| Multilayered Fabrication Assembly Technique to Engineer a Corneal Stromal Equivalent
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Author:
Date:
2021-03-20
[Abstract] Tissue engineering has emerged as a strategy to combat the donor shortage of human corneas for transplantation. Synthetic corneal substitutes are currently unable to support the normal phenotype of human cells and so decellularized animal corneas have been deployed to more closely provide the topographical and biochemical cues to promote cell attachment and function. Although full thickness decellularized corneas can support corneal cells, the cells are slow to populate the scaffold and density declines from the surface. To avoid these problems, this protocol describes the stacking of ...
[摘要] [摘要]组织工程学已成为一种解决人类角膜移植供体短缺的策略。合成的角膜替代物目前不能支持人类细胞的正常表型,因此已经使用脱细胞的动物角膜来更紧密地提供地形和生化线索以促进细胞附着和功能。尽管全厚度的脱细胞角膜可以支持角膜细胞,但这些细胞填充支架的速度很慢,并且密度从表面降低。为了避免这些问题,该协议描述了脱细胞层的交替层的堆叠 猪角膜片和载有细胞的胶原蛋白水凝胶可产生角膜构建体。通过将猪角膜冷冻切片,用去污剂和核酸酶使它们脱细胞,最后进行空气干燥以储存和易于制造,从而获得了薄片。然后将角膜基质细胞封装在I型胶原溶液中,并在这些薄片之间进行浇铸。该协议提出了一种快速的方法,以确保仅使用组织来源的材料即可在整个构建体中获得高细胞度。
图形摘要:
获得角膜基质等效物的主要过程概述
[背景]角膜失明影响着全球数百万人,治疗主要依赖于人类供体角膜的移植(Gain等人,2016)。由于这些捐赠是稀缺的,因此需要基于生物材料的组织工程学的替代方案。正在开发各种各样的策略和材料来工程化角膜组织,一种有前途的方法是使用脱细胞的动物角膜(Fernández- Pérez和Ahearne ...
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| Centromere Chromosome Orientation Fluorescent in situ Hybridization (Cen-CO-FISH) Detects Sister Chromatid Exchange at the Centromere in Human Cells
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Author:
Date:
2018-04-05
[Abstract] Human centromeres are composed of large tandem arrays of repetitive alpha satellite DNA, which are often sites of aberrant rearrangement in cancers (Mitelman et al., 1997; Padilla-Nash et al., 2001). To date, annotation of the human centromere repetitive sequences remains incomplete, greatly hindering in-depth functional studies of these regions essential for chromosome segregation. In order to monitor sister chromatid exchange happening at the centromere (C-SCE) due to recombination and mutagenic events, I have applied the Chromosome-Orientation Fluorescence in situ ...
[摘要] 人类着丝粒由重复的α卫星DNA的大串联阵列组成,这些细胞通常是癌症中异常重排的位点(Mitelman等人,1997; Padilla-Nash等人 >,2001)。迄今为止,对人类着丝粒重复序列的注释仍然不完整,极大地妨碍了这些区域对染色体分离至关重要的深入功能研究。为了监测由于重组和诱变事件而在着丝粒(C-SCE)上发生姊妹染色单体交换,我将染色体定位荧光原位杂交(CO-FISH)技术应用于着丝粒( Cen-CO-FISH)在人类细胞中的表达。这种基于杂交的方法包括(1)通过单轮复制掺入核苷酸类似物,(2)新合成的DNA链的酶消化和(3)单链探针的后续杂交,在不存在变性步骤的情况下。所产生的信号允许基于DNA的5'-3'方向性差异地标记每个姊妹染色单体,并评估指示C-SCE的异常染色模式。应用于人类着丝粒的Cen-CO-FISH方法揭示,人类着丝粒确实在循环细胞中发生重组,导致C-SCE,并且在经历衰老的癌细胞系和原代细胞中着丝粒不稳定性增强(Giunta和Funabiki,2017)。在这里,我介绍了人类细胞中Cen-CO-FISH方法的制备,实验程序和数据采集的详细方案。它还包括该技术的概念性概述,以及代表性图像和评分准则的示例。 Cen-CO-FISH是促进着丝粒重复探索的有用工具。
【背景】人类基因组计划于2003年标记为完成,但它遗漏了超过10%的人类重复DNA(de ...
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| Determining Genome Size from Spores of Seedless Vascular Plants
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Author:
Date:
2017-06-05
[Abstract] Seedless vascular plants, including ferns and lycophytes, produce spores to initiate the gametophyte stage and to complete sexual reproduction. Approximately 10% of them are apomictic through the production of genomic unreduced spores. Being able to measure the spore nuclear DNA content is therefore important to infer their reproduction mode. Here we present a protocol of spore flow cytometry that allows an efficient determination of the reproductive modes of seedless vascular plants.
[摘要] 无核维管植物,包括蕨类植物和lycophytes,产生孢子,以启动配子体阶段并完成有性繁殖。其中约10%通过生产基因组未还原的孢子而脱水。因此,能够测量孢子核DNA含量对推断其再生模式是重要的。在这里,我们提出了一个孢子流式细胞术方案,可以有效地确定无核维管植物的繁殖模式。
背景 在无核维管植物中,传统上用于推断核DNA含量以及繁殖模式的孢子发生特征,如减数分裂染色体计数。然而,这些方法是耗时的,或只能提供间接证据。 Kuo等人(2017)尚未建立一种估计这些植物的孢子核DNA含量的有效可靠的方法。在这里,我们描述了使用流式细胞术基于Kuo等人(2017)的工作来评估这些植物的孢子基因组大小的方案。
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