Organoids 

About: Organoids is an academic journal. The journal publishes majorly in the area(s): Organoid & Biology. It has an ISSN identifier of 2674-1172. Over the lifetime, 21 publications have been published receiving 69 citations. The journal is also known as: Organoids.

Organoid Models of SARS-CoV-2 Infection: What Have We Learned about COVID-19?

Abstract: Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causes coronavirus disease 2019 (COVID-19), which was classified as a pandemic in March 2020. As of 22 January 2022, globally more than 347 million cases of COVID-19 have been diagnosed, with 5.6 million deaths, making it the deadliest pandemic since the influenza pandemic in 1918. The clinical presentation of COVID-19-related illness spans from asymptomatic to mild respiratory symptoms akin to influenza infection to acute symptoms, including pneumonia necessitating hospitalisation and admission to intensive care units. COVID-19 starts in the upper respiratory tract and lungs but in severe cases can also involve the heart, blood vessels, brain, liver, kidneys and intestine. The increasing global health and economic burden of COVID-19 necessitates an urgent and global response. Understanding the functional characteristics and cellular tropism of SARS-CoV-2, and the pathogenesis that leads to multi-organ failure and death, has prompted an unprecedented adoption of organoid models. Successful drug discovery and vaccine development rely on pre-clinical models that faithfully recapitulate the viral life cycle and the host cell response to infection. Human stem cell-derived organoids fulfill these criteria. Here we highlight the role of organoids in the study of SARS-CoV-2 infection and modelling of COVID-19 pathogenesis.

3D Tumor Spheroid and Organoid to Model Tumor Microenvironment for Cancer Immunotherapy

Abstract: The intricate microenvironment in which malignant cells reside is essential for the progression of tumor growth. Both the physical and biochemical features of the tumor microenvironment (TME) play a critical role in promoting the differentiation, proliferation, invasion, and metastasis of cancer cells. It is therefore essential to understand how malignant cells interact and communicate with an assortment of supportive tumor-associated cells including macrophages, fibroblasts, endothelial cells, and other immune cells. To study the complex mechanisms behind cancer progression, 3D spheroid and organoid models are widely in favor because they replicate the stromal environment and multicellular structure present within an in vivo tumor. It provides more precise data about the cell–cell interactions, tumor characteristics, drug discovery, and metabolic profile of cancer cells compared to oversimplified 2D systems and unrepresentative animal models. This review provides a description of the key elements of the tumor microenvironment as well as early research using cell-line derived, 3D spheroid tumor models that paved the way for the adoption of patient-derived spheroid and organoid models. In particular, 3D spheroid and organoid models provide a method for drug screening with a particular emphasis on influence of the TME in cancer immunotherapy.

A Blood Vessel Organoid Model Recapitulating Aspects of Vasculogenesis, Angiogenesis and Vessel Wall Maturation

Abstract: Blood vessel organoids are an important in vitro model to understand the underlying mechanisms of human blood vessel development and for toxicity testing or high throughput drug screening. Here we present a novel, cost-effective, and easy to manufacture vascular organoid model. To engineer the organoids, a defined number of human induced pluripotent stem cells are seeded in non-adhesive agarose coated wells of a 96-well plate and directed towards a lateral plate mesoderm fate by activation of Wnt and BMP4 signaling. We observe the formation of a circular layer of angioblasts around days 5–6. Induced by VEGF application, CD31+ vascular endothelial cells appear within this vasculogenic zone at approximately day 7 of organoid culture. These cells arrange to form a primitive vascular plexus from which angiogenic sprouting is observed after 10 days of culture. The differentiation outcome is highly reproducible, and the size of organoids is scalable depending on the number of starting cells. We observe that the initial vascular ring forms at the interface between two cell populations. The inner cellular compartment can be distinguished from the outer by the expression of GATA6, a marker of lateral plate mesoderm. Finally, 14-days-old organoids were transplanted on the chorioallantois membrane of chicken embryos resulting in a functional connection of the human vascular network to the chicken circulation. Perfusion of the vessels leads to vessel wall maturation and remodeling as indicated by the formation of a continuous layer of smooth muscle actin expressing cells enwrapping the endothelium. In summary, our organoid model recapitulates human vasculogenesis, angiogenesis as well as vessel wall maturation and therefore represents an easy and cost-effective tool to study all steps of blood vessel development and maturation directly in the human setting without animal experimentation.

Why Can Organoids Improve Current Organ-on-Chip Platforms?

Abstract: Preclinical studies are the first stage of introducing a new potential drug to the pharmaceutical market. Many of the compounds with promising results approved in the preclinical stage show poor prognosis during the first stage of clinical studies, which is connected with inadequate in vitro and in vivo models used in this stage. Both basic in vitro models, and in vivo animal models do not represent the human conditions. Therefore, scientists work on creating an appropriate model that will highly reproduce the characteristics of the human body. The solution could be an organoids model: a laboratory-produced human miniature organ, grown in a specially designed Organ-on-Chip microfluidic tools. This review focuses on characterizing the 3D cell culture types, focusing mainly on organoids, the Organ-on-Chip approach, and presenting the latest reports about the application of their combination in biological research, including toxicological studies.

Metabolic Studies in Organoids: Current Applications, Opportunities and Challenges

Abstract: Organoid technologies represent a major breakthrough in biomedical research since they offer increasingly sophisticated models for studying biological mechanisms supporting human development and disease. Organoids are three-dimensional (3D) physiological in vitro systems that recapitulate the genetic, histological and functional features of the in vivo tissues of origin more accurately than classical cell culture methods. In the last decade, organoids have been derived from various healthy and diseased tissues and used for a wide range of applications in basic and translational research, including (cancer) tissue biology, development, regeneration, disease modeling, precision medicine, gene editing, biobanking and drug screening. Here, we report the current applications of organoid models to study (stem) cell metabolism in several pathophysiological contexts such as cancer and metabolic diseases. More precisely, we discuss the relevance and limitations of these 3D cultures to model and study metabolic (dys)functions associated with hepatic, renal or pancreatic disorders, as well as tumor development and progression. We also describe the use of organoids to understand the dynamic interaction between diet, microbiota and the intestinal epithelium. Finally, this review explores recent methodological improvements in organoid culture that may help to better integrate the influence of microenvironmental conditions in the study of tumor cell metabolic phenotypes.