Establishment and test results of HFNet model for burn and scald wound depth assessment

doi:10.3877/cma.j.issn.1673-9450.2025.03.002

Abstract

Abstract:

Objective

To establish a global-local feature hierarchical fusion image classification network model，improve the reliability and accuracy of burn and scald wound depth assessment.

Methods

A total of 619 wound images of burn and scald patients who were admitted to the Department of Burn and Plastic Surgery at Ruijin Hospital Affiliated to Shanghai Jiao Tong University School of Medicine were collected.Two burn physicians with more than 3 years of work experience independently annotated the images using the image annotation tool LabelMe， and cross validated with other physicians in the department.The image set was divided into a training set， validation set， and test set in a ratio of 7∶2∶1， and the training set was expanded to obtain 2 598 images.Designed and constructed a global-local feature hierarchical fusion network HFNet for pre-training， learned the basic features of images and transferred them to the collected burn image classification dataset.Improved classification accuracy through parameter optimization and compared the precision， recall， F1 score， and inference time of the HFNet model with ConvNeXt， Swin-Transformer，UniFormer， and BiFormer models to evaluate its performance.

Results

Testing results showed that the precision of the HFNet model in the classification tasks of first-degree， second-degree， and third-degree burn wounds was 93.53%， 94.08%， and 86.52%， respectively， with a mean of 91.63%.The recall rates were 91.99%， 89.89%， and 92.71%， respectively， with a mean of 91.69%.The F1 index was 93.56%， 90.96%，and 90.46%， respectively， with a mean of 91.66%.The average accuracy was 92.75%， 91.94%， and 89.51%，respectively， with an average accuracy of 91.40%.The confusion matrix showed that the accuracy of the HFNet model in the classification tasks of first-degree， second-degree， and third-degree burn wounds was 90%，92%， and 93%， respectively.Compared to models such as BiFormer， the HFNet model achieved higher precision with moderate inference speed， striking a good overall balance between accuracy and computational efficiency.

Conclusion

The HFNet model enhances the accuracy and efficiency of burn depth assessment，providing burn specialists with precise classification information to rapidly determine the severity of burn injuries.Additionally， the model enables the accumulation of high-quality classification data， supporting further model optimization.

Key words: Burns, Deep learning, Adaptive feature fusion, Burn depth recognition

Kecheng Zhang, Rui Wang, Lei Yi, Zengding Zhou. Establishment and test results of HFNet model for burn and scald wound depth assessment[J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(03): 192-198.

/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: https://zhssyxfzz.cma-cmc.com.cn/EN/10.3877/cma.j.issn.1673-9450.2025.03.002

