Study on the Characterization of Adult Chinese Dura Mater Material Properties Based on Uniaxial Tensile Testing

Changsheng Cai¹Jinming Wang²Ao Liu³Kaifei Deng²Ying Fan²Jianhua Zhang²Jiang Huang¹Changwu Wan^1*Donghua Zou^1,2*Zhengdong Li^2*

• ¹School of Forensic Medicine, Guizhou Medical University, Guiyang, Guizhou, China
• ²Shanghai Key Laboratory of Forensic Medicine, Academy of Forensic Science, Shanghai, China
• ³Hunan University of Science and Technology, Xiangtan, Hunan Province, China

This study investigated the biomechanical properties of the dura mater from 29 Chinese adult donors (20 -86 years), focused on the influence of age, anatomical region, sex and loading direction, to establish Chinese population -specific material parameters for cranial finite element (FE) models and enhance forensic traumatic brain injury analysis. In this study, a total of 275 dural specimens were prepared and categorized into young adult (20-44 years), middle aged (45-64 years), and elderly (≥65 years) cohorts. Samples were excised from frontal, temporal, parietal and occipital regions and tested uniaxially in sagittal and coronal directions, with strain measured via digital image correlation (DIC) techniques. True stress-strain curves were fitted to the Raghavan model to determine elastic fiber modulus (EE), collagen fiber modulus (EC), failure stress (σTf ), and failure strain (εTf); ultimate tensile force (MaxForce) was also recorded. Histological analysis assessed age-related microstructural changes. Results indicated significant age-related degradation: EC, σTf, εTf; and MaxForce significantly decreased with age (median EC declined from 28.0 MPa in young adults to 15.3 MPa in the elderly, P < 0.05; median εTf from 0.215 to 0.156, P < 0.05), while EE showed no significant age correlation (P=0.10). Significant regional variance were observed, with the parietal region exhibiting higher EE (P=0.01) and σTf (P=0.03) compared to the occipital region; εTf showed no significant regional differences (P=0.12). Dura mater demonstrated clear anisotropy: sagittal loading yielded significantly higher median EC (27.0 MPa vs. 18.1 MPa coronal, P=0.003), σTf (4.30 MPa vs. 3.18 MPa coronal, P=0.020), and MaxForce (12.9 N vs. 10.3 N coronal, P=0.014). No statistically significant sex-based differences were found for any parameter (P > 0.05). Histology confirmed progressive age-related collagen disorganization and elastic fiber degradation. In conclusion, Chinese adult dura mater exhibits significant age-dependent decline in mechanical integrity, clear anisotropy favoring the sagittal direction, and notable regional heterogeneity, but no significant sex-based differences. These findings provide crucial, population-specific data for improving the biofidelity of FE head models and forensic injury analysis.