Allometric scaling relationships in mouse placenta.

Fetal growth and maturation are highly intertwined with placental development during pregnancy. Here we used placental vascular morphology measurements (depth and span) as well as the umbilical artery (UA) diameter of previously published studies on three different mouse strains (C57BL6/J, CD-1 and BALB/c), which were exposed to different conditions (combination antiretroviral therapy, chronic maternal hypoxia and malaria infection) at different embryonic days, to test the hypothesis that placental vascularization and specifically the UA size affect conceptus weight. Interaction of each study parameter with embryonic day, strain and exposure to treatments are studied to investigate the stability of the scaling relationships across and/or within strains and conditions. In addition, the effect of UA diameter on the placental growth measurements (depth and span) is studied. These results show that the power-law scaling relationship of conceptus weight and placental depth with the UA diameter is conserved across strains and conditions with the scaling exponent of approximately 3/8 and 5/8, respectively. By contrast, the relationship between conceptus weight and either the placental span or depth is different between strains and conditions, suggesting multiple mechanisms of vascular adaptation.

Wave reflections in the umbilical artery measured by Doppler ultrasound as a novel predictor of placental pathology.

BACKGROUND: The umbilical artery (UA) Doppler pulsatility index is used clinically to detect elevated feto-placental vascular resistance. However, this metric is confounded by variation in fetal cardiac function and is only moderately predictive of placental pathology. Our group developed a novel ultrasound methodology that measures wave reflections in the UA, thereby isolating a component of the Doppler signal that is specific to the placenta. The present study examined whether wave reflections in the UA are predictive of placental vascular pathology. METHODS: Standard clinical Doppler ultrasound of the UAs was performed in 241 pregnant women. Of these, 40 women met narrowly defined preset criteria for the control group, 36 had maternal vascular malperfusion (MVM) and 16 had fetal vascular malperfusion (FVM). Using a computational procedure, the Doppler waveforms were decomposed into a pair of forward and backward propagating waves. FINDINGS: Compared to controls, wave reflections were significantly elevated in women with either MVM (p<0.0001) or FVM pathology (p = 0.02). In contrast, the umbilical and uterine artery pulsatility indices were only elevated in the MVM group (p<0.0001) and there were no differences between women with FVM and the controls. INTERPRETATION: The measurement of wave reflections in the UA, combined with standard clinical ultrasound parameters, has the potential to improve the diagnostic performance of UA Doppler to detect placental vascular pathology. Identifying women with FVM pathology is particularly challenging prenatally and future investigations will determine if women at risk of this specific placental disease could benefit from this novel diagnostic technique.

Interpretation of Wave Reflections in the Umbilical Arterial Segment of the Feto-Placental Circulation: Computational Modeling of the Feto-Placental Arterial Tree.

Placental vascular abnormalities are associated with a host of pregnancy complications including placenta mediated fetal growth restriction (FGR). Umbilical arterial (UA) Doppler ultrasound velocity waveforms are widely used in the diagnosis of underlying placental vascular abnormalities in pregnancies with suspected FGR, which greatly helps to prevent stillbirth via ongoing fetal monitoring and timely delivery. However, the sensitivity of UA Doppler diagnosis diminishes late in gestation. Our goal was to present a generalized wave decomposition method to compute forward and reflected components from UA waveforms. A detailed anatomical based model was also developed to explain observed UA flow waveform and to explore how vascular properties affect the shape of flow wave components. Using data from a previous study of pregnant mice using high frequency ultrasound microscopy, we examined in utero Doppler and M-mode ultrasound measurements in 15 fetuses' UA. Following ultrasound, the placentas had been collected and perfused with contrast agent to obtain high-resolution 3D images of the feto-placental arteries. Model of these specimens indicates the significant role of terminal load impedance (capillary and/or veins) in creating positive or negative reflected flow waveforms. A negative flow reflected waveform is obtained when terminal impedance is elevated. This is consistent with the elongated and non-branching terminal villi that are proposed to cause the highly abnormal UA waveforms found in early-onset FGR. The significance of these findings for the diagnostic utility of UA Doppler in human pregnancy is that the identification and measurement of wave reflections may aid in discriminating between healthy and abnormal placental vasculature in pregnancies with suspected late-onset FGR.

Combination of histochemical analyses and micro-MRI reveals regional changes of the murine cervix in preparation for labor.

The cervix is responsible for maintaining pregnancy, and its timely remodeling is essential for the proper delivery of a baby. Cervical insufficiency, or "weakness", may lead to preterm birth, which causes infant morbidities and mortalities worldwide. We used a mouse model of pregnancy and term labor, to examine the cervical structure by histology (Masson Trichome and Picrosirius Red staining), immunohistochemistry (Hyaluronic Acid Binding Protein/HABP), and ex-vivo MRI (T2-weighted and diffusion tensor imaging), focusing on two regions of the cervix (i.e., endocervix and ectocervix). Our results show that mouse endocervix has a higher proportion of smooth muscle cells and collagen fibers per area, with more compact tissue structure, than the ectocervix. With advanced gestation, endocervical changes, indicative of impending delivery, are manifested in fewer smooth muscle cells, expansion of the extracellular space, and lower presence of collagen fibers. MRI detected three distinctive zones in pregnant mouse endocervix: (1) inner collagenous layer, (2) middle circular muscular layer, and (3) outer longitudinal muscular layer. Diffusion MRI images detected changes in tissue organization as gestation progressed suggesting the potential application of this technique to non-invasively monitor cervical changes that precede the onset of labor in women at risk for preterm delivery.

Establishment of maternal blood supply to the placenta: insights into plugging, unplugging and trophoblast behaviour from an agent-based model.

