A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Biomimetic Liver Lobules from Multi‐Compartmental Microfluidics
https://orcid.org/0000-0003-3495-231X
https://orcid.org/0000-0001-9242-4000
AbstractEngineered liver lobule is highly practical in hepatic disease treatment, while constructing a 3D biomimetic lobule with a heterogeneous architecture on a large scale is challenging. Here, inspired by the natural architectural construction of hepatic lobules, biomimetic hepatic lobules are proposed with coaxially through‐pores for nutrient exchange via microfluidic technology. This multi‐channel microfluidic chip is made by parallelly installing capillaries. Sodium alginate (Alg) is pumped through its central channel, while Ca2+‐loaded gelatin methacrylate (GelMA) solutions encapsulating hepatocytes, mesenchymal stem cells, and endothelia cells are pumped through surrounding channels, respectively. The rapid gelation of Alg and Ca2+ brings about an in situ formation of Alg fiber, with heterogeneous multi‐cell‐laden GelMA microcarriers forming around it. The peeled‐off microcarriers each featured with a coaxially through pore, simulating the cord‐like structure of hepatic lobule and facilitating nutrients exchange. Meanwhile, the spatially anisotropic arrangement of cells highly simulates the hepatic architecture. It is demonstrated that by transplanting these biomimetic microparticles into liver in situ, the failed liver in rat shows increased regeneration and decreased necrosis. These results indicated that the microfluidic multi‐compartmental microcarriers provide a new strategy to engineer 3D artificial livers for clinical translation.
Biomimetic Liver Lobules from Multi‐Compartmental Microfluidics
https://orcid.org/0000-0003-3495-231X
https://orcid.org/0000-0001-9242-4000
AbstractEngineered liver lobule is highly practical in hepatic disease treatment, while constructing a 3D biomimetic lobule with a heterogeneous architecture on a large scale is challenging. Here, inspired by the natural architectural construction of hepatic lobules, biomimetic hepatic lobules are proposed with coaxially through‐pores for nutrient exchange via microfluidic technology. This multi‐channel microfluidic chip is made by parallelly installing capillaries. Sodium alginate (Alg) is pumped through its central channel, while Ca2+‐loaded gelatin methacrylate (GelMA) solutions encapsulating hepatocytes, mesenchymal stem cells, and endothelia cells are pumped through surrounding channels, respectively. The rapid gelation of Alg and Ca2+ brings about an in situ formation of Alg fiber, with heterogeneous multi‐cell‐laden GelMA microcarriers forming around it. The peeled‐off microcarriers each featured with a coaxially through pore, simulating the cord‐like structure of hepatic lobule and facilitating nutrients exchange. Meanwhile, the spatially anisotropic arrangement of cells highly simulates the hepatic architecture. It is demonstrated that by transplanting these biomimetic microparticles into liver in situ, the failed liver in rat shows increased regeneration and decreased necrosis. These results indicated that the microfluidic multi‐compartmental microcarriers provide a new strategy to engineer 3D artificial livers for clinical translation.
Biomimetic Liver Lobules from Multi‐Compartmental Microfluidics
https://orcid.org/0000-0003-3495-231X
https://orcid.org/0000-0001-9242-4000
AbstractEngineered liver lobule is highly practical in hepatic disease treatment, while constructing a 3D biomimetic lobule with a heterogeneous architecture on a large scale is challenging. Here, inspired by the natural architectural construction of hepatic lobules, biomimetic hepatic lobules are proposed with coaxially through‐pores for nutrient exchange via microfluidic technology. This multi‐channel microfluidic chip is made by parallelly installing capillaries. Sodium alginate (Alg) is pumped through its central channel, while Ca2+‐loaded gelatin methacrylate (GelMA) solutions encapsulating hepatocytes, mesenchymal stem cells, and endothelia cells are pumped through surrounding channels, respectively. The rapid gelation of Alg and Ca2+ brings about an in situ formation of Alg fiber, with heterogeneous multi‐cell‐laden GelMA microcarriers forming around it. The peeled‐off microcarriers each featured with a coaxially through pore, simulating the cord‐like structure of hepatic lobule and facilitating nutrients exchange. Meanwhile, the spatially anisotropic arrangement of cells highly simulates the hepatic architecture. It is demonstrated that by transplanting these biomimetic microparticles into liver in situ, the failed liver in rat shows increased regeneration and decreased necrosis. These results indicated that the microfluidic multi‐compartmental microcarriers provide a new strategy to engineer 3D artificial livers for clinical translation.
Biomimetic Liver Lobules from Multi‐Compartmental Microfluidics
Advanced Science
Huang, Danqing (author) / Wu, Zhuhao (author) / Wang, Ji (author) / Wang, Jinglin (author) / Zhao, Yuanjin (author)
Advanced Science ; 11
2024-11-01
Article (Journal)
Electronic Resource
English
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