先進肌肉骨骼超音波電腦輔助診斷:首創用於全身解剖結構即時辨識之低秩適應DETR與大型語言模型智慧診斷前瞻性研究

高駿平; Jyun-Ping Kao

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101372

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳中平	zh_TW
dc.contributor.advisor	Charlie Chung-Ping Chen	en
dc.contributor.author	高駿平	zh_TW
dc.contributor.author	Jyun-Ping Kao	en
dc.date.accessioned	2026-01-27T16:18:25Z	-
dc.date.available	2026-01-28	-
dc.date.copyright	2026-01-27	-
dc.date.issued	2025	-
dc.date.submitted	2026-01-09	-
dc.identifier.citation	[1] T. G. Wang and W. S. Chen, “Musculoskeletal Ultrasound Examination,” Taipei, Taiwan: Leader Book, 2014. [2] del Cura, J. L. (2008). Ultrasound-guided therapeutic procedures in the musculoskeletal system. Current problems in diagnostic radiology, 37(5), 203-218. [3] Lento, P. H., & Primack, S. (2008). Advances and utility of diagnostic ultrasound in musculoskeletal medicine. Current reviews in musculoskeletal medicine, 1, 24-31. [4] Baloch, N., Hasan, O. H., Jessar, M. M., Hattori, S., & Yamada, S. (2018). “Sports Ultrasound”, advantages, indications and limitations in upper and lower limbs musculoskeletal disorders. Review article. International Journal of Surgery, 54, 333-340. [5] Hung, E. H. Y., Griffith, J. F., Hung Ng, A. W., Lee, R. K. L., Lau, D. T. Y., & Leung, J. C. S. (2014). Ultrasound of musculoskeletal soft-tissue tumors superficial to the investing fascia. American Journal of Roentgenology, 202(6), W532-W540. [6] Flores, W. G., de Albuquerque Pereira, W. C., & Infantosi, A. F. C. (2014). Breast ultrasound despeckling using anisotropic diffusion guided by texture descriptors. Ultrasound in medicine & biology, 40(11), 2609-2621. [7] Saba, L., Dey, N., Ashour, A. S., Samanta, S., Nath, S. S., Chakraborty, S., ... & Suri, J. S. (2016). Automated stratification of liver disease in ultrasound: an online accurate feature classification paradigm. Computer methods and programs in biomedicine, 130, 118-134. [8] Litjens, G., Kooi, T., Bejnordi, B. E., Setio, A. A. A., Ciompi, F., Ghafoorian, M., ... & Sánchez, C. I. (2017). A survey on deep learning in medical image analysis. Medical image analysis, 42, 60-88. [9] Krizhevsky, A., Sutskever, I., & Hinton, G. E. (2012). Imagenet classification with deep convolutional neural networks. Advances in neural information processing systems, 25. [10] Zhang, Q., Xiao, Y., Dai, W., Suo, J., Wang, C., Shi, J., & Zheng, H. (2016). Deep learning based classification of breast tumors with shear-wave elastography. Ultrasonics, 72, 150-157. [11] Golan, D., Donner, Y., Mansi, C., Jaremko, J., Ramachandran, M., & CUDL. (2016, September). Fully automating Graf’s method for DDH diagnosis using deep convolutional neural networks. In International Workshop on Deep Learning in Medical Image Analysis (pp. 130-141). Cham: Springer International Publishing. [12] Chiu, P. H., Boudier-Revéret, M., Chang, S. W., Wu, C. H., Chen, W. S., & Özçakar, L. (2022). Deep learning for detecting supraspinatus calcific tendinopathy on ultrasound images. Journal of Medical Ultrasound, 30(3), 196-202. [13] Jegham, N., Koh, C. Y., Abdelatti, M., & Hendawi, A. (2024). Evaluating the evolution of yolo (you only look once) models: A comprehensive benchmark study of yolo11 and its predecessors. arXiv preprint arXiv:2411.00201. [14] Chu, H. Y., Wu, C. H., Chen, P. X., Hung, H. Y., Kao, J. P., Chen, C. P., & Chen, W. S. (2024). Enhancing multi-object