Wan Yanlin, Liu Dayong, Wang Xiaolong, Wang Limin, Ma Rongxing, Jiang Zhao, Li Wenjing, Gao Bing, Zhang Jingyu, Hu Yongcheng
Clinical School/Colledge of Orthopedics, Tianjin Medical University, No. 406, Jiefang Southern Road, Hexi District, Tianjin, 300029, China.
Department of Orthopedics, Tianjin First Central Hospital, 24 Fukang Rd., Nankai District, Tianjin, 300192, China.
BMC Musculoskelet Disord. 2025 Aug 1;26(1):741. doi: 10.1186/s12891-025-09016-w.
While prior studies have investigated cryopreservation, cross-linkers, and radical scavengers for tendon irradiation protection, optimal implementation protocols remain underexplored. We specifically evaluated temperature-dependent efficacy in preserving human tibialis posterior allograft tendons during 25kgy γ-irradiation.
Twenty-four human tibialis posterior tendons were irradiated at -70 °C, 0 °C and room temperature. Collagen integrity was assessed through: (1) HE/Masson-stained fiber arrangement, (2) Sirius Red-polarized collagen periodicity, (3) hydroxyproline quantification. Biomechanical properties including elastic modulus and maximum stress were measured via tensile testing.
In the - 70 °C group, the structure and morphology of collagen fibers were significantly better than in the 0 °C group. At -70 ºC, collagen damage was 46.27% and 50.03% lower compared to 0ºC (P = 0.016) and RT (P < 0.004). The maximum stress of -70 °C (68.19 ± 30.11 MPa) is superior to that at 0 °C (36.58 ± 12.00 MPa) and RT (41.27 ± 16.34 MPa) (P < 0.01). The histological results based on fiber continuity, crimp integrity, and staining uniformity revealed superior collagen organization at -70 °C (7.2 ± 0.8) versus 0 °C (4.1 ± 1.1, P = 0.016) and RT (3.9 ± 1.3, P < 0.004). Hydroxyproline release was reduced by 46.27% (0 °C) and 50.03% (RT) in the - 70 °C group.
Deep cryogenic preservation (-70 °C) demonstrates enhanced protective effects over conventional refrigeration for γ-irradiated tendon allografts, suggesting temperature optimization as critical in clinical processing protocols.
虽然先前的研究已经对用于肌腱辐射防护的冷冻保存、交联剂和自由基清除剂进行了调查,但最佳实施方案仍未得到充分探索。我们专门评估了在25kgyγ射线照射期间保存人胫后异体移植肌腱时温度依赖性的效果。
将24条人胫后肌腱分别在-70°C、0°C和室温下进行照射。通过以下方式评估胶原完整性:(1)苏木精-伊红/马森染色的纤维排列;(2)天狼星红偏振胶原周期性;(3)羟脯氨酸定量。通过拉伸试验测量包括弹性模量和最大应力在内的生物力学性能。
在-70°C组中,胶原纤维的结构和形态明显优于0°C组。在-70°C时,与0°C(P=0.016)和室温(P<0.004)相比,胶原损伤分别降低了46.27%和50.03%。-70°C时的最大应力(68.19±30.11MPa)优于0°C(36.58±12.00MPa)和室温(41.27±16.34MPa)(P<0.01)。基于纤维连续性、卷曲完整性和染色均匀性的组织学结果显示,-70°C时的胶原组织(7.2±0.8)优于0°C(4.1±1.1,P=0.016)和室温(3.9±1.3,P<0.004)。-70°C组中羟脯氨酸释放量在0°C组降低了46.27%,在室温组降低了50.03%。
深度低温保存(-70°C)对γ射线照射的肌腱异体移植物显示出比传统冷藏更强的保护作用,表明温度优化在临床处理方案中至关重要。