https://zhssyxfzz.cma-cmc.com.cn/EN/Y2025/V20/I03/192

Figures/Tables 5

References 24

［1］	Atiyeh B， Gunn S， Hayek S.Military and civilian burns during armed conflicts［J］.Ann Burns Fire Disasters，2007，20（4）：203-215.
［2］	Chang CW， Ho CY， Lai F， et al.Application of multiple deep learning models for automatic burn wound assessment［J］.Burns，2023， 49（5）： 1039-1051.
［3］	张嘉炜，王瑞，张克诚，等.基于深度学习的皮肤烧烫伤创面图像分割与分类及检测的研究进展［J］.中华损伤与修复杂志（电子版）， 2024， 19（2）： 172-175.
［4］	Dosovitskiy A， Beyer L， Kolesnikov A， et al.An image is worth 16×16 words： transformers for image recognition at scale［C］//Proceedings of the 9th International Conference on Learning Representations （ICLR）.2021： arXiv：2010.11929.
［5］	Cirrincione G， Cannata S， Cicceri G， et al.Transformer-based approach to melanoma detection［J］.Sensors， 2023， 23（12）：5677.
［6］	Yuan F， Peng Y， Huang Q， et al.A bi-directionally fused boundary aware network for skin lesion segmentation［J］.IEEE Trans Image Process，2024，33：6340-6353.
［7］	Liu Z， Mao H， Wu CY， et al.A convnet for the 2020s［C］//Proceedings of the IEEE/CVF conference on computer vision and pattern recognition.2022： 11976-11986.
［8］	Liu Z， Lin Y， Cao Y， et al.Swin transformer： hierarchical vision transformer using shifted windows［C］//Proceedings of the IEEE/CVF international conference on computer vision.2021： 10012-10022.
［9］	Li K， Wang Y， Zhang J， et al.Uniformer： unifying convolution and self-attention for visual recognition［J］.IEEE Trans Pattern Anal Mach Intell， 2023， 45（10）： 12581-12600.
［10］	Zhu L， Wang X， Ke Z， et al.Biformer： vision transformer with bi-level routing attention［C］//Proceedings of the IEEE/CVF conference on computer vision and pattern recognition.2023：10323-10333.
［11］	Feizkhah A， Mobayen M， Habibiroudkenar P， et al.The importance of considering biomechanical properties in skin graft：are we missing something？［J］.Burns， 2022， 48（7）： 1768-1769.
［12］	Pabitha C， Vanathi B.Densemask RCNN： a hybrid model for skin burn image classification and severity grading［J］.Neural Processing Letters， 2021， 53（1）： 319-337.
［13］	Wearn C， Lee KC， Hardwicke J， et al.Prospective comparative evaluation study of Laser Doppler Imaging and thermal imaging in the assessment of burn depth［J］.Burns， 2018， 44（1）： 124-133.
［14］	Dang J， Lin M， Tan C， et al.Use of infrared thermography for assessment of burn depth and healing potential： a systematic review［J］.J Burn Care Res， 2021， 42（6）： 1120-1127.
［15］	Korotkova O， Gbur G.Applications of optical coherence theory［J］.Progress in Optics， 2020， 65： 43-104.
［16］	He X， Tan EL， Bi H， et al.Fully transformer network for skin lesion analysis［J］.Med Image Anal， 2022， 77： 102357.
［17］	Pacal I.A novel Swin transformer approach utilizing residual multi-layer perceptron for diagnosing brain tumors in MRI images［J］.International Journal of Machine Learning and Cybernetics， 2024， 15（9）： 3579-3597.
［18］	Hassan E， Hossain MS， Saber A， et al.A quantum convolutional network and ResNet（ 50）-based classification architecture for the MNIST medical datase［tJ］.Biomedical Signal Processing and Control， 2024， 87： 105560.
［19］	Suo Y， He Z， Liu Y.Deep learning CS-ResNet-101 model for diabetic retinopathy classification［J］.Biomedical Signal Processing and Control， 2024， 97： 106661.
［20］	Suha SA， Sanam TF.A deep convolutional neural networkbased approach for detecting burn severity from skin burn images［J］.Machine Learning with Applications， 2022， 9：100371.
［21］	Yıldız M， Sarpdağı Y， Okuyar M， et al.Segmentation and classification of skin burn images with artificial intelligence：development of a mobile application［J］.Burns， 2024， 50（4）：966-979.
［22］	Zhang B， Zhou J.Multi-feature representation for burn depth classification via burn images［J］.Artif Intell Med，2021， 118：102128.
［23］	Rangel-Olvera B， Rosas-Romero R.Detection and classification of burnt skin via sparse representation of signals by over-redundant dictionaries［J］.Comput Biol Med，2021， 132： 104310.
［24］	张嘉炜，王瑞，张克诚，等.烧烫伤创面深度智能检测模型P-YOLO的建立及测试效果［J］.中华损伤与修复杂志（电子版），2024， 19（5）： 379-385.

模型	查准率（%）	召回率（%）	F1指数（%）	推理时间（ms）
ConvNeXt ^［7］	81.90	79.06	80.45	92
Swin-Transformer ^［8］	82.09	80.65	81.36	91
UniFormer ^［9］	87.67	83.54	85.56	49
BiFormer ^［10］	89.66	83.47	86.45	58
HFNet	91.63	91.69	91.66	66

模型	查准率（%）	召回率（%）	F1指数（%）	推理时间（ms）
ConvNeXt ^［7］	81.90	79.06	80.45	92
Swin-Transformer ^［8］	82.09	80.65	81.36	91
UniFormer ^［9］	87.67	83.54	85.56	49
BiFormer ^［10］	89.66	83.47	86.45	58
HFNet	91.63	91.69	91.66	66

