Conventionally, in vitro–fertilized (IVF) bovine embryos are morphologically evaluated at the time of embryo transfer to select those that are likely to establish a pregnancy. This method is, however, subjective and results in unreliable selection. Here we describe a novel selection system for IVF bovine blastocysts for transfer that traces the development of individual embryos with time-lapse cinematography in our developed microwell culture dish and analyzes embryonic metabolism. The system can noninvasively identify prognostic factors that reflect not only blastocyst qualities detected with histological, cytogenetic, and molecular analysis but also viability after transfer. By assessing a combination of identified prognostic factors—(i) timing of the first cleavage; (ii) number of blastomeres at the end of the first cleavage; (iii) presence or absence of multiple fragments at the end of the first cleavage; (iv) number of blastomeres at the onset of lag-phase, which results in temporary developmental arrest during the fourth or fifth cell cycle; and (v) oxygen consumption at the blastocyst stage—pregnancy success could be accurately predicted (78.9%). The conventional method or individual prognostic factors could not accurately predict pregnancy. No newborn calves showed neonatal overgrowth or death. Our results demonstrate that these five predictors and our system could provide objective and reliable selection of healthy IVF bovine embryos.
We have developed a polystyrene-based well-of-the-well (WOW) system using injection molding to track individual embryos throughout culture using time-lapse cinematography (TLC). WOW culture of bovine embryos following in vitro fertilization was compared with conventional droplet culture (control). No differences between control- and WOW-cultured embryos were observed during development to the blastocyst stage. Morphological quality and inner cell mass (ICM) and trophectoderm (TE) cell numbers were not different between control- and WOW-derived blastocysts; however, apoptosis in both the ICM and TE cells was reduced in WOW culture (P < 0.01). Oxygen consumption in WOW-derived blastocysts was closer to physiological level than that of control-derived blastocysts. Moreover, WOW culture improved embryo viability, as indicated by increased pregnancy rates at Days 30 and 60 after embryo transfer (P < 0.05). TLC monitoring was performed to evaluate the cleavage pattern and the duration of the first cell cycle of embryos from oocytes collected by ovum pickup; correlations with success of pregnancy were determined. Logistic regression analysis indicated that the cleavage pattern correlated with success of pregnancy (P < 0.05), but cell cycle length did not. Higher pregnancy rates (66.7%) were observed for animals in which transferred blastocysts had undergone normal cleavage, identified by the presence of two blastomeres of the same size without fragmentation, than among those with abnormal cleavage (33.3%). These results suggest that our microwell culture system is a powerful tool for producing and selecting healthy embryos and for identifying viability biomarkers.
Inclusion complex formation between a conducting polymer, polyaniline (PANI) with emeraldine base, and a molecular nanotube synthesized from α-cyclodextrin (α-CD) has been studied by atomic force microscopy. We observed a rodlike inclusion complex of PANI and the molecular nanotube on mica substrate at room temperature. The height of this structure is nearly equal to the outside diameter of α-CD and almost uniform along the whole length of the structure, which indicates that a conducting wire of PANI is fully covered by molecular nanotubes as insulator. Accordingly, this inclusion complex can be regarded as insulated molecular wire.
Conventionally, in vitro-fertilized (IVF) bovine embryos for transfer are morphologically evaluated at day 7–8 of embryo culture. This method is, however, subjective and results in unreliable selection. We
previously described a novel selection system for IVF bovine blastocysts for transfer that traces the development of individual embryos with time-lapse monitoring in our specially developed microwell culture dishes (LinKID
micro25). The system can noninvasively identify prognostic factors that reflect viability after transfer. By assessing a combination of identified prognostic factors —timing of the first cleavage; number of blastomeres at the end
of the first cleavage; and number of blastomeres at the onset of lag-phase, which results in temporary developmental arrest during the fourth or fifth cell cycle— the pregnancy rate was improved over using conventional
morphological evaluation. Time-lapse monitoring with LinKID micro25 could facilitate objective and reliable selection of healthy IVF bovine embryos. Here, we review the novel bovine embryo selection system that allows for
prediction of viability after transfer.
Derivatives of aluminum-hydroxyquinoline complex were synthesized and used as light emitting materials for electroluminescent devices. The absorption and photo-luminescence spectra, and also the energy levels of the derivatives were shifted from those of the mother compound by electron-withdrawing and electron-releasing groups introduced into the hydroxyquinoline ligands. Using these compounds, the relationship between the electroluminescence efficiency and the energy levels was analyzed. The results strongly suggest that part of the injected electrons and holes recombine across the interface of the stacked organic layers, the process being non-emissive. It was also observed that the current-voltage curves shift toward the lower voltages as the electron accepting energy level of the light emitting material becomes lower.
To identify embryos individually during in vitro development, we
previously developed the well-of-the-well (WOW) dish, which contains 25 microwells. Here
we investigated the effect of embryo density (the number of embryos per volume of medium)
on in vitro development and gene expression of bovine in
vitro-fertilized embryos cultured in WOW dishes. Using both conventional
droplet and WOW culture formats, 5, 15, and 25 bovine embryos were cultured in 125 µl
medium for 168 h. The blastocysts at Day 7 were analyzed for number of cells and
expression of ten genes (CDX2, IFN-tau,
PLAC8, NANOG, OCT4,
SOX2, AKR1B1, ATP5A1,
GLUT1 and IGF2R). In droplet culture, the rates of
formation of >4-cell cleavage embryos and blastocysts were significantly lower in
embryos cultured at 5 embryos per droplet than in those cultured at 15 or 25 embryos per
droplet, but not in WOW culture. In both droplet and WOW culture, developmental kinetics
and blastocyst cell numbers did not differ among any groups. IFN-tau
expression in embryos cultured at 25 embryos per droplet was significantly higher than in
those cultured at 15 embryos per droplet and in artificial insemination (AI)-derived
blastocysts. Moreover, IGF2R expression was significantly lower in the
25-embryo group than in the 5-embryo group and in AI-derived blastocysts. In WOW culture,
these expressions were not affected by embryo density and were similar to those in
AI-derived blastocysts. These results suggest that, as compared with conventional droplet
culture, in vitro development and expression of IFN-tau
and IGF2R in the microwell system may be insensitive to embryo
density.
The properties of organic electroluminescence devices are largely affected by the kind of metals used as the cathode, because the barrier height formed at the interface depends on the electronic and chemical properties of the metals. On the basis of the temperature dependence of currents flowing through the interface between tris(8-hydroxyquinolino)aluminum and a magnesium cathode, the carrier injection mechanism at the interface was ascribed to the thermionic emission with the barrier height of about 0.58±0.03 eV at zero electric field. The barrier height became larger when metals with larger work functions were used as the cathode. The current density was also found to be dependent on the chemical structure of the interfaces.
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