Basic models to advanced systems: harnessing the power of organoids-based microphysiological models of the human brain.

IF 8.2 2区 医学 Q1 ENGINEERING, BIOMEDICAL Biofabrication Pub Date : 2024-05-28 DOI:10.1088/1758-5090/ad4c08
Katherine Boylin, Grace V Aquino, Michael Purdon, Kimia Abedi, Magdalena Kasendra, Riccardo Barrile
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Abstract

Understanding the complexities of the human brain's function in health and disease is a formidable challenge in neuroscience. While traditional models like animals offer valuable insights, they often fall short in accurately mirroring human biology and drug responses. Moreover, recent legislation has underscored the need for more predictive models that more accurately represent human physiology. To address this requirement, human-derived cell cultures have emerged as a crucial alternative for biomedical research. However, traditional static cell culture models lack the dynamic tissue microenvironment that governs human tissue function. Advancedin vitrosystems, such as organoids and microphysiological systems (MPSs), bridge this gap by offering more accurate representations of human biology. Organoids, which are three-dimensional miniaturized organ-like structures derived from stem cells, exhibit physiological responses akin to native tissues, but lack essential tissue-specific components such as functional vascular structures and immune cells. Recent endeavors have focused on incorporating endothelial cells and immune cells into organoids to enhance vascularization, maturation, and disease modeling. MPS, including organ-on-chip technologies, integrate diverse cell types and vascularization under dynamic culture conditions, revolutionizing brain research by bridging the gap betweenin vitroandin vivomodels. In this review, we delve into the evolution of MPS, with a particular focus on highlighting the significance of vascularization in enhancing the viability, functionality, and disease modeling potential of organoids. By examining the interplay of vasculature and neuronal cells within organoids, we can uncover novel therapeutic targets and gain valuable insights into disease mechanisms, offering the promise of significant advancements in neuroscience and improved patient outcomes.

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从基本模型到高级系统:利用基于有机体的人脑微观生理学模型的力量。
了解人类大脑在健康和疾病中的复杂功能是神经科学领域的一项艰巨挑战。虽然动物等传统模型能提供有价值的见解,但它们往往无法准确反映人类生物学和药物反应。此外,最近的立法也强调了对更能准确反映人体生理的预测性模型的需求。为了满足这一要求,人源细胞培养已成为生物医学研究的重要替代方法。然而,传统的静态细胞培养模型缺乏支配人体组织功能的动态组织微环境。先进的体外系统,如有机体和微生理系统(MPS),能更准确地反映人体生物学,从而弥补了这一不足。有机体是源自干细胞的三维微型化器官样结构,其生理反应与原生组织相似,但缺乏重要的组织特异性成分,如功能性血管结构和免疫细胞。最近的研究重点是将内皮细胞和免疫细胞纳入类器官,以增强血管化、成熟和疾病建模。MPS(包括片上器官技术)在动态培养条件下整合了多种细胞类型和血管化,通过弥合体外和体内模型之间的差距,彻底改变了脑研究。在这篇综述中,我们将深入探讨 MPS 的演变,并特别强调血管化对提高器官组织的活力、功能和疾病建模潜力的重要意义。通过研究器官组织内血管和神经细胞的相互作用,我们可以发现新的治疗靶点,并获得对疾病机制的宝贵见解,从而有望在神经科学领域取得重大进展,改善患者的预后。
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来源期刊
Biofabrication
Biofabrication ENGINEERING, BIOMEDICAL-MATERIALS SCIENCE, BIOMATERIALS
CiteScore
17.40
自引率
3.30%
发文量
118
审稿时长
2 months
期刊介绍: Biofabrication is dedicated to advancing cutting-edge research on the utilization of cells, proteins, biological materials, and biomaterials as fundamental components for the construction of biological systems and/or therapeutic products. Additionally, it proudly serves as the official journal of the International Society for Biofabrication (ISBF).
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