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arxiv 2401.12999 v2 pith:TPFARE6R submitted 2024-01-22 physics.chem-ph cs.AIcs.LG

Quantum-Inspired Machine Learning for Molecular Docking

classification physics.chem-ph cs.AIcs.LG
keywords dockingalgorithmsdeepmolecularquantum-inspiredbindingblindcomplex
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Molecular docking is an important tool for structure-based drug design, accelerating the efficiency of drug development. Complex and dynamic binding processes between proteins and small molecules require searching and sampling over a wide spatial range. Traditional docking by searching for possible binding sites and conformations is computationally complex and results poorly under blind docking. Quantum-inspired algorithms combining quantum properties and annealing show great advantages in solving combinatorial optimization problems. Inspired by this, we achieve an improved in blind docking by using quantum-inspired combined with gradients learned by deep learning in the encoded molecular space. Numerical simulation shows that our method outperforms traditional docking algorithms and deep learning-based algorithms over 10\%. Compared to the current state-of-the-art deep learning-based docking algorithm DiffDock, the success rate of Top-1 (RMSD<2) achieves an improvement from 33\% to 35\% in our same setup. In particular, a 6\% improvement is realized in the high-precision region(RMSD<1) on molecules data unseen in DiffDock, which demonstrates the well-generalized of our method.

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