Pre-eclampsia is a severe placenta-related complication of pregnancy with limited early diagnostic and therapeutic options. Aetiological knowledge is controversial, and there is no universal consensus on what constitutes the early and late phenotypes of pre-eclampsia. Phenotyping of native placental three-dimensional (3D) morphology offers a novel approach to improve our understanding of the structural placental abnormalities in pre-eclampsia. Healthy and pre-eclamptic placental tissues were imaged with multiphoton microscopy (MPM). Imaging based on inherent signal (collagen, and cytoplasm) and fluorescent staining (nuclei, and blood vessels) enabled the visualization of placental villous tissue with subcellular resolution. Images were analysed with a combination of open source (FIJI, VMTK, Stardist, MATLAB, DBSCAN), and commercially (MATLAB) available software. Trophoblast organization, 3D-villous tree structure, syncytial knots, fibrosis, and 3D-vascular networks were identified as quantifiable imaging targets. Preliminary data indicate increased syncytial knot density with characteristic elongated shape, higher occurrence of paddle-like villous sprouts, abnormal villous volume-to-surface ratio, and decreased vascular density in pre-eclampsia compared to control placentas. The preliminary data presented indicate the potential of quantifying 3D microscopic images for identifying different morphological features and phenotyping pre-eclampsia in placental villous tissue.
Objective: Pre-eclampsia is a severe placenta related complication of pregnancy and aetiological knowledge, with limited early diagnostic and therapeutic options. Phenotyping of native placental three-dimensional (3D) morphology offers a novel approach to improve our understanding of the functional and structural placental abnormalities underlying this clinical syndrome. The aim of this project was to develop a 3D placental imaging protocol using multiphoton microscopy (MPM) and demonstrate quantifiable imaging targets for phenotyping 3D features of pre-eclampsia. Design: Exploratory pilot study. Setting: Single centre, MUMC. Sample: Formalin fixed placental biopsies from: term control (n=3), pre-eclampsia (n=3), preterm birth (n=2), 2nd trimester placenta (n=1), and intra-uterine growth restriction cases without pre-eclampsia (n=2). Methods: Placental slabs were visualised with MPM. Collagen and cytoplasm (based on inherent signal), and fluorescently stained nuclei and blood vessels, enabled the visualization of villous tissue with subcellular resolution. Segmentation based on pixel classification, deep learning, and clustering algorithms were used to generate quantifiable features. Main outcome measures: Trophoblast arrangement, 3D-villous tree structure, syncytial knots, fibrosis, and 3D-vascular networks were identified as imaging targets. Villous morphology, vascular fraction, vascular network (i.e., branchpoint density and diameter), nuclear density, and knot fraction were quantified to describe placental phenotypes. Results: Pre-eclamptic placentas had disorganized trophoblast arrangement, decreased vascular fraction, and altered vessel diameters, compared to control placentas. The developed 3D-methodology indicated that placental vasculature, syncytial knotting, and villous growth are altered in pre-eclampsia. Conclusion: Our preliminary data demonstrate the potential of the developed quantification method for phenotyping pre-eclampsia, to improve future disease stratification.
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