Abstract: Nanomedicine development currently suffers from a lack of efficient tools to predict pharmacokinetic behavior without relying upon testing in large numbers of animals, impacting success rates and development costs. This work presents dendPoint, the first in silico model to predict the intravenous pharmacokinetics of dendrimers, a commonly explored drug vector, based on physicochemical properties. We have manually curated the largest relational database of dendrimer pharmacokinetic parameters and their structural/physicochemical properties. This was used to develop a machine learning-based model capable of accurately predicting pharmacokinetic parameters, including half-life, clearance, volume of distribution and dose recovered in the liver and urine. dendPoint successfully predicts dendrimer pharmacokinetic properties, achieving correlations of up to r = 0.83 and Q2 up to 0.68. dendPoint is freely available as a user-friendly web-service and database at http://biosig.unimelb.edu.au/dendpoint. This platform is ultimately expected to be used to guide dendrimer construct design and refinement prior to embarking on more time consuming and expensive in vivo testing

Ascher, David B.

Kaminskas, Lisa M.

Pires, Douglas E. V.

Scientific Reports

English

Apollo (Cambridge)

Supplementary MaterialsdendPoint: a web resource for dendrimerpharmacokinetics investigation and prediction Lisa M. Kaminskasa ,†,*, Douglas E.V. Piresb,c,d,†, David B. Ascherc,d,e,*a School of Biomedical Sciences, University of Queensland, St Lucia, Queensland, Australia;b School  of  Computing  and  Information  Systems,  University  of  Melbourne,  Melbourne,Victoria, Australia;c Computational  Biology  and  Clinical  Informatics,  Baker  Heart  and  Diabetes  Institute,Melbourne, Victoria, Australiad Structural  Biology  and  Bioinformatics,  Department  of  Biochemistry,  Bio21  Institute,University of Melbourne, Melbourne, Victoria, Australiae Department of Biochemistry, University of Cambridge, Cambridge, Cambridgeshire, UnitedKingdom;†These authors contributed equally.*To whom correspondence should be addressed. D.B.A. Tel: +61 90354794; Email: david.ascher@unimelb.edu.au; Correspondence may also be addressed to L.M.K: l.kaminskas@uq.edu.au Supplementary MethodsMachine learning algorithmsRandom Forest is an ensemble supervised learning method that is based on the constructionof  a  number  of  small/simple  base  predictors  using  decision  trees  (forest),  outputting  theaverage prediction in case of regression tasks or the mode in case of classification.Supplementary FiguresFigure S1: Distribution of experimental pharmacokinetics parameters for dendrimer constructs on the database.Figure S2: Predicting the percentage of dose that is recovered in the liver and urine. Thegraphs depict the regression plot between experimental and predicted %Doses for Liver (left-hand side graph) and Urine (right-hand side graph), which obtained of up to r=0.87 after 10% outliers were removed (shown in red).Figure S3: ROC curves dendrimer construct classification according to liver uptake and urinary excretion. Both predictions achieved an accuracy of 80% on these tasks, achieving AUCs of 0.87 and 0.86 for urinary excretion and liver uptake, respectively.Figure  S4: PCA analysis  for  he  Half  Life  data  set.  