CombesR.D., and JudsonP. (1995). The use of artificial intelligence systems for predicting toxicity.Pesticide Science45, 179–194.
3.
RichardA.M. (1994). Application of SAR methods to non-congeneric databases associated with carcinogenicity and mutagenicity: issues and approaches.Mutation Research305, 73–97.
4.
SandersonD.M., and EarnshawC.G. (1991). Computer prediction of possible toxic action from chemical structure; the DEREK system.Human and Experimental Toxicology10, 261–273.
5.
RidingsJ.E., BarrattM.D., CaryR., EarnshawC.G., EggingtonE., EllisM.K., JudsonP.N., LangowskiJ.J., MarchantC.A., PayneM.P., WatsonW.P., and YihT.D. (1996). Computer prediction of possible toxic action from chemical structure; an update on the DEREK system.Toxicology106, 267–279.
6.
DupuisG., and BenezraC. (1982). Contact Dermatitis to Simple Chemicals: a Molecular Approach, pp. 66–68. New York: Marcel Dekker.
7.
BasketterD.A., RobertsD.W., CroninM., and ScholesE.W. (1992). The value of the local lymph node assay in quantitative structure-activity investigations.Contact Dermatitis27, 137–142.
8.
FlynnG.L. (1990). Physicochemical determinants of skin absorption. In Principles of Route-to-Route Extrapolation for Risk Assessment (ed. GerrityT.R., HenryC.J.), pp. 93–127. New York: Elsevier Science Publishing Co.
9.
BarrattM.D., BasketterD.A., ChamberlainM., PayneM.P., AdmansG.D., and LangowskiJ.J. (1994). Development of an expert system rulebase for identifying contact allergens.Toxicology in Vitro8, 837–839.
10.
BarrattM.D., BasketterD.A., ChamberlainM., AdmansG.D., and LangowskiJ.J. (1994). An expert system rulebase for identifying contact allergens.Toxicology in Vitro8, 1053–1060.
11.
KimberI., BasketterD.A., Briatico-VangosaG., CookmanG., EvansP., LovelessS., and PauluhnJ. (1997). Skin and Respiratory Sensitizers: Reference Chemicals Data Bank.ECETOC Monograph. Brussels: European Centre for Ecotoxicology and Toxicology of Chemicals, in press.
12.
de SilvaO., BasketterD.A., BarrattM.D., CorsiniE., CroninM.T.D., DasP.K., DegwertJ., EnkA., GarrigueJ.L., HauserC., KimberI., LepoittevinJ-P., PeguetJ., and PonecM. (1996). Alternative methods for skin sensitisation testing. The report and recommendations of ECVAM workshop 19.ATLA24, 683–705.
13.
KayserD., and SchledeE. (1995). Chemikalien und Kontaktallergie — eine bewertende Zusammenstellung, 152 pp. Munich: MMV Medzin Verlag.
14.
BagleyD.M., BothamP.A., GardnerJ.R., HollandG., KreilingR., LewisR.W., StringerD.A., and WalkerA.P. (1992). Eye irritation: reference chemicals data bank.Toxicology in Vitro6, 487–491.
15.
BagleyD.M., GardnerJ.R., HollandG., LewisR.W., RegnierJ-F., StringerD.A., and WalkerA.P. (1996). Skin irritation: reference chemicals data bank.Toxicology in Vitro10, 1–6.
16.
SugaiS., MurataK., KitagakiT., and TomitaI. (1991). Studies of eye irritation caused by chemicals in rabbits: structure-activity relationships and in vitro approaches to primary eye irritation of salicylates in rabbits.Journal of Toxicological Science16, 111–130.
17.
AshbyJ., and TennantR.W. (1988). Chemical structure, Salmonella mutagenicity and extent of carcinogenicity as indicators of genotoxic carcinogenesis among 222 chemicals tested in rodents by the US NCI/NTP.Mutation Research204, 17–115.
18.
LongA., and CombesR.D. (1995). Using DEREK to predict the activity of some carcinogens/mutagens found in food.Toxicology in Vitro9, 563–569.
19.
GoldL.S., SloneT.H., BackmanG.M., MagawR., Da CostaM., LopiperoP., BlumenthalM., and AmesB.N. (1987). Second chronological supplement to the carcinogenic potency database: standardized results of animal bioassays published through December 1984 and by the National Toxicology Program through May 1986.Environmental Health Perspectives74, 237–329.
20.
GoldL.S., SloneT.H., BackmanG.M., EisenbergM., Da CostaM., WongN.B., ManleyN.B., RohrbachL., and AmesB.N. (1990). Third chronological supplement to the carcinogenic potency database: standardized results of animal bioassays published through December 1986 and by the National Toxicology Program through June 1987.Environmental Health Perspectives84, 215–286.
