Artificial General Intelligence for Radiation Oncology

This paper provides an overview of how Artificial General Intelligence (AGI) can transform radiation oncology to elevate the standard of patient care, with the key insight being AGI's ability to exploit multimodal clinical data at scale.
Radiation Oncology:- This paper provides an overview of how Artificial General Intelligence (AGI) can transform radiation oncology to elevate the standard of patient care, with the key insight being AGI's ability to exploit multimodal clinical data at scale.[Wikimedia Commons]
Radiation Oncology:- This paper provides an overview of how Artificial General Intelligence (AGI) can transform radiation oncology to elevate the standard of patient care, with the key insight being AGI's ability to exploit multimodal clinical data at scale.[Wikimedia Commons]
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Radiation Oncology:- This paper provides an overview of how Artificial General Intelligence (AGI) can transform radiation oncology to elevate the standard of patient care, with the key insight being AGI's ability to exploit multimodal clinical data at scale.

An estimated 600,000 people in the United States succumb to cancer every year. Beyond surgery, chemotherapy, and immunotherapy, radiotherapy has shown to be a standard and effective treatment option for nearly 50-70 percent of cancer patients.

Radiotherapy treatment involves six basic stages: initial consultation, simulation, treatment planning, treatment delivery, treatment verification and patient follow-up. With the emergence of Artificial intelligence (AI), radiotherapy is undergoing substantial transformation. AI achieves human-level accuracy in the auto-segmentation, tumor staging, image registration, automatic treatment planning, quality assurance and outcomes prediction, which greatly improves the accuracy, precision, and efficiency of radiation therapy.

According to a recent review published in the KeAi journal Meta-Radiology, pioneering AGI models, such as GPT-4 and PaLM 2, along with large vision models (LVMs) like the Segment Anything Model (SAM), are capable of processing extensive texts and imaging data, respectively. AGI, distinguished by its advanced capabilities in few-shot and zero-shot learning, offers a pathway towards developing highly robust and generalizable AI models. These models are imperative for seamless and effective integration into the various facets of radiation oncology.

They found that the fusion of vision data with LLMs also creates powerful multimodal models that elucidate nuanced clinical patterns. Together, AGI has the potential to catalyze a shift towards data-driven, personalized radiation therapy. The authors stressed that these models should complement human expertise and care.

The findings provide an overview of how AGI can transform radiation oncology to elevate the standard of patient care, with the key insight being AGI’s ability to exploit multimodal clinical data at scale. In addition, the researchers explore the future directions of AGI in radiation oncology and discuss potential developments and bottlenecks in this field. These advancements in clinical applications will further enhance the effectiveness of radiation therapy, bringing more positive outcomes for cancer patients.

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