The  left-hand  figure  depicts  thecontribution of each feature to explain the variability of the data set. The right-hand figureshows a histogram of the percentage of explained variance per feature.Figure S5: dendPoint database. The figure depicts the web-based interface for browsing therelational database linking dendrimer properties and pharmacokinetic behavior. By accessingthe browsing option (1), users have the option to show/hide different properties (2,3,4) aswell as download the full contents of the database (5).Figure S6: dendPoint submission page. The figure depicts the web-based interface for jobsubmission.  By  selecting  the  prediction  mode  (1),  users  can  specify  different  constructproperties (2) and surface functional groups (3) prior to submission (4).Figure S7: dendPoint result page for single dendrimer predictions. The figure depicts theprediction result page for a single dendrimer. The predicted pharmacokinetic properties for auser-defined dendrimer construct are exhibited in tabular format (1). The interface gives theuser the option to either run another prediction (2) or compare the current construct withanother one (3). Also a dendrimer depiction is available, showing the number of generations(as concentric grey circles) and surface groups as spheres. A plasma concentration predictioncurve is also provided (5).Figure S8: dendPoint result page for dendrimer comparison. The figure depicts the predictionresult  page  for  comparing  pharmacokinetics  of  two  dendrimers.  The  predictedpharmacokinetic  properties  are  exhibited  in  tabular  format  for  both  dendrimers  (1).  Theplasma  concentration  prediction  curves  for  both  constructs  are  also  provided  (2).  Thedendrimer  depictions  are  plotted  side-by-side,  showing  the  number  of  generations  (asconcentric grey circles) and surface groups as spheres (3-4).Table S1. Summary of structural characteristics and pharmacokinetic properties for dendrimers that were included in the database.Scaffold Ga# SurfacePEG(kDa)# non-PEGsites# non-PEG surfacefunctionalitybSurfacedrugscSurfacecharge(--- to +++)dStructflexibility(0 to +++)eConstructMW(kDa)T1/2 (h)Cl(ml/h/kg)% Dose inurine (day)% Dose inliver (day)RefSurface characteristics PK parametersTriazineh 2 10 (5) 14 6 (NH2), 8(OH) - 0 0 73 100 1 9 (2) 10 (2) 1Triazineh 2 13 (2) 11 3 (NH2), 8 (OH) - 0 0 30 43 2.7 10 (2) 12 (2) 1Triazineh 2 14 (0.6) 10 2 (NH2), 8 (OH) - 0 0 11 27 4.9 16 (2) 16 (2) 1Triazineh 2 9 (2) 15 3 (NH2), 12 (drug) pac 0 0 39f 15 14g 35 (3) 11 (2) 2Triazineh 2 8 (2) 16 4 (NH2), 12 (drug) pac 0 0 37 19 9g 55 (3) 22 (2) 2Triazineh 2 6.5 (2) 17.5 5.5 (NH2), 12 (drug) pac 0 0 34 20 6g 41 (3) 10 (2) 2Triazineh 2 