Alignment behavior of nerve, vascular, muscle, and intestine cells in two- and three-dimensional strategies.

IF 4.6 3区 医学 Q2 MEDICINE, RESEARCH & EXPERIMENTAL WIREs Mechanisms of Disease Pub Date : 2023-09-01 Epub Date: 2023-07-01 DOI:10.1002/wsbm.1620
Amir Jafari, Erfan Behjat, Haniyeh Malektaj, Faezeh Mobini
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Abstract

By harnessing structural hierarchical insights, plausibly simulate better ones imagination to figure out the best choice of methods for reaching out the unprecedented developments of the tissue engineering products as a next level. Constructing a functional tissue that incorporates two-dimensional (2D) or higher dimensions requires overcoming technological or biological limitations in order to orchestrate the structural compilation of one-dimensional and 2D sheets (microstructures) simultaneously (in situ). This approach enables the creation of a layered structure that can be referred to as an ensemble of layers or, after several days of maturation, a direct or indirect joining of layers. Here, we have avoided providing a detailed methodological description of three-dimensional and 2D strategies, except for a few interesting examples that highlight the higher alignment of cells and emphasize rarely remembered facts associated with vascular, peripheral nerve, muscle, and intestine tissues. The effective directionality of cells in conjunction with geometric cues (in the range of micrometers) is well known to affect a variety of cell behaviors. The curvature of a cell's environment is one of the factors that influence the formation of patterns within tissues. The text will cover cell types containing some level of stemness, which will be followed by their consequences for tissue formation. Other important considerations pertain to cytoskeleton traction forces, cell organelle positioning, and cell migration. An overview of cell alignment along with several pivotal molecular and cellular level concepts, such as mechanotransduction, chirality, and curvature of structure effects on cell alignments will be presented. The mechanotransduction term will be used here in the context of the sensing capability that cells show as a result of force-induced changes either at the conformational or the organizational levels, a capability that allows us to modify cell fate by triggering downstream signaling pathways. A discussion of the cells' cytoskeleton and of the stress fibers involvement in altering the cell's circumferential constitution behavior (alignment) based on exposed scaffold radius will be provided. Curvatures with size similarities in the range of cell sizes cause the cell's behavior to act as if it was in an in vivo tissue environment. The revision of the literature, patents, and clinical trials performed for the present study shows that there is a clear need for translational research through the implementation of clinical trial platforms that address the tissue engineering possibilities raised in the current revision. This article is categorized under: Infectious Diseases > Biomedical Engineering Neurological Diseases > Biomedical Engineering Cardiovascular Diseases > Biomedical Engineering.

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神经、血管、肌肉和肠细胞在二维和三维策略中的对齐行为。
通过利用结构层次的见解,似乎可以模拟更好的人的想象力,找出最佳的方法选择,将组织工程产品的空前发展推向下一个层次。构建包含二维(2D)或更高维度的功能组织需要克服技术或生物学限制,以便同时(原位)协调一维和二维片(微观结构)的结构汇编。这种方法能够创建分层结构,该分层结构可以被称为层的集合,或者在几天的成熟之后,层的直接或间接连接。在这里,我们避免提供三维和二维策略的详细方法描述,除了一些有趣的例子,这些例子强调了细胞的高度排列,并强调了与血管、外周神经、肌肉和肠道组织相关的鲜为人知的事实。众所周知,细胞的有效方向性与几何线索(在微米范围内)会影响各种细胞行为。细胞环境的曲率是影响组织内图案形成的因素之一。该文本将涵盖含有一定程度干性的细胞类型,随后将介绍其对组织形成的影响。其他重要的考虑因素涉及细胞骨架牵引力、细胞器定位和细胞迁移。将介绍细胞排列的概述,以及几个关键的分子和细胞水平的概念,如机械转导、手性和结构弯曲对细胞排列的影响。机械转导术语将在细胞因构象或组织水平的力诱导变化而表现出的传感能力的背景下使用,这种能力使我们能够通过触发下游信号通路来改变细胞命运。基于暴露的支架半径,将对细胞的细胞骨架和参与改变细胞周向结构行为(排列)的应力纤维进行讨论。在细胞大小范围内大小相似的弯曲导致细胞的行为就像在体内组织环境中一样。对本研究的文献、专利和临床试验的修订表明,通过实施临床试验平台来解决当前修订中提出的组织工程可能性,显然需要进行转化研究。本文分类为:传染病>生物医学工程神经疾病>生物医学工程心血管疾病>生物医学工程学。
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WIREs Mechanisms of Disease
WIREs Mechanisms of Disease MEDICINE, RESEARCH & EXPERIMENTAL-
CiteScore
11.40
自引率
0.00%
发文量
45
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