Generation of Human Blastoids from Naive Pluripotent Stem Cells.

Under certain culture conditions, naive human pluripotent stem cells can generate human blastocyst-like structures (called human blastoids). Human blastoids serve as an accessible model for human blastocysts and are amenable for large-scale production. Here, we describe a detailed step-by-step protocol for the robust and high-efficient generation of human blastoids from naive human pluripotent stem cells.

Validation of the Sw71-spheroid model with primary trophoblast cells.

PROBLEM: Human implantation is a limiting factor for the success of natural and IVF reproduction since about 60% of pregnancy losses occur in the peri-implantation period. The in vitro modeling of human implantation challenges the researchers in accurate recreation of the complex in vivo differentiation and function of human blastocyst in the peri-implantation period. In previous studies, we constructed Sw71-spheroid models, which like human blastocyst undergo compactization, attaches to the endometrial epithelium, invade, and migrate. The aim of this study was to validate the trophoblast Sw71-spheroid model with primary trophoblast cells, derived from healthy women in early pregnancy. METHOD OF STUDY: We performed a direct comparison of Sw71-spheroid model with placenta-derived primary trophoblasts regarding their hybrid phenotype and HLA status, as well as the ability to generate spheroids able to migrate and invade. From the primary trophoblast cells, isolated by mild enzymatic treatment and Percoll gradient separation, were generated long-lived clones, which phenotype was assessed by FACS and immunocytochemistry. RESULTS: Our results showed that cultured primary trophoblasts have the EVT phenotype (Vim+/CK7+/HLA-C+/HLA-G+), like Sw71 cells. In both 3D culture settings, we obtained stable, round-shaped, multilayered spheroids. Although constructed from the same number of cells, the primary trophoblast spheroids were smaller. The primary trophoblast spheroids migrate successfully, and in term of invasion are equally potent but less stable as compared to Sw71 spheroids. CONCLUSIONS: The Sw71 cell line and cultured native trophoblast cells are interchangeable regarding their EVT phenotype (HLA-C+/HLA-G+/Vim+/CK7+). The blastocyst-like spheroids sourced by both types of cells differentiate in the same time frame and function similarly. We strongly advise the use of Sw71 spheroids as blastocyst surrogate for observation on trophectoderm differentiation and function during early human implantation.

Modeling Epiblast Shape in Implanting Mammalian Embryos.

An indispensable prerequisite of mammalian development is successful morphogenesis in the epiblast, the embryonic tissue that gives rise to all differentiated cells of the adult mammal. The right control of both epiblast morphogenesis and the events that regulate its shape in particular during implantation is henceforth of tremendous importance. However, monitoring the process of development in implanting human embryos is ethically and technically challenging, making it difficult to troubleshoot when things go wrong, as it is unfortunately the case with over 30% of pregnancy failures. Although modern in vitro techniques have proven very insightful lately, more tools are needed in the quest to elucidate mammalian and human development. Mathematical and computational modeling position themselves as helpful complementary tools in the biologist's toolbox, enabling the exploration of the living in silico, beyond the boundaries set by ethical concerns and the potential limitations of wet lab techniques. Here, we show how mathematical modeling and computer simulations can be used to emulate and investigate mechanisms driving epiblast shape changes in mouse and human embryos during implantation.

Application prospect of silicon nitride ceramics in dental implants / 口腔疾病防治

@#Silicon nitride has high fracture toughness and compressive strength similar to human bone. It meets the basic mechanical requirements of implants and has good biocompatibility. The micrometer/nanometer morphology surface characteristics of silicon nitride give it good osteogenic activity and antibacterial properties, which are helpful to reduce the incidence of periimplant inflammation. Therefore, silicon nitride has good application potential in dental implants. In orthopedics, silicon nitride implants have been used in spine repair and joint implantation. However, there is a lack of research on silicon nitride as dental implant material. The evaluation of the osteogenic and antibacterial properties of silicon nitride bioceramics prepared using different sintering additives and sintering processes, the antibacterial properties of silicon nitride on different dominant oral pathogens, and the osteogenic activity and antibacterial properties of silicon nitride materials implanted into the jaw need to be further studied. Combined with the latest research results at home and abroad, this review discusses the application potential of silicon nitride materials in dentistry.