[1]	Shuhan Sun, Yajing Chen, Qingqing Zong, Cuiying Li, Shumei Miao, Bin Yang, Feihong Yu. Ultrasound-based deep learning nomogram for predicting axillary lymph node status after neoadjuvant chemotherapy for breast cancer [J]. Chinese Journal of Medical Ultrasound (Electronic Edition), 2025, 22(02): 97-105.
[2]	Yahong Hou, Na Li, Xiaxia Zhang, Hongjun Di. Analysis of clinical characteristics and treatment in inpatients with extensive burns [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(02): 128-132.
[3]	Ning Sun, Guangyi Wang, Lijing Zhu, Ping Feng, Jingwen He, Like Zhang, We Yi, Chenyue Qiu, Guosheng Wu. Visual analysis of research status and trends on inhalation injury based on CiteSpace [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(01): 22-29.
[4]	Sida Xu, Yaohua Yu, Pei Xu, Yanyan Pan, Xin Le, Weiwei Wu, Youfen Fan. Effects of hsa_circ_0001618 on the proliferation， migration， and apoptosis of post-burn skin fibroblasts through the miR-184/LARP1 pathway [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(01): 61-67.
[5]	Haoran Tang, Biao Zhou, Te Ba, Yangyang Li. Research progress of biomarkers related to early diagnosis of sepsis after severe burn [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(01): 70-74.
[6]	Tuo Shen, Feng Zhu. Clinical significance of heteroresistance in nonfermenting gram-negative bacilli infection in burn patients [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2025, 20(01): 75-80.
[7]	Ling Peng, Hong Wu, Shiyong Wan, Lan Chen, Ziqing Ye, Jing Zhou. Observation on the efficacy of collagenase ointment combined with hydrogel dressing in the treatment of deep partial-thickness burn wounds [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2024, 19(06): 511-516.
[8]	Tonghui Lin, Weixi Yang. Research progress on the application of anterolateral thigh perforator flap in the treatment of electrical burns [J]. Chinese Journal of Injury Repair and Wound Healing(Electronic Edition), 2024, 19(06): 526-530.
[9]	Wenbo Zhuang, Yue Hu, Qinhao Chen, Li Shang, Yitian Zhang, Haijun Gui. Advances in research and application of convolutional neural network - assisted automated target detection of anatomical landmarks in three-dimensional cephalograms [J]. Chinese Journal of Stomatological Research(Electronic Edition), 2025, 19(01): 70-74.
[10]	Li Ye, Yu Du. Application of deep learning in clinical diagnosis and treatment of pulpal and periapical diseases [J]. Chinese Journal of Stomatological Research(Electronic Edition), 2024, 18(06): 351-356.
[11]	Yue Zhang, Ke Zhang, Sisi Deng, Qing Xiang, Yahao Guo, Jian Cao, Tao Luo, Zhan'ao Meng. Application of deep learning-based image reconstruction with three low scheme in renal artery angiography [J]. Chinese Journal of Endourology(Electronic Edition), 2025, 19(01): 76-82.
[12]	Junlong Huang, Wenshuang Li, Xiaoyang Li, bolong Liu, Yilong Chen, Huiping Qiu, Xiangfu Zhou. Application of artificial intelligence model based on pelvic floor ultrasound for the diagnosis of female stress urinary incontinence [J]. Chinese Journal of Endourology(Electronic Edition), 2024, 18(06): 597-605.
[13]	Mingjie Zhang, Mengna Li, Mingyao Chen, Yuliang Wang, Yongjian Nian, Ruicheng Zhao, Yu Yang, Muyuan Liu, Yuan Liao, Chao Tang. Construction and optimization of the deep learning model for pulmonary ultrasound screening with plateau pulmonary edema [J]. Chinese Journal of Lung Diseases(Electronic Edition), 2025, 18(01): 68-73.
[14]	Zexin Yin, Jilin Yang, Youyao Li, Meilong Wu, Liping Liu. Research progress in preoperative prediction of microvascular invasion in liver cancer [J]. Chinese Journal of Hepatic Surgery(Electronic Edition), 2025, 14(01): 128-134.
[15]	Mingyuan Sun, Heng Chu, Haibin Xu, Zhe Zhang. Progress in application of artificial intelligence in diagnosis of multiple pulmonary nodules [J]. Chinese Journal of Clinicians(Electronic Edition), 2024, 18(08): 785-790.

Please choose a citation manager

Content to export