Shravanthi Rajasekar scite author profile

Despite the complexity and structural sophistication that 3D organoid models provide, their lack of vascularization and perfusion limit the capability of these models to recapitulate organ physiology effectively. A microfluidic platform named IFlowPlate is engineered, which can be used to culture up to 128 independently perfused and vascularized colon organoids in vitro. Unlike traditional microfluidic devices, the vascularized organoid‐on‐chip device with an “open‐well” design does not require any external pumping systems and allows tissue extraction for downstream analyses, such as histochemistry or even in vivo transplantation. By optimizing both the extracellular matrix (ECM) and the culture media formulation, patient‐derived colon organoids are co‐cultured successfully within a self‐assembled vascular network, and it is found that the colon organoids grow significantly better in the platform under constant perfusion versus conventional static condition. Furthermore, a colon inflammation model with an innate immune function where circulating monocytes can be recruited from the vasculature, differentiate into macrophage, and infiltrate the colon organoids in response to tumor necrosis factor (TNF)‐ inflammatory cytokine stimulation is developed using the platform. With the ability to grow vascularized colon organoids under intravascular perfusion, the IFlowPlate platform could unlock new possibilities for screening potential therapeutic targets or modeling relevant diseases.

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Deep-LUMEN assay – human lung epithelial spheroid classification from brightfield images using deep learning

Abdul

Rajasekar

Lin

et al. 2020

Lab Chip

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Microfluidics: IFlowPlate—A Customized 384‐Well Plate for the Culture of Perfusable Vascularized Colon Organoids (Adv. Mater. 46/2020)

et al. 2020

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Human stem‐cell‐derived organoids have provided new opportunities to model biological processes and recapitulate organ development. However, organoid systems lack perfusable vascular networks to deliver nutrients and drugs. In article number 2002974, Boyang Zhang and co‐workers introduce IFlowPlate—a microfluidic system with an “open‐well” design in a 384‐well plate format that can be used to vascularize and intravascularly perfuse organoids. This image shows three independently perfused microvascular networks in an IFlowPlate.

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Subtractive manufacturing with swelling induced stochastic folding of sacrificial materials for fabricating complex perfusable tissues in multi-well plates

et al. 2022

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From Model System to Therapy: Scalable Production of Perfusable Vascularized Liver Spheroids in “Open-Top“ 384-Well Plate

Lin

Rajasekar

Marway

et al. 2020

ACS Biomater. Sci. Eng.

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Vasculature is a key component of many biological tissues and helps to regulate a wide range of biological processes. Modeling vascular networks or the vascular interface in organ-on-a-chip systems is an essential aspect of this technology. In many organ-on-a-chip devices, however, the engineered vasculatures are usually designed to be encapsulated inside closed microfluidic channels, making it difficult to physically access or extract the tissues for downstream applications and analysis. One unexploited benefit of tissue extraction is the potential of vascularizing, perfusing, and maturing the tissue in well-controlled, organ-on-a-chip microenvironments and then subsequently extracting that product for in vivo therapeutic implantation. Moreover, for both modeling and therapeutic applications, the scalability of the tissue production process is important. Here we demonstrate the scalable production of perfusable and extractable vascularized tissues in an “open-top“ 384-well plate (referred to as IFlowPlate), showing that this system could be used to examine nanoparticle delivery to targeted tissues through the microvascular network and to model vascular angiogenesis. Furthermore, tissue spheroids, such as hepatic spheroids, can be vascularized in a scalable manner and then subsequently extracted for in vivo implantation. This simple multiple-well plate platform could not only improve the experimental throughputs of organ-on-a-chip systems but could potentially help expand the application of model systems to regenerative therapy.

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