Your search keyword '"QSAR (Biochemistry)"' showing total 7 results

1. Deep learning applications in structure-based drug discovery

Author

Meli, Rocco, Biggin, Philip, and Morris, Garrett

Subjects

Pharmaceutical chemistry, Computational chemistry, Ensemble learning (Machine learning), Supervised learning (Machine learning), Computational biology, Chemistry, Physical and theoretical, Structure-activity relationships (Biochemistry), QSAR (Biochemistry), Deep learning (Machine learning), Ligand binding (Biochemistry)

Abstract

In recent years, machine learning and deep learning applications have permeated all fields of science thanks to rapid algorithmic advances and computer hardware developments. A very active area of research is the use of deep learning in structure-based drug design, where the goal is to design effective drugs against a pharmacological target of interest. In this work, we explored the use of deep learning in the early stages of drug discovery. In particular, we focussed on structure-based virtual screening, binding affinity prediction, and de novo drug design. First, we enabled docking with flexible residues within Gnina, a state-of-the- art docking software based on convolutional neural networks, and we performed a large-scale cross-docking study of such methodology, outlining its strengths and weaknesses. Second, we extracted the convolutional neural network scoring function from the docking software into a standalone package for fast prototyping. With the new software at hand, we explored different annotations for supervised learning to improve the convolutional neural network scoring function for docking with flexible residues. Third, we developed a novel scoring function for binding affinity prediction based on a successful deep learning architecture used to develop machine learning force fields. Finally, we carefully evaluate a generative model for de novo design for the application in industrial drug discovery pipelines. We outline the weaknesses of the method and the problems with current evaluations of generative models.

Published

2022

2. Quantum Nanochemistry, Volume Five : Quantum Structure-Activity Relationships (Qu-SAR)

Author

Mihai V. Putz and Mihai V. Putz

Subjects

Quantum theory, QSAR (Biochemistry), Quantum chemistry, Chemistry, Physical and theoretical, Nanochemistry

Abstract

Volume 5 of the 5-volume Quantum Nanochemistry focuses on modeling and predicting of the enzyme kinetics and quantitative structure-activity relationships. It reveals the quantum implications to bio-organic and bio-inorganic systems, to enzyme kinetics, and to pharmacophore binding sites of chemical-biological interaction of molecules through cell

Published

2016

3. Quantum Nanochemistry, Volume Two : Quantum Atoms and Periodicity

Author

Mihai V. Putz and Mihai V. Putz

Subjects

Quantum theory, QSAR (Biochemistry), Quantum chemistry, Chemistry, Physical and theoretical, Nanochemistry

Abstract

Volume 2 of the 5-volume Quantum Nanochemistry presents in a balanced manner the fundamental and advanced concepts, principles, and models as well as their first and novel combinations and applications in quantum (physical) and chemical theory of atomic structure. It exposes the atom's perspective of quantum structures, spanning its diverse analyti

Published

2016

4. Quantum Nanochemistry, Volume One : Quantum Theory and Observability

Author

Mihai V. Putz and Mihai V. Putz

Subjects

Quantum theory, QSAR (Biochemistry), Quantum chemistry, Chemistry, Physical and theoretical, Nanochemistry

Abstract

Volume 1 of the 5-volume Quantum Nanochemistry set presents an overall perspective of nuclear, atomic, molecular, and solids structures, and the observability and quantum properties as based on the quantum principles in their various levels of applications, from Planck, Bohr, Einstein, Schrodinger, Hartree-Fock, up to Feynman Path Integral approach

Published

2016

5. Quantum Nanochemistry, Volume Three : Quantum Molecules and Reactivity

Author

Mihai V. Putz and Mihai V. Putz

Subjects

Quantum theory, QSAR (Biochemistry), Quantum chemistry, Chemistry, Physical and theoretical, Nanochemistry

Abstract

Volume 3 of the 5-volume Quantum Nanochemistry presents the chemical reactivity throughout the molecular structure in general and chemical bonding in particular by introducing the bondons as the quantum bosonic particles of the chemical field, localization, from Huckel to Density Functional expositions, especially in relation to how chemical princi

Published

2016

6. Quantum Nanochemistry, Volume Four : Quantum Solids and Orderability

Author

Mihai V. Putz and Mihai V. Putz

Subjects

Quantum theory, QSAR (Biochemistry), Quantum chemistry, Chemistry, Physical and theoretical, Nanochemistry

Abstract

Volume 4 of the 5-volume Quantum Nanochemistry covers quantum (physical) chemical theory of solids and orderability and addresses the electronic order problems in the solid state viewed as a huge molecule in special quantum states, including also the bondonic treatment of the graphene nano-ribbons, along basic crystallographic principles, from geom

Published

2016

7. Deep learning applications in structure-based drug discovery

Author

Meli, R, Biggin, P, and Morris, G

Subjects

Computational biology, Computational chemistry, Ensemble learning (Machine learning), QSAR (Biochemistry), Deep learning (Machine learning), Structure-activity relationships (Biochemistry), Pharmaceutical chemistry, Ligand binding (Biochemistry), Supervised learning (Machine learning), Chemistry, Physical and theoretical

Abstract

In recent years, machine learning and deep learning applications have permeated all fields of science thanks to rapid algorithmic advances and computer hardware developments. A very active area of research is the use of deep learning in structure-based drug design, where the goal is to design effective drugs against a pharmacological target of interest. In this work, we explored the use of deep learning in the early stages of drug discovery. In particular, we focussed on structure-based virtual screening, binding affinity prediction, and de novo drug design. First, we enabled docking with flexible residues within Gnina, a state-of-the- art docking software based on convolutional neural networks, and we performed a large-scale cross-docking study of such methodology, outlining its strengths and weaknesses. Second, we extracted the convolutional neural network scoring function from the docking software into a standalone package for fast prototyping. With the new software at hand, we explored different annotations for supervised learning to improve the convolutional neural network scoring function for docking with flexible residues. Third, we developed a novel scoring function for binding affinity prediction based on a successful deep learning architecture used to develop machine learning force fields. Finally, we carefully evaluate a generative model for de novo design for the application in industrial drug discovery pipelines. We outline the weaknesses of the method and the problems with current evaluations of generative models.

Published

2023