycol and dimethyl sulfoxide No.of
recipients
used
pregnant
Stage
of embryo
are
Treatments
No.of embryos transferred total to pregnant recipient
No. (X) of normal fetusesa
Morula
vitrified control
9 5
6 3
118 68
79 42
27 (34) 15 (36)
Blastocyst
vitrified control
8 5
6 2
96 68
71 28
35 (49) 14 (50)
a Total number to recipients
of live fetuses / total which became pregnant.
number
of embryos
transferred
cryopreservation of embryos are that freezing equipment is not necessary and the time required for cooling is reduced. However, vitrification solutions are known to be embryo-toxic at room temperature (1, 10). In our present study, embryos were equilibrated in each vitrification solution that was diluted by 50% for 5 minutes at room temperature and for another 5 minutes at 4 "C; then the embryos were exposed to the vitrification solution at 4°C for a short period (30 seconds). The mixture most effective blastocysts by conditions. The
494
of ethylene glycol and dimethyl sulfoxide was the for the cryopreservation of mouse morulae and vitrification under the present experimental in viva development of embryos vitrified in this
FEBRUARY 1992 VOL. 37 NO. 2
THERIOGENOLOGY solution in
was
the
previous by Kasai of
the
mentioned
workers et a1.(4)
embryos.
7. and
has
been
suggested
from
dilution
in
dimethyl vitrification cryopratectants
ethylene rapid
over also
0.5
be
effective
serious
mixture
al.(lO)
of
for
show.
solution exposure
glycerol
the
In
their
There
two
injury
and
compared to
permeable Urano
et
sulfoxide at
to
a1.(15)
protect the time
the of
glycol
and
ethylene
during
propylene not
embryos
our
warming
and
has
been
The method suggested
(2,
developmental Zwalmen et blastocysts procedure
cause The cells
dilution
equilibration blastocysts
al.
stage (17) after Massip
with
of embryos obta. ined in vitrification et a1.(18).
earlier
applied
present
and blastocyst ethylene glycol
of study
every
embryos
has
If
successfully sulfoxide
FEBRUARY 1992 VOL. 37 NO. 2
80 minutes vitrification present
low
et of study
equilibration
was lower concentration permeable
than (13).
cryoprotectant
been
reported
morulae
conventional and in
when
into
one
that
to
the
et
freezing. survival
the method,
al. with of
of
simpler
and
mouse
embryos
(15) each
Van Der bovine
method
stage
lower
equilibration however,
vitrification
vitrified under the
be
vitrification
Urano differ
viva
modifying modified
become
demonstrates
stages are and dimethyl
to
of
(16) were used. cryoprotectants
in vitro
short
vitrification
our
a
too
our
Zwalmen
in
highly the
developmental will
20
was
Der
in
time.
by This
stages. to
of
and of
“C
composition
although
lo-minute
4
between
to (2,
rate
Van
exposure
the
20%).
fast freezing effectiveness
at of
shown
vitrification
survival
concentration particular,
In
embryos
low
rate, and intracellular
in
a
or the
cryopreservation The
vs
by
mixture
difference 10)
permeation
of
a
30-second
adequate
6-8) that
successfully
a
(12.5%
in
survival optimal
(2,
eight-cell
of
succeed
also
embryos
findings
to
survival with
a
glycol
of this
the
cryoprotectant solutions.
glycol
within
compared
in as
to a low to reach
reports
lead
propylene
resulted
study,
was
previous
solution, i.e., their equilibration
not
highly 14).
pressure
cryopreservation
at 4°C led was needed
conditions.
of
control
low
permeate the embryo to time exposure (30 seconds). efflux from the embryonic
osmotic
but this mixture 5, 6, 10). The 30-second exposure study. for good embryo survival,
may
development
M sucrose+PBS. The
and
similar
fresh
was
Therefore,
may easily a short may easily
of
rate
also
it is possible technique.
is
dimethyl
found
survival
viva
fetuses
by
rates
was
7, 12), transfer
osmotic
freezing.
vitro in
(13,
reported
the
those
cell
and of
conventional
sulfoxide
causing
in
live
the
glycol
in
The
sulfoxide
change
than
from
morulae
rates
solution
10).