6.5 (5) 17.5 1.5 (NH2), 16 (drug) pac 0 0 61 38 1.4 5 (2) 20 (2) 3PAMAM 5 0 128 128 (OH) - 0 0 29 3 500g - 12 (1) 4PAMAM 6 0 256 256 (OH) - 0 0 58 4 250g - 35 (1) 4PAMAM 7 0 512 512 (OH) - 0 0 117 6 50g - 7 (1) 4PAMAM 5 10 (2) 118 74 (Ac), 44 (NH2) - + 0 52 14g 2g 2 (2) 15 (2) 5PAMAM 4 0 64 7 (NH2), 57 (do3a-Gd)- 0 0 50 72g 13g 35 (2) 40(2) 6PAMAM 5 0 128 10 (DTPA-Tc), 81 (Ac), 9 (biotin), 28 (NH2)- 0 0 ~41 19g* 12g - 57 (0.25) 7PAMAM 3 12 (5) 12 2 (NH2), 10 (Do3a-Gd)- 0 0 69 20 - - 8 8PAMAM 3 9 (2) 15 15 (Do3a-Gd) - 0 0 33 3 - - 4 8PAMAM 2 3 (5) 9 9 (Do3a-Gd) - 0 0 24 0.6 - 38 1 8PAMAM 2 7 (2) 5 5 (D03a-Gd) - 0 0 21 6 - 30 7 8PAMAM 4 60 (5) 4 4 (Ac) - 0 0 334 78g 1g - 6 (1) 9PAMAM 5 110 (2) 5 5 (Ac) - 0 0 284 31g 3g - 7 (1) 9PAMAM 4 63 (2) 1 1 (Ac) - 0 0 162 41g 3 - 7(1) 9PAMAM 4 0 64 64 (Ac) - 0 0 36 2g 36g - 4(1) 9PAMAM 3 0 32 29 (NH2), Cy3 (3) - +++ 0 8 2 40g - 4 (0.25) 10PAMAM 3 24 (1) 8 5 (NH2), Cy3 (3) - 0 0 33 18 3g - 4 (0.25) 10polyester 3 8 (20) 8 8 (OH) - 0 + 160 50 2 7(2) 2(0.4) 11polyester 2 4 (20) 4 4 (OH) - 0 ++ 87 25 3 10(2) 2(0.4) 11polyester 3 8 (10) 8 8 (OH) - 0 + 85 40 2 2(2) 6(0.4) 11polyester 3 8 (5) 8 8 (OH) - 0 + 45 31 3 3(2) 4(0.4) 11polyester 1 2 (20) 2 2 (OH) - 0 +++ 44 1 152 20(2) 2(0.4) 11polyester 2 4 (10) 4 4 (OH) - 0 ++ 43 26 4 34(2) 6(0.4) 11polyester 2 4 (5) 4 4 (OH) - 0 ++ 23 11 21 22(2) 2(0.4) 11polyester 1 2 (10) 2 2 (OH) - 0 +++ 22 8 103 33(2) 1(0.4) 11polyglycerol 2 0 16 16 (OH) - 0 0 6 16g 14g 55(0.04) 8(1) 12polyglycerol 2 0 16 6 (SO3), 10 (OH) - - 0 9 1g 56g 5(0.04) 90(1) 12polyglycerol 2 0 16 13 (SO3), 3 (OH) - -- 0 13 1g 64g 1(0.04) 76(1) 12polylysine 5 32 (1) 32 32 (COOH) - - + 64 33 3 16 (5) 16(5) 13polylysine 5 28 (1) 36 16 (NH2), 15 (drug),5 (CNNH2)dox + + 53 34 2 3(5) 9(5) 14polylysine 5 28 (1) 36 16 (NH2), 20 (-CNNH2)- + + 45 22 3 4(5) 4(3) 14polylysine 5 28 (1) 36 36 (NH2) - ++ + 41 29 14 4(3) 37(3) 14polylysine 5 18 (1) 46 23 (NH2), 15 (drug),8 (-CNNH2)dox + + 36 35 2 13(5) 5(5) 14polylysine 5 18 (1) 46 23 (NH2), 23 (CNNH2)- + + 31 25 3 16(5) 3(5) 14polylysine 5 18 (1) 55 55 (NH2) - ++ + 27 30 2 24(3) 5(3) 14polylysine 5 30 (1) 34 4 (NH2), 15 (-CNNH2), 15 (drug)dox 0 + 56 51 1 - - 15polylysine 5 32 (1) 32 6 (NH2), 26 (drug) MTXotb 0 0 64 26 2 9 (5) 8(5) 16polylysine 5 32 (1) 32 6 (NH2), 26 (drug) MTX - 0 64 1 24 2 (3) 52 (3) 16polylysine 5 32 (1) 32 4 (NH2), 28 (drug) MTXotb 0 + 71 33 2 14 (5) 10(5) 16polylysine 5 32 (1) 32 8 (NH2), 24 (drug) MTX - + 68 0.3 65 2 (3) 85(3) 16polylysine 4 32 (0.57) 0 0 - 0 0 22 14 9 33 (1) 2 (1) 17polylysine 4 16 (0.57) 16 16 (drug) MTXotb 0 0 21 0.4 173 29 (1) 1 (1) 17polylysine 5 64 (0.57) 0 0 - 0 0 48 37 1 6 (5) 8 (5) 17polylysine 5 32 (0.57) 32 32 (drug) MTXotb 0 0 42 24 5 2 (5) 10(5) 17polylysine 3 8 (0.57) 8 8 (drug) MTXotb 0 0 11 0.1 443 56 (1) 1 (1) 17polylysine 3 8 (1) 8 8 (drug) MTXotb 0 0 15 0.2 330 64 (1) 1(1) 17polylysine 4 16 (1) 16 16 (drug) MTXotb 0 0 30 21 5 24(4) 7(4) 17polylysine 4 16 (2.3) 16 16 (drug) MTXotb 0 0 47 34 2 8(5) 10(5) 17polylysine 5 32 (1) 32 32 (drug) MTXotb 