detection in ultrasound images through semi-supervised learning, focal loss and relation of frame. Ultrasound in Medicine & Biology, 50(12), 1868-1878. [15] Yeh, C. L., Wu, C. H., Hsiao, M. Y., & Kuo, P. L. (2023). Real-time automated segmentation of median nerve in dynamic ultrasonography using deep learning. Ultrasound in Medicine & Biology, 49(5), 1129-1136. [16] Vaswani, A., Shazeer, N., Parmar, N., Uszkoreit, J., Jones, L., Gomez, A. N., ... & Polosukhin, I. (2017). Attention is all you need. Advances in neural information processing systems, 30. [17] Shamshad, F., Khan, S., Zamir, S. W., Khan, M. H., Hayat, M., Khan, F. S., & Fu, H. (2023). Transformers in medical imaging: A survey. Medical image analysis, 88, 102802. [18] Dosovitskiy, A., Beyer, L., Kolesnikov, A., Weissenborn, D., Zhai, X., Unterthiner, T., ... & Houlsby, N. (2020). An image is worth 16x16 words: Transformers for image recognition at scale. arXiv preprint arXiv:2010.11929. [19] Carion, N., Massa, F., Synnaeve, G., Usunier, N., Kirillov, A., & Zagoruyko, S. (2020, August). End-to-end object detection with transformers. In European conference on computer vision (pp. 213-229). Cham: Springer International Publishing. [20] Perera, S., Adhikari, S., & Yilmaz, A. (2021, September). Pocformer: A lightweight transformer architecture for detection of covid-19 using point of care ultrasound. In 2021 IEEE international conference on image processing (ICIP) (pp. 195-199). IEEE. [21] Gheflati, B., & Rivaz, H. (2022, July). Vision transformers for classification of breast ultrasound images. In 2022 44th annual international conference of the IEEE Engineering in Medicine & Biology Society (EMBC) (pp. 480-483). IEEE. [22] Hu, E. J., Shen, Y., Wallis, P., Allen-Zhu, Z., Li, Y., Wang, S., ... & Chen, W. (2022). Lora: Low-rank adaptation of large language models. ICLR, 1(2), 3. [23] Zhao, Y., Lv, W., Xu, S., Wei, J., Wang, G., Dang, Q., ... & Chen, J. (2024). Detrs beat yolos on real-time object detection. In Proceedings of the IEEE/CVF conference on computer vision and pattern recognition (pp. 16965-16974). [24] Girshick, R., Donahue, J., Darrell, T., & Malik, J. (2014). Rich feature hierarchies for accurate object detection and semantic segmentation. In Proceedings of the IEEE conference on computer vision and pattern recognition (pp. 580-587). [25] Girshick, R. (2015). Fast r-cnn. In Proceedings of the IEEE international conference on computer vision (pp. 1440-1448). [26] Han, S., Kang, H. K., Jeong, J. Y., Park, M. H., Kim, W., Bang, W. C., & Seong, Y. K. (2017). A deep learning framework for supporting the classification of breast lesions in ultrasound images. Physics in Medicine & Biology, 62(19), 7714. [27] Ma, J., Wu, F., Zhu, J., Xu, D., & Kong, D. (2017). A pre-trained convolutional neural network based method for thyroid nodule diagnosis. Ultrasonics, 73, 221-230. [28] Yang, T., Yuan, L., Li, P., & Liu, P. (2023). Real-time automatic assisted detection of uterine fibroid in ultrasound images using a deep learning detector. Ultrasound in Medicine & Biology, 49(7), 1616-1626. [29] Huang, D., Li, C., Karlas, A., Chu, X., Au, K. S., Navab, N., & Jiang, Z. (2025). VibNet: Vibration-Boosted Needle Detection in Ultrasound Images. IEEE Transactions on Medical Imaging. [30] Shin, Y., Yang, J., Lee, Y. H., & Kim, S. (2020). Artificial intelligence in musculoskeletal ultrasound imaging. Ultrasonography, 