P. Brumm, Anna Fritschen, Lara Doß, E. Dörsam, A. Blaeser
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引用次数: 3
Abstract
Mammalian tissue comprises a plethora of hierarchically organized channel networks that serve as routes for the exchange of liquids, nutrients, bio-chemical cues or electrical signals, such as blood vessels, nerve fibers, or lymphatic conduits. Despite differences in function and size, the networks exhibit a similar, highly branched morphology with dendritic extensions. Mimicking such hierarchical networks represents a milestone in the biofabrication of tissues and organs. Work to date has focused primarily on the replication of the vasculature. Despite initial progress, reproducing such structures across scales and increasing biofabrication efficiency remain a challenge. In this work, we present a new biofabrication method that takes advantage of the viscous fingering phenomenon. Using flexographic printing, highly branched, inter-connective channel structures with stochastic, biomimetic distribution and dendritic extensions can be fabricated with unprecedented efficiency. Using gelatin (5%–35%) as resolvable sacrificial material, the feasability of the proposed method is demonstrated on the example of a vascular network. By selectively adjusting the printing velocity (0.2–1.5 m s−1), the anilox roller dip volume (4.5–24 ml m−2) as well as the shear viscosity of the printing material used (10–900 mPas), the width of the structures produced (30–400 µm) as well as their distance (200–600 µm) can be specifically determined. In addition to the flexible morphology, the high scalability (2500–25 000 mm2) and speed (1.5 m s−1) of the biofabrication process represents an important unique selling point. Printing parameters and hydrogel formulations are investigated and tuned towards a process window for controlled fabrication of channels that mimic the morphology of small blood vessels and capillaries. Subsequently, the resolvable structures were casted in a hydrogel matrix enabling bulk environments with integrated channels. The perfusability of the branched, inter-connective structures was successfully demonstrated. The fabricated networks hold great potential to enable nutrient supply in thick vascularized tissues or perfused organ-on-a-chip systems. In the future, the concept can be further optimized and expanded towards large-scale and cost-efficient biofabrication of vascular, lymphatic or neural networks for tissue engineering and regenerative medicine.
哺乳动物组织包括大量分层组织的通道网络,这些通道网络充当液体、营养物质、生化线索或电信号(如血管、神经纤维或淋巴管)交换的途径。尽管在功能和大小上存在差异,但网络表现出相似的、高度分支的形态,并具有树枝状延伸。模仿这样的层级网络代表着组织和器官生物制造的一个里程碑。迄今为止的工作主要集中在血管系统的复制上。尽管取得了初步进展,但跨规模复制这种结构和提高生物制造效率仍然是一个挑战。在这项工作中,我们提出了一种新的生物制造方法,利用粘性指法现象。使用柔性版印刷,可以以前所未有的效率制造具有随机、仿生分布和树枝状延伸的高度分支、互连通道结构。使用明胶(5%-35%)作为可溶解的牺牲材料,以血管网络为例证明了该方法的可行性。通过选择性地调整印刷速度(0.2–1.5 m s−1)、网纹辊浸渍体积(4.5–24 ml m−2)以及所用印刷材料的剪切粘度(10–900 mPas)、所产生结构的宽度(30–400µm)及其距离(200–600µm),可以具体确定。除了灵活的形态外,高可扩展性(2500–25 000 mm2)和生物制造过程的速度(1.5 m s−1)代表了一个重要的独特卖点。研究了印刷参数和水凝胶配方,并将其调整为模拟小血管和毛细血管形态的通道的受控制造的工艺窗口。随后,将可分解结构浇铸在水凝胶基质中,从而实现具有集成通道的本体环境。分支结缔结构的可灌注性得到了成功的证明。所制造的网络具有巨大的潜力,可以在厚血管组织或灌注芯片上的器官系统中提供营养。未来,该概念可以进一步优化和扩展,用于组织工程和再生医学的血管、淋巴或神经网络的大规模和成本效益高的生物制造。
期刊介绍:
The goal of the journal is to publish original research findings and critical reviews that contribute to our knowledge about the composition, properties, and performance of materials for all applications relevant to human healthcare.
Typical areas of interest include (but are not limited to):
-Synthesis/characterization of biomedical materials-
Nature-inspired synthesis/biomineralization of biomedical materials-
In vitro/in vivo performance of biomedical materials-
Biofabrication technologies/applications: 3D bioprinting, bioink development, bioassembly & biopatterning-
Microfluidic systems (including disease models): fabrication, testing & translational applications-
Tissue engineering/regenerative medicine-
Interaction of molecules/cells with materials-
Effects of biomaterials on stem cell behaviour-
Growth factors/genes/cells incorporated into biomedical materials-
Biophysical cues/biocompatibility pathways in biomedical materials performance-
Clinical applications of biomedical materials for cell therapies in disease (cancer etc)-
Nanomedicine, nanotoxicology and nanopathology-
Pharmacokinetic considerations in drug delivery systems-
Risks of contrast media in imaging systems-
Biosafety aspects of gene delivery agents-
Preclinical and clinical performance of implantable biomedical materials-
Translational and regulatory matters