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1. Rational Design of Nanomedicine for Placental Disorders: Birthing a New Era in Women's Reproductive Health

   https://doi.org/10.1002/smll.202300852  

   Geisler, Hannah C; Safford, Hannah C; Mitchell, Michael J (May 2023, Small)

   Abstract The placenta is a transient organ that forms during pregnancy and acts as a biological barrier, mediating exchange between maternal and fetal circulation. Placental disorders, such as preeclampsia, fetal growth restriction, placenta accreta spectrum, and gestational trophoblastic disease, originate in dysfunctional placental development during pregnancy and can lead to severe complications for both the mother and fetus. Unfortunately, treatment options for these disorders are severely lacking. Challenges in designing therapeutics for use during pregnancy involve selectively delivering payloads to the placenta while protecting the fetus from potential toxic side effects. Nanomedicine holds great promise in overcoming these barriers; the versatile and modular nature of nanocarriers, including prolonged circulation times, intracellular delivery, and organ‐specific targeting, can control how therapeutics interact with the placenta. In this review, nanomedicine strategies are discussed to treat and diagnose placental disorders with an emphasis on understanding the unique pathophysiology behind each of these diseases. Finally, prior study of the pathophysiologic mechanisms underlying these placental disorders has revealed novel disease targets. These targets are highlighted here to motivate the rational design of precision nanocarriers to improve therapeutic options for placental disorders. 

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2. Visual Analytics for Robust Investigations of Placental Aquaporin Gene Expression in Response to Maternal SARS-CoV-2 Infection

   https://doi.org/10.3390/analytics3010007  

   Isokpehi, Raphael D.; Abioye, Amos O.; Hamilton, Rickeisha S.; Fryer, Jasmin C.; Hollman, Antoinesha L.; Destefano, Antoinette M.; Ezekiel, Kehinde B.; Taylor, Tyrese L.; Brooks, Shawna F.; Johnson, Matilda O.; et al (March 2024, Analytics)

   The human placenta is a multifunctional, disc-shaped temporary fetal organ that develops in the uterus during pregnancy, connecting the mother and the fetus. The availability of large-scale datasets on the gene expression of placental cell types and scholarly articles documenting adverse pregnancy outcomes from maternal infection warrants the use of computational resources to aid in knowledge generation from disparate data sources. Using maternal Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection as a case study in microbial infection, we constructed integrated datasets and implemented visual analytics resources to facilitate robust investigations of placental gene expression data in the dimensions of flow, curation, and analytics. The visual analytics resources and associated datasets can support a greater understanding of SARS-CoV-2-induced changes to the human placental expression levels of 18,882 protein-coding genes and at least 1233 human gene groups/families. We focus this report on the human aquaporin gene family that encodes small integral membrane proteins initially studied for their roles in water transport across cell membranes. Aquaporin-9 (AQP9) was the only aquaporin downregulated in term placental villi from SARS-CoV-2-positive mothers. Previous studies have found that (1) oxygen signaling modulates placental development; (2) oxygen tension could modulate AQP9 expression in the human placenta; and (3) SARS-CoV-2 can disrupt the formation of oxygen-carrying red blood cells in the placenta. Thus, future research could be performed on microbial infection-induced changes to (1) the placental hematopoietic stem and progenitor cells; and (2) placental expression of human aquaporin genes, especially AQP9. 

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3. Recent progress in 2D, 3D, and on-a-chip models of the placenta

   https://doi.org/10.1159/000547560  

   Harrison, Alexandra M; Bailey-Hytholt, Christina M (July 2025, Cells Tissues Organs)