40(1), 30. [31] Yu, S., Tan, K. K., Sng, B. L., Li, S., & Sia, A. T. H. (2015). Lumbar ultrasound image feature extraction and classification with support vector machine. Ultrasound in medicine & biology, 41(10), 2677-2689. [32] Inui, A., Mifune, Y., Nishimoto, H., Mukohara, S., Fukuda, S., Kato, T., ... & Kuroda, R. (2023). Detection of elbow OCD in the ultrasound image by artificial intelligence using YOLOv8. Applied Sciences, 13(13), 7623. [33] Burlina, P., Billings, S., Joshi, N., & Albayda, J. (2017). Automated diagnosis of myositis from muscle ultrasound: Exploring the use of machine learning and deep learning methods. PloS one, 12(8), e0184059. [34] Zhou, W., Zhou, C., Hu, L., & Qiu, L. (2024). Automated elbow ultrasound image recognition: a two-stage deep learning system via Swin Transformer. Quantitative Imaging in Medicine and Surgery, 15(1), 731. [35] Bradshaw, T. J., Huemann, Z., Hu, J., & Rahmim, A. (2023). A guide to cross-validation for artificial intelligence in medical imaging. Radiology: Artificial Intelligence, 5(4), e220232. [36] Fort, S., Ren, J., & Lakshminarayanan, B. (2021). Exploring the limits of out-of-distribution detection. Advances in neural information processing systems, 34, 7068-7081. [37] Tajbakhsh, N., Shin, J. Y., Gurudu, S. R., Hurst, R. T., Kendall, C. B., Gotway, M. B., & Liang, J. (2016). Convolutional neural networks for medical image analysis: Full training or fine tuning?. IEEE transactions on medical imaging, 35(5), 1299-1312. [38] Zhong, Z., Tang, Z., He, T., Fang, H., & Yuan, C. (2024). Convolution meets lora: Parameter efficient finetuning for segment anything model. arXiv preprint arXiv:2401.17868. [39] Price, W. N., & Cohen, I. G. (2019). Privacy in the age of medical big data. Nature medicine, 25(1), 37-43. [40] Zhu, X., Su, W., Lu, L., Li, B., Wang, X., & Dai, J. (2020). Deformable detr: Deformable transformers for end-to-end object detection. arXiv preprint arXiv:2010.04159. [41] Li, F., Zhang, H., Liu, S., Guo, J., Ni, L. M., & Zhang, L. (2022). Dn-detr: Accelerate detr training by introducing query denoising. In Proceedings of the IEEE/CVF conference on computer vision and pattern recognition (pp. 13619-13627). [42] Zhang, H., Li, F., Liu, S., Zhang, L., Su, H., Zhu, J., ... & Shum, H. Y. (2022). Dino: Detr with improved denoising anchor boxes for end-to-end object detection. arXiv preprint arXiv:2203.03605. [43] Singhal, K., Azizi, S., Tu, T., Mahdavi, S. S., Wei, J., Chung, H. W., ... & Natarajan, V. (2023). Large language models encode clinical knowledge. Nature, 620(7972), 172-180. [44] Singhal, K., Tu, T., Gottweis, J., Sayres, R., Wulczyn, E., Amin, M., ... & Natarajan, V. (2025). Toward expert-level medical question answering with large language models. Nature Medicine, 1-8. [45] Wu, S. H., Tong, W. J., Li, M. D., Hu, H. T., Lu, X. Z., Huang, Z. R., ... & Wang, W. (2024). Collaborative enhancement of consistency and accuracy in US diagnosis of thyroid nodules using large language models. Radiology, 310(3), e232255. [46] Zhang, L., Liu, M., Wang, L., Zhang, Y., Xu, X., Pan, Z., ... & Xie, X. (2024). Constructing a large language model to generate impressions from findings in radiology reports. Radiology, 312(3), e240885. [47] Huang, J., Neill, L., Wittbrodt, M., Melnick, D., Klug, M., Thompson, M., ... & Etemadi, M. (2023). Generative artificial intelligence for chest radiograph