Pregnancy Outcome Clinical Trial
Official title:
Improvement of the Post ICSI Pregnancy Outcome by Induction of the Acrosome Reaction Prior to ICSI
Introduction To get through the egg vestment and fertilize the oocyte, the spermatozoon uses
its acrosomal enzymes. When Intracytoplasmic sperm microinjection (ICSI) is performed, the
acrosomal enzymes are introduced with the spermatozoa inside the ooplasme.
The fate of these enzymes, that normally never enter the oocyte, is not known. But they
impair the embryo development.
Indeed, although the ICSI outcome is satisfactory in humans, a series of studies in many
species (mouse, hamster, cattle, and horse) demonstrate the deleterious effects of the
introduction of acrosomal material in the oocyte cytoplasm, on embryo and fetal development.
These studies have also shown two things:
- The bigger the acrosome, the more deleterious are the effects of their introduction
into the egg.
- And that the induction of the acrosome reaction (AR) prior to ICSI significantly
improves embryonic development and the number of babies born after embryo transfer as
it is the case in the mouse. The microinjection of acrosome reacted sperm increases
from 40 to 70 % the percentage of pups born per embryo transferred.
Hypothesis :
It is possible to improve ICSI outcome, in terms of babies born in human, by induction of
the AR prior to microinjection.
After studying several techniques, we choose a physiologic technique for acrosome induction.
The induction of acrosome reaction prior to ICSI should improve in utero fetal development
and decrease the rate of miscarriage and pregnancy arrest.
1. Introduction Intracytoplasmic sperm microinjection (ICSI) produces 70% of fertilized
oocytes and zygotes which mostly develop normally. To perform ICSI, a spermatozoon is
taken from a sperm suspension after gradient migration. It is then immobilized by
breaking its flagellum using a micropipette, and introduced into the oocyte cytoplasm.
The rate of spontaneous acrosome reaction in humans is less than 20 %. Two studies on
the percentage of acrosome reacted and immobilized sperm showed that 95% of them have a
destabilization of the membrane but only 17.8% of them had made a full RA. In other
words, when we microinjected 10 spermatozoa, only 2 of them are completely rid of their
acrosome material. All others are introduced into the oocyte with acrosomal material.
But this material does not normally enter the oocyte since the acrosome reaction is a
prerequisite to the passage of the zona pellucida that surrounds the egg .
The importance of using an acrosome-reacted spermatozoon for the success of ICSI has
been previously highlighted in several animal species. It has been demonstrated that
the induction of the acrosome reaction in mice lead to higher fertilization rates (from
30% to about 60 % ) . It is similar, in the rabbit and horses . Kimura et al. also
reported that mouse oocytes injected with acrosome-intact rabbit and hamster sperm
exhibited a nuclear activation and cessation of embryonic development without reaching
the two-cell stage. This "cytotoxicity" of the same sperm disappears when they are
released from their acrosomes before injection. In another study, the detrimental
effect on oocyte survival of the presence of the acrosome during the injection of sperm
heads was demonstrated in the golden hamster. All oocytes microinjected with
acrosome-intact sperm were dead, while only those injected with acrosome reacted sperm
have not only survived, but have also developed to the stage of two pronucleus in 79 %
of cases and helped to get live births ( 19%).
The team of Yanagimachi reported a study on the potentially dangerous effect of the
incorporation of the sperm acrosome of different species within mouse oocytes.
According to these authors, harmful components would probably be the enzymes such as
trypsin-like acrosine and hyaluronidase, since their injection mimicked the effects of
ICSI with acrosome-intact sperm. In the same study, it was confirmed that the toxic
effects were correlated with the size of the acrosome and therefore the contents of
protease enzymes.
The toxic effects of the acrosome and its contents have been described explicitly by
Morozumi and Yanagimachi. It induces deformation of the oocyte with an irregular
appearance, edema or cytolysis with a pseudo-vacuolated cytoplasm appearance.
Furthermore, it has been established that the damage caused by exogenous or acrosomales
enzymes were correlated with oocyte cytoskeleton disruption through an aberrant
accumulation of microtubules in the cortex of the oocyte.
In addition to the morphological and ultrastructural alterations in the oocyte, the
incorporation of the acrosome may result in a lack of nuclear activation of the oocyte.
Kasai et al. reported that the completion of oocyte meiosis occur faster if the sperm
was released from the acrosome. Similarly, an increase in fertilization rate after ICSI
with acrosome reacted sperm was observed in pigs. The study by Morozumi et al. also
demonstrated that the induction of the acrosome reaction of sperm from several species
prior to ICSI resulted in an acceleration of oocyte activation, which was manifest in
human spermatozoa. This was evidenced by the significant differences between the
profiles of calcium oscillations after ICSI with acrosome-intact or acrosome-reacted
sperm. Calcium waves recorded in oocytes injected with acrosome-reacted spermatozoa
were characterized by an early onset and amplitude and a higher frequency. In contrast,
the calcium response was abnormally delayed in oocytes injected with acrosome-intact
sperm.
Thus, altered calcium oscillations, the "key" oocyte activation signals during ICSI, is
the cause of abnormal pre-implantation embryo development to the blastocyst stage.
Indeed, the proportion of live healthy mice births is increased from 40% to 71%, when
intact or acrosome-reacted sperm are microinjected, respectively .
These same studies have also shown two things:
- The introduction of acrosomal material is more harmful when the quantity is large
compared to the oocyte volume. There is therefore interest in systematically
reducing the amount of material introduced into the oocyte cytoplasm to improve
embryonic development.
- The second thing is that the induction of the acrosome reaction before ICSI
greatly improves embryonic development and therefore the number of babies born
from embryo transfer.
Although ICSI in human gives very satisfactory results, the rate of infants obtained by
embryo is lower than after IVF embryos transfer. Hence, there is a possibility of
improving the results of ICSI by induction of the acrosome reaction prior to
microinjection.
After several studies we used incubation of spermatozoa with the follicular fluid (FF)
of the partner to induce the spermatozoa acrosome reaction (Karim Rahal, 2011 Master
Thesis 2). FF is indeed a potent inducer of the AR. There is no problem of traceability
since the FF of the patient is used only for the sperm of her husband. This technic can
be applied to the poorest semen. Finally, the technique is used in a very easy routine,
since the follicular fluid is always recovered during oocyte retrieval and thus
available.
2. Hypothesis A preliminary study was run in human on microinjection of spermatozoa that
were selected for their acrosomal status by birefringence microscopy. It showed that it
improves the implantation rate from 24,4 % to 39 % . We therefore hypothesize that the
improvement in the implantation rate of embryos obtained by ICSI after acrosomal
induction as well as the reduction of miscarriage rate may result in improved clinical
pregnancy outcome and birth rates of about 10 %.
;
Allocation: Randomized, Endpoint Classification: Bio-equivalence Study, Intervention Model: Parallel Assignment, Masking: Open Label
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