Sclera Vessel Segmentation Based on Fusion Filtering and Reflection Suppression

Ming-Xuan FAN; Zong-Qing MA; Chu-Xiang GAO; Yi-Xuan SHI; Zi-Hang ZHANG; Zhe-Xuan JIA; Fan FAN; Guo-Liang HUANG; Jiang ZHU

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Sclera Vessel Segmentation Based on Fusion Filtering and Reflection Suppression

VernacularTitle:基于融合滤波与反光抑制的巩膜血管分割算法研究
Author: Ming-Xuan FAN ¹ ; Zong-Qing MA ¹ ; Chu-Xiang GAO ¹ ; Yi-Xuan SHI ² ; Zi-Hang ZHANG ¹ ; Zhe-Xuan JIA ¹ ; Fan FAN ¹ ; Guo-Liang HUANG ² ; Jiang ZHU ¹
Author Information

1. Laboratory of Optical Imaging and Medical Instruments, School of Instrumentation Science and Opto-electronics Engineering, Beijing Information Science and Technology University, Beijing 102206, China
2. School of Biomedical Engineering, Tsinghua University, Beijing 100084, China
Publication Type:Journal Article
Keywords: eye diagnosis in traditional Chinese medicine; sclera vessel segmentation; fusion filtering; reflection suppression
From: Progress in Biochemistry and Biophysics 2026;53(5):1195-1206
CountryChina
Language:Chinese
Abstract: ObjectiveIn traditional Chinese medicine (TCM), the foundational doctrine that the eyes reflect the essence of the internal viscera establishes ocular observation as a cornerstone of diagnostic practice. Specifically, the morphological characteristics and coloration variations of the scleral microvasculature serve as critical clinical indicators for assessing the dynamic balance of Qi and Blood, as well as the pathological status of internal organs. Historically, however, TCM eye diagnosis has relied predominantly on the subjective clinical experience and visual acuity of individual practitioners, leading to inherent challenges in standardization and reproducibility. While automated computer-aided diagnostic systems offer a promising solution, existing vessel segmentation algorithms encounter significant domain-specific bottlenecks when applied to scleral imagery. These challenges primarily stem from the highly reflective and moist nature of the ocular surface, which generates severe reflective interference. Furthermore, the inherent low contrast of fine capillary networks against complex background textures, compounded by non-uniform illumination, frequently results in high false-positive rates, misdetections, and severe vessel fragmentation. To address these critical limitations and advance the objective quantification of TCM diagnostics, this paper proposes a novel, highly robust sclera vessel segmentation framework that innovatively integrates Frangi-Sato dual-filter adaptive enhancement with pixel-level reflection detection. MethodsThe proposed methodology systematically addresses the segmentation pipeline through three synergistic stages. First, to overcome the structural limitations of single-filter approaches, a multi-scale weighted fusion strategy is meticulously designed to harness the complementary extraction capabilities of both Frangi and Sato filters. This adaptive enhancement optimally balances the preservation of main vessel trunk continuity with the heightened sensitivity required for delineating delicate, low-contrast peripheral capillaries. Second, to tackle the persistent issue of reflective highlights, a sophisticated multi-feature synergistic reflection detection module is introduced. By jointly analyzing local information entropy, gradient field variations, and intensity statistical distributions, this module achieves precise, pixel-level identification and elimination of reflective artifacts without compromising the underlying vascular structures. Finally, a dual-level adaptive thresholding strategy, featuring an innovative “core protection” mechanism, is implemented. This critical step effectively suppresses complex background noise while rigorously preserving the structural and topological integrity of the intricate vessel network, preventing the structural breaks often seen in conventional binarization methods. ResultsThe efficacy of the proposed framework was rigorously evaluated using both self-constructed clinical datasets specifically acquired for TCM research and standardized public datasets. Extensive experimental results demonstrate that the proposed method consistently outperforms state-of-the-art traditional approaches and contemporary deep learning models. Specifically, the proposed method achieves a Dice similarity coefficient of approximately 0.71 on the private clinical dataset, and secures the best performance across the majority of quantitative metrics on both datasets. Notably, the framework exhibits exceptional robustness and generalization capabilities in highly challenging scenarios characterized by intense reflective interference, low signal-to-noise ratios, and cross-domain image variations. ConclusionThis study successfully realizes the high-integrity, automated segmentation of scleral vessel networks under complex clinical imaging conditions. By overcoming the fundamental algorithmic challenges of reflection interference and micro-vessel loss, the proposed methodology provides potential support for the digitization, objective standardization, and intelligent advancement of modern TCM eye diagnosis systems.