4. the
vitrified
to
The same
of
that
dimethyl
the
lower
a1.(6). this
studies (2, by refining
and
that
embryo
was
(6, 7, different
reported
glycol
without
et in
of
similar
it
proportion
with that of previous improve this proportion It
but
previous reports not significantly the
rate was
11). Valdez
vitrified
Although,
ethylene
survival
solution
(2,
blastocysts
to that of rates were
The
confirmed.
above
embryos,
more
in same
did can
at
be the
practical. the
morula
a mixture equilibration
of
485
THERIOGENOLOGY
The in viva development and dilution conditions. vitrified using this solution was also confirmed.
of
the
embryos
REFERENCES 1. Rall, W.F. and Fahy, G.M. Ice-free embryos at -196 "C by vitrification. 2.
Scheffen, B., and efficient vitrification.
Van Der Zwalmen, procedure for Cryo-Letters
cryopreservation of mouse Nature 313:573-575(1985).
P. and Massip, A. preservation of mouse 7:260-269(1986). -
affecting Factors by vitrification.
A simple embryos
by
the survival of mouse embryos Cryobiology 24:387-402(1987). -
3.
Rall, W.F. cryopreserved
4.
Takakamo, A., Kasai, M., Komi, H., Tsudera, H., Sakurai, T. and Machida, T. A simple method for mouse embryo cryopreservation in a low toxicity vitrification solution, without appreciable loss of viability. J. Reprod. Fertil. 89:9197(1990).
5.
Van Der Zwalmen. P., Scheffen, B. and Ectors. Massip, A., Pregnancies following transfer of cattle embryos preserved 7:270-273(1986). vitrification. Cryo-Letters -
6.
Valdez. C.A., and Kanagawa. developmental cryopreserved
0.. Takahashi, Y., Hishinuma, M. Abas, Mazni. H. Effects of equilibration time, pre-cooling and stage on the survival of mouse embryos Theriogenology 33:627-636(1990). by vitrification. -
7.
Kono, T. and vitrification. Japanese).
Tsunoda, Jpn.
8.
of mouse embryos Nakagata, N. Survival fertilization after ultrarapid freezing Japanese). Ova. Res. -6:23-26(1989)(in
9.
Y. Frozen J. Anim.
Whittingham, D.G. Culture 14 (Suppl.):7-21(1971). -
storage Reprod.
of mouse
of mouse embryos 33:77-81(1987)(in -
derived
and
ova.
F. by
by
from in vitro thawing. J. Mamm.
J.
Reprod.
Fertil.
10.
Van Der Zwalmen, P., Gaurois. B., Ectors, F.,Jr., affecting Massip, A. and Ectors, F. Some factors vitrification of mouse blastocysts. Theriogenology 1183(1988).
11.
Survival In vitro of zona pellucida free mouse Bielanski. A. embryos after cooling by conventional two-step or vitrification Cryo-Letters 8:294-301(1987). methods. -
12.
Kirby, C. Rail, W.F.. Wood, M.J., and Whittingham, Development of mouse embryos cryopreserved by vitrification. Reprod. Fertil. 80:499-504(1987). -
486
FEBRUARY
Touati, K., successful 30:1177-
D.G. .I.
1992 VOL. 37 NO. 2
THERIOGENOLOGY Levy, D.I. 13. Pahy, G.M., underlying the physical utility of vitrification 14.
principles Ali, S.E. Some emerging and properties, biological actions, and Cryobiology 24:196-213(19873. solution. -
characteristics Shelton, J.N. and Szell. K. Osmotic Szell. A., 26:297-301(1989). of sheep and cattle embryos. Cryobiology -
Effect of various and Kanagawa, H. Takahashi. Y. 15. Urano. K., mouse embryos. cryoprotectants on the survival of frozen-thawed 32:130_133(1986)(in Japanese). Jpn. J. Anim. Reprod. 16. Massip. A., Van Der of development on Cryobiology rapidly. 17.
Zwalmen, P. and Leroy, F. Effect of storage survival of mouse embryos frozen-thawed 21:574-577(1984). -
Van Der Zwalmen, P., Touati, K., Ectors. F. Vitrification J.F. and Ectors. Beckers, Theriogenology 31:270 abstr.(1989). -
18. Massip, A, Van cryopreservation 79(1987).
Der
F..Jr.. of bovine
Massip. A., blastocysts.
