A mechanically active nucleus pulposus-on-a-chip for studying mechanobiology and therapeutic strategies in intervertebral disc disease

机械生物学 机械转化 细胞外基质 椎间盘 细胞生物学 下调和上调 神经科学 基质(化学分析) 核心 退行性椎间盘病 变性(医学) 糖胺聚糖 生物 神经退行性变 化学 分解代谢 调解人 生物医学工程 细胞外 医学 基因表达 细胞 压缩(物理) 疾病 电池类型 刺激 微阵列分析技术 癌症研究 微阵列 材料科学 蛋白多糖 细胞培养 生物信息学
作者
Olga Krupková,Bianca Aterini,Nader Rahal,Elias Schulze,Salim Darwiche,Martin Ehrbar,Karoliina Pelttari,Ivan Martin,Stefan Schären,Arne Mehrkens,Andrea Barbero,Andrea Mainardi
出处
期刊:Biofabrication [IOP Publishing]
卷期号:18 (1): 015031-015031
标识
DOI:10.1088/1758-5090/ae3d85
摘要

Abstract Intervertebral disc (IVD) degeneration is the primary contributor to low back pain, the leading cause of disability worldwide. Although various triggers have been associated with IVD degeneration, its precise aetiology remains unclear. Consequently, current treatments fail to address the underlying degradative processes. Mechanical loading plays a critical role in IVD homeostasis, and aberrant mechanical stimulation has been identified as a key driver of extracellular matrix degradation in the proteoglycan-rich core of the IVD—the nucleus pulposus (NPs). Elucidating the molecular mechanisms of IVD mechanotransduction could therefore be pivotal in identifying effective drug targets. However, we are lacking easy-to-use, reliable models to study IVD’s mechanobiological mechanisms in human cells. Here, we present the first mechanically active, microscale, human cell-based NP-on-a-Chip (NPoC) model that mimics the native NP microenvironment and enables controlled investigation of mechanically induced degenerative processes. Starting from primary human NP cells, we demonstrate that hypoxic culture (i.e. 2% O 2 ) results in 3D constructs with gene expression levels of NP markers ( ACAN, COL2A1, CDH2, OVOS2 ), and matrix composition (collagen type II and glycosaminoglycans) comparable with the native NP tissue. NPoC constructs respond to cyclic compression in an intensity- and duration-dependent manner. Physiological compression (10%) enhances glycosaminoglycan deposition, whereas hyperphysiological compression (30%), especially if prolonged in time (16 h d −1 ), induces upregulation of inflammatory and catabolic markers ( PTGS2, MMP13 ), matrix degradation, and increased apoptosis—thus recapitulating clinical hallmarks of NP degeneration. As a proof of concept for the platform’s perspective utility in therapeutic screening, we demonstrate that inhibition of the mechanoresponsive channel TRPV4 with GSK205 restores baseline expression levels of mechanosensitive and catabolic genes. The new NPoC is thus suitable for studying NP mechanobiology and screening mechanotransduction-targeting drugs, and it may facilitate the future discovery of disease modifying therapies for discogenic low back pain.
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