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CardioClassifier:针对临床基因组解读的疾病和基因特异性计算决策支持。

CardioClassifier: disease- and gene-specific computational decision support for clinical genome interpretation.

机构信息

National Heart & Lung Institute, Imperial College London, London, UK.

Cardiovascular Research Centre at Royal Brompton and Harefield NHS Foundation Trust, London, UK.

出版信息

Genet Med. 2018 Oct;20(10):1246-1254. doi: 10.1038/gim.2017.258. Epub 2018 Jan 25.

DOI:10.1038/gim.2017.258
PMID:29369293
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6558251/
Abstract

PURPOSE

Internationally adopted variant interpretation guidelines from the American College of Medical Genetics and Genomics (ACMG) are generic and require disease-specific refinement. Here we developed CardioClassifier ( http://www.cardioclassifier.org ), a semiautomated decision-support tool for inherited cardiac conditions (ICCs).

METHODS

CardioClassifier integrates data retrieved from multiple sources with user-input case-specific information, through an interactive interface, to support variant interpretation. Combining disease- and gene-specific knowledge with variant observations in large cohorts of cases and controls, we refined 14 computational ACMG criteria and created three ICC-specific rules.

RESULTS

We benchmarked CardioClassifier on 57 expertly curated variants and show full retrieval of all computational data, concordantly activating 87.3% of rules. A generic annotation tool identified fewer than half as many clinically actionable variants (64/219 vs. 156/219, Fisher's P = 1.1  ×  10), with important false positives, illustrating the critical importance of disease and gene-specific annotations. CardioClassifier identified putatively disease-causing variants in 33.7% of 327 cardiomyopathy cases, comparable with leading ICC laboratories. Through addition of manually curated data, variants found in over 40% of cardiomyopathy cases are fully annotated, without requiring additional user-input data.

CONCLUSION

CardioClassifier is an ICC-specific decision-support tool that integrates expertly curated computational annotations with case-specific data to generate fast, reproducible, and interactive variant pathogenicity reports, according to best practice guidelines.

摘要

目的

美国医学遗传学与基因组学学院(ACMG)的国际采用变异解释指南是通用的,需要针对特定疾病进行细化。在这里,我们开发了 CardioClassifier(http://www.cardioclassifier.org),这是一种用于遗传性心脏疾病(ICC)的半自动决策支持工具。

方法

CardioClassifier 通过交互式界面整合了从多个来源检索到的数据和用户输入的特定于病例的信息,以支持变异解释。通过将疾病和基因特异性知识与大病例和对照队列中的变异观察相结合,我们细化了 14 项计算 ACMG 标准,并创建了三个 ICC 特异性规则。

结果

我们在 57 个经过精心整理的变体上对 CardioClassifier 进行了基准测试,结果显示所有计算数据都被完整检索,一致地激活了 87.3%的规则。一个通用注释工具仅识别了不到一半的具有临床可操作性的变体(64/219 与 156/219,Fisher's P=1.1×10),且存在重要的假阳性,这说明了疾病和基因特异性注释的重要性。CardioClassifier 在 33.7%的 327 例心肌病病例中识别出了疑似致病的变体,与领先的 ICC 实验室相当。通过添加手动整理的数据,超过 40%的心肌病病例中的变体都得到了全面注释,而无需额外的用户输入数据。

结论

CardioClassifier 是一种 ICC 特异性决策支持工具,它将精心整理的计算注释与特定于病例的数据相结合,根据最佳实践指南生成快速、可重复和交互式的变异致病性报告。