Related papers: Towards quantum-enabled cell-centric therapeutics

Towards quantum-enabled cell-centric therapeutics

URL: http://arxiv.org/abs/2307.05734v2
Date: Tue, 1 Aug 2023 14:44:38 GMT
Title: Towards quantum-enabled cell-centric therapeutics
Authors: Saugata Basu, Jannis Born, Aritra Bose, Sara Capponi, Dimitra Chalkia, Timothy A Chan, Hakan Doga, Frederik F. Flother, Gad Getz, Mark Goldsmith, Tanvi Gujarati, Aldo Guzman-Saenz, Dimitrios Iliopoulos, Gavin O. Jones, Stefan Knecht, Dhiraj Madan, Sabrina Maniscalco, Nicola Mariella, Joseph A. Morrone, Khadijeh Najafi, Pushpak Pati, Daniel Platt, Maria Anna Rapsomaniki, Anupama Ray, Kahn Rhrissorrakrai, Omar Shehab, Ivano Tavernelli, Meltem Tolunay, Filippo Utro, Stefan Woerner, Sergiy Zhuk, Jeannette M. Garcia, and Laxmi Parida
Abstract summary: We discuss the transformational changes we expect from the use of quantum computation for HCLS research. We identify and elaborate open problems in cell engineering, tissue modeling, perturbation modeling, and bio-topology.
Score: 2.3677262918873745
License: http://creativecommons.org/licenses/by/4.0/
Abstract: In recent years, there has been tremendous progress in the development of quantum computing hardware, algorithms and services leading to the expectation that in the near future quantum computers will be capable of performing simulations for natural science applications, operations research, and machine learning at scales mostly inaccessible to classical computers. Whereas the impact of quantum computing has already started to be recognized in fields such as cryptanalysis, natural science simulations, and optimization among others, very little is known about the full potential of quantum computing simulations and machine learning in the realm of healthcare and life science (HCLS). Herein, we discuss the transformational changes we expect from the use of quantum computation for HCLS research, more specifically in the field of cell-centric therapeutics. Moreover, we identify and elaborate open problems in cell engineering, tissue modeling, perturbation modeling, and bio-topology while discussing candidate quantum algorithms for research on these topics and their potential advantages over classical computational approaches.

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