Zwalmen, P. and Ectors. P. Recent progress in of cattle embryos. Theriogenology -27:69-
FEBRUARY 1992 VOL. 37 NO. 2
487
VIABILITY OF VITRIFIED MOUSE USING VARIOUS CRYOPROTECTANT H. Ishimorit
Y. Takahashi
EMBRYOS MIXTURES
and H. Kanagawa
Department of Theriogenology Faculty of Veterinary Medicine Hokkaido University, Sapporo 060, Japan Received
for
publication:
Accepted:
February 27, 1991 October 29, 1991
ABSTRACT Mouse morulae and blastocysts were cryopreserved by vitrification using six types of solutions. Each solution was composed of two types of cryoprotectants. glycerol(GL) + ethylene GL + dimethyl sulfoxide(DMSO), glycol(EG). GL + propylene glycol(PG), EG + PG. EG + DMSO, and PG + DMSO at an each cryoprotectant concentration of 25% v/v. Embryos were exposed to each type of vitrification solutions, which had been diluted 50% in PBS, for 5 then for another 5 minutes at 4 "C. minutes at room temperature, The embryos were loaded into straws containing vitrification solution at 4°C and plunged into liquid nitrogen within 30 seconds. After warming in water at OC and following one-step dilution of the cryoprotectant in 0.5 M sucrose+PBS, the embryos were cultured in vitro. The survival rates of morulae were 51, 16, 78, 44, 79 and 50%. respectively, for the six solutions. The survival rates of the morulae using GL + DMSO and EG + DMSO were significantly higher than those of the other solutions (P
words:
mouse
embryo,
vitrification,
cryoprotectant
mixture
INTRODUCTION Rall
and
Fahy
(1)
first
reported
vitrification
Acknowledgments The authors thank Drs, Conrad0 A. Valdez reviewing this manuscript. 1 Present address : Embryo Transplantation Milk Products Co., Ltd., Uenae Tomakomai,
FEBRUARY 1992 VOL. 37 NO. 2
and Antonio
as
a new
A. Rayos
for
Laboratory, Snow Brand Hokkaido 059-13. Japan.
481
THERIOGENOLOGY approach for the preservation of embryos. Since then, many researchers have studied cryopreservation of embryos by vitrification. Some effective vitrification solutions such as mixtures of glycerol and propylene glycol (2). polyethylene glycol and glycerol or propylene glycol (3), and ethylene glycol, ficoll and sucrose (4) have been reported. Scheffen et a1.(2) showed high in vitro survival rates of compacted mouse morulae and early blastocysts vitrified in a mixture of glycerol and propylene glycol. Massip et al.(S) reported the solution to be effective for bovine morulae and early blastocysts. Both their vitrification solution and method were simple; however, the survival rates for mouse and bovine blastocysts were lower in comparison with those for morulae. Other researchers also have reported similar findings using the same solution (6) and another vitrification solution (7, 8). Embryos at the morula and blastocyst stages are used most A vitrification solution frequently in bovine embryo transfer. same equilibration and applicable at both stages using the vitrification conditions is therefore desirable. There have been no reports regarding the comparison of different cryoprotectant mixtures used for the vitrification of embryos. This study was the in vitro viability of undertaken to investigate and compare morula and blastocyst stage embryos using different cryoprotectant mixtures. MATERIALS
AND
METHODS
Embryos Female ICR mice (4 to 7 weeks old) were induced to superovulate by intraperitoneal injections of 5 IU PMSG and 5 Ill hCG 48 hours apart. They were mated with male ICR mice except in the embryo transfer experiment, for which C57BL/6 males were used. Morulae or blastocysts were flushed from the oviducts and uteri at 70 to 72 hours or 90 to 92 hours after hCG treatment using Dulbecco's with 0.4mg/ml bovine phosphate buffered saline (PBS) supplemented serum albumin. Vitrification
Solution
