QSAR Application Toolbox Workflow

1. QSAR Application Toolbox Workflow Laboratory of Mathematical Chemistry, Bourgas University “Prof. Assen Zlatarov” Bulgaria

2. Outlook Description General scheme and workflow Basic functionalities Forming categories

3. The regulatory context • Animal testing as last resort under REACH • Use of alternatives without compromising the level of protection for human health and environment • Annex XI general provisions • Transparency of the methods as a key for regulatory acceptance

4. The regulatory context Annex XI of the REACH regulation Art 1.3: (..)Results of (Q)SARs may be used instead of testing when the following conditions are met: • results are derived from a (Q)SAR model whose scientific validity has been established, • the substance falls within the applicability domain of the (Q)SAR model, • results are adequate for the purpose of classification and labelling and/or risk assessment, and • adequate and reliable documentation of the applied method is provided.

5. The regulatory context Annex XI – Use of (Q)SARs Satisfies OECD Principles and is documented as such i.e. QMRF (QSAR Model Reporting Format) Applicability domain Is the scope of the model relevant for the substance of interest? Reliable (Q)SAR result (Q)SAR model applicable to query chemical Scientifically valid QSAR method Adequate (Q)SAR result (Q)SAR model relevant to regulatory purpose Result needs to documented in appropriate format, i.e. QPRF (QSAR Prediction Reporting Format) i.e. REACH endpoint

6. The regulatory context Scientific validity Five OECD principles for assessing (Q)SAR model’s scientific validity: • A defined endpoint • An unambiguous algorithm • A defined domain of applicability • Appropriate measures of goodness-of-fit, robustness and predictivity • A mechanistic interpretation, if possible

7. The concept • The QSAR Toolbox is a decision supporting tool for hazard assessment - predicting properties is only one of its functionalities • Toolbox is not a QSAR model and hence can not be compared with other QSAR models • Training sets (categories) for each prediction are defined dynamically as compared to other (Q)SAR model which have rigid training sets • Each estimated value can be individually justified based on: • Category hypothesis (justification) and consistency • Quality of measured data and • Computational method used for grouping and data gap filling

8. The concept • Toolbox helps registrants and authorities to • Use the methodologies to group chemicals into categories and • Refine and expand the categories approach • Provide a mechanistic transparency of the formed categories • Fill data gaps by read-across, trend analysis and (Q)SARs • Ensure uniform application of read-across • Support the regulatory use of (Q)SAR approach • Improve the regulatory acceptance of (Q)SAR methods

9. The concept • (Q)SAR Toolbox is a central tool for non-test data in ECHA and OECD • ECHA and OECD coordinate the Toolbox development

10. The concept • It is developed under the continuing peer review of: • Member state countries, • Regulatory agencies • Chemical industry and NGOs • The predictions are getting acceptance by toxicologists and regulators due to the: • International peer review process for developing the system and • Mechanistic transparency of the results • The system is freely available and maintained in the public domain by OECD

11. History • Phase I - The first version (2005 - 2008) • Emphasizes technological proof-of-concept • Released in 2008 • Developed by LMC • Phase II (2008 - 2012) • More comprehensive Toolbox which fully implements the capabilities of the first version • Second version released in 2010 • Developed by LMC, subcontractors: LJMU, Lhasa Ltd and TNO • Third version released in 2012 • Maintenance 2013 - v. 3.2 in January 2014 • Version 3.3.1 - released in December 2014 • Version 3.3.2 - released in February 2015 • Version 3.3.5 - released in June 30, 2015 • Version 3.4 - released in July, 2016

12. History • Phase III (2014 – 2019 + 4 years maintenance) • Toolbox v.4.x • Significant focus on streamlining • Building automated and standardized workflows for selected endpoints • Migrating to a new IT platform • Knowledge and data rationalization and curation • Implementation of Ontology • Implementation of knowledge and data on ADME • Implementation of AOPs • Developed by LMC, subcontractors: LJMU and Lhasa Ltd

13. Main Toolbox Supporters • OECD • European Chemicals Agency • US EPA, OPP • US EPA, OPPTs • US EPA, NHEERL • Environment Canada • Health Canada • NITE Japan • NIES Japan • Danish EPA • UBA Germany • NICNAS Australia • DEWNA Australia • ISS Italy • Fraunhofer Germany • BfR Germany • Cefic • Oasis • L’Oreal • DuPont • Givaudan • Dow chemicals • BASF • ExxonMobil • 3M • Firmenich SV • SRC, Syracuse • Unilever • Multicase • ChemAxon • International QSAR Foundation

14. Download statistic • Downloads (version 2.1): • 1496 downloads of standalone version (July 15, 2011) • 171 downloads of server based version (July 15, 2011) • Downloads (version 2.2): • 2051 downloads of standalone version (July 15 – Feb. 06, 2012) • 424 downloads of server based version (Feb. 06, 2012) • 62 automatic updates (Feb. 06, 2012) • Downloads (version 3.x): March 2017 • 11264: Total number of user accounts • 10514: Activated user accounts • 10373: Users that have logged in at least once • 11251: Distinct IP addresses from which a Toolbox 3 has been downloaded • Downloads (version 4.x): February 2018 • 3148: Downloads by user • 3388: Downloads by IP Adress • 3969: Downloads by user + IP Adress • 12634: Total active users (new active users since 04.04.2017: 2150)

15. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

16. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

17. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

18. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

19. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

20. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

21. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

22. Download statistics of QSAR Toolbox 4.x by registered users worldwide (February 2018)

23. QSAR and read-across based submissions to the ECHA For existing substances at or above 1000 tpa* (2011 ECHA report) ENV = environmental endpoint; HH = human health endpoint *H. Spielmann et al. ATLA 39, 481–493, 2011

24. Outlook Description General scheme and workflow Basic functionalities Forming categories

25. General Scheme • Theoretical knowledge • Empiric knowledge • Computational methods • Information technologies.

26. Input

27. Input • Is the chemical included in regulatory or chemical categories? • Could this chemical interact with DNA or specific proteins? • Could this chemical cause adverse effects? • Is the effect due to parent chemical or its metabolites? Knowledge

28. Input Knowledge Experimental Data • Are data available for assessed endpoints of target chemical? • Is information for the data sources available?

29. Input Knowledge Experimental Data • Search for possible analogues using existing categorization schemes • Group chemicals based on common chemical/toxicological mechanisms and/or metabolism • Design a data matrix of a chemical category • Set the endpoints hierarchy in the data matrix Categorization tools

30. Input Knowledge Experimental Data • Read-across • Trend Analysis • (Q)SAR Data gap filling tools Categorization tools

31. Input Knowledge Experimental Data • Read-across • Trend Analysis • (Q)SAR Data gap filling tools Categorization tools

32. Input Knowledge Experimental Data • Read-across • Trend Analysis • (Q)SAR Data gap filling tools Categorization tools

33. Input Knowledge Experimental Data Data gap filling tools Reporting tools Categorization tools

34. Input • IUCLID 6 interface: Web Services • Submission of in silico predictions from Toolbox to IUCLID 6 Knowledge Experimental Data IUCLID6 Data gap filling tools Reporting tools Categorization tools

35. Input • IUCLID 6 interface: Web Services • Transfer of data from IUCLID 6 to Toolbox Knowledge Experimental Data IUCLID6 Data gap filling tools Reporting tools Categorization tools

36. SystemWorkflow Knowledge Base IUCLID6 Data Base Chemical input Profiling Endpoints Category Definition Filling data gap Report Data gap filling tools Reporting tools Categorization tools

37. Outlook Description General scheme and workflow Basic functionalities Forming categories

38. What can we do with Toolbox? Predictions and much more… • Searching for available experimental data • Profiling chemicals • Grouping analogues • Simulating metabolites • Filling data gaps with prediction workflows for (eco)toxicological endpoints 39

39. Keywords: TARGET CHEMICAL - chemical of interest MODULE – a Toolbox module is a section dedicated to specific actions and options WORKFLOW – the use, in combination, of the different modules (e.g. prediction workflow: from input to report) PROFILER -algorithm (rule set) for the identification of specific features of the chemicals. Several types of profilers are available, such as structural (e.g. organic functional groups) and mechanistic (e.g. Protein binding by OECD) profilers. CATEGORY – “group” of substances sharing same characteristics (e.g. the same functional groups or mode of action). In a typical Toolbox workflow, it consists of the target chemical and its analogues gathered according to the selected profilers ENDPOINT TREE –Endpointsare structured in a branched scheme, from a broader level (Phys-Chem properties, Environmental Fate and transport, Ecotoxicology, Human health hazard) to a more detailed one (e.g. EC3 in LLNA test under Human health hazard-Skin sensitization) DATA MATRIX – Table reporting the chemical(s) and data (experimental results, profilers outcomes, predictions). Each chemical is in a different column and each data in a different row 40

40. The interface Toolbox modules 1 2 3 4 5 6 Input Profiling Data Category definition Data gap filling Report

41. The interface Endpoint tree • Branched scheme that reports the information in different levels • Each branch corresponds to one cell in the data matrix

42. The interface Document tree • The document tree: • lists the actions performed by the user • can be browsed to go back and forward in the workflow

43. The interface Document tree manipulation • Allows to move up and down through document levels and do different actions • The name of the document level shows the main action that is done on current level Move to upper level and start different subcategorization 44

44. The interface Data matrix manipulation • Allows rearrangement of the columns • Filtering parameters and experimental data which to appear for the analogues is possible Select a chemical and drag it next to the target 45

45. The interface Data matrix manipulation • Allows rearrangement of the columns • Filtering parameters and experimental data which to appear for the analogues is possible 46

46. Toolbox modules: • Input • Profiling • Data • Category definition • Data Gap Filling • Report

47. Toolbox modules: • Input • Structure - QA • Endpoint definition • Query tool (separate presentation – see “QSAR_Toolbox_Customized_search_QT_TB42.ppt”) • Profiling • Data • Category definition • Data Gap Filling • Report

48. Input • Chemical can be loaded in Toolbox by: • CAS # • Name • SMILES • Selection from a list, database or inventory • The chemical identification related to the correspondence between substance identity and associated data in Toolbox, currently is based on: • CAS # • SMILES • Predefined substance type • Composition: • Constituents • Additives • Impurities

49. Input Structure Expanded chemical structure CAS 50-00-0

50. Input Structure Expanded chemical structure Explain of QA label CAS 50-00-0 CAS-SMILES relation