The ability of the baby to receive nutrients and oxygen in utero depends on the healthy development of the placenta. For maternal blood to adequately perfuse the placenta, it dramatically alters the arteries in the uterus that supply it with nutrient-rich blood right from the start of pregnancy. Placental cells (trophoblasts) invade both into the tissue of the uterus and into the maternal blood vessels nearest to the site of implantation (the spiral arteries (SAs)) and transform these allowing a relatively high and steady flow of nutrient-rich blood to perfuse the placenta. Trophoblasts also form plugs that occlude SAs, preventing maternal blood flow to the placenta until the late first trimester, at which point these plugs dislodge or disintegrate. Here we present an agent-based model of trophoblast migration within plugged SAs to tease apart the impact of chemical signals and mechanical factors on trophoblast behaviour. The model supports our previous in vitro hypothesis that plugging of the maternal arteries in early pregnancy can act to promote trophoblast invasion by providing a 'low flow' environment and extends our understanding by suggesting 'weak spots' in plug structure can lead to plug degeneration, allowing increased blood flow through the materno-fetal circulation.

Trophoblast plugs: impact on utero-placental haemodynamics and spiral artery remodelling.

STUDY QUESTION: How does trophoblast plugging impact utero-placental haemodynamics? SUMMARY ANSWER: Physiological trophoblast plug structures are dense enough to restrict flow of oxygenated blood to the intervillous space (IVS) in the first trimester, and result in a shear stress environment upstream of the plugs that promotes spiral artery remodelling. WHAT IS KNOWN ALREADY: Trophoblast plugging of the uterine spiral arteries is thought to be the dominant factor restricting the flow of oxygenated maternal blood to the placenta in the first trimester of pregnancy. However, the extent of plugging, the timing of plug break up, and the impact of plug structure on pregnancy outcomes is debated. STUDY DESIGN, SIZE, DURATION: A computational model of the uterine radial and spiral arteries, incorporating arteriovenous anastomoses was developed. The model was parameterized with our own histological data and previous literature descriptions of the dimensions of the spiral arteries, and the structural properties (porosity) of trophoblast plugs. PARTICIPANTS/MATERIALS, SETTING, METHODS: Structural data were acquired from the literature, and supplemented by images of the spiral arteries acquired by standard thin-section 2D immunohistochemistry, and whole mount immunohistochemistry imaged in 3D by micro-CT. Computational models were solved using Matlab software, via custom written scripts. MAIN RESULTS AND THE ROLE OF CHANCE: We confirm that physiological lengths (>0.1 mm) and porosities (0.2-0.6) of trophoblast plugs are sufficient to restrict the flow of oxygenated maternal blood flow to the placental surface. Trophoblast plugs also have important haemodynamic consequences upstream in the spiral arteries by generating shear stress conditions of <2 dyne/cm2 that promote trophoblast-induced spiral artery remodelling. Structural changes in plugs as they dislodge are likely to result in rapid increases in blood flow to the IVS, and it is likely at this stage of gestation that the major source of resistance in the utero-placental circulation transitions from the spiral arteries to the radial arteries, which then act as a the 'rate-limiting' step to IVS flow. LIMITATIONS, REASONS FOR CAUTION: Structural descriptions of the spiral arteries, radial arteries and trophoblast plugs largely rely on 2D histological sections, or historical measurements. Increased focus on quantitatively assessing the 3D structure of the uterine arteries using more modern imaging technologies in the future will strengthen model predictions. WIDER IMPLICATIONS OF THE FINDINGS: Our work suggests that trophoblast plugs play a previously under-appreciated role in regulating spiral artery remodelling in the first trimester of human pregnancy. This creates the possibility that inadequate trophoblast plugging in the first trimester may contribute to the inadequate artery remodelling observed in pregnancy pathologies such as pre-eclampsia. The incorporation of arteriovenous anastomoses in our model highlights the important influence that shunted blood can play in utero-placental haemodynamics, and together with the emerging role of radial arteries in regulating blood flow to the placenta, the influence of arteriovenous anastomoses on radial artery haemodynamics in normal and pathological pregnancies warrants further investigation. STUDY FUNDING/COMPETING INTEREST(S): This research was supported by a Royal Society of New Zealand Marsden Fund award (13-UOA-032). A.R.C. is supported by a Royal Society of New Zealand Rutherford Discovery Fellowship (14-UOA-019). R.S. was supported by a Gravida (National Centre for Growth and Development) postgraduate scholarship. The authors have no conflicts of interest. TRIAL REGISTRATION NUMBER: N/A.

Association of Placental Jets and Mega-Jets With Reduced Villous Density.

Spiral arteries (SAs) lie at the interface between the uterus and placenta, and supply nutrients to the placental surface. Maternal blood circulation is separated from the fetal circulation by structures called villous trees. SAs are transformed in early pregnancy from tightly coiled vessels to large high-capacity channels, which is believed to facilitate an increased maternal blood flow throughout pregnancy with minimal increase in velocity, preventing damage to delicate villous trees. Significant maternal blood flow velocities have been theorized in the space surrounding the villi (the intervillous space, IVS), particularly when SA conversion is inadequate, but have only recently been visualized reliably using pulsed wave Doppler ultrasonography. Here, we present a computational model of blood flow from SA openings, allowing prediction of IVS properties based on jet length. We show that jets of flow observed by ultrasound are likely correlated with increased IVS porosity near the SA mouth and propose that observed mega-jets (flow penetrating more than half the placental thickness) are only possible when SAs open to regions of the placenta with very sparse villous structures. We postulate that IVS tissue density must decrease at the SA mouth through gestation, supporting the hypothesis that blood flow from SAs influences villous tree development.