Synthetic biology (SynBio) is a rapidly growing scientific discipline. In the Netherlands, various universities and companies are tackling a variety of opportunities and challenges within this... Show moreSynthetic biology (SynBio) is a rapidly growing scientific discipline. In the Netherlands, various universities and companies are tackling a variety of opportunities and challenges within this field. In this perspective article, we review the current synthetic biology landscape in the Netherlands across academia, industry, politics, and society. Especially within Dutch academia there is an active, though only partially connected, research community involved in various domains of SynBio. Mostly supported by governmental funding, academic research is focusing on top-down synthetic biology, involving the engineering of for example bacteria and yeast for bioproduction, as well as bottom-up and cell-free synthetic biology aiming to understand life and build synthetic cells. There is also a large number of talented and motivated students interested in the field, exemplified by the participation and success of Dutch teams in the international iGEM synthetic biology competition. Commercial synthetic biology activities are taking place in various large industrial companies, as well as in start-ups and spin-offs, mostly divided over several ‘SynBio hubs’ in the Netherlands. However, the investment, regulatory and public-perception landscape is not yet optimal to stimulate entrepreneurial activities in SynBio. The Dutch and global society can further benefit from the large promise of SynBio through better integration of people active in the Dutch SynBio field, frequent political and public dialogue, and more attention towards regulatory issues. The recently founded Dutch synthetic biology association SynBioNL aims to contribute to realizing a positive impact on society by stimulating advances of the field in the Netherlands and beyond. Show less
Human reproductive success relies on the intricate interplay between the developing embryo and the maternal endometrium. These highly-coordinated interactions facilitate implantation, setting in... Show moreHuman reproductive success relies on the intricate interplay between the developing embryo and the maternal endometrium. These highly-coordinated interactions facilitate implantation, setting in motion a series of developmental programs to establish a sustained fetal-maternal interface. Understanding endometrial function and the early human embryo-maternal dialogue is thus an important prerequisite for refining clinical approaches to alleviate implantation failure, early pregnancy loss and other obstetric complications. Yet, many mediators of implantation remain elusive. Driven by endocrine factors, interactions at the embryo-maternal interface are tightly regulated and highly complex. Coupled to the inaccessibility of the in vivo environment and scarcity of research material, studying human implantation remains exceptionally challenging. Nevertheless, the field continues to gain momentum. Cutting-edge omics technologies and high-resolution imaging have revealed important structural and functional insights into endometrial biology, while emerging bioengineering tools are enhancing our ability to model the synergies and individual features of the embryo-maternal environment. Novel in vitro platforms using human cells and embryos are considerably more accessible and easier to manipulate compared to in vivo approaches, enhancing our ability to capture specific stages of implantation. This review aims to showcase current and emerging technologies used to study human endometrial biology and the early embryo-maternal interface, including single cell omics approaches, bioengineered endometrial models and embryo-endometrium co-culture platforms. We highlight the value of these approaches and provide our perspective on the current challenges faced by the field. Recognizing the physiological scope of these emerging technologies will be key for utilizing their full potential and driving future innovation. Show less
Cell-based in vitro developed human skin equivalents facilitate screenings of compounds for therapeutic potential or toxicity and enable scientific research expanding knowledge on skin physiology... Show moreCell-based in vitro developed human skin equivalents facilitate screenings of compounds for therapeutic potential or toxicity and enable scientific research expanding knowledge on skin physiology and pathophysiology. Human skin equivalents resemble key features of native human skin, including the dermal and epidermal architecture. However, a limitation of human skin equivalents is the altered lipid barrier formation, which leads to a decreased barrier functionality. This could be induced by suboptimal cell culture conditions or the different cell microenvironment. The primary aim of this dissertational research was to enhance the morphogenesis and barrier formation of human skin equivalents to better mimic that of native human skin. The results indicate that modification of the dermal extracellular matrix by the biopolymer chitosan enhanced epidermal morphogenesis and barrier formation. Furthermore, by better resembling native skin conditions in vitro, primarily through a reduction in oxygen level, the epidermal morphogenesis and lipid barrier formation was improved. Finally, using a combinatory approach of optimized cell culture conditions and enhanced cell culture medium, the epidermal morphogenesis and barrier formation of human skin equivalents resembled that of native human skin more closely. Show less
Duinen, V. van; Stam, W.; Borgdorff, V.; Reijerkerk, A.; Orlova, V.; Vulto, P.; ... ; Zonneveld, A.J. van 2019
Pre-clinical drug research of vascular diseases requires in vitro models of vasculature that are amendable to high-throughput screening. However, current in vitro screening models that have... Show morePre-clinical drug research of vascular diseases requires in vitro models of vasculature that are amendable to high-throughput screening. However, current in vitro screening models that have sufficient throughput only have limited physiological relevance, which hinders the translation of findings from in vitro to in vivo. On the other hand, microfluidic cell culture platforms have shown unparalleled physiological relevancy in vitro, but often lack the required throughput, scalability and standardization. We demonstrate a robust platform to study angiogenesis of endothelial cells derived from human induced pluripotent stem cells (iPSC-ECs) in a physiological relevant cellular microenvironment, including perfusion and gradients. The iPSC-ECs are cultured as 40 perfused 3D microvessels against a patterned collagen-1 scaffold. Upon the application of a gradient of angiogenic factors, important hallmarks of angiogenesis can be studied, including the differentiation into tip- and stalk cell and the formation of perfusable lumen. Perfusion with fluorescent tracer dyes enables the study of permeability during and after anastomosis of the angiogenic sprouts. In conclusion, this method shows the feasibility of iPSC-derived ECs in a standardized and scalable 3D angiogenic assay that combines physiological relevant culture conditions in a platform that has the required robustness and scalability to be integrated within the drug screening infrastructure. Show less
