Mechanistic role of plant-based bitter principles and bitterness prediction for natural product studies I: Database and methods
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Fidele Ntie-Kang
Abstract
This chapter discusses the rationale behind the bitter sensation elicited by chemical compounds, focusing on natural products. Emphasis has been placed on a brief presentation of BitterDB (the database of bitter compounds), along with available methods for the prediction of bitterness in compounds. The fundamental basis for explaining bitterness has been provided, based on the structural features of human bitter taste receptors and have been used to shed light on the mechanistic role of a few out of the 25 known human taste receptors to provide the foundation for understanding how bitter compounds interact with their receptors. Some case studies of ligand-based prediction models based on 2D fingerprints and 3D pharmacophores, along with machine learning methods have been provided. The chapter closes with an attempt to establish the relationship between bitterness and toxicity.
Acknowledgements
The author acknowledges a return fellowship and an equipment subsidy from the Alexander von Humboldt Foundation, Germany. Financial support for this work is acknowledged from the Ministry of Education, Youth and Sports of the Czech Republic.
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Artikel in diesem Heft
- Disappearing ink! Unraveling the fading of a contemporary design object
- Laser-induced breakdown spectroscopy in heritage science
- Mechanistic role of plant-based bitter principles and bitterness prediction for natural product studies I: Database and methods
- Homogeneous visible light mediated transition metal catalysis other than Ruthenium and Iridium
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- Cheminformatics techniques in antimalarial drug discovery and development from natural products 1: basic concepts
Artikel in diesem Heft
- Disappearing ink! Unraveling the fading of a contemporary design object
- Laser-induced breakdown spectroscopy in heritage science
- Mechanistic role of plant-based bitter principles and bitterness prediction for natural product studies I: Database and methods
- Homogeneous visible light mediated transition metal catalysis other than Ruthenium and Iridium
- Total reflection X-ray fluorescence
- Cheminformatics techniques in antimalarial drug discovery and development from natural products 1: basic concepts
