toplogo
Log på

Unlocking the Power of Language Models in Biomedical Imaging Tasks


Kernekoncepter
Residual-based large language models (LLMs) can significantly enhance performance in biomedical imaging tasks, setting new benchmarks in 2D and 3D classification.
Resumé
  • Language models traditionally used for text processing are now proven to be effective encoders for biomedical imaging tasks.
  • A novel approach using frozen transformer blocks from pre-trained LLMs as boosters shows significant performance improvements.
  • The study explores the potential of LLMs in biomedical imaging, offering new avenues for research and application.
  • Detailed experiments and results across various datasets and tasks demonstrate the effectiveness of LLMs in enhancing biomedical image analysis.
edit_icon

Tilpas resumé

edit_icon

Genskriv med AI

edit_icon

Generer citater

translate_icon

Oversæt kilde

visual_icon

Generer mindmap

visit_icon

Besøg kilde

Statistik
The proposed framework achieved state-of-the-art results on extensive datasets in MedMNIST-2D and 3D. Performance improvements were observed across a spectrum of biomedical imaging applications. The ViT model outperformed existing state-of-the-art methods in several datasets.
Citater
"In pursuit of understanding the capability of LLMs in visual tasks, our research offers a novel and affirmative insight." "We introduce a novel residual-based framework that incorporates a frozen transformer block from pre-trained LLMs as a visual encoder layer."

Vigtigste indsigter udtrukket fra

by Zhixin Lai,J... kl. arxiv.org 03-27-2024

https://arxiv.org/pdf/2403.17343.pdf
Language Models are Free Boosters for Biomedical Imaging Tasks

Dybere Forespørgsler

How can the findings of this study be applied to other domains beyond biomedical imaging?

The findings of this study can be applied to other domains beyond biomedical imaging by leveraging the innovative approach of using residual-based large language models (LLMs) as encoders for visual tasks. This methodology can be adapted to various industries such as autonomous vehicles, robotics, agriculture, manufacturing, and more. By incorporating frozen transformer blocks from pre-trained LLMs as boosters, these models can enhance performance in tasks requiring image analysis, object recognition, and pattern detection. The versatility of LLMs in processing visual data opens up opportunities for applications in diverse fields where image interpretation and classification are essential.

What are the potential limitations or drawbacks of using LLMs as boosters in visual tasks?

While using LLMs as boosters in visual tasks offers significant benefits, there are potential limitations and drawbacks to consider. One limitation is the computational resources required to train and fine-tune large transformer models, especially when dealing with high-resolution images or complex datasets. Additionally, the interpretability of LLMs in visual tasks may pose challenges, as understanding the decision-making process of these models can be complex. Another drawback is the potential bias or lack of diversity in the pre-trained language models, which can impact the performance and generalization of the visual tasks. Furthermore, the integration of LLMs may introduce additional complexity to the model architecture, requiring careful optimization and tuning to achieve optimal results.

How might the integration of LLMs reshape the landscape of AI applications in healthcare and beyond?

The integration of LLMs in healthcare and beyond has the potential to reshape the landscape of AI applications by revolutionizing the way visual tasks are approached and solved. In healthcare, LLMs can enhance medical image analysis, disease diagnosis, and treatment planning by providing more accurate and efficient solutions. The use of LLMs as boosters in visual tasks can lead to improved patient outcomes, reduced errors, and enhanced diagnostic processes. Beyond healthcare, the integration of LLMs can transform industries such as autonomous driving, agriculture, manufacturing, and more by enabling advanced image recognition, object detection, and predictive analytics. This integration can drive innovation, efficiency, and automation in various sectors, paving the way for new applications and advancements in AI technology.
0
star