21.
AshbyJ., and PatonD. (1993). The influence of chemical structure on the extent and sites of carcinogenesis for 522 rodent carcinogens and 55 different human carcinogen exposures.Mutation Research286, 3–74.
22.
BarrattM.D. (1995). Quantitative structure-activity relationships for skin permeability.Toxicology in Vitro9, 27–37.
23.
KlopmanG. (1984). Artificial intelligence approach to structure-activity studies. Computer automated structure evaluation of biological activity of organic molecules.Journal of the American Chemical Society106, 7315–7320.
KlopmanG., and RosenkranzH.S. (1994). Approaches to SAR in carcinogenesis and mutagenesis. Prediction of carcinogenicity/mutagenicity using Multi-CASE.Mutation Research305, 33–46.
26.
MalacarneD., PesentiR., PaolucciM., and ParodiS. (1993). Relationship between molecular connectivity and carcinogenic activity: a confirmation with a new software program based on graph theory.Environmental Health Perspectives101, 332–342.
27.
DawsonD.A., SchultzT.W., and HunterR.S. (1996). Developmental toxicity of carboxylic acids to Xenopus embryos: a quantitative structure-activity relationship and computer-automated structure evaluation.Teratogenesis, Carcinogenesis and Mutagenesis16, 109–124.
28.
ParkeD.V., IoannidesC., and LewisD.F.V. (1990). The safety evaluation of drugs and chemicals by the use of computer optimised molecular parametric analysis of chemical toxicity (COMPACT).ATLA18, 91–102.
29.
LewisD.F.V. (1996). The Cytochromes P450: Structure, Function and Mechanism, 348 pp. London: Taylor & Francis.
30.
LewisD.F.V., and LakeB.G. (1996). Molecular modelling of CYP1A subfamily members based on an alignment with CYP102: rationalization of CYP1A substrate specificity in terms of active site amino acid residues.Xenobiotica26, 723–753.
31.
LewisD.F.V., and LakeB.G. (1993). The interaction of some peroxisome proliferators with the mouse liver peroxisome proliferator-activated receptor (ppar): a molecular modelling and quantitative structure-activity relationship study.Xenobiotica23, 79–96.
32.
LewisD.F.V., IoannidesC., and ParkeD.V. (1994). Molecular modelling of cytochrome CYP1A1: a putative access channel explains differences in induction potency between the isomers benzo[a]pyrene and benzo[e]pyrene, and 2- and 4-acetylaminofluorene.Toxicology Letters71, 235–243.
33.
ZhouZ., and ParrR.G. (1990). Activation hardness: new index for describing the orientation of electrophilic aromatic substitution.Journal of the American Chemical Society112, 5720–5724.
34.
LewisD.F.V., IoannidesC., WalkerR., and ParkeD.V. (1995). Quantitative structure-activity relationships and COMPACT analysis of food mutagens.Food Additives and Contaminants12, 715–724.
35.
LewisD.F.V. (1997). Quantitative structure-activity relationships in substrates, inducers and inhibitors of cytochrome P4501 (CYP1).Drug Metabolism Reviews, in press.
36.
LewisD.F.V., IoannidesC., and ParkeD.V. (1990). A prospective toxicity evaluation (COMPACT) on 40 chemicals currently being tested by the National Toxicology Program.Mutagenesis5, 433–435.
37.
LewisD.V.F., IoannidesC., and ParkeD.V. (1993). Validation of a novel molecular orbital approach (COMPACT) for the prospective safety evaluation of chemicals, by comparison with rodent carcinogenicity and Salmonella mutagenicity data evaluated by the US NCI/NTP.Mutation Research291, 61–77.
38.
BrownS.J., RajaA.A., and LewisD.F.V. (1994). A comparison between COMPACT and Hazardexpert evaluations for 80 chemicals tested by the NTP/NCI rodent bioassy.ATLA22, 482–500.
39.
EnsleinK. (1993). The future of toxicity prediction with QSAR.In Vitro Toxicology6, 163–169.
40.
EnsleinK., GombarV.K., and BlakeB.W. (1994). Use of SAR in computer-assisted prediction of carcinogenicity and mutagenicity of chemicals by the TOPKAT program.Mutation Research305, 47–61.
41.
EnsleinK. (1988). An overview of structure-activity relationships as an alternative to testing in animals for carcinogenicity, mutagenicity, dermal and eye irritation, and acute oral toxicity.Toxicology and Industrial Health4, 479–498.
