A Pharmacogenomics-Based In Silico Investigation of Opioid Prescribing in Post-operative Spine Pain Management and Personalized Therapy.

IF 3.6 4区 医学 Q3 CELL BIOLOGY
Kai-Uwe Lewandrowski, Alireza Sharafshah, John Elfar, Sergio Luis Schmidt, Kenneth Blum, Franklin Todd Wetzel
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引用次数: 0

Abstract

Considering the variability in individual responses to opioids and the growing concerns about opioid addiction, prescribing opioids for postoperative pain management after spine surgery presents significant challenges. Therefore, this study undertook a novel pharmacogenomics-based in silico investigation of FDA-approved opioid medications. The DrugBank database was employed to identify all FDA-approved opioids. Subsequently, the PharmGKB database was utilized to filter through all variant annotations associated with the relevant genes. In addition, the dpSNP ( https://www.ncbi.nlm.nih.gov/snp/ ), a publicly accessible repository, was used. Additional analyses were conducted using STRING-MODEL (version 12), Cytoscape (version 3.10.1), miRTargetLink.2, and NetworkAnalyst (version 3). The study identified 125 target genes of FDA-approved opioids, encompassing 7019 variant annotations. Of these, 3088 annotations were significant and pertained to 78 genes. During variant annotation assessments (VAA), 672 variants remained after filtration. Further in-depth filtration based on variant functions yielded 302 final filtered variants across 56 genes. The Monoamine GPCRs pathway emerged as the most significant signaling pathway. Protein-protein interaction (PPI) analysis revealed a fully connected network comprising 55 genes. Gene-miRNA Interaction (GMI) analysis of these 55 candidate genes identified miR-16-5p as a pivotal miRNA in this network. Protein-Drug Interaction (PDI) assessment showed that multiple drugs, including Ibuprofen, Nicotine, Tramadol, Haloperidol, Ketamine, L-Glutamic Acid, Caffeine, Citalopram, and Naloxone, had more than one interaction. Furthermore, Protein-Chemical Interaction (PCI) analysis highlighted that ABCB1, BCL2, CYP1A2, KCNH2, PTGS2, and DRD2 were key targets of the proposed chemicals. Notably, 10 chemicals, including carbamylhydrazine, tetrahydropalmatine, Terazosin, beta-methylcholine, rubimaillin, and quinelorane, demonstrated dual interactions with the aforementioned target genes. This comprehensive review offers multiple strong, evidence-based in silico findings regarding opioid prescribing in spine pain management, introducing 55 potential genes. The insights from this report can be applied in exome analysis as a pharmacogenomics (PGx) panel for pain susceptibility, facilitating individualized opioid prescribing through genotyping of related variants. The article also points out that African Americans represent an important group that displays a high catabolism of opioids and suggest the need for a personalized therapeutic approach based on genetic information.

Abstract Image

基于药物基因组学的脊柱术后疼痛管理和个性化治疗中阿片类药物处方的硅学研究。
考虑到个体对阿片类药物反应的差异性以及人们对阿片类药物成瘾的日益关注,在脊柱手术后开具阿片类药物用于术后疼痛治疗面临着巨大挑战。因此,本研究对美国食品与药物管理局批准的阿片类药物进行了一项基于药物基因组学的新型硅学研究。研究采用 DrugBank 数据库来识别所有经 FDA 批准的阿片类药物。随后,利用 PharmGKB 数据库筛选与相关基因有关的所有变异注释。此外,还使用了可公开访问的数据库 dpSNP ( https://www.ncbi.nlm.nih.gov/snp/ )。其他分析还使用了 STRING-MODEL(12 版)、Cytoscape(3.10.1 版)、miRTargetLink.2 和 NetworkAnalyst(3 版)。研究确定了 125 个 FDA 批准的阿片类药物的靶基因,包括 7019 个变异注释。其中 3088 个注释具有重要意义,涉及 78 个基因。在变异注释评估(VAA)过程中,有 672 个变异经过过滤后保留了下来。根据变异功能进一步深入筛选,最终筛选出 302 个变异,涉及 56 个基因。单胺 GPCR 通路成为最重要的信号通路。蛋白-蛋白相互作用(PPI)分析显示,一个完全连接的网络包含 55 个基因。对这 55 个候选基因进行的基因-miRNA 相互作用(GMI)分析发现,miR-16-5p 是该网络中的关键 miRNA。蛋白质-药物相互作用(PDI)评估显示,包括布洛芬、尼古丁、曲马多、氟哌啶醇、氯胺酮、L-谷氨酸、咖啡因、西酞普兰和纳洛酮在内的多种药物具有一种以上的相互作用。此外,蛋白质与化学物质相互作用(PCI)分析显示,ABCB1、BCL2、CYP1A2、KCNH2、PTGS2 和 DRD2 是拟议化学物质的主要靶标。值得注意的是,10 种化学物质(包括氨基肼、四氢巴马汀、特拉唑嗪、β-甲基胆碱、鲁比马林和喹诺酮)表现出与上述靶基因的双重相互作用。这篇综合综述提供了有关脊柱疼痛治疗中阿片类药物处方的多种有力的、基于证据的硅学研究结果,介绍了 55 个潜在基因。该报告的见解可应用于外显子组分析,作为疼痛易感性的药物基因组学(PGx)面板,通过相关变异的基因分型促进阿片类药物处方的个体化。文章还指出,非裔美国人是阿片类药物分解率较高的一个重要群体,这表明需要基于遗传信息的个性化治疗方法。
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
CiteScore
7.70
自引率
0.00%
发文量
137
审稿时长
4-8 weeks
期刊介绍: Cellular and Molecular Neurobiology publishes original research concerned with the analysis of neuronal and brain function at the cellular and subcellular levels. The journal offers timely, peer-reviewed articles that describe anatomic, genetic, physiologic, pharmacologic, and biochemical approaches to the study of neuronal function and the analysis of elementary mechanisms. Studies are presented on isolated mammalian tissues and intact animals, with investigations aimed at the molecular mechanisms or neuronal responses at the level of single cells. Cellular and Molecular Neurobiology also presents studies of the effects of neurons on other organ systems, such as analysis of the electrical or biochemical response to neurotransmitters or neurohormones on smooth muscle or gland cells.
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