Trophectoderm mechanics direct epiblast shape upon embryo implantation.

Implantation is a hallmark of mammalian embryogenesis during which embryos establish their contacts with the maternal endometrium, remodel, and undertake growth and differentiation. The mechanisms and sequence of events through which embryos change their shape during this transition are largely unexplored. Here, we show that the first extraembryonic lineage, the polar trophectoderm, is the key regulator for remodeling the embryonic epiblast. Loss of its function after immuno-surgery or inhibitor treatments prevents the epiblast shape transitions. In the mouse, the polar trophectoderm exerts physical force upon the epiblast, causing it to transform from an oval into a cup shape. In human embryos, the polar trophectoderm behaves in the opposite manner, exerting a stretching force. By mimicking this stretching behavior in mouse embryogenesis, we could direct the epiblast to adopt the disc-like shape characteristic of human embryos at this stage. Thus, the polar trophectoderm acts as a conserved regulator of epiblast shape.

Anterior Lumbar Interbody Fusion Using Reaction Bonded Silicon Nitride Implants: Long-Term Case Series of the First Synthetic Anterior Lumbar Interbody Fusion Spacer Implanted in Humans.

BACKGROUND: In this study, a historical case series is reported of reaction bonded silicon nitride (Si3N4) implants for anterior lumbar interbody fusion (ALIF) for a patient population of 30 and surgery levels L3/4, L4/5, and/or L5/S1. Before the study, the only work on Si3N4 as a biomedical material was associated preliminary work, which involved animal trials using a rabbit model. The objective was to undertake the first use of Si3N4 as a biomedical material for humans, as an implant for ALIF. METHODS: The Si3N4 implants were prepared by die-pressing silicon powder and reaction bonding in 95 N2/5 H2 at ∼1400°C for ∼50 hours. The surgeries involved a retroperitoneal approach for L3/4 and L4/5 levels and a transperitoneal approach for L5/S1 level. The patient follow-up involved assessment of radiologic fusion up to 30 years and clinical outcomes to 10 years. RESULTS: The reaction bonded Si3N4 implants were found to be biologically safe and to show high fusion rates with minimal subsidence, no abnormal reaction, and no other complications. The primary outcome measure, visual analog scale back pain, improved from a preoperative mean of 8.4 (range, 6-10) to a mean of 3.7 (range, 0-9) at 5 years and a mean of 4.9 (range, 0-9) at 10 years. The Oswestry Disability Index improved from a preoperative mean of 48 (range, 26-84) to a mean of 35 (range, 4-76) at 10 years. CONCLUSIONS: This study confirms that Si3N4 is biologically safe in the long-term, with capacity for excellent radiologic osseointegration.

Implantation and extravillous trophoblast invasion: From rare archival specimens to modern biobanking.

Extravillous trophoblast invasion serves to attach the placenta to the uterus and to enable access to nutrients for the embryo throughout pregnancy - secretions of the uterine glands in the first trimester, maternal blood in the second and third trimester. For assessing extravillous trophoblast invasion, histology (in combination with immunohistochemistry) still plays a major role in placental research. This is especially true for the re-assessment of rare archival specimens from early human implantation sites or placenta in utero with the background of recent knowledge which may help to strengthen current hypotheses. This review summarizes the recently expanded picture of extravillous trophoblast invasion, gives an overview about fundamental archival specimens in placental research, presents new images of archival specimens, gives insights into the latest developments in the field of biobanking and provides insight into the current situation on sample usage in the absence of biobanks. Modern techniques allow expanding our hitherto believed concept of extravillous trophoblast invasion, which is not restricted to spiral arteries: Extravillous trophoblasts also invade into uterine glands and uterine veins and thereby connect all these luminal structures with the intervillous space. All biomedical research dramatically depends on the quality of the assessed biological samples. Hence, researchers should be aware that the time between collection of a sample from a body and the beginning of analysis (pre-analytical phase) may have more impact on the outcome of a study than previously assumed.