interpretation in the emergency department. JAMA network open, 6(10), e2336100-e2336100. [48] Nwachukwu, B. U., Varady, N. H., Allen, A. A., Dines, J. S., Altchek, D. W., Williams III, R. J., & Kunze, K. N. (2025). Currently available large language models do not provide musculoskeletal treatment recommendations that are concordant with evidence-based clinical practice guidelines. Arthroscopy: The Journal of Arthroscopic & Related Surgery, 41(2), 263-275. [49] Getzmann, J. M., Zantonelli, G., Messina, C., Albano, D., Serpi, F., Gitto, S., & Sconfienza, L. M. (2024). The use of artificial intelligence in musculoskeletal ultrasound: a systematic review of the literature. La radiologia medica, 129(9), 1405-1411. [50] Papineni, K., Roukos, S., Ward, T., & Zhu, W. J. (2002, July). Bleu: a method for automatic evaluation of machine translation. In Proceedings of the 40th annual meeting of the Association for Computational Linguistics (pp. 311-318). [51] Zhang, T., Kishore, V., Wu, F., Weinberger, K. Q., & Artzi, Y. (2019). Bertscore: Evaluating text generation with bert. arXiv preprint arXiv:1904.09675. [52] Jain, S., Agrawal, A., Saporta, A., Truong, S. Q., Duong, D. N., Bui, T., ... & Rajpurkar, P. (2021). Radgraph: Extracting clinical entities and relations from radiology reports. arXiv preprint arXiv:2106.14463. [53] Goh, E., Gallo, R., Hom, J., Strong, E., Weng, Y., Kerman, H., ... & Chen, J. H. (2024). Large language model influence on diagnostic reasoning: a randomized clinical trial. JAMA Network Open, 7(10), e2440969-e2440969. [54] Guevara, M., Chen, S., Thomas, S., Chaunzwa, T. L., Franco, I., Kann, B. H., ... & Bitterman, D. S. (2024). Large language models to identify social determinants of health in electronic health records. NPJ digital medicine, 7(1), 6. [55] Lucas, M. M., Yang, J., Pomeroy, J. K., & Yang, C. C. (2024). Reasoning with large language models for medical question answering. Journal of the American Medical Informatics Association, 31(9), 1964-1975. [56] Tanno, R., Barrett, D. G., Sellergren, A., Ghaisas, S., Dathathri, S., See, A., ... & Ktena, I. (2025). Collaboration between clinicians and vision–language models in radiology report generation. Nature Medicine, 31(2), 599-608. [57] Christensen, M., Vukadinovic, M., Yuan, N., & Ouyang, D. (2024). Vision–language foundation model for echocardiogram interpretation. Nature Medicine, 30(5), 1481-1488. [58] Meyer, A., Murali, A., Mutter, D., & Padoy, N. (2024). UltraSam: A Foundation Model for Ultrasound using Large Open-Access Segmentation Datasets. arXiv preprint arXiv:2411.16222. [59] Grattafiori, A., Dubey, A., Jauhri, A., Pandey, A., Kadian, A., Al-Dahle, A., ... & Vasic, P. (2024). The llama 3 herd of models. arXiv preprint arXiv:2407.21783.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101372	-
dc.description.abstract	用於物件偵測的醫學影像模型通常仰賴大量的預訓練資料，但由於醫學資料的稀缺性和隱私限制，造成資料難以獲取。實際上，醫院通常僅能存取預訓練模型的權重，無法取得原始訓練資料，導致難以將模型調整以適應特定的病患族群和成像設備。這種僅共享權重的模式帶來了顯著的挑戰：當醫院在有限的本地資料集上微調這些模型時，傳統微調方法需要改寫數百萬個參數，從而導致模型對於預訓練資料的災難性遺忘和顯著的領域偏移。此類偏移經常導致模型性能大幅的下降，各解剖結構上準確率下降 6-24%，某些關鍵解剖結構甚至下降高達 100%，使原先可偵測的解剖結構完全無法辨識。為了解決上述挑戰，本研究提出首個應用於全身肌肉骨骼超音波的低秩適應（LoRA）增強型即時檢測 Transformer (RT-DETR) 模型。透過在 RT-DETR 的部分編碼器和解碼器層嵌入 LoRA 模組，在保留模型表徵能力的同時，可將訓練參數量分別減少99.45%（RT-DETR-L）和99.68%（RT-DETR-X）。如此大幅的參數精簡使模型僅需利用極少量的本地資料（約為預訓練資料集的10%）即可進行高效微調，不僅在微調資料集中缺乏的解剖結構上仍維持原本的準確率，更顯著提升在本地資料中解剖結構上的辨識準確率。此方法有效模擬了醫院間僅共享模型權重的臨床情境，使接收機構能夠運用自身有限的資料成功微調模型，同時不影響模型在先前已學領域上的性能。在五折交叉驗證實驗中，所提出的 LoRA 增強模型相較於傳統的全模型微調表現更佳，不僅在各類肌肉骨骼結構上維持甚至提升了辨識準確率，還展現出避免領域偏移的特性。我們所提出的 LoRA 增強 RT-DETR 大幅降低了 Transformer 架構物件偵測模型於臨床部署的門檻，提供了一種兼顧隱私且輕量化微調的即時全身肌肉骨骼超音波辨識的解決方法，且無需大量的預訓練或預訓練資料共享即可有效適應各種臨床環境。此外，本研究亦包含了探討將大型語言模型應用於肌肉骨骼超音波的智慧診斷的前瞻性研究。我們利用Llama 3.2 11B Vision 模型並模擬醫師於臨床診斷的報告流程進行微調，以實現生成人工智慧輔助診斷報告。	zh_TW