42.
Anon. (1993). Toxicological Principles for the Safety Assessment of Direct Food Additives and Color Additives used in Food (Red Book II). 235 pp. Washington, DC: US Food and Drug Administration.
43.
SmithingM.P., and DarvasF. (1992). Hazardexpert: an expert system for predicting chemical toxicity. In Food Safety Assessment (ed. Fin-layJ.W., RobinsonS.F., ArmstrongD.J.), pp. 191–200. Washington: American Chemical Society.
44.
WooY-T., LaiD., ArgusM., and ArcosJ. (1995). Development of structure-activity relationship rules for predicting carcinogenic potential of chemicals.Toxicology Letters79, 219–228.
45.
ArcosJ.C., and ArgusM.F. (1974). Polynuclear compounds. In Chemical Induction of Cancer, Vol. IIA (ed. ArgusJ.C., ArgusM.F., WooY-T., LaiD.Y.), 387 pp. New York: Academic Press.
46.
ArcosJ.C., and ArgusM.F. (1974). Aromatic amines and azo compounds. In Chemical Induction of Cancer, Vol. IIB (ed. ArgusJ.C., ArgusM.F., WooY-T., LaiD.Y.), 379 pp. New York: Academic Press.
47.
ArcosJ.C., WooY-T., & ArgusM.F. (1982). Aliphatic carcinogens. In Chemical Induction of Cancer, Vol. IIIA (ed. ArgusJ.C., ArgusM.F., WooY-T., LaiD.Y.), 780 pp. New York: Academic Press.
48.
WooY-T., LaiD.Y., ArcosJ.C., & ArgusM.F. (1985). Aliphatic and polyhalogenated carcinogens. In Chemical Induction of Cancer, Vol. IIIB (ed. ArgusJ.C., ArgusM.F., WooY-T., LaiD.Y.), 598 pp. New York: Academic Press.
49.
WooY-T., LaiD.Y., ArcosJ.C., & ArgusM.F. (1988). Natural, metal, fiber and macromolecular carcinogens. In Chemical Induction of Cancer, Vol. IIIC (ed. ArgusJ.C., ArgusM.F., WooY-T., LaiD.Y.), 869 pp. New York: Academic Press.
50.
Anon. (1976). Toxic Substances Control Act, United States Public Law 94–469, 90 Stat. 2003, October 11, 1976. Washington, DC: US Federal Government.
51.
AuerC.M., and GouldD.H. (1987). Carcinogenicity assessment and the role of structure-activity relationships (SAR) analysis under TSCA section 5.Environmental Carcinogenesis ReviewC5, 27–71.
52.
WooY-T., LaiD., ArgusM., and ArcosJ. (1996). Carcinogenicity of organophosphorus pesticides/compounds: an analysis of their structure-activity relationships.Environmental Carcinogenesis & Ecotoxicology ReviewsC14, 1–42.
53.
PurdyR. (1996). A mechanism mediated model for carcinogenicity: model content and prediction of the outcome of rodent carcinogenicity bioas-says currently being conducted on 25 organic chemicals.Environmental Health Perspectives104, 1085–1094.
54.
KrauseP., FoxJ., and JudsonP. (1993/4). An argumentation-based approach to risk assessment.IMA Journal of Mathematics Applied in Business and Industry5, 249–263.
55.
LangowskiJ.J., JudsonP.N., TonnelierC.A.G., and PatelM. (1997). StAR: a knowledge-based computer system for carcinogenic risk assessment.Developments in Animal and Veterinary Science, in press.
56.
KrauseP.J., AmblerS.J., Elvang-GøranssonM., and FoxJ. (1995). A logic of argumentation for reasoning under uncertainty.Computational Intelligence11, 113–131.
57.
JudsonP.N. (1994). Rule induction for systems predicting biological activity.Journal of Chemical Informatics and Computer Science34, 148–153.
58.
JudsonP.N. (1992). QSAR and expert systems in the prediction of biological activity.Pesticide Science365, 155–160.
59.
JudsonP.N. (1992). Structural similarity searching using descriptors developed for structure-activity relationship studies.Journal of Chemical Informatics and Computer Science32, 657–663.
60.
KhabazaT. (1997). Data mining for toxic hazard analysis.Data Mining and Knowledge Discovery, in press.
61.
KingR.D., MuggletonS.H., SrinivasanA., and SternbergM.J.E. (1996). Structure-activity relationships derived by machine learning: the use of atoms and their bond connectivities to predict mutagenicity by inductive logic programming.Proceedings of the National Academy of Sciences USA93, 438–442.
62.
