Implementations of Quantum Computing in Medicine: Evidence from Drug Discovery, Genomics, and Medical Imaging

Hengyi Liu

doi:10.54097/sa5x8f65

Authors

Hengyi Liu

DOI:

https://doi.org/10.54097/sa5x8f65

Keywords:

Quantum Computing, Drug Discovery, Genomics, and Medical Imaging.

Abstract

Quantum computing is becoming a revolutionary technology with vast applicability across many sectors, including medicine. As the medical science is in front of more complicated problems involving drug discovery, genomics, and disease modeling, the application of quantum computing opens doors to new opportunities. This paper also discusses specific uses of quantum computing in the healthcare domain: drug discovery, genomics and genetics, medical imaging, biomolecular simulations, and public health. The research also embraces how quantum algorithms improve drug discovery, genome data, and disease diagnosis with focus on improving techniques in medical imaging and biomolecular modeling. These include quantum machine learning, applying in personalized medicine, quantum simulations, for protein folding, and increased resolution of imaging techniques. As with all technologies, there are still numerous concerns associated with scaling such a tool, optimizing the employed algorithms, and maintaining the privacy of the patient’s information and the security of this data. Its relevance is in the investigations conducted to show the applicability of current problems in medicine to quantum computing in order to spearhead more research and cooperation across various fields. Over time, quantum technologies’ potential keeps emerging and consequently will revolutionize healthcare, enhance patient experience, and fuel pharmaceutical development.

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References

[1] Klco N, Savage M J. Digitization of scalar fields for quantum computing. Physical Review A, 2019, 99 (5): 052335.

[2] Chow J C L. Quantum Computing in Medicine. Medical Sciences, 2024, 12 (4): 67.

[3] Taha B A, Addie A J, Haider A J, et al. Exploring Trends and Opportunities in Quantum‐Enhanced Advanced Photonic Illumination Technologies. Advanced Quantum Technologies, 2024, 7 (3): 2300414.

[4] Wei L, Liu H, Xu J, et al. Quantum machine learning in medical image analysis: A survey. Neurocomputing, 2023, 525: 42-53.

[5] Vasanthakumar G U, Singh M. 3 Quantum machine learning in healthcare: diagnostics and drug discovery. Quantum Machine Learning: Quantum Algorithms and Neural Networks, 2024: 39.

[6] Ladd T D, Jelezko F, Laflamme R, et al. Quantum computers. nature, 2010, 464 (7285): 45-53.

[7] Bravyi S, Dial O, Gambetta J M, et al. The future of quantum computing with superconducting qubits. Journal of Applied Physics, 2022, 132 (16).

[8] Li W. Quantum-Accelerated Big Data Analytics on Cloud Platforms: Leveraging Quantum Computing for Large-Scale Data Processing. Journal of Big-Data Analytics and Cloud Computing, 2024, 9 (1): 14-24.

[9] Li W, Yin Z, Li X, et al. A hybrid quantum computing pipeline for real world drug discovery. Scientific Reports, 2024, 14 (1): 16942.

[10] Myers W R. Potential applications of microtesla magnetic resonance imaging detected using a superconducting quantum interference device. 2006.

[11] Cao Y, Romero J, Aspuru-Guzik A. Potential of quantum computing for drug discovery. IBM Journal of Research and Development, 2018, 62 (6): 6: 1-6: 20.

[12] Sharma P. Quantum Computing in Drug Design: Enhancing Precision and Efficiency in Pharmaceutical Development. Sage Science Review of Applied Machine Learning, 2024, 7 (1): 1-9.

[13] Pinheiro G A, Mucelini J, Soares M D, et al. Machine learning prediction of nine molecular properties based on the SMILES representation of the QM9 quantum-chemistry dataset. The Journal of Physical Chemistry A, 2020, 124 (47): 9854-9866.

[14] Mishra R, Mishra P S, Mazumder R, et al. Quantum Computing and Its Promise in Drug Discovery. Drug Delivery Systems Using Quantum Computing, 2024: 57-92.

[15] Marchetti L, Nifosì R, Martelli P L, et al. Quantum computing algorithms: getting closer to critical problems in computational biology. Briefings in Bioinformatics, 2022, 23 (6): bbac437.

[16] Yingngam B, Khang A. Quantum Computing in Drug Discovery. The Quantum Evolution. CRC Press, 2024: 242-275.

[17] Patel A. Quantum algorithms and the genetic code. Pramana, 2001, 56: 367-381.

[18] Yan F, Huang H, Pedrycz W, et al. Review of medical image processing using quantum-enabled algorithms. Artificial Intelligence Review, 2024, 57 (11): 300.

[19] Robson B. De novo protein folding on computers. Benefits and challenges. Computers in biology and medicine, 2022, 143: 105292.

[20] Wu L, Qin L, Nie Y, et al. Computer-aided understanding and engineering of enzymatic selectivity. Biotechnology Advances, 2022, 54: 107793.

[21] Zhou Y, Chen J, Cheng J, et al. Quantum-machine-assisted Drug Discovery: Survey and Perspective. arxiv preprint arxiv: 2408.13479, 2024.

[22] Zare M, Thomas V, Ramakrishna S. Nanoscience and quantum science-led biocidal and antiviral strategies. Journal of Materials Chemistry B, 2021, 9 (36): 7328-7346.

[23] Kairon P, Bhattacharyya S. COVID-19 outbreak prediction using quantum neural networks. Intelligence Enabled Research: DoSIER 2020, 2021: 113-123.

[24] Aramyan S, McGregor K, Sandeep S, et al. SP-A binding to the SARS-CoV-2 spike protein using hybrid quantum and classical in silico modeling and molecular pruning by Quantum Approximate Optimization Algorithm (QAOA) Based MaxCut with ZDOCK. Frontiers in Immunology, 2022, 13: 945317.