A critical look: Challenges in differentiating human pluripotent stem cells into desired cell types and organoids

Fowler, Jonas L.; Ang, Lay Teng; Loh, Kyle M.

doi:10.1002/wdev.368

Cited by 36 publications

(37 citation statements)

References 150 publications

(268 reference statements)

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“…Spontaneous differentiation due to long-term culture can generate unwanted lineages ( Tang et al., 2019 ) and the high frequency of contaminating progenitors compared with the desired cell types during in vitro differentiation of PSCs can affect organoid reproducibility ( Veres et al., 2019 ; Yao et al., 2017 ). Therefore “separating the wheat from the chaff” is important to generate organoids, as a minor population of undifferentiated human PSCs has a higher chance to give rise to teratoma (tumor) that often out-competes organ reconstitution in vivo ( Fowler et al., 2020 ). Heterogeneity of both differentiated and undifferentiated PSCs is a common problem, and therefore using specific cell surface markers can efficiently generate the desired lineage.…”

Section: Challenges and Future Perspectivesmentioning

confidence: 99%

Translating Embryogenesis to Generate Organoids: Novel Approaches to Personalized Medicine

Sahu

Sharan

2020

iScience

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Summary The astounding capacity of pluripotent stem cells (PSCs) to differentiate and self-organize has revolutionized the development of 3D cell culture models. The major advantage is its ability to mimic in vivo microenvironments and cellular interactions when compared with the classical 2D cell culture models. Recent innovations in generating embryo-like structures (including blastoids and gastruloids) from PSCs have advanced the experimental accessibility to understand embryogenesis with immense potential to model human development. Taking cues on how embryonic development leads to organogenesis, PSCs can also be directly differentiated to form mini-organs or organoids of a particular lineage. Organoids have opened new avenues to augment our understanding of stem cell and regenerative biology, tissue homeostasis, and disease mechanisms. In this review, we provide insights from developmental biology with a comprehensive resource of signaling pathways that in a coordinated manner form embryo-like structures and organoids. Moreover, the advent of assembloids and multilineage organoids from PSCs opens a new dimension to study paracrine function and multi-tissue interactions in vitro . Although this led to an avalanche of enthusiasm to utilize organoids for organ transplantation studies, we examine the current limitations and provide perspectives to improve reproducibility, scalability, functional complexity, and cell-type characterization. Taken together, these 3D in vitro organ-specific and patient-specific models hold great promise for drug discovery, clinical management, and personalized medicine.

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Section: Challenges and Future Perspectivesmentioning

confidence: 99%

Translating Embryogenesis to Generate Organoids: Novel Approaches to Personalized Medicine

Sahu

Sharan

2020

iScience

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“…However, the lack of standardization and quality control of stem cell culture are an obstacle for their use in clinical studies. The use of pluripotent stem cells for organoid generation can be hampered by the presence of contaminating progenitors that can yield undesired cell types and a small population of undifferentiated PSCs can give rise to tumors that outcompete organ reconstitution in vivo (Fowler et al, 2020). Furthermore, due to different culture methods, organoids may present undesired phenotypic variabilities.…”

Section: Shortcomings and Future Directives Of Organotypic Models In mentioning

confidence: 99%

Organotypic Modeling of the Tumor Landscape

Haykal

Nahmias

Varon

et al. 2020

Front. Cell Dev. Biol.

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Cancer is a complex disease and it is now clear that not only epithelial tumor cells play a role in carcinogenesis. The tumor microenvironment is composed of non-stromal cells, including endothelial cells, adipocytes, immune and nerve cells, and a stromal compartment composed of extracellular matrix, cancer-associated fibroblasts and mesenchymal cells. Tumorigenesis is a dynamic process with constant interactions occurring between the tumor cells and their surroundings. Even though all connections have not yet been discovered, it is now known that crosstalk between actors of the microenvironment drives cancer progression. Taking into account this complexity, it is important to develop relevant models to study carcinogenesis. Conventional 2D culture models fail to represent the entire tumor microenvironment properly and the use of animal models should be decreased with respect to the 3Rs rule. To this aim, in vitro organotypic models have been significantly developed these past few years. These models have different levels of complexity and allow the study of tumor cells alone or in interaction with the microenvironment actors during the multiple stages of carcinogenesis. This review depicts recent insights into organotypic modeling of the tumor and its microenvironment all throughout cancer progression. It offers an overview of the crosstalk between epithelial cancer cells and their microenvironment during the different phases of carcinogenesis, from the early cell autonomous events to the late metastatic stages. The advantages of 3D over classical 2D or in vivo models are presented as well as the most promising organotypic models. A particular focus is made on organotypic models used for studying cancer progression, from the less complex spheroids to the more sophisticated body-on-a-chip. Last but not least, we address the potential benefits of these models in personalized medicine which is undoubtedly a domain paving the path to new hopes in terms of cancer care and cure.

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“…Organoids derived from human pluripotent stem cells are widely expected to fill the remaining gaps between animal models and humans, as stem cells derived from humans are the main sources of cultured organoid [20,21]. The development of research platforms using organoid models takes less time than the establishment of animal models.…”

Section: Introductionmentioning

confidence: 99%

Modeling of Hypoxic Brain Injury through 3D Human Neural Organoids

Kim¹,

Kim²,

Kang³

et al. 2021

Cells

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Brain organoids have emerged as a novel model system for neural development, neurodegenerative diseases, and human-based drug screening. However, the heterogeneous nature and immature neuronal development of brain organoids generated from pluripotent stem cells pose challenges. Moreover, there are no previous reports of a three-dimensional (3D) hypoxic brain injury model generated from neural stem cells. Here, we generated self-organized 3D human neural organoids from adult dermal fibroblast-derived neural stem cells. Radial glial cells in these human neural organoids exhibited characteristics of the human cerebral cortex trend, including an inner (ventricular zone) and an outer layer (early and late cortical plate zones). These data suggest that neural organoids reflect the distinctive radial organization of the human cerebral cortex and allow for the study of neuronal proliferation and maturation. To utilize this 3D model, we subjected our neural organoids to hypoxic injury. We investigated neuronal damage and regeneration after hypoxic injury and reoxygenation. Interestingly, after hypoxic injury, reoxygenation restored neuronal cell proliferation but not neuronal maturation. This study suggests that human neural organoids generated from neural stem cells provide new opportunities for the development of drug screening platforms and personalized modeling of neurodegenerative diseases, including hypoxic brain injury.

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A critical look: Challenges in differentiating human pluripotent stem cells into desired cell types and organoids

Cited by 36 publications

References 150 publications

Translating Embryogenesis to Generate Organoids: Novel Approaches to Personalized Medicine

Translating Embryogenesis to Generate Organoids: Novel Approaches to Personalized Medicine

Organotypic Modeling of the Tumor Landscape

Modeling of Hypoxic Brain Injury through 3D Human Neural Organoids

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