In Silico Prediction of Human Clinical Pharmacokinetics with ANDROMEDA by Prosilico: Predictions for an Established Benchmarking Data Set,a Modern Small Drug Data Set,and a Comparison with Laboratory Methods

Abstract

There is an ongoing aim to replace animal and in vitro laboratory models with in silico methods. Such replacement requires the successful validation and comparably good performance of the alternative methods. We have developed an in silico prediction system for human clinical pharmacokinetics, based on machine learning, conformal prediction and a new physiologically-based pharmacokinetic model, i.e. ANDROMEDA. The objectives of this study were: a) to evaluate how well ANDROMEDA predicts the human clinical pharmacokinetics of a previously proposed benchmarking data set comprising 24 physicochemically diverse drugs and 28 small drug molecules new to the market in 2021; b) to compare its predictive performance with that of laboratory methods; and c) to investigate and describe the pharmacokinetic characteristics of the modern drugs. Median and maximum prediction errors for the selected major parameters were ca 1.2 to 2.5-fold and 16-fold for both data sets, respectively. Prediction accuracy was on par with, or better than, the best laboratory-based prediction methods (superior performance for a vast majority of the comparisons), and the prediction range was considerably broader. The modern drugs have higher average molecular weight than those in the benchmarking set from 15 years earlier (ca 200 g/mol higher), and were predicted to (generally) have relatively complex pharmacokinetics, including permeability and dissolution limitations and significant renal, biliary and/or gut-wall elimination. In conclusion, the results were overall better than those obtained with laboratory methods, and thus serve to further validate the ANDROMEDA in silico system for the prediction of human clinical pharmacokinetics of modern and physicochemically diverse drugs.

Keywords

absorption biopharmaceutics conformal prediction excretion machine learning metabolism pharmacokinetics prediction

Get full access to this article

View all access options for this article.

References

Poulin

Jones

RDO

Jones

, et al. PHRMA CPCDC initiative on predictive models of human pharmacokinetics, Part 5: Prediction of plasma concentration–time profiles in human by using the physiologically-based pharmacokinetic modeling approach. J Pharm Sci 2011; 100: 4127–4157.

Miljković

Martinsson

Obrezanova

, et al. Machine learning models for human in vivo pharmacokinetic parameters with in-house validation. Mol Pharm 2021; 18: 4520–4530.

Fuse

Tanii

Kurata

, et al. Unpredicted clinical pharmacology of UCN-01 caused by specific binding to human alpha1-acid glycoprotein. Cancer Res 1998; 58: 3248–3253.

Fagerholm

Hellberg

Spjuth

. Advances in predictions of oral bioavailability of candidate drugs in man with new machine learning methodology. Molecules 2021; 26: 2572.

Stringer

Nicklin

Houston

. Reliability of human cryopreserved hepatocytes and liver microsomes as in vitro systems to predict metabolic clearance. Xenobiotica 2008; 38: 1313–1329.

Sohlenius-Sternbeck

A-K

Afzelius

Prusis

, et al. Evaluation of the human prediction of clearance from hepatocyte and microsome intrinsic clearance for 52 drug compounds. Xenobiotica 2010; 40: 637–649.

Fagerholm

Spjuth

Hellberg

. The impact of reference data selection for the prediction accuracy of intrinsic hepatic metabolic clearance. J Pharm Sci 2022; 111: 2645–2649.

Skolnik

Lin

Wang

, et al. Towards prediction of in vivo intestinal absorption using a 96-well Caco-2 assay. J Pharm Sci 2010; 99: 3246–3265.

Fagerholm

Hellberg

Alvarsson

, et al. In silico prediction of volume of distribution of drugs in man using conformal prediction performs on par with animal data-based models. Xenobiotica 2021; 51: 1366–1371.

10.

Vovk

Gammerman

Shafer

. Algorithmic learning in a random world. New York: Springer Science & Business Media, 2005, 332 pp.

11.

Norinder

Carlsson

Boyer

, et al. Introducing conformal prediction in predictive modeling. A transparent and flexible alternative to applicability domain determination. J Chem Inf Model 2014; 54: 1596–1603.

12.

Norinder

Carlsson

Boyer

, et al. Introducing conformal prediction in predictive modeling for regulatory purposes. A transparent and flexible alternative to applicability domain determination. Reg Toxicol Pharmacol 2015; 71: 279–284.

13.

Norinder

Rybacka

Andersson

. Conformal prediction to define applicability domain — A case study on predicting ER and AR binding. SAR QSAR Environ Res 2016; 27: 303–316.

14.

Alvarsson

Arvidsson McShane

Norinder

, et al. Predicting with confidence: Using conformal prediction in drug discovery. J Pharm Sci 2021; 110: 42–49.

15.

Fagerholm

Hellberg

Alvarsson

, et al. In silico predictions of the human pharmacokinetics/toxicokinetics of 65 chemicals from various classes using conformal prediction methodology. Xenobiotica 2021; 51: 1366–1371.

16.

Fagerholm

Hellberg

Alvarsson

, et al. In silico predictions of the gastrointestinal uptake of macrocycles in man using conformal prediction methodology. J Pharm Sci 2022; 111: 2614–2619.

17.

Sköld

Winiwarter

Wernevik

, et al. Presentation of a structurally diverse and commercially available drug data set for correlation and benchmarking studies. J Med Chem 2006; 49: 6660–6671.

18.

Waring

. Defining optimum lipophilicity and molecular weight ranges for drug candidates — Molecular weight dependent lower log D limits based on permeability. Bioorg Med Chem Letters 2009; 19: 2844–2851.

