Intrinsic Angiogenic Potential and Migration Capacity of Human Mesenchymal Stromal Cells Derived from Menstrual Blood and Bone Marrow.

Several therapies are being developed to increase blood circulation in ischemic tissues. Despite bone marrow-derived mesenchymal stromal cells (bmMSC) are still the most studied, an interesting and less invasive MSC source is the menstrual blood, which has shown great angiogenic capabilities. Therefore, the aim of this study was to evaluate the angiogenic properties of menstrual blood-derived mesenchymal stromal cells (mbMSC) in vitro and in vivo and compared to bmMSC. MSC's intrinsic angiogenic capacity was assessed by sprouting and migration assays. mbMSC presented higher invasion and longer sprouts in 3D culture. Additionally, both MSC-spheroids showed cells expressing CD31. mbMSC and bmMSC were able to migrate after scratch wound in vitro, nonetheless, only mbMSC demonstrated ability to engraft in the chick embryo, migrating to perivascular, perineural, and chondrogenic regions. In order to study the paracrine effects, mbMSC and bmMSC conditioned mediums were capable of stimulating HUVEC's tube-like formation and migration. Both cells expressed VEGF-A and FGF2. Meanwhile, PDGF-B was expressed exclusively in mbMSC. Our results indicated that mbMSC and bmMSC presented a promising angiogenic potential. However, mbMSC seems to have additional advantages since it can be obtained by non-invasive procedure and expresses PDGF-B, an important molecule for vascular formation and remodeling.

Human Menstrual Blood-Derived Mesenchymal Cells Improve Mouse Embryonic Development.

There is a constant need for improving embryo culture conditions in assisted reproduction. One possibility is to use mesenchymal stem/stromal cells derived from menstrual blood (mbMSCs), with an endometrial origin. In this study, we sought to analyze the expansion of mouse embryos in a direct coculture model with mbMSCs. Our results showed that after five passages, mbMSCs presented a spindle-shaped morphology, with surface markers that were comparable with the normal mesenchymal cell phenotype. mbMSCs could differentiate into adipogenic and osteogenic lineages and secrete angiopoetin-2 and hepatocyte growth factor. The coculture experiments employed 103 two-cell-stage embryos that were randomly divided into two groups: control (n = 50), embryos cultured in GV-Blast medium, and cocultured mbMSCs (n = 53), embryos cocultured with GV-Blast and mbMSCs. Typically, two to three embryos were placed in a well with 200 µL of culture medium and observed until developmental day 5. After 5 days, the cocultured group had more embryos in the blastocyst stage (69.8%) when compared with the control group (30%) (p < 0.001). It was also found that nearly 57% of blastocysts in the cocultured group reached the hatching stage, while only 13% achieved this stage in the control group (p < 0.001). Analyses of cultured mbMSCs and growth media, in the presence or absence of an embryo, were also performed. Immunofluorescence detected similar levels of collagen I and III and fibronectin in both mbMSCs and cocultured mbMSCs, and similar amounts of growth factors, VEGF, PDGF-AA, and PDGF-BB, were also observed in the conditioned medium, regardless of embryo presence. The present study describes, for the first time, an easy, noninvasive, and autologous method that could potentially increase blastocyst growth rates during assisted reproductive procedures (i.e., in vitro fertilization). It is proposed that this mbMSC coculture strategy enriches the embryonic microenvironment and promotes embryo development. This technique may complement or replace existing assisted reproduction methods and is directly relevant to the field of personalized medicine. Impact statement The study demonstrates a novel and potentially personalized assisted reproduction approach. The search for alternative and autologous methods provides assisted reproduction patients with a better chance of a successful pregnancy. In this study, mesenchymal cells derived from menstrual blood resembled the outside uterine surface and could potentially be employed for improving embryo outgrowth. Our protocol enriches the embryonic microenvironment and facilitates high-quality single-embryo transfer.