Tissue Microarray Technology for Molecular Applications: Investigation of Cross-Contamination between Tissue Samples Obtained from the Same Punching Device.

Microarrays Pub Date : 2015-04-02 DOI:10.3390/microarrays4020188

Erik Vassella, José A Galván, Inti Zlobec

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引用次数: 2

Abstract

Background: Tissue microarray (TMA) technology allows rapid visualization of molecular markers by immunohistochemistry and in situ hybridization. In addition, TMA instrumentation has the potential to assist in other applications: punches taken from donor blocks can be placed directly into tubes and used for nucleic acid analysis by PCR approaches. However, the question of possible cross-contamination between samples punched with the same device has frequently been raised but never addressed.

Methods: Two experiments were performed. (1) A block from mycobacterium tuberculosis (TB) positive tissue and a second from an uninfected patient were aligned side-by-side in an automated tissue microarrayer. Four 0.6 mm punches were cored from each sample and placed inside their corresponding tube. Between coring of each donor block, a mechanical cleaning step was performed by insertion of the puncher into a paraffin block. This sequence of coring and cleaning was repeated three times, alternating between positive and negative blocks. A fragment from the 6110 insertion sequence specific for mycobacterium tuberculosis was analyzed; (2) Four 0.6 mm punches were cored from three KRAS mutated colorectal cancer blocks, alternating with three different wild-type tissues using the same TMA instrument (sequence of coring: G12D, WT, G12V, WT, G13D and WT). Mechanical cleaning of the device between each donor block was made. Mutation analysis by pyrosequencing was carried out. This sequence of coring was repeated manually without any cleaning step between blocks.

Results/discussion: In both analyses, all alternating samples showed the expected result (samples 1, 3 and 5: positive or mutated, samples 2, 4 and 6: negative or wild-type). Similar results were obtained without cleaning step. These findings suggest that no cross-contamination of tissue samples occurs when donor blocks are punched using the same device, however a cleaning step is nonetheless recommended. Our result supports the use of TMA technology as an accessory to PCR applications.

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分子应用的组织微阵列技术:从同一冲孔装置获得的组织样品之间交叉污染的调查。

背景:组织微阵列(TMA)技术允许通过免疫组织化学和原位杂交快速可视化分子标记。此外，TMA仪器还具有其他应用的潜力:从供体块中取出的穿孔可以直接放入管中，并通过PCR方法用于核酸分析。然而，用同一设备打孔的样品之间可能存在交叉污染的问题经常被提出，但从未得到解决。方法:进行两项实验。(1)将来自结核分枝杆菌(TB)阳性组织的一块和来自未感染患者的另一块在自动组织微阵列中并排排列。从每个样品中取出4个0.6 mm的冲孔，并将其放入相应的管中。在每个供体块取心之间，通过将冲孔器插入石蜡块进行机械清洗。取心和清洗的顺序重复了三次，在正负块之间交替进行。分析了结核分枝杆菌6110特异插入序列的片段;(2)从3个KRAS突变的结直肠癌块中取4个0.6 mm的孔，使用相同的TMA仪器与3种不同的野生型组织交替取芯(取芯顺序:G12D、WT、G12V、WT、G13D和WT)。对每个供体块之间的装置进行机械清洗。采用焦磷酸测序进行突变分析。该取心顺序是手动重复的，在取心块之间没有任何清洗步骤。结果/讨论:在两种分析中，所有交替的样本都显示了预期的结果(样本1、3和5:阳性或突变，样本2、4和6:阴性或野生型)。没有清洗步骤也得到了类似的结果。这些发现表明，当供体块使用相同的设备打孔时，不会发生组织样本的交叉污染，但仍然建议进行清洁步骤。我们的结果支持使用TMA技术作为PCR应用的辅助。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Microarrays

自引率

0.00%

发文量

审稿时长

11 weeks

期刊介绍： High-Throughput (formerly Microarrays, ISSN 2076-3905) is a multidisciplinary peer-reviewed scientific journal that provides an advanced forum for the publication of studies reporting high-dimensional approaches and developments in Life Sciences, Chemistry and related fields. Our aim is to encourage scientists to publish their experimental and theoretical results based on high-throughput techniques as well as computational and statistical tools for data analysis and interpretation. The full experimental or methodological details must be provided so that the results can be reproduced. There is no restriction on the length of the papers. High-Throughput invites submissions covering several topics, including, but not limited to: Microarrays, DNA Sequencing, RNA Sequencing, Protein Identification and Quantification, Cell-based Approaches, Omics Technologies, Imaging, Bioinformatics, Computational Biology/Chemistry, Statistics, Integrative Omics, Drug Discovery and Development, Microfluidics, Lab-on-a-chip, Data Mining, Databases, Multiplex Assays.