高效聚类病毒基因组序列的新型自然图谱

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-12-15 DOI:10.2174/0115748936269106231025064143
Harris Song, Nan Sun, Wenping Yu, Stephen Yau
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引用次数: 0

摘要

研究背景本研究解决了分析病毒基因组序列和了解其遗传关系的需求。重点是引入一种新颖的自然图方法作为解决方案。研究目的本研究的目的是证明所提出的自然图方法在将病毒基因组序列聚类为不同的支系、亚型或区方面的有效性和优势。此外,目的还在于探索其可解释性、潜在应用以及对流行病控制和公共卫生干预的影响。研究方法本研究利用提出的自然图算法对病毒基因组序列进行聚类。研究结果与现有方法和多维尺度进行了比较,以评估该方法的性能和有效性。结果:自然图方法成功聚类了病毒基因组序列,为了解病毒进化和传播动态提供了宝贵的信息。节点之间产生有向连接的能力增强了结果的可解释性,为研究传播途径和病毒适应性提供了便利。结论研究结果凸显了自然图算法在大流行病控制、传播追踪和疫苗设计方面的潜在应用。未来的研究方向可能包括将分析扩展到更大的数据集,并纳入更多遗传特征以提高分辨率。自然图方法为病毒基因组学研究提供了一种前景广阔的工具,对公共卫生干预具有重要意义。
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A Novel Natural Graph for Efficient Clustering of Virus Genome Sequences
Background: This study addresses the need for analyzing viral genome sequences and understanding their genetic relationships. The focus is on introducing a novel natural graph approach as a solution. Objective: The objective of this study is to demonstrate the effectiveness and advantages of the proposed natural graph approach in clustering viral genome sequences into distinct clades, subtypes, or districts. Additionally, the aim is to explore its interpretability, potential applications, and implications for pandemic control and public health interventions. Methods: The study utilizes the proposed natural graph algorithm to cluster viral genome sequences. The results are compared with existing methods and multidimensional scaling to evaluate the performance and effectiveness of the approach. Results: The natural graph approach successfully clusters viral genome sequences, providing valuable insights into viral evolution and transmission dynamics. The ability to generate directed connections between nodes enhances the interpretability of the results, facilitating the investigation of transmission pathways and viral fitness. Conclusion: The findings highlight the potential applications of the natural graph algorithm in pandemic control, transmission tracing, and vaccine design. Future research directions may involve scaling up the analysis to larger datasets and incorporating additional genetic features for improved resolution. The natural graph approach presents a promising tool for viral genomics research with implications for public health interventions.
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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