Elucidation of cryotolerancein preimplantation murine embryos using confocal microscopy and developmental study / Razif Dasiman
The early stages of embryo development are highly unique, very predictable developmental transitions that begin with fertilization and continue throughout embryogenesis. The organization of the structural elements such as actin and tubulin undergoes dramatic architectural changes which is associated...
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| Format: | Thesis |
| Language: | English |
| Published: |
2014
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| Subjects: | |
| Online Access: | https://ir.uitm.edu.my/id/eprint/14328/1/TM_RAZIF%20DASIMAN%20MD%2014_5.pdf |
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| Summary: | The early stages of embryo development are highly unique, very predictable developmental transitions that begin with fertilization and continue throughout embryogenesis. The organization of the structural elements such as actin and tubulin undergoes dramatic architectural changes which is associated with the distribution of
mitochondria and nucleus. Cryopreservation of preimplantation embryos is a valuable technique in Assisted Reproductive Technology (ART) because it can preserve the embryos for extended times. However, to date, limited information is available about the ultrastructural changes and damages in the cytoskeletal elements of the preimplantation embryos after being cryopreserved with different cryopreservation techniques namely vitrification and slow freezing. The information is needed and
essential in the cryopreservation programme to select the best cryotolerant stages that can be a potential candidate for embryonic transfer and IVF. The Confocal Laser Scanning Microscope (CLSM) is used to analyze the distributions of each cytoskeletal elements. The objectives of this research was to determine the most cryotolerant stage of embryonic development in in vivo and in vitro produced embryos and to establish whether a correlation exists between the structural changes and developmental capacity of vitrified embryos. The results demonstrate that in vivo embryonic survival until the hatched blastocyst stage was more adversely affected by slow freezing
compared to control and vitrified embryos. However, in the in vitro study, although the pattern were similar, the difference between the slow freezing and vitrification were not significant. The 8-cell stages were found to be the best embryonic stage with the best embryonic grading scores both in vitrified and slow freezing techniques as compared to the other stages. In terms of cytoskeletal alterations, vitrification and slow frezing method caused highly significant changes in cytoskeletal structures of
the 2-, 4-, and 8-cell stage embryos especially in the tubulin, actin, nucleus and mitochondria. The lowest intensities of tubulin, actin, nucleus and mitochondria were shown in the slow frozen embryos as compared to the normal and vitrified embryos both in in vivo and in vitro group |
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