0 0 59 51 2 1(7) 12(7) 17polylysine 4 16 (0.57) 16 16 (NH2) - ++ + 13 0.1 213 74 (1) 3(1) 18polylysine 4 16 (0.57) 16 16 (Ac) - 0 + 14 0.1 1433 72(1) 0.3(1) 18polylysine 4  32 (2) 0 0 - 0 + 68 75 1 3(7) 9(7) 19polylysine 3 16 (2) 0 0 - 0 + 34 24 3 26 (5) 4(5) 19polylysine 4 32 (0.57) 0 0 - 0 + 22 10 17 43(1) 2(1) 19polylysine 4 32 (0.2) 0 0 - 0 + 11 0.7 383 80(1) 0(1) 19polylysine 3 16 (0.2) 0 0 - 0 + 6 0.6 647 82(1) 0(1) 19polylysine 4 0 32 32 (COOH) - -- + 5 0.9 71 25(1) 12(1) 20polylysine 4 0 16 16 (SO4) - --- + 10 0.9 21 30 (1) 26(1) 20polylysine 4 0 32 32 (SO4) - --- + 14 1 24 3(1) 49(1) 20polylysine 4 0 32 32 ([SO4]2) - --- + 7 0.2 1736 63(1) 0(1) 20polylysine 3 0 16 16 (NH2) - +++ + 2 0.1 1942 8(1) 5(1) 21polylysine 4 0 32 32 (NH2) - +++ + 4 0.1 4630 4(1) 10(1) 21polylysine 4 0 32 32 (NH2) - +++ + 4 0.1 2880 4(1) 24(1) 21aDendrimer generationbFunctionality or identity of chemical groups conjugated to non-PEGylated surface reactive sitescSurface conjugated drugs representing paclitaxel (pac), doxorubicin (dox), α-carboxyl OtButylated methotrexate (MTXotb) and methotrexatebearing unmodified α-carboxyl functionality (MTX).dStrength of surface charge (from highly anionic [---] to highly cationic [+++]). Assigned based on discussion in the respective manuscripts orbased on the number and type of surface charge as well as surface PEG loading.eStructural flexibility of the dendrimer (from relatively rigid [0] to highly flexible [+++]). Relative structural flexibility of each dendrimerconstruct was assigned based on discussion in the respective manuscripts.fExists as a 400 kDa aggregate in solution.gPharmacokinetic parameters calculated based on data that was extrapolated from plasma concentration vs time curves shown in the manuscript.hSurface treatment of the published triazine dendrimers has resulted in 24 available surface groups rather than the standard 16. *Represents a recalculated value since the value reported in the manuscript was not the correct terminal Half-life.REFERENCES1. Lim, J. et al. The role of the size and number of polyethylene glycol chains in the biodistribution and tumour localization of triazine dendrimers. Molecular Pharmaceutics 5, 540-547 (2008).2. Lim, J. et al. Design, Synthesis, Characterization, and Biological Evaluation of Triazine Dendrimers Bearing Paclitaxel Using Ester and Ester/Disulfide Linkages. Bioconjugate Chemistry 20, 2154-2161 (2009).3. Lee, C. et al. Design, Synthesis and Biological Assessment of a Triazine Dendrimer with Approximately 16 Paclitaxel Groups and 8 PEG Groups. Molecular Pharmaceutics 10, 4452-4461 (2013).4. Sadekar, S. et al. Comparative Pharmacokinetics of Pamam-Oh Dendrimers and Hpma Copolymers in Ovarian-Tumor-Bearing Mice. Drug Deliv Transl Res 3, 260-271 (2013).5. Medina, S.H. et al. Targeting hepatic cancer cells with pegylated dendrimers displaying N-acetylgalactosamine and SP94 peptide ligands. Adv Healthc Mater 2, 1337-50 (2013).6. Biricova, V., Laznickova, A., Laznicek, M., Polasek, M. & Hermann, P. Radiolabelingof