3d生物打印人类牙周/成骨细胞微流控组织芯片系统和模型药物相互作用的评估

M. Vurat, Sukran Seker, Özge Lalegül-Ülker, Mahmut Parmaksiz, A. E. Elçin, Y. M. Elçin
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引用次数: 1

摘要

虽然牙周病是全球范围内牙齿脱落的主要原因之一,但伴随的软质和矿化PD组织的调节以及PD的发病机制尚未完全阐明。此外,相关的临床前模型和体外平台在准确模拟人体生理方面存在局限性。牙周芯片,模拟牙周韧带-牙槽骨(PDL-AB)生物界面尚未开发。在这项研究中,我们首次利用三维生物打印(3DP)技术来开发这样一个系统。采用明胶甲基丙烯酰(Gel-MA)生物墨水对人牙周韧带成纤维细胞进行生物打印。另一方面,使用凝胶-ma和羟基磷灰石磁性氧化铁纳米颗粒(凝胶-ma /HAp-MNPs)组成的复合生物墨水对AB进行建模,用于生物打印人成骨细胞。MNPs被纳入到矿化层中,用于前瞻性正畸机械转导研究。优化了复合微组织的3d打印参数;评估了构建体的物理、化学、流变、机械和热性能。最后,对模型药物四环素相互作用进行初步评价。因此,四环素类药物对PD - ab的影响对PD疾病的治疗具有临床意义。这种牙周芯片模型代表了一个可重复的体外平台,用于研究健康和患病人类牙周细胞生长过程。
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3D-Bioprinted Human Periodontal/Osteoblastic Microfluidic Tissue-on-A-Chip System and Evaluation of Model Drug Interactions
While periodontal (PD) disease is among principal causes of tooth loss worldwide, regulation of concomitant soft and mineralized PD tissues, and PD pathogenesis have not been completely clarified yet. Besides, relevant pre-clinical models and in vitro platforms have limitations in accurately simulating human physiology. A periodontium-on-a-chip, emulating PD ligament-alveolar bone (PDL-AB) biointerface has not been developed to date. In this study, we have harnessed three-dimensional bioprinting (3DP) technology for developing such a system for the first time. PDL was modelled by using gelatin methacryloyl (Gel-MA) bioink for bioprinting human periodontal ligament fibroblasts. On the side, AB was modelled by using a composite bioink comprised of Gel-MA and hydroxyapatite-magnetic iron oxide nanoparticles (Gel-MA/HAp-MNPs) for bioprinting human osteoblasts. MNPs were incorporated to bring magnetic properties to the mineralized layer for use in prospective orthodontic mechanotransduction studies. The 3DP parameters of the composite microtissue were optimized; the physical, chemical, rheological, mechanical, and thermal properties of the constructs were assessed. Finally, preliminary evaluation of the model drug tetracycline interactions was performed. Thus, the effects of the tetracyclines on PDL-AB have clinical significance for treating PD diseases. This periodontium-on-a-chip model represents a reproducible in vitro platform for studying processes of healthy and diseased human PDL.
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