Keshav Kumar K. and Narasimham NVSL
Adv. Artif. Intell. Mach. Learn., 4 (3):2452-2467
Keshav Kumar K. : G. Narayanamma Institute of Technology and Science (for Women), Hyderabad, India
Narasimham NVSL : G. Narayanamma Institute of Technology and Science (for Women), Hyderabad
Article History: Received on: 29-Apr-24, Accepted on: 05-Aug-24, Published on: 12-Aug-24
Corresponding Author: Keshav Kumar K.
Email: keshav.gnits@gmail.com
Citation: Keshav Kumar K, et al. Biomimicry in Radiation Therapy: Optimizing Patient Scheduling for Improved Treatment Outcomes. Advances in Artificial Intelligence and Machine Learning. 2024;4(3):143.
In the realm of medical
science, the pursuit of enhancing treatment efficacy and patient outcomes
continues to drive innovation. This study delves into the integration of
biomimicry principles within the domain of Radiation Therapy (RT) to optimize
patient scheduling, ultimately aiming to augment treatment results. RT stands
as a vital medical technique for eradicating cancer cells and diminishing tumour
sizes. Yet, the manual scheduling of patients for RT proves both laborious and
intricate. In this research, the focus is on automating patient scheduling for
RT through the application of optimization methodologies. Three bio-inspired
algorithms are employed for optimization to tackle the complex online
stochastic scheduling problem. These algorithms include the Genetic Algorithm
(GA), Firefly Optimization (FFO), and Wolf Optimization (WO). These algorithms are harnessed to address the
intricate challenges of online stochastic scheduling. Through rigorous
evaluation, involving the scrutiny of convergence time, runtime, and objective
values, the comparative performance of these algorithms is determined. The
results of this study unveil the effectiveness of the applied bio-inspired
algorithms in optimizing patient scheduling for RT. Among the algorithms
examined, WO emerges as the frontrunner, consistently delivering superior
outcomes across various evaluation criteria. The optimization approach
showcased in this study holds the potential to streamline processes, reduce
manual intervention, and ultimately improve treatment outcomes for patients
undergoing RT.