bims-orenst Biomed News
on Organs-on-chips and engineered stem cell models
Issue of 2021‒04‒11
seven papers selected by
Joram Mooiweer
University of Groningen


  1. Biosens Bioelectron. 2021 Mar 26. pii: S0956-5663(21)00234-7. [Epub ahead of print]183 113197
      Most of the compounds are impermeable to the blood-brain barrier (BBB), which poses a significant challenge in the development of therapeutics for the treatment of neurological diseases. Most of the existing in vitro BBB models are not capable of mimicking the in vivo conditions and functions. The numerical approach-based simulation model was proposed to accurately predict the in vivo level shear stress for the microfluidic BBB-on-a-chip. The in vivo level shear stress was predicted for various conditions of volume flow rates, porosities of the polycarbonate membrane of the BBB model, and dimensions of the microfluidic channel. The in vivo shear stress of the microfluidic BBB model increased with a decrease in the dimension of the microfluidic channel and a decrease in the porosity. The in vivo shear stress predicted by the optimized numerical approach-based simulation was validated within 2.17% error with the experimental in vivo level of shear stress at the porosity of 0.01% and all volume flow rates. The shear stress value, according to the volume flow rate of the microfluidic BBB chip with the optimal microfluidic channel size, was effective for the successful formation of tight junctions in primary endothelial cell culture. In this regard, the proposed method provided a standard for the development of various microfluidic organ-on-chip devices that replicate the in vivo conditions and shear stress.
    Keywords:  BBB-on-a-chip; Blood-brain barrier; Microfluidic system; Organ-on-a-chip; Shear stress
    DOI:  https://doi.org/10.1016/j.bios.2021.113197
  2. ACS Biomater Sci Eng. 2020 10 12. 6(10): 5734-5743
      Nonalcoholic fatty liver disease (NAFLD) is a common metabolic and progressive disease, which has emerged as a major cause of chronic liver disease worldwide. It is characterized by the process ranging from simple steatosis to nonalcoholic steatohepatitis. However, a deep understanding of NAFLD progression remains challenging due to the lack of proper in vitro human disease models. In this work, we proposed a new strategy to establish a human NAFLD model based on a human-induced pluripotent stem cell (hiPSC)-derived liver organoids-on-a-chip system. This system allows us to characterize the pathological features of NAFLD in liver organoids by exposure to free fatty acids (FFAs) in perfused three-dimensional (3D) cultures during a prolonged period. Upon FFA induction, liver organoids exhibited lipid droplet formation and triglyceride accumulation. Moreover, they showed upregulated expressions of lipid metabolism-associated genes, indicating the abnormal lipid metabolic process in NAFLD. The FFA-exposed organoids also showed reactive oxygen species (ROS) production and elevated expression of various inflammatory cytokine genes and fibrogenic markers. These alterations represented the typical biochemical characteristics of NAFLD progression, which may provide insight into the potential mechanisms underlying steatosis. The proposed human NAFLD-on-a-chip model combines stem cell organoids with organs-on-chips, which may provide a promising platform for extending their applications for disease studies and effective therapies.
    Keywords:  NAFLD-on-a-chip; human-induced pluripotent stem cells; liver organoid; nonalcoholic fatty liver disease (NAFLD); organoids-on-a-chip
    DOI:  https://doi.org/10.1021/acsbiomaterials.0c00682
  3. APL Bioeng. 2021 Jun;5(2): 026102
      In the lungs, vascular endothelial cells experience cyclic mechanical strain resulting from rhythmic breathing motions and intraluminal blood pressure. Mechanical stress creates evident physiological, morphological, biochemical, and gene expression changes in vascular endothelial cells. However, the exact mechanisms of the mechanical signal transduction into biological responses remain to be clarified. Besides, the level of mechanical stress is difficult to determine due to the complexity of the local distension patterns in the lungs and thus assumed to be the same as the one acting on the alveolar epithelium. Existing in vitro models used to investigate the effect of mechanical stretch on endothelial cells are usually limited to two-dimensional (2D) cell culture platforms, which poorly mimic the typical three-dimensional structure of the vessels. Therefore, the development of an advanced in vitro vasculature model that closely mimics the dynamic of the human lung vasculatures is highly needed. Here, we present the first study that investigates the interplay of the three-dimensional (3D) mechanical cyclic stretch and its magnitude with vascular endothelial growth factor (VEGF) stimulation on a 3D perfusable vasculature in vitro. We studied the effects of the cyclic strain on a perfusable 3D vasculature, made of either human lung microvascular endothelial cells or human umbilical vein endothelial cells embedded in a gel layer. The in vitro 3D vessels underwent both in vivo-like longitudinal and circumferential deformations, simultaneously. Our results showed that the responses of the human lung microvascular endothelial cells and human umbilical vein endothelial cells to cyclic stretch were in good agreement. Although our 3D model was in agreement with the 2D model in predicting a cytoskeletal remodeling in response to different magnitudes of cyclic stretch, however, we observed several phenomena in the 3D model that the 2D model was unable to predict. Angiogenic sprouting induced by VEGF decreased significantly in the presence of cyclic stretch. Similarly, while treatment with VEGF increased vascular permeability, the cyclic stretch restored vascular barrier tightness and significantly decreased vascular permeability. One of the major findings of this study was that a 3D microvasculature can be exposed to a much higher mechanical cyclic stress level than reported in the literature without any dysfunction of its barrier. For higher magnitudes of the cyclic stretch, the applied longitudinal strain level was 14% and the associated circumferential strain reached the equivalent of 63%. In sharp contrast to our findings, such strain typically leads to the disruption of the endothelial barrier in a 2D stretching assay and is considered pathological. This highlights the importance of 3D modeling to investigate mechanobiology effects rather than using a simple endothelial monolayer, which truly recapitulates the in vivo situation.
