A biopsy-sized 3D skin model with a perifollicular vascular plexus enables studying immune cell trafficking in the skin.

IF 8.2 2区 医学 Q1 ENGINEERING, BIOMEDICAL
Krutav Rakesh Shah, Laura Garriga-Cerda, Alberto Pappalardo, Leila Sorrells, Hun Jin Jeong, Chang H Lee, Hasan Erbil Abaci
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引用次数: 0

Abstract

Human skin vasculature features a unique anatomy in close proximity to the skin appendages and acts as a gatekeeper for constitutive lymphocyte trafficking to the skin. Approximating such structural complexity and functionality in 3D skin models is an outstanding tissue engineering challenge. In this study, we leverage the capabilities of the digital-light-processing bioprinting to generate an anatomically-relevant and miniaturized 3D skin-on-a-chip (3D-SoC) model in the size of a 6 mm punch biopsy. The 3D-SoC contains a perfusable vascular network resembling the superficial vascular plexus of the skin and closely surrounding bioengineered hair follicles. The perfusion capabilities of the 3D-SoC enables the circulation of immune cells, and high-resolution imaging of the immune cell-endothelial cell interactions, namely tethering, rolling, and extravasation in real-time. Moreover, the vascular pattern in 3D-SoC captures the physiological range of shear rates found in cutaneous blood vessels and allows for studying the effect of shear rate on T cell trafficking. In 3D-SoC, as expected,in vitro-polarized T helper 1 (Th1) cells show a stronger attachment on the vasculature compared to naïve T cells. Both naïve and T cells exhibit higher retention in the low-shear zones in the early stages (<5 min) of T cell attachment. Interestingly, at later stages T cell retention rate becomes independent of the shear rate. The attached Th1 cells further transmigrate from the vessel walls to the extracellular space and migrate toward the bioengineered hair follicles and interfollicular epidermis. When the epidermis is not present, Th1 cell migration toward the epidermis is significantly hindered, underscoring the role of epidermal signals on T cell infiltration. Our data validates the capabilities of 3D-SoC model to study the interactions between immune cells and skin vasculature in the context of epidermal signals. The biopsy-sized 3D-SoC model in this study represents a new level of anatomical and cellular complexity, and brings us a step closer to generating a truly functional human skin with its tissue-specific vasculature and appendages in the presence of circulating immune cells.

活检大小的三维皮肤模型带有毛囊周围血管丛,可用于研究皮肤中免疫细胞的迁移。
人体皮肤血管具有独特的解剖结构,紧邻皮肤附属器官,是淋巴细胞向皮肤输送的守门员。在三维皮肤模型中模拟这种结构的复杂性和功能性是组织工程学面临的一个突出挑战。在这项研究中,我们利用数字光处理(DLP)生物打印技术的能力,生成了一个解剖学相关的微型三维片上皮肤(3D-SoC)模型,其大小仅为 6 毫米打孔活检组织的大小。三维芯片皮肤包含一个可灌注的血管网络,类似于皮肤表层的血管丛,并紧紧围绕着生物工程毛囊。三维 SoC 的灌注功能可实现免疫细胞的循环,以及免疫细胞与内皮细胞相互作用(即滚动、系留和外渗)的高分辨率实时成像。此外,3D-SoC 中的血管模式捕捉到了皮肤血管中剪切率的生理范围,可用于研究剪切率对 T 细胞迁移的影响。正如预期的那样,在三维-SoC 中,体外极化的 T 辅助细胞 1(Th1)与天真 T 细胞相比,对血管的附着力更强。在 T 细胞附着的早期阶段(< 5 分钟),天真细胞和 T 细胞在低剪切力区都有较高的滞留率。有趣的是,在后期阶段,T细胞的滞留率与剪切率无关。附着的 Th1 细胞进一步从血管壁转移到细胞外空间,并向生物工程毛囊和角质层间表皮迁移。当表皮不存在时,Th1 细胞向表皮的迁移会明显受阻,这说明表皮信号对 T 细胞浸润的作用。我们的数据验证了三维-SoC 模型在表皮信号背景下研究免疫细胞与皮肤血管之间相互作用的能力。这项研究中活检大小的三维-SoC 模型代表了解剖学和细胞复杂性的一个新水平,使我们离生成具有组织特异性血管和附属物的、存在循环免疫细胞的真正功能性人类皮肤更近了一步。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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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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