PAMAM dendrimers conjugated to a pyridine-N-oxide DOTA analog with (1)(1)(1)In: Optimization of reaction conditions and biodistribution. J Pharm Biomed Anal 56, 505-12 (2011).7. Xu, X. et al. Radiosynthesis, biodistribution and micro-SPECT imaging study of dendrimer-avidin conjugate. Bioorg Med Chem 19, 1643-8 (2011).8. Margerum, L.D. et al. Gadolinium(III) DO3A macrocycles and polyethylene glycol coupled to dendrimers - Effect of molecular weight on physical and biological properties of macromolecular magnetic resonance imaging contrast agents. Journal ofAlloys and Compounds 249, 185-190 (1997).9. Kojima, C., Regino, C., Umeda, Y., Kobayashi, H. & Kono, K. Influence of dendrimergeneration and polyethylene glycol length on the biodistribution of PEGylated dendrimers. Int J Pharm 383, 293-396 (2010).10. Zhong, Q., Merkel, O.M., Reineke, J.J. & da Rocha, S.R. Effect of the Route of Administration and PEGylation of Poly(amidoamine) Dendrimers on Their Systemic and Lung Cellular Biodistribution. Mol Pharm (2016).11. Gillies, E.R., Dy, E., Frechet, J.M. & Szoka, F.C. Biological evaluation of polyester dendrimer: poly(ethylene oxide) "bow-tie" hybrids with tunable molecular weight andarchitecture. Mol Pharm 2, 129-38 (2005).12. Pant, K. et al. Synthesis and biodistribution studies of (3)H- and (64)Cu-labeled dendritic polyglycerol and dendritic polyglycerol sulfate. Bioconjug Chem 26, 906-18 (2015).13. Kaminskas, L.M. et al. Methotrexate-Conjugated PEGylated Dendrimers Show Differential Patterns of Deposition and Activity in Tumor-Burdened Lymph Nodes after Intravenous and Subcutaneous Administration in Rats. Molecular Pharmaceutics 12, 432-443 (2015).14. Kaminskas, L.M. et al. Characterisation and tumour targeting of PEGylated polylysine dendrimers bearing doxorubicin via a pH labile linker. J Control Release 152, 241-8 (2011).15. Kaminskas, L.M. et al. Doxorubicin-conjugated PEGylated dendrimers show similar tumoricidal activity but lower systemic toxicity when compared to PEGylated liposome and solution formulations in mouse and rat tumor models. Mol Pharm 9, 422-32 (2012).16. Kaminskas, L.M. et al. Capping methotrexate alpha-carboxyl groups enhances systemic exposure and retains the cytotoxicity of drug conjugated PEGylated polylysine dendrimers. Mol Pharm 8, 338-49 (2011).17. Kaminskas, L.M. et al. Pharmacokinetics and tumor disposition of PEGylated, methotrexate conjugated poly-l-lysine dendrimers. Mol Pharm 6, 1190-204 (2009).18. Kaminskas, L.M. et al. Partly-PEGylated Poly-L-lysine Dendrimers Have Reduced Plasma Stability and Circulation Times Compared With Fully PEGylated Dendrimers.Journal of Pharmaceutical Sciences 98, 3871-3875 (2009).19. Kaminskas, L.M. et al. The impact of molecular weight and PEG chain length on the systemic pharmacokinetics of PEGylated poly l-lysine dendrimers. Mol Pharm 5, 449-63 (2008).20. 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dendPoint: a web resource for dendrimer pharmacokinetics investigation and prediction