Six types of vitrification solutions were used, each consisting of a mixture of two types of permeating cryoprotectants in PBS: glycerol(GL) + ethylene glycol(EG), GL + propylene glycol(PG), GL + dimethyl sulfoxide(DMSO), EG + PG, EG + DMSO, and PG + DMSO. The concentration of each cryoprotectant was 25% v/v. All solutions in the straws remained transparent during cooling and warming, which is one indication that the solutions vitrified (4). Equilibration Each
482
type
and
Cooling
of vitrification
solution
was
diluted
by 50%
in PBS
FEBRUARY 1992 VOL. 37 NO. 2
THERIOGENOLOGY and was prepared for equilibration before vitrification. Embryos were equilibrated in a 50% diluted vitrification solution for 5 minutes at room temperature (22 to 24 "C) and for another 5 minutes 20-k 1 at 4°C , at which time they were pipetted into a vitrification solution column into 0.25 ml French straws (IMV, Within 30 seconds the straws were heat-sealed and L'Aigle. France). They were stored for periods between immersed into liquid nitrogen. 1 hour and 1 week. Warming,
Dilution
and
In Vitro
Culture
The vitrified samples were warmed in water at 0°C seconds. The contents of each straw were expelled into M sucrose+PBS. The embryos were held for 5 minutes then were transferred to fresh PBS. Recovered embryos in Ml6 solution (9) and were cultured in 0.1-1111 drops paraffin oil in 5% CO, in air at 37 "C. The survival embryos was assessed by their ability to develop to blastocyst stage following 48 hours (morula) (blastocyst) of culture. In Vivo
for 15 to 20 2.5 ml of 0.5 at 37 "C and were washed of Ml6 under rate of the the expanded or 24 hours
Survival
Morulae and blastocysts vitrified in a mixture of EG and DMSO were transferred to Day-3 pseudopregnant recipient females immediately after warming and dilution. Five to seven embryos were transferred to each uterine horn. In addition, fresh embryos were transferred as controls. The recipients were autopsied and examined on Day 18 of pregnancy to record the number of live fetuses. Statistical Data
Analyses were
analyzed
by the
x'
test.
RESULTS The survival rates of morulae vitrified in GL + DMSO and in EG + DMSO were significantly higher than those of the other solutions (PCO.01). On the other hand, the survival rates of blastocysts using GL + EG and EG + DMSO were significantly higher than those of the other solutions (PcO.05). The mixture of EG and DMSO gave the highest in vitro survival rates (79%) for both morulae and blastocysts, as shown in Table 1. Results after the transfer of vitrified embryos are shown in Table 2. The in viva development rates of vitrified morulae and blastocysts were 34 and 50%. respectively. These rates were not significantly different from those of the fresh control embryos (36 and 49%). DISCUSSION
The
FEBRUARY
primary
advantages
1992 VOL. 37 NO. 2
of
the
vitrification
method
for
the
483
THERIOGENOLOGY Table
1. In vitro survival after vitrification
Type of solution
GL GL GL EG EG PG
+ + + + + +
of mouse morulae and blastocysts in six types of vitrification solutions
No.(%) of morulae vitrified developed
EG PG DMSO PG DMSO DMSO
59 6'2 60 61 63 60
No.(%) of blastocysts vitrified developed
30(5$ lO(16) 47(78)c 27(44)a 50(79)c 30c50ia
a5 85 85 a4 89 89
61(72)d 25(29); 47(55)f 39(46)d 70179)f 41(46)
GL : Glycerol, EG : Ethylene gtycol. PG : Propylene glycol. DMSO : Dimethyl sulfoxide. Data were pooled for 7-10 replicates. Values with different superscripts within the same columns significantly different (a, b, c: P~0.01; d, e. f: P~0.05).
Table
2.
In viva development of mouse morulae and blastocysts vitrified in a mixture of ethylene glycol and dimethyl sulfoxide No.of
recipients
used
pregnant
Stage
of embryo
are
Treatments
No.of embryos transferred total to pregnant recipient
No. (X) of normal fetusesa
Morula
vitrified control
9 5
6 3
118 68
79 42
27 (34) 15 (36)
Blastocyst
vitrified control
8 5
6 2
96 68
71 28
35 (49) 14 (50)
a Total number to recipients
of live fetuses / total which became pregnant.