dc.description.abstract	Medical imaging models for object identification often rely on extensive pretraining data, which is difficult to obtain due to data scarcity and privacy constraints. In practice, hospitals typically have access only to pretrained model weights without the original training data, severely limiting their ability to tailor models to specific patient populations and imaging devices. This weight-only sharing paradigm presents significant challenges: when recipient hospitals fine-tune these models on their limited local datasets, conventional approaches rewrite millions of parameters, triggering catastrophic forgetting and substantial domain shifts. Such shifts frequently result in devastating performance degradation, with accuracy declining by 6-24% across anatomical structures and up to 100% for certain critical structures, essentially rendering some previously detectable features completely unrecognizable. We address these challenges with the first Low-Rank Adaptation (LoRA)-enhanced Real-Time Detection Transformer (RT-DETR) model for full body musculoskeletal (MSK) ultrasound (US). By injecting LoRA modules into select encoder and decoder layers of RT-DETR, we achieved a 99.45% (RT-DETR-L) and 99.68% (RT-DETR-X) reduction in trainable parameters while preserving the model’s representational power. This extreme reduction enables efficient fine-tuning using only minimal institution-specific data (10% of the pretraining dataset) and not only maintains robust performance on anatomical structures absent from the fine-tuning set but also significantly enhances detection accuracy on domain-specific structures. This approach effectively simulates a clinical scenario where hospitals share only model weights, and recipient institutions can successfully adapt these models using their own limited data without compromising performance on previously learned domains. In extensive 5-fold cross-validation, our LoRA-enhanced model outperformed traditional full-model fine-tuning and maintained or improved detection accuracy across a wide range of MSK structures while demonstrating strong resilience to domain shifts. The proposed LoRA-enhanced RT-DETR significantly lowers the barrier for deploying transformer-based detection in clinics, offering a privacy-conscious, computationally lightweight solution for real-time, full-body MSK US identification that can be effectively adapted across diverse clinical settings without requiring extensive retraining or data sharing. Looking beyond detection, we are pioneering research into intelligent diagnosis of MSK US using large language models (LLMs). We have applied the first LLM capable of interpreting sequential ultrasound scans through the Llama 3.2 11B Vision model in a prospective study that mimics clinician workflows for AI assisted diagnostic reporting.	en