Nanomedicine development currently suffers from a lack of efficient tools to predict pharmacokinetic behavior without relying upon testing in large numbers of animals, impacting success rates and development costs. This work presents dendPoint, the first in silico model to predict the intravenous pharmacokinetics of dendrimers, a commonly explored drug vector, based on physicochemical properties. We have manually curated the largest relational database of dendrimer pharmacokinetic parameters and their structural/physicochemical properties. This was used to develop a machine learning-based model capable of accurately predicting pharmacokinetic parameters, including half-life, clearance, volume of distribution and dose recovered in the liver and urine. dendPoint successfully predicts dendrimer pharmacokinetic properties, achieving correlations of up to r = 0.83 and Q2 up to 0.68. dendPoint is freely available as a user-friendly web-service and database at http://biosig.unimelb.edu.au/dendpoint. This platform is ultimately expected to be used to guide dendrimer construct design and refinement prior to embarking on more time consuming and expensive in vivo testing

Kaminskas, LM

Pires, DEV

Ascher, DB

University of Melbourne Institutional Repository

Nanomedicine development currently suffers from a lack of efficient tools to predict pharmacokinetic behavior without relying upon testing in large numbers of animals, impacting success rates and development costs. This work presents dendPoint, the first in silico model to predict the intravenous pharmacokinetics of dendrimers, a commonly explored drug vector, based on physicochemical properties. We have manually curated the largest relational database of dendrimer pharmacokinetic parameters and their structural/physicochemical properties. This was used to develop a machine learning-based model capable of accurately predicting pharmacokinetic parameters, including halflife, clearance, volume of distribution and dose recovered in the liver and urine. dendPoint successfully predicts dendrimer pharmacokinetic properties, achieving correlations of up to r=0.83 and Q(2) up to 0.68. dendPoint is freely available as a user-friendly web-service and database at http://biosig.unimelb.edu.au/dendpoint. This platform is ultimately expected to be used to guide dendrimer construct design and refinement prior to embarking on more time consuming and expensive in vivo testing

University of Queensland eSpace

Nanomedicine development currently suffers from a lack of efficient tools to predict pharmacokinetic behavior without relying upon testing in large numbers of animals, impacting success rates and development costs. This work presents dendPoint, the first in silico model to predict the intravenous pharmacokinetics of dendrimers, a commonly explored drug vector, based on physicochemical properties. We have manually curated the largest relational database of dendrimer pharmacokinetic parameters and their structural/physicochemical properties. This was used to develop a machine learning-based model capable of accurately predicting pharmacokinetic parameters, including half-life, clearance, volume of distribution and dose recovered in the liver and urine. dendPoint successfully predicts dendrimer pharmacokinetic properties, achieving correlations of up to r = 0.83 and Q2 up to 0.68. dendPoint is freely available as a user-friendly web-service and database at http://biosig.unimelb.edu.au/dendpoint . This platform is ultimately expected to be used to guide dendrimer construct design and refinement prior to embarking on more time consuming and expensive in vivo testing.L.M.K was funded by an NHMRC Career Development Fellowship. D.B.A. and D.E.V.P were funded by a Newton Fund RCUK-CONFAP Grant awarded by The Medical Research Council (MRC) and Fundação de Amparo à Pesquisa do Estado de Minas Gerais (FAPEMIG) (MR/M026302/1, APQ-00828-15). D.E.V.P. received support from Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (409780/2016-2), Brazil. DBA was supported by a C. J. Martin Research Fellowship from the National Health and Medical Research Council of Australia (APP1072476) and the Jack Brockhoff Foundation (JBF 4186, 2016). This work was supported in part by the Victorian Government's OIS Program

Kaminskas, Lisa M

Pires, Douglas EV

Ascher, David B

dendPoint: a web resource for dendrimer pharmacokinetics investigation and prediction.

https://www.repository.cam.ac.uk/bitstream/handle/1810/312162/41598_2019_51789_MOESM1_ESM.pdf?sequence=3&isAllowed=y

dendPoint: a web resource for dendrimer pharmacokinetics investigation and prediction

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