Ligand-Based Combinatorial Design of Selective Purinergic Receptor (A<sub>2A</sub>) Antagonists Using Self-Organizing Maps

Schneider, Gisbert; Nettekoven, Matthias

doi:10.1021/cc020092j

Cited by 73 publications

(45 citation statements)

References 23 publications

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“…16) Applications of the SOM have been reported across the range of pharmaceutical and medical fields. [17][18][19] We also have been applying this promising technique for the formulation design of pharmaceuticals. 10,11,20,21) The typical structure of the SOM comprises one input layer The model emulsion (#9) was packed in tubes and then stored at 60°C for up to 12 d, then, at designated intervals, the creaming was monitored using MRI.…”

Section: Resultsmentioning

confidence: 99%

Self-organizing Map Analysis for Understanding Comprehensive Relationships between Formulation Variables, State of Water, and the Physical Stability of Pharmaceutical Emulsions

Onuki

Hasegawa

Horita³

et al. 2015

CHEMICAL & PHARMACEUTICAL BULLETIN

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The physical stability of pharmaceutical emulsions is an important quality attribute to be considered. To obtain a better understanding of this issue, this study investigated the contribution of the state of water to the physical stability of pharmaceutical emulsions. The key technology to evaluate the state of water was magnetic resonance imaging (MRI). For sample preparation, model emulsions with different formulation variables (surfactant content, water content, and hydrophilic-lipophilic balance) were prepared. The T 1 relaxation time, diffusion coefficient, and viscosity were measured as physical properties. The physical stability of the samples was evaluated using apparent diffusion coefficient maps acquired by MRI. Data analysis of the observed data was performed using the nonlinear response surface method and Kohonen's self-organizing map (SOM). It was determined that, depending on the formulation variables, the state of water was substantially changed and it played a significant role in the physical stability. SOM analysis successfully classified the conditions of formulation variables into four distinct clusters in terms of the similarity of the physical properties of the resultant emulsions, and then clarified the characteristics of the stable emulsions. This study provided us with a comprehensive understanding of the formulation variables, physical properties, and stability concerning the preparation of the model emulsion.Key words pharmaceutical emulsion; magnetic resonance imaging; physical stability; T 1 relaxation time; diffusion coefficient Oil-in-water type emulsions are widely used for various semisolid topical dosage forms. Pharmaceutical emulsions are less greasy than ointments, they are easier to apply and can be easily washed off from the skin surface; thus, they are highly acceptable to patients. 1) For the development of pharmaceutical emulsions, physical stability is a very important quality attribute to be considered. This is because emulsions are thermodynamically unstable by nature. In general, the destabilization processes of emulsions are classified into four distinct processes: creaming, flocculation, coalescence, and Ostwald ripening.1) Coalescence and Ostwald ripening are the most serious types of destabilization, whereas creaming and flocculation are subtle destabilization processes.We have been investigating the physical stability of pharmaceutical emulsions using magnetic resonance imaging (MRI).2-4) MRI is one of the most popular molecular imaging methods; it permits the nondestructive monitoring of a sample using the principle of nuclear magnetic resonance (NMR). In addition, MRI can visualize the state of water in a sample by using magnetic resonance (MR) parameters. In a previous study, we established a new method to monitor destabilization processes of pharmaceutical emulsions.4) The key technology is the visualization of the state of water. Water in pharmaceutical emulsions can exist in various states depending on its particular location and microenvironment.2) Once cre...

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Section: Resultsmentioning

confidence: 99%

Self-organizing Map Analysis for Understanding Comprehensive Relationships between Formulation Variables, State of Water, and the Physical Stability of Pharmaceutical Emulsions

Onuki

Hasegawa

Horita³

et al. 2015

CHEMICAL & PHARMACEUTICAL BULLETIN

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“…There are many successful applications of the SOM concept in chemistry including mapping of chemical space [27], projection of molecular surface properties [28,29], clustering and diversity analysis [30,31], and property prediction [32,33]. Therefore, the application of SOM was not selected as an example for the present paper (see refs.…”

Section: Methods and Algorithmsmentioning

confidence: 99%

ChemSpaceShuttle: A tool for data mining in drug discovery by classification, projection, and 3D visualization

Givehchi¹,

Dietrich²,

Wrede³

et al. 2003

QSAR Comb. Sci.

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The ChemSpaceShuttle toolbox provides a graphical interface allowing for ligand-based design of focused compound libraries by means of linear and non-linear projection techniques and clustering algorithms. The software implements a non-linear encoder network and non-linear partial least squares for the projection of high-dimensional descriptor vectors into a three dimensional space for visualisation. Compound clustering by a self-organising map (SOM) is incorporated. Visualization can facilitate the selection of compounds with desired properties from large compound libraries. Two sample applications are presented: similarity-based compound selection for focused library design, and classification of drugs and nondrugs. A version of ChemSpaceShuttle is freely available at URL: http://gecco.org.chemie.uni-frankfurt.de/gecco.html.

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“…In general, the neighborhood of an output neuron is defined as square or hexagonal and this means that each neuron has 4 or 6 nearest neighbors, respectively [51][52][53]. Figure 4 exemplifies the output layers of a SOM model using square and hexagonal neurons for a combinatorial design of purinergic receptor antagonists [54] and cannabinoid compounds [30], respectively. Example of output layers of SOM models using square and hexagonal neurons for the combinatorial design of (a) purinergic receptor antagonists [54] and (b) cannabinoid compounds [30], respectively.…”

Section: Self-organizing Map or Kohonen Neural Networkmentioning

confidence: 99%

Applications of Artificial Neural Networks in Chemical Problems

Matarollo¹,

Honório²,

Silva³

2013

Artificial Neural Networks - Architectures and Applications

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Ligand-Based Combinatorial Design of Selective Purinergic Receptor (A_2A) Antagonists Using Self-Organizing Maps

Cited by 73 publications

References 23 publications

Self-organizing Map Analysis for Understanding Comprehensive Relationships between Formulation Variables, State of Water, and the Physical Stability of Pharmaceutical Emulsions

Self-organizing Map Analysis for Understanding Comprehensive Relationships between Formulation Variables, State of Water, and the Physical Stability of Pharmaceutical Emulsions

ChemSpaceShuttle: A tool for data mining in drug discovery by classification, projection, and 3D visualization

Applications of Artificial Neural Networks in Chemical Problems

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Ligand-Based Combinatorial Design of Selective Purinergic Receptor (A2A) Antagonists Using Self-Organizing Maps

Cited by 73 publications

References 23 publications

Self-organizing Map Analysis for Understanding Comprehensive Relationships between Formulation Variables, State of Water, and the Physical Stability of Pharmaceutical Emulsions

Self-organizing Map Analysis for Understanding Comprehensive Relationships between Formulation Variables, State of Water, and the Physical Stability of Pharmaceutical Emulsions

ChemSpaceShuttle: A tool for data mining in drug discovery by classification, projection, and 3D visualization

Applications of Artificial Neural Networks in Chemical Problems

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Ligand-Based Combinatorial Design of Selective Purinergic Receptor (A_2A) Antagonists Using Self-Organizing Maps