The application of magnetic cell sorter (MACS) to detect fetal cells in maternal peripheral blood

Noninvasive prenatal diagnosis targeting fetal nucleated red blood cells

Noninvasive prenatal diagnosis (NIPD) aims to detect fetal-related genetic disorders before birth by detecting markers in the peripheral blood of pregnant women, holding the potential in reducing the risk of fetal birth defects. Fetal-nucleated red blood cells (fNRBCs) can be used as biomarkers for NIPD, given their remarkable nature of carrying the entire genetic information of the fetus. Here, we review recent advances in NIPD technologies based on the isolation and analysis of fNRBCs. Conventional cell separation methods rely primarily on physical properties and surface antigens of fNRBCs, such as density gradient centrifugation, fluorescence-activated cell sorting, and magnetic-activated cell sorting. Due to the limitations of sensitivity and purity in Conventional methods, separation techniques based on micro-/nanomaterials have been developed as novel methods for isolating and enriching fNRBCs. We also discuss emerging methods based on microfluidic chips and nanostructured substrates for static and dynamic isolation of fNRBCs. Additionally, we introduce the identification techniques of fNRBCs and address the potential clinical diagnostic values of fNRBCs. Finally, we highlight the challenges and the future directions of fNRBCs as treatment guidelines in NIPD.

HUNTER-Chip: Bioinspired Hierarchically Aptamer Structure-Based Circulating Fetal Cell Isolation for Non-Invasive Prenatal Testing

Isolation and genetic analysis of circulating fetal cells from billions of maternal cells in peripheral blood are the cornerstone of fetal cell-based non-invasive prenatal testing. Inspired by the hierarchically multivalent architecture for enhanced capture of nature, an aptamer-based Hierarchically mUltivalent aNTibody mimic intERface (HUNTER) was designed with a tremendous avidity effect for highly efficient capture and non-destructive release of fetal cells. It was engineered by grafting Y-shaped DNA nanostructures to a linear polymer chain, creating a flexible polymer chain with bivalent aptamer side chains. This hierarchical arrangement of the aptamer ensures morphological complementarity, collective multiple-site interaction, and multivalent recognition between the aptamer and target cells. In combination with a deterministic lateral displacement (DLD)-patterned microdevice named as HUNTER-Chip, it achieves a binding affinity over 65-fold and a capture efficiency over 260%-fold due to the combination of hierarchically designed aptamers and frequent cell-ligand collision created by DLD. Moreover, a nuclease-assisted cell release strategy facilitates the release of fetal cells for gene analysis, such as fluorescence in situ hybridization. With the advantages of high affinity, excellent capture efficiency, and compatible downstream analysis, the HUNTER-Chip holds great potential for non-invasive prenatal diagnosis.

Detection of fetal cells from transcervical mucus plug before first-trimester termination of pregnancy by cytokeratin-7 immunohistochemistry

AIM

The presence of fetal cells in the endocervical mucus of pregnant women was first reported in 1971. The uterine cavity is patent during the first trimester prior to fusion of amnion and chorion. Fetal cells from degenerating chorion frondosum are theoretically shed into the uterine cavity between seven and 13 weeks' gestation and are trapped in the transcervical mucus; they can be identified by immunohistochemistry.

METHOD

Ninety-nine transcervical mucosal plugs from pregnant women of between 7 and 13 weeks before abortion were collected, fixed, embedded, sectioned and stained with monoclonal antibody of cytokeratin-7 (CK-7) by immunohistochemistry.

RESULT

The identification of trophoblasts on each slide was defined according to positive staining and histologically chorionic villous similarity under microscopic examination, using the following five categories: none (1), less than five single positive-stained cells per-section (2), more than five single positive-stained cells per-section (3), clumps of positive-stained cells (4), and histological-like intact or fragmented chorionic villi (5). From amongst 71 samples that qualified for analysis, individual slides were evaluated and categorized into three groups, with the following results: 32 (45.1%) fell into group 1 (category 1) denoting a negative result, 10 (14.1%) fell into group 2 (category 2) indicating a possible positive result and 29 (40.8%) fell into group 3 (any combination of categories 3-5) representing a positive result.

CONCLUSIONS

Fetal cells, identified by CK-7, can be found in more than 59.2% of the transcervical mucus in early pregnancy by use of a minimally invasive sampling method. Prenatal diagnosis of single-gene or chromosome disorders may be possible in the pregnant transcervical mucus by use of modern molecular methods and they deserve further study.