In Silico Prediction of Membrane Permeability from Calculated Molecular Parameters.

Hanne H.F. Refsgaard; Berith F. Jensen; Per B. Brockhoff; Søren B. Padkjær; Mette Guldbrandt; Michael S. Christensen

In Silico Prediction of Membrane Permeability from Calculated Molecular Parameters.

Hanne H.F. Refsgaard, Berith F. Jensen, Per B. Brockhoff, Søren B. Padkjær, Mette Guldbrandt, Michael S. Christensen

Publikation: Artikel i tidsskrift og konference artikel i tidsskrift › Tidsskriftartikel › Forskning › peer review

Abstract

A data set consisting of 712 compounds was used for classification into two classes with respect to membrane permeation in a cell-based assay: (0) apparent permeability (P_app) below 4 × 10^(-6) cm/s and (1) (P_app) on 4 × 10^(-6)cm/s or higher. Nine molecular descriptors were calculated for each compound and Nearest-Neighbor classification was applied using five neighbors as optimized by full cross-validation. A model based on five descriptors, number of flex bonds, number of hydrogen bond acceptors and donors, and molecular and polar surface area, was selected by variable selection. In an external test set of 112 compounds, 104 compounds were classified and 8 compounds were judged as “unknown”. Among the 104 compounds, 16 were misclassified corresponding to a misclassification rate of 15% and no compounds were falsely predicted in the nonpermeable class.

Originalsprog	Engelsk
Tidsskrift	Journal of Medicinal Chemistry
Vol/bind	48
Udgave nummer	3
Sider (fra-til)	805-811
ISSN	0022-2623
Status	Udgivet - 2005
Udgivet eksternt	Ja

Emneord

Membrane permeation
Cell-based assay
Apparent permeability (Papp)
Molecular descriptors
Nearest-Neighbor classification

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Citationsformater

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title = "In Silico Prediction of Membrane Permeability from Calculated Molecular Parameters.",

abstract = "A data set consisting of 712 compounds was used for classification into two classes with respect to membrane permeation in a cell-based assay: (0) apparent permeability (Papp) below 4 × 10(-6) cm/s and (1) (Papp) on 4 × 10(-6) cm/s or higher. Nine molecular descriptors were calculated for each compound and Nearest-Neighbor classification was applied using five neighbors as optimized by full cross-validation. A model based on five descriptors, number of flex bonds, number of hydrogen bond acceptors and donors, and molecular and polar surface area, was selected by variable selection. In an external test set of 112 compounds, 104 compounds were classified and 8 compounds were judged as “unknown”. Among the 104 compounds, 16 were misclassified corresponding to a misclassification rate of 15% and no compounds were falsely predicted in the nonpermeable class.",

keywords = "Membrane permeation, Cell-based assay, Apparent permeability (Papp), Molecular descriptors, Nearest-Neighbor classification, Membrane permeation, Cell-based assay, Apparent permeability (Papp), Molecular descriptors, Nearest-Neighbor classification",

author = "Refsgaard, {Hanne H.F.} and Jensen, {Berith F.} and Brockhoff, {Per B.} and Padkj{\ae}r, {S{\o}ren B.} and Mette Guldbrandt and Christensen, {Michael S.}",

year = "2005",

language = "English",

volume = "48",

pages = "805--811",

journal = "Journal of Medicinal Chemistry",

issn = "0022-2623",

publisher = "American Chemical Society",

number = "3",

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TY - JOUR

T1 - In Silico Prediction of Membrane Permeability from Calculated Molecular Parameters.

AU - Refsgaard, Hanne H.F.

AU - Jensen, Berith F.

AU - Brockhoff, Per B.

AU - Padkjær, Søren B.

AU - Guldbrandt, Mette

AU - Christensen, Michael S.

PY - 2005

Y1 - 2005

N2 - A data set consisting of 712 compounds was used for classification into two classes with respect to membrane permeation in a cell-based assay: (0) apparent permeability (Papp) below 4 × 10(-6) cm/s and (1) (Papp) on 4 × 10(-6) cm/s or higher. Nine molecular descriptors were calculated for each compound and Nearest-Neighbor classification was applied using five neighbors as optimized by full cross-validation. A model based on five descriptors, number of flex bonds, number of hydrogen bond acceptors and donors, and molecular and polar surface area, was selected by variable selection. In an external test set of 112 compounds, 104 compounds were classified and 8 compounds were judged as “unknown”. Among the 104 compounds, 16 were misclassified corresponding to a misclassification rate of 15% and no compounds were falsely predicted in the nonpermeable class.

AB - A data set consisting of 712 compounds was used for classification into two classes with respect to membrane permeation in a cell-based assay: (0) apparent permeability (Papp) below 4 × 10(-6) cm/s and (1) (Papp) on 4 × 10(-6) cm/s or higher. Nine molecular descriptors were calculated for each compound and Nearest-Neighbor classification was applied using five neighbors as optimized by full cross-validation. A model based on five descriptors, number of flex bonds, number of hydrogen bond acceptors and donors, and molecular and polar surface area, was selected by variable selection. In an external test set of 112 compounds, 104 compounds were classified and 8 compounds were judged as “unknown”. Among the 104 compounds, 16 were misclassified corresponding to a misclassification rate of 15% and no compounds were falsely predicted in the nonpermeable class.

KW - Membrane permeation

KW - Cell-based assay

KW - Apparent permeability (Papp)

KW - Molecular descriptors

KW - Nearest-Neighbor classification

KW - Membrane permeation

KW - Cell-based assay

KW - Apparent permeability (Papp)

KW - Molecular descriptors

KW - Nearest-Neighbor classification

M3 - Journal article

SN - 0022-2623

VL - 48

SP - 805

EP - 811

JO - Journal of Medicinal Chemistry

JF - Journal of Medicinal Chemistry

IS - 3

ER -

In Silico Prediction of Membrane Permeability from Calculated Molecular Parameters.

Abstract

Emneord

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