    DOI:  https://doi.org/10.1063/5.0010159
  4. Adv Drug Deliv Rev. 2021 Apr 05. pii: S0169-409X(21)00084-3. [Epub ahead of print]
      Over the past decade, organs-on-a-chip and microphysiological systems have emerged as a disruptive in vitro technology for biopharmaceutical applications. By enabling new capabilities to engineer physiological living tissues and organ units in the precisely controlled environment of microfabricated devices, these systems offer great promise to advance the frontiers of basic and translational research in biomedical sciences. Here, we review an emerging body of interdisciplinary work directed towards harnessing the power of organ-on-a-chip technology for reproductive biology and medicine. The focus of this topical review is to provide an overview of recent progress in the development of microengineered female reproductive organ models with relevance to drug delivery and discovery. We introduce the engineering design of these advanced in vitro systems and examine their applications in the study of pregnancy, infertility, and reproductive diseases. We also present two case studies that use organ-on-a-chip design principles to model placental drug transport and hormonally regulated crosstalk between multiple female reproductive organs. Finally, we discuss challenges and opportunities for the advancement of reproductive organ-on-a-chip technology.
    Keywords:  IVF; Microfluidics; Microphysiological systems; Organ-on-a-chip; Pregnancy; Preterm birth; Reproductive biology and medicine; Reproductive system
    DOI:  https://doi.org/10.1016/j.addr.2021.03.010
  5. Front Bioeng Biotechnol. 2021 ;9 627877
      Aortic aneurysm is a common cardiovascular disease characterised by continuous dilation of the aorta, and this disease places a heavy burden on healthcare worldwide. Few drugs have been suggested to be effective in controlling the progression of aortic aneurysms. Preclinical drug responses from traditional cell culture and animals are usually controversial. An effective in vitro model is of great demand for successful drug screening. In this study, we induced an in vitro microphysiological system to test metformin, which is a potential drug for the treatment of aortic aneurysms. Human pluripotent stem cell-derived aortic smooth muscle cells (hPSC-HASMCs) were cultured on an in vitro microphysiological system, which could replicate the cyclic stretch of the human native aortic wall. By using this system, we found that HASMCs were more likely to present a physiologically contractile phenotype compared to static cell cultures. Moreover, we used hPSC-HASMCs in our microphysiological system to perform metformin drug screening. The results showed that hPSC-HASMCs presented a more contractile phenotype via NOTCH 1 signalling while being treated with metformin. This result indicated that metformin could be utilised to rescue hPSC-HASMCs from phenotype switching during aortic aneurysm progression. This study helps to elucidate potential drug targets for the treatment of aortic aneurysms.
    Keywords:  aortic aneurysm; drug screening; human pluripotent stem cells; metformin; microphysiological system
    DOI:  https://doi.org/10.3389/fbioe.2021.627877
  6. Stem Cell Reports. 2021 Apr 03. pii: S2213-6711(21)00145-4. [Epub ahead of print]
      Microphysiological systems (MPSs) (i.e., tissue or organ chips) exploit microfluidics and 3D cell culture to mimic tissue and organ-level physiology. The advent of human induced pluripotent stem cell (hiPSC) technology has accelerated the use of MPSs to study human disease in a range of organ systems. However, in the reduction of system complexity, the intricacies of vasculature are an often-overlooked aspect of MPS design. The growing library of pluripotent stem cell-derived endothelial cell and perivascular cell protocols have great potential to improve the physiological relevance of vasculature within MPS, specifically for in vitro disease modeling. Three strategic categories of vascular MPS are outlined: self-assembled, interface focused, and 3D biofabricated. This review discusses key features and development of the native vasculature, linking that to how hiPSC-derived vascular cells have been generated, the state of the art in vascular MPSs, and opportunities arising from interdisciplinary thinking.
    DOI:  https://doi.org/10.1016/j.stemcr.2021.03.015
  7. Biofabrication. 2021 Apr 09.
      In vitro cancer models that can largely mimic the in vivo microenvironment are crucial for conducting more accurate research. Models of three-dimensional (3D) culture that can mimic some aspects of cancer microenvironment or cancer biopsies that can adequately represent tumor heterogeneity are intensely used currently. Those models still lack the dynamic stress stimuli in gastric carcinoma exposed to stomach peristalsis in vivo. This study leveraged a lab-developed four-dimensional (4D) culture model by a magnetic responsive alginate-based hydrogel to rotating magnets that can mimic stress stimuli in gastric cancer. We used the 4D model to culture human gastric cancer cell line AGS and SGC7901, cells at the primary and metastasis stage. We revealed the 4D model altered the cancer cell growth kinetics mechanistically by altering PCNA and p53 expression compared to the 3D culture that lacks stress stimuli. We found the 4D model altered the cancer spheroids stemness as evidenced by enhanced cancer stem cells (CD44) marker expression in AGS spheroids but the expression was dampened in SGC7901 cells. We examined the multi-drug resistance (MDR1) marker expression and found the 4D model dampened the MDR1 expression in SGC7901 cell spheroids, but not in spheroids of AGS cells. Such a model provides the stomach peristalsis mimic and is promising for conducting basic or translational gastric cancer-associated research, drug screening, and culturing patient gastric biopsies to tailor the therapeutic strategies in precision medicine.
    Keywords:  Alginate,; gastric cancer spheroids; magnetic hydrogel; stress stimuli
    DOI:  https://doi.org/10.1088/1758-5090/abf6bf