19.

Fagerholm

. Prediction of human pharmacokinetics — Renal metabolic and excretion clearance. J Pharm Pharmacol 2007; 59: 1463–1471.

20.

Fagerholm

. The role of permeability in drug ADME/PK, interactions and toxicity — Presentation of a permeability-based classification system (PCS) for prediction of ADME/PK in humans. Pharm Res 2008; 25: 625–638.

21.

Fagerholm

. Prediction of human pharmacokinetics — Biliary and intestinal clearance and enterohepatic circulation. J Pharm Pharmacol 2008; 60: 535–542.

22.

McGinnity

Collington

Austin

, et al. Evaluation of human pharmacokinetics, therapeutic dose and exposure predictions using marketed oral drugs. Curr Drug Metab 2007; 8: 463–479.

23.

Thomas

Brightman

Gill

, et al. Simulation modelling of human intestinal absorption using Caco-2 permeability and kinetic solubility data for early drug discovery. J Pharm Sci 2008; 97: 4557–4574.

24.

Gertz

Houston

Galetin

. Physiologically based pharmacokinetic modeling of intestinal first-pass metabolism of CYP3A substrates with high intestinal extraction. Drug Metab Dispos 2011; 39: 1633–1642.

25.

Poulin

Kenny

Hop

CECA

, et al. In vitro–in vivo extrapolation of clearance: Modeling hepatic metabolic clearance of highly bound drugs and comparative assessment with existing calculation methods. J Pharm Sci 2012; 101: 838–851.

26.

Kimoto

Y-A

Kosa

, et al. Hepatobiliary clearance prediction: Species scaling from monkey, dog, and rat, and in vitro–in vivo extrapolation of sandwich-cultured human hepatocytes using 17 drugs. J Pharm Sci 2017; 106: 2795–2804.

27.

Mathialagan

Piotrowski

Tess

, et al. Quantitative prediction of human renal clearance and drug–drug interactions of organic anion transporter substrates using in vitro transport data: A relative activity factor approach. Drug Metab Dispos 2017; 45: 409–417.

28.

Yamagata

Zanelli

Gallemann

, et al. Comparison of methods for the prediction of human clearance from hepatocyte intrinsic clearance for a set of reference compounds and an external evaluation set. Xenobiotica 2017; 47: 741–751.

29.

Winiwarter

Ahlberg

Watson

, et al. In silico ADME in drug design — enhancing the impact. ADMET DMPK 2018; 6: 15–33.

30.

Varma

MVS

Obach

Rotter

, et al. Physicochemical space for optimum oral bioavailability: Contribution of human intestinal absorption and first-pass elimination. J Med Chem 2010; 53: 1098–1108.

31.

Musther

Olivares-Morales

Hatley

OJD

, et al.

Animal versus human oral drug bioavailability: Do they correlate?

Eur J Pharm Sci 2014; 57: 280–291.

32.

Aros Bio

. CPSign documentation, https://arosbio.com/cpsign/docs/latest/ (2021, accessed 9 November 2022).

33.

Chang

Lin

. LIBSVM: A library for support vector machines. ACM Trans Intell Syst Technol 2011; 2: 1–27.

34.

Fan

Chang

Hsieh

, et al. LIBLINEAR: A library for large linear classification. J Machine Learning Res 2008; 9: 1871–1874.

35.

Faulon

Churchwell

Visco

. The signature molecular descriptor. 2. Enumerating molecules from their extended valence sequences. J Chem Inf Comp Sci 2003; 43: 721–734.

36.

Willighagen

Mayfield

Alvarsson

, et al. The Chemistry Development Kit (CDK) v2.0: Atom typing, depiction, molecular formulas, and substructure searching. J Cheminformatics 2017; 9: 1–19.

37.

Carlsson

Eklund

Norinder

. Aggregated conformal prediction. In: Iliadis

Maglogiannis

Papadopoulos

, et al. (eds) Artificial intelligence applications and innovations, AIAI 2014. IFIP Advances in Information and Communication Technology, vol. 437. Springer, Berlin, Heidelberg: Springer, 2014.

38.

Hearst

Dumais

Osuna

, et al. Support vector machines. IEEE Intell Syst 1998; 13: 18–28.

39.

Alvarsson

Eklund

Andersson

, et al. Benchmarking study of parameter variation when using signature fingerprints together with support vector machines. J Chem Inf Model 2014; 54: 3211–3217.

40.

Fagerholm

Spjuth

Hellberg

. Comparison between lab variability and in silico prediction errors for the unbound fraction of drugs in human plasma. Xenobiotica 2021; 51: 1095–1100.

41.

Hellriegel

Bjornsson

Hauck

. Interpatient variability in bioavailability is related to the extent of absorption: Implications for bioavailability and bioequivalence studies. Clin Pharmacol Ther 1996; 60: 601–607.

42.

Lombardo

Waters

Argikar

, et al. Comprehensive assessment of human pharmacokinetic prediction based on in vivo animal pharmacokinetic data, part 1: Volume of distribution at steady state. J Clin Pharmacol 2013; 53: 167–177.

43.

Lombardo

Waters

Argikar

, et al. Comprehensive assessment of human pharmacokinetic prediction based on in vivo animal pharmacokinetic data, part 2: Clearance. J Clin Pharmacol 2013; 53: 178–191.

44.

Poulin

Kenny

Hop

CECA

45.

Yun

Tornero-Velez

Purucker

, et al. Evaluation of quantitative structure property relationship algorithms for predicting plasma protein binding in humans. Comput Toxicol 2021; 17: 100142.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.32 MB