Your search keyword '"Benchmark dose analysis"' showing total 4 results

1. Benchmark dose modeling of transcriptional data: a systematic approach to identify best practices for study designs used in radiation research.

Author

Stainforth, Robert, Vuong, Ngoc, Adam, Nadine, Kuo, Byron, Wilkins, Ruth C., Yauk, Carole, Beheshti, Afshin, and Chauhan, Vinita

Subjects

*GENE expression profiling, *RADIATION, *EXPOSURE dose, *RADIATION exposure, *ABSOLUTE value

Abstract

Benchmark dose (BMD) modeling is a method commonly used in chemical toxicology to identify the point of departure (POD) from a dose-response curve linked to a health-related outcome. Recently, its application in the analysis of transcriptional data for quantitative adverse outcome pathway (AOP) development is being explored. As AOPs are informed by diverse data types, it is important to understand the impact of study parameters such as dose selection, the number of replicates and dose range on BMD outputs for radiation-induced genes and pathways. Data were selected from the Gene Expression Omnibus (GSE52403) that featured gene expression profiles of peripheral blood samples from C57BL/6 mice 6 hours post-exposure to 137Cs gamma-radiation at 0, 1, 2, 3, 4.5, 6, 8 and 10.5 Gy. The dataset comprised a broad dose range over multiple dose points with consistent dose spacing and multiple biological replicates. This dataset was ideal for systematically transforming across three categories: (1) dose range, (2) dose-spacing and (3) number of controls/replicates. Across these categories, 29 transformed datasets were compared to the original dataset to determine the impact of each transformation on the BMD outputs. Most of the experimental changes did not impact the BMD outputs. The transformed datasets were largely consistent with the original dataset in terms of the number of reproduced genes modeled and absolute BMD values for genes and pathways. Variations in dose selection identified the importance of the absolute value of the lowest and second dose. It was determined that dose selection should include at least two doses <1 Gy and two >5 Gy to achieve meaningful BMD outputs. Changes to the number of biological replicates in the control and non-zero dose groups impacted the overall accuracy and precision of the BMD outputs as well as the ability to fit dose-response models consistent with the original dataset. Successful application of transcriptomic BMD modeling for radiation datasets requires considerations of the exposure dose and the number of biological replicates. Most important is the selection of the lowest doses and dose spacing. Reflections on these parameters in experimental design will provide meaningful BMD outputs that could correlate well to apical endpoints of relevance to radiation exposure assessment. [ABSTRACT FROM AUTHOR]

Published

2022

2. Transcriptomics in Toxicogenomics, Part III: Data Modelling for Risk Assessment

Author

Angela Serra, Michele Fratello, Luca Cattelani, Irene Liampa, Georgia Melagraki, Pekka Kohonen, Penny Nymark, Antonio Federico, Pia Anneli Sofia Kinaret, Karolina Jagiello, My Kieu Ha, Jang-Sik Choi, Natasha Sanabria, Mary Gulumian, Tomasz Puzyn, Tae-Hyun Yoon, Haralambos Sarimveis, Roland Grafström, Antreas Afantitis, and Dario Greco

Subjects

toxicogenomics, transcriptomics, data modelling, benchmark dose analysis, network analysis, read-across, Chemistry, QD1-999

Abstract

Transcriptomics data are relevant to address a number of challenges in Toxicogenomics (TGx). After careful planning of exposure conditions and data preprocessing, the TGx data can be used in predictive toxicology, where more advanced modelling techniques are applied. The large volume of molecular profiles produced by omics-based technologies allows the development and application of artificial intelligence (AI) methods in TGx. Indeed, the publicly available omics datasets are constantly increasing together with a plethora of different methods that are made available to facilitate their analysis, interpretation and the generation of accurate and stable predictive models. In this review, we present the state-of-the-art of data modelling applied to transcriptomics data in TGx. We show how the benchmark dose (BMD) analysis can be applied to TGx data. We review read across and adverse outcome pathways (AOP) modelling methodologies. We discuss how network-based approaches can be successfully employed to clarify the mechanism of action (MOA) or specific biomarkers of exposure. We also describe the main AI methodologies applied to TGx data to create predictive classification and regression models and we address current challenges. Finally, we present a short description of deep learning (DL) and data integration methodologies applied in these contexts. Modelling of TGx data represents a valuable tool for more accurate chemical safety assessment. This review is the third part of a three-article series on Transcriptomics in Toxicogenomics.