Interaction of human trophoblast cells with gland-like endometrial spheroids: a model system for trophoblast invasion.

STUDY QUESTION: Do maternal endometrial epithelial cell (EEC) differentiation and polarity impact the invasive capacity of extravillous trophoblast (EVT) cells during early human implantation? SUMMARY ANSWER: In a three dimensional (3D) confrontation co-culture the invasiveness of the human trophoblast cell line AC-1M88 was inversely correlated with the degree of differentiation and polarization of human endometrial adenocarcinoma cell spheroids. WHAT IS KNOWN ALREADY: In a previous study desmosomal and adherens junction proteins were shown to spread from a subapically restricted lateral position to the entire lateral membrane in human glandular EECs during the implantation window of the menstrual cycle. Whether this change in EEC junction localization has an impact on the interaction of EVT cells with glandular EECs during early human implantation is not known. STUDY DESIGN, SIZE, DURATION: A new 3D cell culture system was developed in order to mimic early implantation events in humans. As a model for the invasion of endometrial glands by EVT cells, spheroids of three differently differentiated and polarized endometrial adenocarcinoma cell lines were confronted with an EVT cell line in co-culture experiments. PARTICIPANTS/MATERIALS, SETTING, METHODS: Three human adenocarcinoma EEC lines were chosen for this study because of their differences in differentiation and polarization: HEC-1-A, which is well differentiated and highly polarized, Ishikawa, which is well differentiated and moderately polarized, and RL95-2, which is moderately differentiated and poorly polarized. When the cell lines were grown in reconstituted basement membrane, they formed gland-like, multicellular spheroids. The degree of polarization within the different EEC spheroids was assessed by 3D confocal immunofluorescence microscopy detecting the basal membrane protein integrin α6, the apical tight junction-associated protein ZO-1 and the desmosomal plaque protein desmoplakin 1/2 (Dsp). Cells of the human EVT cell line AC-1M88, which is a fusion cell line of primary EVT cells and choriocarcinoma-derived JEG-3 cells, were added to the different EEC spheroids to examine their interaction. For the analyses of trophoblast-endometrial confrontation sites, HLA-G was used as a specific EVT cell marker. MAIN RESULTS AND THE ROLE OF CHANCE: The endometrial HEC-1-A and Ishikawa cells formed gland-like structures in reconstituted basement membrane with apicobasal polarization towards their well-developed internal lumina, while most of the RL95-2 spheroids showed no lumen formation at all. The three EEC lines strongly differed in their apicobasal distribution pattern of Dsp. Ishikawa and HEC-1-A spheroids showed a subapical concentration of Dsp. In contrast, an equal distribution of Dsp was discerned along the entire lateral membranes in RL95-2 spheroids. In 3D confrontation co-cultures the highest invasiveness of AC-1M88 was observed in the poorly polarized RL95-2 spheroids. LIMITATIONS, REASONS FOR CAUTION: Human endometrial and trophoblast cell lines were used for this study because of ethical and legal restrictions for implantation studies with human blastocysts and because of limited access to primary human endometrial cells. WIDER IMPLICATIONS OF THE FINDINGS: The presented 3D cell culture system can be used to investigate the contribution of epithelial junctions to trophoblast-endometrial interactions. The identified impact of endometrial differentiation and polarity on the invasiveness of EVT cells improves our understanding of the relevance of endometrial receptivity for early implantation and may contribute to higher success rates in assisted reproductive technology. STUDY FUNDING/COMPETING INTERESTS: This work was supported by Grant 146/14, 'START-Program', Medical Faculty, RWTH Aachen University, to V.U.B., by Grant Lec_16_12, 'RWTH Lecturer Award', RWTH Aachen University to I.C.-L. and by the German Research Council (Grant LE 566-20-1). The authors declare no conflict of interest.