R2Gen-Mamba offers a more efficient approach to automatic radiology report generation by combining the Mamba model's efficient sequence processing with the contextual understanding of Transformer architectures, resulting in high-quality reports with reduced computational burden.
従来のレントゲンレポート生成における評価指標は、専門用語の多用により、患者の理解を妨げ、モデルの学習を歪ませる可能性がある。本稿では、専門用語を使わない、わかりやすい言葉で記述されたレポート生成の枠組みを提案し、より正確な評価と、より人間らしい解釈の実現を目指す。
This research proposes a novel framework called Layman's RRG, which leverages layman's terms to improve the generation and evaluation of radiology reports, addressing the limitations of traditional word-overlap metrics and the highly technical nature of medical language.
This paper introduces X-RGen, a novel framework for generating radiology reports across multiple anatomical regions, mimicking the reasoning process of human radiologists to improve accuracy and clinical relevance.
This paper introduces SAE-Rad, a novel approach using sparse autoencoders (SAEs) to generate interpretable radiology reports by decomposing image features into human-understandable concepts, achieving competitive performance with fewer resources compared to traditional VLMs.
Improving the inter-report consistency of radiology report generation by extracting lesions, examining their characteristics, and using a lesion-aware mixup technique to align the representations of semantically equivalent lesions.
SERPENT-VLM introduces a self-refining mechanism that leverages the similarity between the pooled image representation and the contextual representation of the generated radiological text to improve the accuracy and coherence of radiology report generation, reducing hallucination.
Radiology report generation (RRG) aims to automatically generate free-text descriptions from clinical radiographs, which plays an essential role in promoting clinical automation and assisting inexperienced doctors and radiologists.
A memory-based cross-modal semantic alignment network is proposed to generate accurate and fluent radiology reports by learning disease-related representations and prior knowledge shared between radiology images and reports, and performing fine-grained feature consolidation with semantic alignment.
The author introduces a novel method, LM-RRG, that combines large models with clinical quality reinforcement learning to generate accurate and comprehensive chest X-ray radiology reports. The approach aims to address the shortcomings of current methods by emphasizing specific regions with medical significance and incorporating a novel clinical quality reinforcement learning strategy.