An adaptive, negative feedback circuit in a biohybrid device reprograms dynamic networks of systemic inflammation in vivo

Frontiers in systems biology Pub Date : 2023-01-10 DOI:10.3389/fsysb.2022.926618

R. Namas, Maxim Mikheev, Jinling Yin, D. Barclay, B. Jefferson, Qi Mi, T. Billiar, R. Zamora, J. Gerlach, Y. Vodovotz

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引用次数: 1

Abstract

Introduction: Systemic acute inflammation accompanies and underlies the pathobiology of sepsis but is also central to tissue healing. We demonstrated previously the in vivo feasibility of modulating the key inflammatory mediator tumor necrosis factor-alpha (TNF-α) through the constitutive production and systemic administration of soluble TNF-α receptor (sTNFR) via a biohybrid device. Methods: We have now created multiple, stably transfected human HepG2 cell line variants expressing the mouse NF-κB/sTNFR. In vitro, these cell lines vary with regard to baseline production of sTNFR, but all have ~3.5-fold elevations of sTNFR in response to TNF-α. Results: Both constitutive and TNF-α-inducible sTNFR constructs, seeded into multicompartment, capillary-membrane liver bioreactors could reprogram dynamic networks of systemic inflammation and modulate PaO2, a key physiological outcome, in both endotoxemic and septic rats. Discussion: Thus, Control of TNF-α may drive a new generation of tunable biohybrid devices for the rational reprogramming of acute inflammation.

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生物混合装置中的自适应负反馈电路重新编程体内全身性炎症的动态网络

全身性急性炎症伴随着败血症的病理生物学基础，但也是组织愈合的核心。我们先前证明了通过生物混合装置通过可溶性TNF-α受体(sTNFR)的组成性产生和全身给药来调节关键炎症介质肿瘤坏死因子-α (TNF-α)的体内可行性。方法:我们现在已经创建了多个稳定转染的表达小鼠NF-κB/sTNFR的人HepG2细胞系变体。在体外，这些细胞系在sTNFR的基线产生方面有所不同，但在对TNF-α的反应中，所有细胞系的sTNFR都升高了约3.5倍。结果:将组成型和TNF-α-诱导的sTNFR构建物植入多室毛细血管膜肝生物反应器中，可以对内毒素中毒和脓毒症大鼠的全身炎症动态网络进行重编程，并调节PaO2，这是一种关键的生理结果。讨论:因此，控制TNF-α可能推动新一代可调生物混合装置的合理重编程急性炎症。

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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Frontiers in systems biology

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