Published

2020

3. Transcriptomics in Toxicogenomics, Part III : Data Modelling for Risk Assessment

Author

Serra, Angela, Fratello, Michele, Cattelani, Luca, Liampa, Irene, Melagraki, Georgia, Kohonen, Pekka, Nymark, Penny, Federico, Antonio, Kinaret, Pia Anneli Sofia, Jagiello, Karolina, Ha, My Kieu, Choi, Jang-Sik, Sanabria, Natasha, Gulumian, Mary, Puzyn, Tomasz, Yoon, Tae-Hyun, Sarimveis, Haralambos, Grafström, Roland, Afantitis, Antreas, Greco, Dario, and Institute of Biotechnology

Subjects

benchmark dose analysis, TOXICITY PREDICTION, QSAR, EXPRESSION DATA, deep learning, GENE-COEXPRESSION NETWORK, data modelling, DRUG DISCOVERY, transcriptomics, VARIABLE SELECTION, machine learning, toxicogenomics, CONNECTIVITY MAP, MICROARRAY DATA, FEATURE-SELECTION, 1182 Biochemistry, cell and molecular biology, NONNEGATIVE MATRIX FACTORIZATION, DOSE-RESPONSE, network analysis, data integration, read-across

Abstract

Transcriptomics data are relevant to address a number of challenges in Toxicogenomics (TGx). After careful planning of exposure conditions and data preprocessing, the TGx data can be used in predictive toxicology, where more advanced modelling techniques are applied. The large volume of molecular profiles produced by omics-based technologies allows the development and application of artificial intelligence (AI) methods in TGx. Indeed, the publicly available omics datasets are constantly increasing together with a plethora of different methods that are made available to facilitate their analysis, interpretation and the generation of accurate and stable predictive models. In this review, we present the state-of-the-art of data modelling applied to transcriptomics data in TGx. We show how the benchmark dose (BMD) analysis can be applied to TGx data. We review read across and adverse outcome pathways (AOP) modelling methodologies. We discuss how network-based approaches can be successfully employed to clarify the mechanism of action (MOA) or specific biomarkers of exposure. We also describe the main AI methodologies applied to TGx data to create predictive classification and regression models and we address current challenges. Finally, we present a short description of deep learning (DL) and data integration methodologies applied in these contexts. Modelling of TGx data represents a valuable tool for more accurate chemical safety assessment. This review is the third part of a three-article series on Transcriptomics in Toxicogenomics.

Published

2020

4. Transcriptomics in Toxicogenomics, Part III: Data Modelling for Risk Assessment

Author

Penny Nymark, Tae Hyun Yoon, Haralambos Sarimveis, Pekka Kohonen, Natasha Sanabria, Michele Fratello, Georgia Melagraki, Antreas Afantitis, Roland C. Grafström, Pia Anneli Sofia Kinaret, Dario Greco, Antonio Federico, My Kieu Ha, Luca Cattelani, Jang-Sik Choi, Karolina Jagiello, Angela Serra, Irene Liampa, Tomasz Puzyn, and Mary Gulumian

Subjects

benchmark dose analysis, Computer science, General Chemical Engineering, 02 engineering and technology, Review, Machine learning, computer.software_genre, Data modeling, lcsh:Chemistry, data modelling, 03 medical and health sciences, transcriptomics, Benchmark (surveying), General Materials Science, network analysis, data integration, 030304 developmental biology, 0303 health sciences, business.industry, QSAR, Deep learning, Physics, deep learning, 021001 nanoscience & nanotechnology, machine learning, lcsh:QD1-999, toxicogenomics, Artificial intelligence, Data pre-processing, 0210 nano-technology, Toxicogenomics, business, Risk assessment, computer, Engineering sciences. Technology, Network analysis, Data integration, read-across

Abstract

Transcriptomics data are relevant to address a number of challenges in Toxicogenomics (TGx). After careful planning of exposure conditions and data preprocessing, the TGx data can be used in predictive toxicology, where more advanced modelling techniques are applied. The large volume of molecular profiles produced by omics-based technologies allows the development and application of artificial intelligence (AI) methods in TGx. Indeed, the publicly available omics datasets are constantly increasing together with a plethora of different methods that are made available to facilitate their analysis, interpretation and the generation of accurate and stable predictive models. In this review, we present the state-of-the-art of data modelling applied to transcriptomics data in TGx. We show how the benchmark dose (BMD) analysis can be applied to TGx data. We review read across and adverse outcome pathways (AOP) modelling methodologies. We discuss how network-based approaches can be successfully employed to clarify the mechanism of action (MOA) or specific biomarkers of exposure. We also describe the main AI methodologies applied to TGx data to create predictive classification and regression models and we address current challenges. Finally, we present a short description of deep learning (DL) and data integration methodologies applied in these contexts. Modelling of TGx data represents a valuable tool for more accurate chemical safety assessment. This review is the third part of a three-article series on Transcriptomics in Toxicogenomics.