   Background: The placenta is a temporary organ that develops throughout pregnancy, connecting a developing fetus to the maternal uterine wall. The placenta’s structure is species specific and complex, resulting in recent advancements with in vitro models to help study this dynamic organ. The main cell type composing the placenta, trophoblast cells, serve several roles and have been incorporated within biomaterials and devices to recapitulate the placental microenvironment. Summary: This review highlights in vitro 2D, 3D, and on-a-chip models of two placental interfaces: the interface between the endometrium and extravillous trophoblast cells and the interface between the chorionic villi and intervillous space. First, an overview of placental cell types and in vitro model types used in the discussed studies is provided. Next, models of invasive trophoblasts cells at the endometrium where the placenta is anchored and the spiral arteries are remodeled are discussed. Next, the review highlights models of the chorionic villi and intervillous space, an interface where cytotrophoblast cells fuse into syncytiotrophoblasts. Finally, we discuss key takeaways and future directions in creating representative placental models.Key Messages: The combination of biomaterial and engineering approaches has led to the development of physiologically relevant models, allowing placental trophoblast functions to be investigated with more clarity. Each cell type (e.g. trophoblast cell line vs. stem cells vs. primary placental cells) and biomaterial system (e.g. organoid vs. on-a-chip) that is selected for a given model has a unique combination of advantages and limitations, which are detailed within this review. Overall, the placental models discussed enable trophoblast cell behavior to be studied in vitro with the inclusion of extracellular matrix materials, growth factors, and other environmental cues. While one model alone does not fully recapitulate every function of the placenta, individual models are tailored to inform on specific placental trophoblast behaviors. 

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4. Orthogonal Design of Experiments for Engineering of Lipid Nanoparticles for mRNA Delivery to the Placenta

   https://doi.org/10.1002/smll.202303568  

   Safford, Hannah C; Swingle, Kelsey L; Geisler, Hannah C; Hamilton, Alex G; Thatte, Ajay S; Ghalsasi, Aditi A; Billingsley, Margaret M; Alameh, Mohamad‐Gabriel; Weissman, Drew; Mitchell, Michael J (August 2023, Small)

   Abstract During healthy pregnancy, the placenta develops to allow for exchange of nutrients and oxygen between the mother and the fetus. However, placental dysregulation can lead to several pregnancy disorders, such as preeclampsia and fetal growth restriction. Recently, lipid nanoparticle (LNP)‐mediated delivery of messenger RNA (mRNA) has been explored as a promising approach to treat these disorders. Here, iterative libraries of LNPs with varied excipient molar ratios are screened in vitro for enhanced mRNA delivery to placental cells with minimal cytotoxicity when compared to an LNP formulation with a standard excipient molar ratio. LNP C5, the top formulation identified by these screens, demonstrates a fourfold increase in mRNA delivery in vitro compared to the standard formulation. Intravenous administration of LNP C5 to pregnant mice achieves improved in vivo placental mRNA delivery compared to the standard formulation and mediates mRNA delivery to placental trophoblasts, endothelial cells, and immune cells. These results identify LNP C5 as a promising optimized LNP formulation for placental mRNA delivery and further validates the design of experiments strategy for LNP excipient optimization to enhance mRNA delivery to cell types and organs of interest. 

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5. Adaptive structural and functional evolution of the placenta protects fetal growth in high-elevation deer mice

   https://doi.org/10.1073/pnas.2218049120  

   Wilsterman, Kathryn; Moore, Emily C.; Schweizer, Rena M.; Cunningham, Kirksey; Good, Jeffrey M.; Cheviron, Zachary A. (June 2023, Proceedings of the National Academy of Sciences)

   Environmental hypoxia challenges female reproductive physiology in placental mammals, increasing rates of gestational complications. Adaptation to high elevation has limited many of these effects in humans and other mammals, offering potential insight into the developmental processes that lead to and protect against hypoxia-related gestational complications. However, our understanding of these adaptations has been hampered by a lack of experimental work linking the functional, regulatory, and genetic underpinnings of gestational development in locally adapted populations. Here, we dissect high-elevation adaptation in the reproductive physiology of deer mice (Peromyscus maniculatus), a rodent species with an exceptionally broad elevational distribution that has emerged as a model for hypoxia adaptation. Using experimental acclimations, we show that lowland mice experience pronounced fetal growth restriction when challenged with gestational hypoxia, while highland mice maintain normal growth by expanding the compartment of the placenta that facilitates nutrient and gas exchange between gestational parent and fetus. We then use compartment-specific transcriptome analyses to show that adaptive structural remodeling of the placenta is coincident with widespread changes in gene expression within this same compartment. Genes associated with fetal growth in deer mice significantly overlap with genes involved in human placental development, pointing to conserved or convergent pathways underlying these processes. Finally, we overlay our results with genetic data from natural populations to identify candidate genes and genomic features that contribute to these placental adaptations. Collectively, these experiments advance our understanding of adaptation to hypoxic environments by revealing physiological and genetic mechanisms that shape fetal growth trajectories under maternal hypoxia. 

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