number
of embryos
transferred
cryopreservation of embryos are that freezing equipment is not necessary and the time required for cooling is reduced. However, vitrification solutions are known to be embryo-toxic at room temperature (1, 10). In our present study, embryos were equilibrated in each vitrification solution that was diluted by 50% for 5 minutes at room temperature and for another 5 minutes at 4 "C; then the embryos were exposed to the vitrification solution at 4°C for a short period (30 seconds). The mixture most effective blastocysts by conditions. The
494
of ethylene glycol and dimethyl sulfoxide was the for the cryopreservation of mouse morulae and vitrification under the present experimental in viva development of embryos vitrified in this
FEBRUARY 1992 VOL. 37 NO. 2
THERIOGENOLOGY solution in
was
the
previous by Kasai of
the
mentioned
workers et a1.(4)
embryos.
7. and
has
been
suggested
from
dilution
in
dimethyl vitrification cryopratectants
ethylene rapid
over also
0.5
be
effective
serious
mixture
al.(lO)
of
for
show.
solution exposure
glycerol
the
In
their
There
two
injury
and
compared to
permeable Urano
et
sulfoxide at
to
a1.(15)
protect the time
the of
glycol
and
ethylene
during
propylene not
embryos
our
warming
and
has
been
The method suggested
(2,
developmental Zwalmen et blastocysts procedure
cause The cells
dilution
equilibration blastocysts
al.
stage (17) after Massip
with
of embryos obta. ined in vitrification et a1.(18).
earlier
applied
present
and blastocyst ethylene glycol
of study
every
embryos
has
If
successfully sulfoxide
FEBRUARY 1992 VOL. 37 NO. 2
80 minutes vitrification present
low
et of study
equilibration
was lower concentration permeable
than (13).
cryoprotectant
been
reported
morulae
conventional and in
when
into
one
that
to
the
et
freezing. survival
the method,
al. with of
of
simpler
and
mouse
embryos
(15) each
Van Der bovine
method
stage
lower
equilibration however,
vitrification
vitrified under the
be
vitrification
Urano differ
viva
modifying modified
become
demonstrates
stages are and dimethyl
to
of
(16) were used. cryoprotectants
in vitro
short
vitrification
our
a
too
our
Zwalmen
in
highly the
developmental will
20
was
Der
in
time.
by This
stages. to
of
and of
“C
composition
although
lo-minute
4
between
to (2,
rate
Van
exposure
the
20%).
fast freezing effectiveness
at of
shown
vitrification
survival
concentration particular,
In
embryos
low
rate, and intracellular
in
a
or the
cryopreservation The
vs
by
mixture
difference 10)
permeation
of
a
30-second
adequate
6-8) that
successfully
a
(12.5%
in
survival optimal
(2,
eight-cell
of
succeed
also
embryos
findings
to
survival with
a
glycol
of this
the
cryoprotectant solutions.
glycol
within
compared
in as
to a low to reach
reports
lead
propylene
resulted
study,
was
previous
solution, i.e., their equilibration
not
highly 14).
pressure
cryopreservation
at 4°C led was needed
conditions.
of
control
low
permeate the embryo to time exposure (30 seconds). efflux from the embryonic
osmotic
but this mixture 5, 6, 10). The 30-second exposure study. for good embryo survival,
may
development
M sucrose+PBS. The
and
similar
fresh
was
Therefore,
may easily a short may easily
of
rate
also
it is possible technique.
is
dimethyl
found
survival
viva
fetuses
by
rates
was
7, 12), transfer
osmotic
freezing.
vitro in
(13,
reported
the
those
cell
and of
conventional
sulfoxide
causing
in
live
the
glycol
in
The
sulfoxide
change
than
from
morulae
rates
solution
10).
4. the
vitrified
to
The same
of
that
dimethyl
the
lower
a1.(6). this
studies (2, by refining
and
that
embryo
was
(6, 7, different
reported
glycol
without
et in
of
similar
it
proportion
with that of previous improve this proportion It
but
previous reports not significantly the
rate was
11). Valdez
vitrified
Although,
ethylene
survival
solution
(2,
blastocysts
to that of rates were
The
confirmed.
above
embryos,
more
in same
did can
at
be the
practical. the
morula
a mixture equilibration
of
485
THERIOGENOLOGY
The in viva development and dilution conditions. vitrified using this solution was also confirmed.
of
the
embryos
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