Mohammad Hossein Ahmadi scite author profile

The prenatal determination of the fetal Rh genotype could lead to a substantial reduction in the use of anti-D immunoglobulin and prevention of unnecessary exposure of pregnant women carrying RhD negative fetus. The aim of this study was fetal RHD genotyping through the analysis of cffDNA in plasma samples of RhD negative pregnant women by real-time PCR technique. In this experiment, 30 plasma samples were collected from RhD negative pregnant women. DNA were extracted and real-time PCR reactions were done by specific primers for and beta-globin () genes. The Rh phenotypes of mothers and their babies were determined by agglutination method and specific anti-serums. From the 30 maternal plasma samples considered for genotyping, 16 samples revealed the presence of the gene. Regarding the fetal genotyping, 26 samples were positive for RhD and 4 samples were negative. In all cases, the predicted RhD and SRY genotypes were in concordance with the serologically determined phenotypes. The sensitivity, specificity and precision of the fetal and genotyping test were calculated 100 % ( value <0.0005; K = 100 %). The present study confirms the precision of fetal RHD and SRY genotyping in maternal plasma by real-time PCR technique. This method helps RhD negative pregnant women about the appropriate use of anti-D immunoglobulin and also on the management and prevention of HDFN. However, superior and confirmatory studies are recommended before fetal RHD genotyping by real-time PCR is introduced as a non-invasive prenatal screening test.

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Noninvasive Prenatal Diagnosis of Fetal RHD Status Using Cell-free Fetal DNA in Maternal Plasma

Ahmadi¹,

Pourfathollah²,

Rabiei³

et al. 2022

JRI

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Background: The main cause of hemolytic disease of the fetus and newborn (HDFN) is the incompatibility of the RHD antigen between mother and fetus. Following the discovery of cell-free fetal DNA (cffDNA), noninvasive fetal RHD genotyping also became possible, which will help in the better management of immunized RHD negative mothers and in the targeted prenatal injection of Rho(D) immune globulin (RhIG). The objective of this study was to establish a reliable method with high accuracy to determine the fetal RHD genotype. Methods: The project was a prospective observational cohort study. After cell-free DNA (cfDNA) extraction from maternal plasma, fetal RHD genotyping was performed by duplex real-time polymerase chain reaction (PCR) and exons 5, 7, and 10 of the RHD gene were examined. SRY and RASSF1A genes were used as internal controls to confirm the presence of cffDNA in maternal plasma. Results: Out of 40 samples, 33 were RhD positive heterozygous mothers and 7 cases were RHD negative. In three cases where both the fetal RHD and SRY genotypes were negative, RASSF1A was amplified in cell-free DNA sample treated with the BstUI enzyme, and the presence of cffDNA was confirmed. Conclusion: The findings reveal that the strategy used in this study is reliable and it is possible to determine the fetal RHD status with high accuracy. The strategy can help targeted injection of RhIG and prevent unnecessary injection in RhD negative mothers who carry an RhD negative fetus.

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Electrochemical Performance Improvement of the Catalyst of the Methanol Micro-Fuel Cell Using Carbon Nanotubes

Nasrabadi¹,

Fard²,

Ebrahimi‐Moghadam³

et al. 2019

Preprint

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Due to low working temperature, high energy density and low pollution, proton exchange fuel cells have been investigated under different operating conditions in different applications. Using platinum catalyst in methanol fuel cell leads to increasing the cost of this kind of fuel cells which is considered as a barrier to the commercialism of this technology. For this reason, a lot of efforts have been made to reduce the loading of the catalyst required on different supports. In this study, carbon black (CB) and carbon nanotubes (CNT) have been used as catalyst supports of the fuel cell as well as using the double-metal combination of platinum-ruthenium (PtRu) as anode electrode catalyst and platinum (Pt) as cathode electrode catalyst. The performance of these two types of the electro-catalyst in oxidation reaction of methanol has been compared based on electrochemical tests. Results showed that the carbon nanotubes increase the performance of the micro-fuel cell by 37% at maximum power density, compared to the carbon black. Based on thee-electrode tests of chronoamperometry and voltammetry, it was found that oxidation onset potential of methanol for CNT has been around 20% less than CB, leading to the kinetic improvement of the oxidation reaction. In addition, the active electrochemical surface area of catalyst has been increased up to 90% by using CNT compared to CB which shows the significant rise of the electrocatalytic activity in CNT supported catalyst with 62% increase in current density of methanol oxidation reaction respect to CB supported one. Moreover, the resistance of CNT supported sample to poisonous intermediate species has been found 3% more than CB supported one. According to the chronoamperometry test results, it was concluded that the performance and sustainability of NCT electro-catalyst shows remarkable improvement compared to CB electro-catalyst in long term.

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