Pneumatic piston hydrostatic bioreactor for cartilage tissue engineering.

IF 1.3 4区 工程技术 Q4 CHEMISTRY, ANALYTICAL Instrumentation Science & Technology Pub Date : 2023-01-01 DOI:10.1080/10739149.2022.2124418
J Hallas, A J Janvier, K F Hoettges, J R Henstock
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Abstract

During exercise, mechanical loads from the body are transduced into interstitial fluid pressure changes which are sensed as dynamic hydrostatic forces by cells in cartilage. The effects of these loading forces in health and disease are of interest to biologists, but the availability of affordable equipment for in vitro experimentation is an obstacle to research progress. Here, we report the development of a cost-effective hydropneumatic bioreactor system for research in mechanobiology. The bioreactor was assembled from readily available components (a closed-loop stepped motor and pneumatic actuator) and a minimal number of easily-machined crankshaft parts, whilst the cell culture chambers were custom designed by the biologists using CAD and entirely 3 D printed in PLA. The bioreactor system was shown to be capable of providing cyclic pulsed pressure waves at a user-defined amplitude and frequency ranging from 0 to 400 kPa and up to 3.5 Hz, which are physiologically relevant for cartilage. Tissue engineered cartilage was created from primary human chondrocytes and cultured in the bioreactor for five days with three hours/day cyclic pressure (300 kPa at 1 Hz), simulating moderate physical exercise. Bioreactor-stimulated chondrocytes significantly increased their metabolic activity (by 21%) and glycosaminoglycan synthesis (by 24%), demonstrating effective cellular transduction of mechanosensing. Our Open Design approach focused on using 'off-the-shelf' pneumatic hardware and connectors, open source software and in-house 3 D printing of bespoke cell culture containers to resolve long-standing problems in the availability of affordable bioreactors for laboratory research.

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软骨组织工程用气动活塞静压生物反应器。
在运动过程中,来自身体的机械负荷被转导成间质流体压力的变化,并被软骨细胞感知为动态流体静力。这些负荷力对健康和疾病的影响是生物学家感兴趣的,但可负担得起的体外实验设备的可用性是研究进展的障碍。在这里,我们报告了一种具有成本效益的水力气动生物反应器系统的发展,用于机械生物学的研究。生物反应器由现成的组件(闭环步进电机和气动执行器)和少量易于加工的曲轴部件组装而成,而细胞培养室则由生物学家使用CAD和PLA完全3d打印定制设计。生物反应器系统被证明能够在用户定义的振幅和频率范围内提供循环脉冲压力波,范围从0到400kpa,高达3.5 Hz,这与软骨的生理相关。组织工程软骨由原代人软骨细胞制备,在模拟中度体育锻炼的条件下,在生物反应器中以3小时/天的循环压力(300 kPa, 1 Hz)培养5天。生物反应器刺激的软骨细胞的代谢活性(提高21%)和糖胺聚糖合成(提高24%)显著增加,证明了机械传感的有效细胞转导。我们的开放式设计方法专注于使用“现成的”气动硬件和连接器,开源软件和定制细胞培养容器的内部3d打印,以解决长期存在的可负担生物反应器用于实验室研究的问题。
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来源期刊
Instrumentation Science & Technology
Instrumentation Science & Technology 工程技术-分析化学
CiteScore
3.50
自引率
0.00%
发文量
45
审稿时长
>12 weeks
期刊介绍: Instrumentation Science & Technology is an internationally acclaimed forum for fast publication of critical, peer reviewed manuscripts dealing with innovative instrument design and applications in chemistry, physics biotechnology and environmental science. Particular attention is given to state-of-the-art developments and their rapid communication to the scientific community. Emphasis is on modern instrumental concepts, though not exclusively, including detectors, sensors, data acquisition and processing, instrument control, chromatography, electrochemistry, spectroscopy of all types, electrophoresis, radiometry, relaxation methods, thermal analysis, physical property measurements, surface physics, membrane technology, microcomputer design, chip-based processes, and more. Readership includes everyone who uses instrumental techniques to conduct their research and development. They are chemists (organic, inorganic, physical, analytical, nuclear, quality control) biochemists, biotechnologists, engineers, and physicists in all of the instrumental disciplines mentioned above, in both the laboratory and chemical production environments. The journal is an important resource of instrument design and applications data.
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