Department of Internal Medicine II, University Hospital Würzburg, Würzburg, Germany.
Department of Musculoskeletal Tissue Regeneration, Orthopedic Clinic König-Ludwig-Haus, University of Würzburg, Würzburg, Germany.
Acta Biomater. 2024 Aug;184:210-225. doi: 10.1016/j.actbio.2024.06.041. Epub 2024 Jul 4.
Osteocytes perceive and process mechanical stimuli in the lacuno-canalicular network in bone. As a result, they secrete signaling molecules that mediate bone formation and resorption. To date, few three-dimensional (3D) models exist to study the response of mature osteocytes to biophysical stimuli that mimic fluid shear stress and substrate strain in a mineralized, biomimetic bone-like environment. Here we established a biomimetic 3D bone model by utilizing a state-of-art perfusion bioreactor platform where immortomouse/Dmp1-GFP-derived osteoblastic IDG-SW3 cells were differentiated into mature osteocytes. We evaluated proliferation and differentiation properties of the cells on 3D microporous scaffolds of decellularized bone (dBone), poly(L-lactide-co-trimethylene carbonate) lactide (LTMC), and beta-tricalcium phosphate (β-TCP) under physiological fluid flow conditions over 21 days. Osteocyte viability and proliferation were similar on the scaffolds with equal distribution of IDG-SW3 cells on dBone and LTMC scaffolds. After seven days, the differentiation marker alkaline phosphatase (Alpl), dentin matrix acidic phosphoprotein 1 (Dmp1), and sclerostin (Sost) were significantly upregulated in IDG-SW3 cells (p = 0.05) on LTMC scaffolds under fluid flow conditions at 1.7 ml/min, indicating rapid and efficient maturation into osteocytes. Osteocytes responded by inducing the mechanoresponsive genes FBJ osteosarcoma oncogene (Fos) and prostaglandin-endoperoxide synthase 2 (Ptgs2) under perfusion and dynamic compressive loading at 1 Hz with 5 % strain. Together, we successfully created a 3D biomimetic platform as a robust tool to evaluate osteocyte differentiation and mechanobiology in vitro while recapitulating in vivo mechanical cues such as fluid flow within the lacuno-canalicular network. STATEMENT OF SIGNIFICANCE: This study highlights the importance of creating a three-dimensional (3D) in vitro model to study osteocyte differentiation and mechanobiology, as cellular functions are limited in two-dimensional (2D) models lacking in vivo tissue organization. By using a perfusion bioreactor platform, physiological conditions of fluid flow and compressive loading were mimicked to which osteocytes are exposed in vivo. Microporous poly(L-lactide-co-trimethylene carbonate) lactide (LTMC) scaffolds in 3D are identified as a valuable tool to create a favorable environment for osteocyte differentiation and to enable mechanical stimulation of osteocytes by perfusion and compressive loading. The LTMC platform imitates the mechanical bone environment of osteocytes, allowing the analysis of the interaction with other cell types in bone under in vivo biophysical stimuli.
骨陷窝-骨小管网络中的骨细胞感知和处理机械刺激。因此,它们分泌信号分子,介导骨形成和吸收。迄今为止,很少有三维 (3D) 模型可用于研究成熟骨细胞对生物物理刺激的反应,这些刺激在矿化的仿生骨样环境中模拟流体剪切力和基质应变。在这里,我们利用最先进的灌注生物反应器平台建立了仿生 3D 骨模型,其中 immortomouse/Dmp1-GFP 衍生的成骨细胞 IDG-SW3 细胞分化为成熟的骨细胞。我们评估了在生理流体流动条件下,IDG-SW3 细胞在脱细胞骨 (dBone)、聚 (L-丙交酯-共-三亚甲基碳酸酯) 丙交酯 (LTMC) 和 β-磷酸三钙 (β-TCP) 的 3D 微孔支架上的增殖和分化特性,持续 21 天。在 dBone 和 LTMC 支架上,IDG-SW3 细胞均匀分布,骨细胞活力和增殖相似。七天后,在 1.7 ml/min 的流体流动条件下,LTMC 支架上 IDG-SW3 细胞中的碱性磷酸酶 (Alpl)、牙本质基质酸性磷酸蛋白 1 (Dmp1) 和骨硬化蛋白 (Sost) 等分化标志物显著上调 (p = 0.05),表明其快速有效地向骨细胞成熟。在灌注和 1 Hz、5%应变的动态压缩加载下,骨细胞通过诱导机械反应基因 Fos 和前列腺素内过氧化物合酶 2 (Ptgs2) 做出反应。总之,我们成功地创建了一个 3D 仿生平台,作为一种强大的工具来评估体外骨细胞分化和机械生物学,同时再现体内机械线索,如陷窝-骨小管网络内的流体流动。本研究强调了创建三维 (3D) 体外模型来研究骨细胞分化和机械生物学的重要性,因为二维 (2D) 模型中细胞功能有限,缺乏体内组织组织。通过使用灌注生物反应器平台,模拟了骨细胞在体内暴露的生理流体流动和压缩加载条件。在 3D 中,微孔聚 (L-丙交酯-共-三亚甲基碳酸酯) 丙交酯 (LTMC) 支架被确定为促进骨细胞分化和通过灌注和压缩加载对骨细胞进行机械刺激的有价值工具。LTMC 平台模拟了骨细胞的机械骨环境,允许在体内生物物理刺激下分析与骨内其他细胞类型的相互作用。
