Silica nanoparticles enhance interfacial self-adherence of a multi-layered extracellular matrix scaffold for vascular tissue regeneration.

IF 2 4区生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biotechnology Letters Pub Date : 2024-06-01 Epub Date: 2024-02-17 DOI:10.1007/s10529-024-03469-0

Leslie A Goldberg, Helena D Zomer, Calum McFetridge, Peter S McFetridge

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Abstract

Purpose: Based on the clinical need for grafts for vascular tissue regeneration, our group developed a customizable scaffold derived from the human amniotic membrane. Our approach consists of rolling the decellularized amniotic membrane around a mandrel to form a multilayered tubular scaffold with tunable diameter and wall thickness. Herein, we aimed to investigate if silica nanoparticles (SiNP) could enhance the adhesion of the amnion layers within these rolled grafts.

Methods: To test this, we assessed the structural integrity and mechanical properties of SiNP-treated scaffolds. Mechanical tests were repeated after six months to evaluate adhesion stability in aqueous environments.

Results: Our results showed that the rolled SiNP-treated scaffolds maintained their tubular shape upon hydration, while non-treated scaffolds collapsed. By scanning electron microscopy, SiNP-treated scaffolds presented more densely packed layers than untreated controls. Mechanical analysis showed that SiNP treatment increased the scaffold's tensile strength up to tenfold in relation to non-treated controls and changed the mechanism of failure from interfacial slipping to single-point fracture. The nanoparticles reinforced the scaffolds both at the interface between two distinct layers and within each layer of the extracellular matrix. Finally, SiNP-treated scaffolds significantly increased the suture pullout force in comparison to untreated controls.

Conclusion: Our study demonstrated that SiNP prevents the unraveling of a multilayered extracellular matrix graft while improving the scaffolds' overall mechanical properties. In addition to the generation of a robust biomaterial for vascular tissue regeneration, this novel layering technology is a promising strategy for a number of bioengineering applications.

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二氧化硅纳米粒子增强多层细胞外基质支架的界面自粘附性，促进血管组织再生。

目的：根据临床上对血管组织再生移植物的需求，我们的研究小组开发出了一种从人类羊膜中提取的可定制支架。我们的方法是将脱细胞羊膜绕心轴滚动，形成直径和壁厚可调的多层管状支架。在此，我们旨在研究二氧化硅纳米粒子（SiNP）是否能增强这些滚动移植物内羊膜层的粘附性：为了验证这一点，我们评估了经 SiNP 处理的支架的结构完整性和机械性能。六个月后重复进行机械测试，以评估在水环境中的粘附稳定性：结果：我们的研究结果表明，经过 SiNP 处理的轧制支架在水化后仍能保持管状形状，而未经处理的支架则会塌陷。通过扫描电子显微镜观察，SiNP 处理过的支架比未经处理的对照组呈现出更密集的层。力学分析表明，与未处理的对照组相比，SiNP 处理使支架的抗拉强度提高了 10 倍，并改变了从界面滑动到单点断裂的失效机制。纳米粒子在两个不同层之间的界面以及细胞外基质的每一层内都增强了支架。最后，与未经处理的对照组相比，SiNP 处理过的支架明显增加了缝合拉力：我们的研究表明，SiNP 可防止多层细胞外基质移植物解离，同时改善支架的整体机械性能。除了为血管组织再生生成一种坚固的生物材料外，这种新颖的分层技术还是一种很有前景的生物工程应用策略。

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来源期刊

Biotechnology Letters 工程技术-生物工程与应用微生物

CiteScore

5.90

自引率

3.70%

发文量

108

审稿时长

1.2 months

期刊介绍： Biotechnology Letters is the world’s leading rapid-publication primary journal dedicated to biotechnology as a whole – that is to topics relating to actual or potential applications of biological reactions affected by microbial, plant or animal cells and biocatalysts derived from them. All relevant aspects of molecular biology, genetics and cell biochemistry, of process and reactor design, of pre- and post-treatment steps, and of manufacturing or service operations are therefore included. Contributions from industrial and academic laboratories are equally welcome. We also welcome contributions covering biotechnological aspects of regenerative medicine and biomaterials and also cancer biotechnology. Criteria for the acceptance of papers relate to our aim of publishing useful and informative results that will be of value to other workers in related fields. The emphasis is very much on novelty and immediacy in order to justify rapid publication of authors’ results. It should be noted, however, that we do not normally publish papers (but this is not absolute) that deal with unidentified consortia of microorganisms (e.g. as in activated sludge) as these results may not be easily reproducible in other laboratories. Papers describing the isolation and identification of microorganisms are not regarded as appropriate but such information can be appended as supporting information to a paper. Papers dealing with simple process development are usually considered to lack sufficient novelty or interest to warrant publication.