Can the In Vivo Maximum Tolerated Dose be Predicted Using In Vitro Techniques? A Working Hypothesis 1

Abstract

All new chemical entities synthesised in our laboratories have routinely been subjected to in vitro toxicity tests. Out of curiosity, we established a working hypothesis in which the in vitro data could be empirically transformed to predict the in vivo four-week standard maximum tolerated dose (MTD) studies in rats and dogs.

As a first step to verifying this hypothesis, we report here the findings of an in vitro cytotoxicity study of 25 compounds randomly selected from our files, possessing a wide range of pharmacological activities and for which data from standard four-week MTD studies were available. Single blind in vitro toxicity studies in three carefully selected types of primary and cell line cultures were carried out. In vitro CT50 (concentration inducing 50% cell death) and CT100 (concentration inducing 100% cell death) values were obtained for each of the three cell types and, using empirical assumptions, these results were used to predict the MTD in vivo in the rat and dog. The actual in vivo threshold and toxic doses were obtained from the MTD study reports. The in vivo toxicity values predicted from the in vitro toxicity results with this series of 25 compounds showed a better than 80% correlation with the actual in vivo results obtained in the MTD studies.

Whether or not in vitro cytotoxicity predictions are ultimately found to be directly and consistently related to the MTD in vivo for all pharmacological classes of compounds will require many additional studies, but it is hoped that these results will stimulate the necessary research effort required to answer this question.

Keywords

MTD in vitro cytotoxicity in vivo toxicity correlation hypothesis

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References

Mehlman

M.A.

, Pfitzer

E.A.

, and Scala

R.A.

(1989). A report on methods to reduce, refine and replace animal testing in industrial toxicology laboratories. Cell Biology and Toxicology 5, 349–358.

Southee

J.A.

, and Balls

(1990). Replacement alternative methods in drug development. In Pharmaceutical Manufacturing International (ed. Barber

M.S.

), 3rd edn, pp. 41–43. London: Sterling Publications International Limited.

Gad

S.C.

(1990). Recent developments in replacing, reducing and refining animal use in toxicology research and testing. Fundamental and Applied Toxicology 15, 8–16.

Bellemann

(1980). Primary monolayer culture of liver parenchymal cells and kidney cortical tubules as a useful new model for biochemical pharmacology and toxicology. Archives of Toxicology 44, 63–84.

Flint

O.P.

, and Orton

T.C.

(1984). An in vitro assay for teratogens with cultures of rat embryo midbrain and limb bud cells. Toxicology and Applied Pharmacology 76, 383–395.

Ray

V.A.

(1979). Application of microbial and mammalian cells to the assessment of mutagenicity. Pharmacological Reviews 30, 537–546.

Kennah

H.E.

, Albulescu

, Hignet

, and Barrow

C.S.

(1989). A critical evaluation of predicting ocular irritancy potential from an in vitro cytotoxicity assay. Fundamental and Applied Toxicology 12, 281–290.

Rowan

A.N.

(1987). Scientific perspectives in the development of alternatives in toxicology. Comments Toxicology 1, 275–288.

Ekwall

(1980). Screening of toxic compounds in tissue culture. Toxicology 17, 127–142.

10.

Smith

J.H.

(1988). The use of renal cortical slices from the Fischer 344 rat as an in vitro model to evaluate nephrotoxicity. Fundamental and Applied Toxicology 11, 132–142.

11.

Maier

(1988). Development of in vitro toxicity tests with cultures of freshly isolated hepatocytes. Experientia 44, 807–817.

12.

Butterworth

B.E.

, Oliver

T.S.

, Earle

, Loury

, White

R.D.

, Doolittle

D.J.

, Working

P.K.

, Cattley

R.C.

, Jirtle

, Michalopoulos

, and Strom

(1989). Use of primary cultures of human hepatocytes in toxicology studies. Cancer Research 49, 1075–1084.

13.

Ekwall

, Bondesson

, Castell

J.V.

, Gómez-Lechón

M.J.

, Högberg

, Jover

, Ponsoda

, Romert

, Stenberg

, and Walum

(1989). Cytotoxicity evaluation of the first ten MEIC chemicals: acute lethal toxicity in man predicted by cytotoxicity in five cellular assays and by oral LD50 tests in rodents. ATLA 17, 83–100.

14.

Fry

J.R.

, Garle

M.J.

, and Hammond

A.M.

(1988). Choice of acute toxicity measures for comparison of in vivo/in vitro toxicity. ATLA 16, 175–179.

15.

Lumley

, and Walker

S.R.

(1985). The value of chronic animal toxicology studies of pharmaceutical compounds: a retrospective analysis. Fundamental and Applied Toxicology 5, 1007–1024.

16.

McConnell

E.E.

(1989). The maximum tolerated dose: the debate. Journal of the American College of Toxicology 8, 1115–1120.

17.

Moldeus

, Högberg

, and Orrenius

(1978). Isolation and use of liver cells. Methods in Enzymology 52, 60–71.

18.

Ekwall

, and Ekwall

(1988). Comments on the use of diverse cell systems in toxicity testing. ATLA 15, 193–200.

19.

Bondesson

, Ekwall

, Hellberg

, Romert

, Stenberg

, and Walum

(1989). MEIC: a new international multicenter project to evaluate the relevance to human toxicity of in vitro cytotoxicity tests. Cell Biology and Toxicology 5, 331–347.

20.

Willson

R.A.

, Hall

, and Hart

(1988). Oxmetidine (H₂ receptor antagonist) induced cytotoxicity in isolated rat hepatocytes. Journal of Applied Toxicology 8, 223–225.