KingR.D., and SrinivasanA. (1996). Prediction of rodent carcinogenicity bioasssays from molecular structure using inductive logic programming.Environmental Health Perspectives104, 1031–1040.
63.
BenigniR., and GiulianiA. (1986). Quantitative structure-activity relationship (QSAR) studies of mutagens and carcinogens.Medicinal Research Reviews16, 267–284.
64.
TennantR.W., SpaldingJ., StasiewiczS., and AshbyJ. (1990). Prediction of the outcome of rodent carcinogenicity bioassays currently being conducted on 44 chemicals by the National Toxicology Program.Mutagenesis5, 3–14.
65.
AshbyJ., TennantR.W., ZeigerE., and StasiewiczS. (1989). Classification according to chemical structure, mutagenicity to Salmonella and level of carcinogenicity of a further 42 chemicals tested for carcinogenicity by the US National Toxicology Program.Mutation Research223, 73–103.
66.
JonesJ.D., and EasterlyC.E. (1991). On the rodent bioassays currently being conducted on 44 chemicals: a RASH analysis to predict test results from the National Toxicology Program.Mutagenesis6, 507–514.
67.
RosenkranzH.S., and KlopmanG. (1990). Prediction of the carcinogenicity in rodents of 42 chemicals currently being tested by the US National Toxicology Program: structure-activity correlations.Mutagenesis5, 425–432.
68.
EnsleinK., BlakeB.W., and BorgstedtH.H. (1990). Prediction of probability of carcinogenicity for a set of ongoing NTP bioassays.Mutagenesis5, 305–306.
69.
BakaleG., and McCrearyR.D. (1992). Prospective Ke screening of potential carcinogens being tested in rodents by the US National Toxicology Program.Mutagenesis7, 91–94.
70.
BenigniR. (1991). QSAR prediction of rodent carcinogenity for a set of chemicals currently bioassayed by the US National Toxicology Program.Mutagenesis6, 423–425.
71.
BenigniR., Cotta-RamusinoM., AndreoliC., and GiulianiA. (1992). Electrophilicity as measured by Ke: molecular determinants, relationship with other physical chemical and quantum mechanical parameters, and ability to predict rodent carcinogenicity.Carcinogenesis13, 547–553.
72.
HilemanB. (1993). “Expert intuition” tops in test of carcinogenicity prediction.Chemical Engineering News21, 35–37.
73.
AshbyJ., and TennantR.W. (1994). Prediction of rodent carcinogenicity for 44 chemicals: results.Mutagenesis9, 7–15.
74.
BenigniR. (1995). Predicting chemical carcinogenesis in rodents: the state of the art in light of a comparative exercise.Mutation Research334, 103–113.
75.
BristolD.W., WachsmanJ.T., and GreenwellA. (1996). The NIEHS predictive-toxicology evaluation project.Environmental Health Perspectives104, Suppl. 5, 1001–1010.
76.
SelkirkJ.K., and SowardS.M. (1993). Compendium of abstracts from long-term cancer studies reported by the National Toxicology Program from 1976 to 1992.Environmental Health Perspectives101, Suppl. 1, 295 pp.
77.
BarrattM.D., CastellJ.V., ChamberlainM., CombesR.D., DeardenJ.C., FentemJ.H., GernerI., GiulianiA., GrayT.J.B., LivingstoneD.J., ProvanW.M., RuttenA.A.J.J.L., VerhaarH.J.M., and ZbindenP. (1995). The integrated use of alternative approaches for predicting toxic hazard. The report and recommendations of ECVAM workshop 8.ATLA23, 410–429.
78.
BristolD.W. (1995). Summary and recommendations: activity classification and structure-activity relationship modelling for human health risk assessment of toxic substances.Toxicology Letters79, 265–280.
79.
Anon. (1996). Use of (quantitative) structure-activity relationships (Q)SARs in risk assessment. In Technical Guidance Documents in Support of the Commission Directive 93/67/EEC on Risk Assessment for New Notified Substances and the Commission Regulation (EC) 1488/94 on Risk Assessment for Existing Substances, pp. 517–526. Luxembourg: CEC.
80.
BlaauboerB.J., BaylissM.K., CastellJ.V., EveloC.T.A., FrazierJ.M., GroenK., GuldenM., GuillouzoA., HissinkA.M., HoustonJ.B., JohansonG., de JonghJ., KedderisG.L., ReinhardtC.A., van de SandtJ.J.M., and SeminoG. (1996). The use of biokinetics and in vitro methods in toxicological risk evaluation. The report and recommendations of ECVAM workshop 15.ATLA24, 473–497.
