毒理基因组学

Toxicogenomics integrates toxicology and genomics to understand the molecular responses to environmental stressors.
毒理基因组学整合了毒理学和基因组学，以理解对环境压力因素的分子响应。
The application of toxicogenomics in drug discovery can help predict potential adverse effects before clinical trials.
毒理基因组学在药物发现中的应用有助于在临床试验前预测潜在的不良影响。
Through toxicogenomic analysis, researchers can identify biomarkers that indicate early signs of toxicity.
通过毒理基因组学分析，研究人员可以识别出表明毒性早期迹象的生物标志物。
Toxicogenomics aids in understanding how different individuals may respond differently to the same chemical exposure.
毒理基因组学有助于理解不同个体对相同化学物质暴露可能产生不同的反应。
A toxicogenomic study on liver cancer revealed gene expression changes associated with carcinogenic compounds.
一项关于肝癌的毒理基因组学研究揭示了与致癌化合物相关的基因表达变化。
By comparing genomic profiles after treatment, toxicogenomics can identify mechanisms of toxicity at the molecular level.
通过比较治疗后的基因组谱，毒理基因组学可以在分子水平上识别毒性机制。
The field of toxicogenomics holds promise for advancing personalized medicine by predicting patient-specific drug responses.
毒理基因组学领域有望通过预测患者特定的药物反应来推动个性化医学的发展。
Toxicogenomics helps in deciphering complex dose-response relationships in environmental health research.
毒理基因组学有助于解读环境健康研究中复杂的剂量-效应关系。
High-throughput screening using toxicogenomics can expedite the safety assessment of new chemicals entering the market.
使用毒理基因组学的高通量筛选可以加快对进入市场的新型化学品的安全评估。
In ecotoxicogenomics, scientists analyze the impact of pollutants on entire ecosystems using genomic approaches.
在生态毒理基因组学中，科学家们采用基因组学方法分析污染物对整个生态系统的影响。