基于K-Modes聚类与加权K-近邻的脊髓损伤患者适配康复辅具智能决策方法

doi:10.3969/j.issn.0258-8021.2025.06.007

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Abstract The injury segments, nature, and limb muscle strength characteristics of patients with spinal cord injuries are complex and variable. Inappropriate rehabilitation assistive device fitting has long hindered the overall rehabilitation process and efficacy for such patients. This study proposed a smart assistive device fitting decision-making method (KKA) that integrated K-modes clustering with weighted KNN, aiming to enhance the precision and efficiency of assistive device fitting. The study collected clinical data from 600 spinal cord injury patients across different hospitals. A 13-member expert panel comprising cross-disciplinary, cross-professional, and frontline assistive device fitting expert′s consensus determined nine feature attributes, including injury segment, injury nature, limb muscle strength and different fitting schemes. The KAA method comprised three key steps: (1) using entropy weighting and the analytic hierarchy process to determine feature weights and construct a weighted feature space; (2) optimizing the case library structure using the K-modes clustering algorithm to effectively reduce classification bias; and (3) combining weighted KNN case retrieval with a rule-based inference model to generate personalized adaptation prescriptions. The algorithm′s performance was validated using 600 static medical records and 40 medical records tracked dynamically over a one-month period. The study demonstrated that KAA performed exceptionally well in the adaptation of four types of assistive devices, achieving average accuracy and recall rates of 94.6-97.9% and 89.5-97.2%, respectively, indicating that the KAA algorithm possessed high effectiveness and reliability in the field of rehabilitation assistive product recommendation. Additionally, dynamic clinical tracking assessments indicated that the optimal threshold for SCIM improvement in the KAA algorithm was 24.2%, while the optimal threshold for ICF improvement was 2.3%. The AUC values for both SCIM and ICF improvement levels were greater than 0.7, indicating that the KAA method had high diagnostic value in assessing the effectiveness and applicability of rehabilitation assistive product fitting for patients. In conclusion, the KAA method demonstrated significant advantages in terms of fitting accuracy, efficiency, and rehabilitation outcomes, and is expected to provide reliable technical support for precise rehabilitation in spinal cord injury patients.

Key words： spinal cord injury clinical decision-making hybrid reasoning clustering algorithm follow-up evaluation

Received: 18 February 2025

PACS:

R318

About author:: ^#Member,Chinese Society of Biomedical Engineering

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	Li Sujiao
	Shao Jiang
	Liu Qi
	Chen Shizheng
	Yu Hongliu

Cite this article:

Li Sujiao,Shao Jiang,Liu Qi, et al. An Intelligent Decision-Making Method for Rehabilitation Assistive Device Matching inSpinal Cord Injury Patients Based on K-Modes Clustering and Weighted K-Nearest Neighbor[J]. Chinese Journal of Biomedical Engineering, 2025, 44(6): 711-719.

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http://cjbme.csbme.org/EN/10.3969/j.issn.0258-8021.2025.06.007 OR http://cjbme.csbme.org/EN/Y2025/V44/I6/711

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