Modeling error in experimental assays using the bootstrap principle: understanding discrepancies between assays using different dispensing technologies

Hanson, Sonya M.; Ekins, Sean; Chodera, John D.

doi:10.1007/s10822-015-9888-6

Cited by 15 publications

(13 citation statements)

References 32 publications

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“… 54 At each λ value, a total of 1 ns simulation was carried out and the last 800 ps was used for free energy calculations by thermodynamic integration (TI). 58 To remove bias when estimating the free energy change, uncorrelated data were extracted based on their correlation time and the bootstrapping protocol 59 , 60 was applied to obtain the free energy error with 1000 repetitions for each transformation. The convergence of the determined free energy values was checked by extending the simulation length to 2 ns for each system.…”

Section: Methodsmentioning

confidence: 99%

Dynamic, structural and thermodynamic basis of insulin-like growth factor 1 kinase allostery mediated by activation loop phosphorylation

Nam

2017

Chem. Sci.

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Section: Methodsmentioning

confidence: 99%

Dynamic, structural and thermodynamic basis of insulin-like growth factor 1 kinase allostery mediated by activation loop phosphorylation

Nam

2017

Chem. Sci.

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“…While acoustic dispensing does not completely rule out the use of plasticware, it does significantly reduce it. Furthermore, the removal of tip-based pipetting also eliminates sample carryover, and errors are not propagated throughout the entire serial dilution, allowing for both reliable and reproducible preparation of concentration-response curves 14,15 .…”

Section: Discussionmentioning

confidence: 99%

Automated Acoustic Dispensing for the Serial Dilution of Peptide Agonists in Potency Determination Assays

Naylor¹,

Rossi²,

Brankin³

et al. 2016

JoVE

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As with small molecule drug discovery, screening for peptide agonists requires the serial dilution of peptides to produce concentration-response curves. Screening peptides affords an additional layer of complexity as conventional tip-based sample handling methods expose peptides to a large surface area of plasticware, providing an increased opportunity for peptide loss via adsorption. Preventing excessive exposure to plasticware reduces peptide loss via adherence to plastics and thus minimizes inaccuracies in potency prediction, and we have previously described the benefits of non-contact acoustic dispensing for in vitro high-throughput screening of peptide agonists. Here we discuss a fully integrated automation solution for non-contact acoustic preparation of peptide serial dilutions in microtiter plates utilizing the example of screening for peptide agonists at the mouse glucagon-like peptide-1 receptor (GLP-1R). Our methods allow for high-throughput cell-based assays to screen for agonists and are easily scalable to support increased sample throughput, or to allow for increased numbers of assay plate copies (e.g., for a panel of more target cell lines).

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“…Good approaches to uncertainty analysis propagate all known sources of experimental error into the final estimates of uncertainty. To accomplish this, we developed a parametric bootstrap model [26] of the experiment based on earlier work [27], with the goal of propagating pipetting volume and technical replicate errors through the complex analysis procedure to estimate their impact on the overall estimated logD measurements.…”

Section: Experimental Methodsmentioning

confidence: 99%

“…Uncertainties in pipetting operations were modeled based on manufacturer descriptions [29, 30], following the work of Hanson, Ekins and Chodera [27]. Technical replicate variation was modeled by calculating the coefficient of variation (CV) between individual experimental replicates.…”

Section: Experimental Methodsmentioning

confidence: 99%

Measuring experimental cyclohexane-water distribution coefficients for the SAMPL5 challenge

Rustenburg

Dancer

Lin³

et al. 2016

J Comput Aided Mol Des

Self Cite

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Small molecule distribution coefficients between immiscible nonaqueuous and aqueous phases—such as cyclohexane and water—measure the degree to which small molecules prefer one phase over another at a given pH. As distribution coefficients capture both thermodynamic effects (the free energy of transfer between phases) and chemical effects (protonation state and tautomer effects in aqueous solution), they provide an exacting test of the thermodynamic and chemical accuracy of physical models without the long correlation times inherent to the prediction of more complex properties of relevance to drug discovery, such as protein-ligand binding affinities. For the SAMPL5 challenge, we carried out a blind prediction exercise in which participants were tasked with the prediction of distribution coefficients to assess its potential as a new route for the evaluation and systematic improvement of predictive physical models. These measurements are typically performed for octanol-water, but we opted to utilize cyclohexane for the nonpolar phase. Cyclohexane was suggested to avoid issues with the high water content and persistent heterogeneous structure of water saturated octanol phases, since it has greatly reduced water content and a homogeneous liquid structure. Using a modified shake-flask LC-MS/MS protocol, we collected cyclohexane/water distribution coefficients for a set of 53 drug like compounds at pH 7.4. These measurements were used as the basis for the SAMPL5 Distribution Coefficient Challenge, where 18 research groups predicted these measurements before the experimental values reported here were released. In this work, we describe the experimental protocol we utilized for measurement of cyclohexane-water distribution coefficients, report the measured data, propose a new bootstrap-based data analysis procedure to incorporate multiple sources of experimental error, and provide insights to help guide future iterations of this valuable exercise in predictive modeling.

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Modeling error in experimental assays using the bootstrap principle: understanding discrepancies between assays using different dispensing technologies

Cited by 15 publications

References 32 publications

Dynamic, structural and thermodynamic basis of insulin-like growth factor 1 kinase allostery mediated by activation loop phosphorylation

Dynamic, structural and thermodynamic basis of insulin-like growth factor 1 kinase allostery mediated by activation loop phosphorylation

Automated Acoustic Dispensing for the Serial Dilution of Peptide Agonists in Potency Determination Assays

Measuring experimental cyclohexane-water distribution coefficients for the SAMPL5 challenge

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