{"title":"M,基于反向度、还原反向度和邻域度拓扑指标的 NM 多项式在 Y 结纳米管键能中的应用。","authors":"Medha Itagi Huilgol, Shobha P H, Jayakrishna Udupa H, Ismail Naci Cangul","doi":"10.2174/0113862073320196240917145749","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>In graph theory, M polynomials like the matching polynomial are very crucial in examining the matching structures within graphs, while NM polynomials extends this to analyze non-matching edges. These polynomials are important in many fields, including chemistry and network architecture. They support the derivation of topological indices for protein structure analysis, network communication optimization, and drug design in QSAR/QSPR investigations.</p><p><strong>Objective: </strong>The aim of this paper is to define novel M and NM polynomials for different topological indices and to derive their closed-form expressions, specifically for Y-junction nanotubes. These new polynomials and indices are employed to create a robust QSPR model to predict bond energy in Y-junction nanotubes, that provide high accuracy and reliability in the model's statistical performance.</p><p><strong>Method: </strong>This paper introduces new forms of M and NM polynomials tailored to specific topological indices related to reverse and neighborhood reverse properties. We derive closed-form expressions for these indices in Y-junction nanotubes. Furthermore, we develop a QSPR model to predict bond energy in Y-junction nanotubes using the newly defined indices.</p><p><strong>Result: </strong>We define novel M and NM polynomials for various topological indices and derive precise expressions for Y-junction nanotubes. Utilizing these indices, we construct a highly accurate QSPR model (R² = 0.999) for predicting bond energy in Y-junction nanotubes, confirming the validity of our polynomial definitions and indices.</p><p><strong>Conclusion: </strong>We have presented new M and NM polynomials for different topological indices and derive their expressions specifically for Y-junction nanotubes. With these newly defined indices, we have developed a highly precise QSPR model to predict bond energy, achieving an R² value of 0.999. This work underscores the effectiveness of our polynomial definitions and indices in predicting material properties.</p>","PeriodicalId":10491,"journal":{"name":"Combinatorial chemistry & high throughput screening","volume":" ","pages":""},"PeriodicalIF":1.6000,"publicationDate":"2024-10-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"M, NM-polynomials Based on Reverse, Reduced Reverse Degree and Neighborhood Degree Based Topological Indices with Applications to Bond Energy of Y-Junction Nanotubes.\",\"authors\":\"Medha Itagi Huilgol, Shobha P H, Jayakrishna Udupa H, Ismail Naci Cangul\",\"doi\":\"10.2174/0113862073320196240917145749\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Background: </strong>In graph theory, M polynomials like the matching polynomial are very crucial in examining the matching structures within graphs, while NM polynomials extends this to analyze non-matching edges. 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引用次数: 0
摘要
背景:在图论中,M 多项式(如匹配多项式)对于研究图内的匹配结构非常重要,而 NM 多项式则将其扩展到分析非匹配边。这些多项式在化学和网络结构等许多领域都非常重要。它们支持蛋白质结构分析、网络通信优化和 QSAR/QSPR 研究中药物设计的拓扑指数推导:本文旨在为不同的拓扑指数定义新的 M 和 NM 多项式,并推导出它们的闭式表达式,特别是针对 Y 型连接纳米管。这些新的多项式和指数被用来创建一个稳健的 QSPR 模型,以预测 Y 结纳米管中的键能,该模型的统计性能具有高准确性和可靠性:本文针对与反向和邻域反向特性相关的特定拓扑指数,引入了新形式的 M 多项式和 NM 多项式。我们推导出了这些指数在 Y 结纳米管中的闭式表达式。此外,我们还开发了一个 QSPR 模型,利用新定义的指数预测 Y 结纳米管中的键能:我们为各种拓扑指数定义了新的 M 和 NM 多项式,并推导出 Y 结纳米管的精确表达式。利用这些指数,我们构建了一个高度精确的 QSPR 模型(R² = 0.999),用于预测 Y 结纳米管中的键能,从而证实了我们的多项式定义和指数的有效性:我们为不同的拓扑指数提出了新的 M 和 NM 多项式,并推导出了它们专门用于 Y 结纳米管的表达式。利用这些新定义的指数,我们建立了一个高度精确的 QSPR 模型来预测键能,R² 值达到 0.999。这项工作强调了我们的多项式定义和指数在预测材料特性方面的有效性。
M, NM-polynomials Based on Reverse, Reduced Reverse Degree and Neighborhood Degree Based Topological Indices with Applications to Bond Energy of Y-Junction Nanotubes.
Background: In graph theory, M polynomials like the matching polynomial are very crucial in examining the matching structures within graphs, while NM polynomials extends this to analyze non-matching edges. These polynomials are important in many fields, including chemistry and network architecture. They support the derivation of topological indices for protein structure analysis, network communication optimization, and drug design in QSAR/QSPR investigations.
Objective: The aim of this paper is to define novel M and NM polynomials for different topological indices and to derive their closed-form expressions, specifically for Y-junction nanotubes. These new polynomials and indices are employed to create a robust QSPR model to predict bond energy in Y-junction nanotubes, that provide high accuracy and reliability in the model's statistical performance.
Method: This paper introduces new forms of M and NM polynomials tailored to specific topological indices related to reverse and neighborhood reverse properties. We derive closed-form expressions for these indices in Y-junction nanotubes. Furthermore, we develop a QSPR model to predict bond energy in Y-junction nanotubes using the newly defined indices.
Result: We define novel M and NM polynomials for various topological indices and derive precise expressions for Y-junction nanotubes. Utilizing these indices, we construct a highly accurate QSPR model (R² = 0.999) for predicting bond energy in Y-junction nanotubes, confirming the validity of our polynomial definitions and indices.
Conclusion: We have presented new M and NM polynomials for different topological indices and derive their expressions specifically for Y-junction nanotubes. With these newly defined indices, we have developed a highly precise QSPR model to predict bond energy, achieving an R² value of 0.999. This work underscores the effectiveness of our polynomial definitions and indices in predicting material properties.
期刊介绍:
Combinatorial Chemistry & High Throughput Screening (CCHTS) publishes full length original research articles and reviews/mini-reviews dealing with various topics related to chemical biology (High Throughput Screening, Combinatorial Chemistry, Chemoinformatics, Laboratory Automation and Compound management) in advancing drug discovery research. Original research articles and reviews in the following areas are of special interest to the readers of this journal:
Target identification and validation
Assay design, development, miniaturization and comparison
High throughput/high content/in silico screening and associated technologies
Label-free detection technologies and applications
Stem cell technologies
Biomarkers
ADMET/PK/PD methodologies and screening
Probe discovery and development, hit to lead optimization
Combinatorial chemistry (e.g. small molecules, peptide, nucleic acid or phage display libraries)
Chemical library design and chemical diversity
Chemo/bio-informatics, data mining
Compound management
Pharmacognosy
Natural Products Research (Chemistry, Biology and Pharmacology of Natural Products)
Natural Product Analytical Studies
Bipharmaceutical studies of Natural products
Drug repurposing
Data management and statistical analysis
Laboratory automation, robotics, microfluidics, signal detection technologies
Current & Future Institutional Research Profile
Technology transfer, legal and licensing issues
Patents.