Generation of Human Blood Vessel and Vascularized Cerebral Organoids
Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brai...
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| Published in | BIO-PROTOCOL Vol. 13; no. 21; p. e4870 |
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| Main Authors | , , , , , |
| Format | Journal Article |
| Language | English |
| Published |
United States
Bio-Protocol, LLC
05.11.2023
Bio-Protocol Bio-protocol LLC |
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| Abstract | Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brain and blood vessels originate from two different germ layers, making it difficult to induce vascularized brain organoids in vitro. We developed this protocol to generate brain-specific blood vessel and cerebral organoids and then fused them at a specific developmental time point. The fused cerebral organoids exhibited robust vascular network-like structures, which allows simulating the in vivo developmental processes of the brain for further applications in various neurological diseases. Key Features • Culturing vascularized brain organoids using human embryonic stem cells (hESCs). • The new approach generates not only neural cells and vessel-like networks but also brain-resident microglia immune cells in a single organoid. |
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| AbstractList | Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brain and blood vessels originate from two different germ layers, making it difficult to induce vascularized brain organoids in vitro. We developed this protocol to generate brain-specific blood vessel and cerebral organoids and then fused them at a specific developmental time point. The fused cerebral organoids exhibited robust vascular network-like structures, which allows simulating the in vivo developmental processes of the brain for further applications in various neurological diseases.Key Features• Culturing vascularized brain organoids using human embryonic stem cells (hESCs).• The new approach generates not only neural cells and vessel-like networks but also brain-resident microglia immune cells in a single organoid.Graphical overviewWorkflow and timeline for vessel organoid and vascularized brain organoid generation. (By Figdraw, ID: RTIURffccf) Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brain and blood vessels originate from two different germ layers, making it difficult to induce vascularized brain organoids in vitro. We developed this protocol to generate brain-specific blood vessel and cerebral organoids and then fused them at a specific developmental time point. The fused cerebral organoids exhibited robust vascular network-like structures, which allows simulating the in vivo developmental processes of the brain for further applications in various neurological diseases. Key Features • Culturing vascularized brain organoids using human embryonic stem cells (hESCs). • The new approach generates not only neural cells and vessel-like networks but also brain-resident microglia immune cells in a single organoid. Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brain and blood vessels originate from two different germ layers, making it difficult to induce vascularized brain organoids in vitro. We developed this protocol to generate brain-specific blood vessel and cerebral organoids and then fused them at a specific developmental time point. The fused cerebral organoids exhibited robust vascular network-like structures, which allows simulating the in vivo developmental processes of the brain for further applications in various neurological diseases. Key Features • Culturing vascularized brain organoids using human embryonic stem cells (hESCs). • The new approach generates not only neural cells and vessel-like networks but also brain-resident microglia immune cells in a single organoid. Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brain and blood vessels originate from two different germ layers, making it difficult to induce vascularized brain organoids in vitro. We developed this protocol to generate brain-specific blood vessel and cerebral organoids and then fused them at a specific developmental time point. The fused cerebral organoids exhibited robust vascular network-like structures, which allows simulating the in vivo developmental processes of the brain for further applications in various neurological diseases. Key Features • Culturing vascularized brain organoids using human embryonic stem cells (hESCs). • The new approach generates not only neural cells and vessel-like networks but also brain-resident microglia immune cells in a single organoid.Brain organoids have been widely used to study diseases and the development of the nervous system. Many reports have investigated the application of brain organoids, but most of these models lack vascular structures, which play essential roles in brain development and neurological diseases. The brain and blood vessels originate from two different germ layers, making it difficult to induce vascularized brain organoids in vitro. We developed this protocol to generate brain-specific blood vessel and cerebral organoids and then fused them at a specific developmental time point. The fused cerebral organoids exhibited robust vascular network-like structures, which allows simulating the in vivo developmental processes of the brain for further applications in various neurological diseases. Key Features • Culturing vascularized brain organoids using human embryonic stem cells (hESCs). • The new approach generates not only neural cells and vessel-like networks but also brain-resident microglia immune cells in a single organoid. |
| Author | Zhi You Hong Zhao Run Han Xiang Ju Zhen Luo Xin Sun |
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| Keywords | Human embryonic stem cells Blood vessel organoids Neural organoids Vascularized brain organoids Cerebral organoids |
| Language | English |
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| Title | Generation of Human Blood Vessel and Vascularized Cerebral Organoids |
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