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dc.description.provenance	Made available in DSpace on 2026-01-27T16:18:25Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	摘要 I Abstract III Table of Contents V List of Figures VIII List of Tables IX Chapter 1 Introduction 1 1.1 Medical Ultrasound 1 1.2 Computer-Aided Diagnosis in Medical Ultrasound 4 1.3 Constraints of Deep Learning in Medical Applications 5 1.4 Contribution 7 1.5 Organization 8 Chapter 2 Literature Review 10 2.1 Deep Learning in Medical Ultrasound Imaging 10 2.1.1 Object Detection Frameworks 10 2.1.2 CNN-based Lesion Classification in Medical Ultrasound 10 2.1.3 Real-Time Object Detection in Medical Ultrasound 11 2.2 Deep Learning in Musculoskeletal Ultrasound 11 2.2.1 Domain-Specific Features and Classical Methods 11 2.2.2 Deep Learning for Musculoskeletal Pathology Detection 12 2.2.3 Transformer-Based Ultrasound Analysis 13 2.3 Low-Rank Adaptation (LoRA) in Deep Learning 14 2.3.1 Challenges of Model Adaptation in Medical Imaging 14 2.3.2 Low-Rank Adaptation (LoRA) Method 15 2.3.3 Privacy Constraints and Fine-Tuning 15 2.3.4 LoRA-Enhanced RT-DETR for Musculoskeletal Ultrasound 16 Chapter 3 Background 17 3.1.1 Introduction to Transformer model 17 3.1.2 Introduction to Low-Rank Adaptation (LoRA) 20 3.2 Model Framework 26 3.3 Dataset 32 3.4 Training process 35 3.5 Loss Function 37 3.6 Evaluation methods 39 3.7 Ablation studies 42 Chapter 4 Results 44 4.1 Comparison of Overall Performance 44 4.2 Performance of 5-fold cross-validation of RT-DETR-L 47 4.3 Comparative Analysis of LoRA-Enhanced RT-DETR Variants 62 Chapter 5 Discussion 66 Chapter 6 Conclusion 73 Chapter 7 Prospective Study in Intelligent Diagnosis Using Large LanguageModels 75 7.1 Introduction 75 7.2 Literature Review and Background 77 7.2.1 Large Language Models in Medicine 77 7.2.2 LLMs in Radiology and Imaging 78 7.2.3 Ultrasound-specific Vision–Language Models 80 7.2.4 Current Evaluation Metrics and Limitations 81 7.3 Methods 82 7.3.1 Dataset and Preprocessing 83 7.3.2 Prompt Engineering 84 7.3.3 Model Fine-Tuning 86 7.4 Results 86 7.5 Discussion 87 7.6 Conclusion and Future Directions 93 Appendix 97 List of Publications 111 References 112	-
dc.language.iso	en	-
dc.subject	深度學習	-
dc.subject	Transformer	-
dc.subject	微調	-
dc.subject	低秩適應	-
dc.subject	物件偵測	-
dc.subject	肌肉骨骼超音波	-
dc.subject	大型語言模型	-
dc.subject	Deep Learning	-
dc.subject	Transformer	-
dc.subject	Fine-tune	-
dc.subject	Low-Rank Adaptation	-
dc.subject	Object Detection	-
dc.subject	Musculoskeletal Ultrasound	-
dc.subject	Large Language Model	-
dc.title	先進肌肉骨骼超音波電腦輔助診斷:首創用於全身解剖結構即時辨識之低秩適應DETR與大型語言模型智慧診斷前瞻性研究	zh_TW
dc.title	Advancing Computer-Aided Diagnosis in Musculoskeletal Ultrasound: First Low-Rank Adaptation Based DETR for Real-Time Full Body Anatomical Structures Identification with Prospective Study in Intelligent Diagnosis Using Large Language Model	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.coadvisor	陳文翔	zh_TW
dc.contributor.coadvisor	Wen-Shiang Chen	en
dc.contributor.oralexamcommittee	郭柏齡;吳爵宏	zh_TW
dc.contributor.oralexamcommittee	Po-Ling Kuo;Chueh-Hung Wu	en
dc.subject.keyword	深度學習,Transformer微調低秩適應物件偵測肌肉骨骼超音波大型語言模型	zh_TW
dc.subject.keyword	Deep Learning,TransformerFine-tuneLow-Rank AdaptationObject DetectionMusculoskeletal UltrasoundLarge Language Model	en
dc.relation.page	121	-
dc.identifier.doi	10.6342/NTU202504693	-
dc.rights.note	未授權	-
dc.date.accepted	2026-01-09	-
dc.contributor.author-college	電機資訊學院	-
dc.contributor.author-dept	生醫電子與資訊學研究所	-
dc.date.embargo-lift	N/A	-
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