Application of photocrosslinkable nanofiber scaffold loaded with decellularized cartilage matrix in cartilage tissue engineering

doi:10.12307/2026.457

Abstract

Abstract: BACKGROUND: Tissue engineering strategies, particularly those based on decellularized cartilage matrix and biomimetic scaffolds, offer new therapeutic directions for cartilage regeneration.
OBJECTIVE: To develop a photocrosslinkable nanofiber scaffold loaded with decellularized cartilage matrix and evaluate its potential for cartilage tissue engineering.
METHODS: (1) Decellularized cartilage matrix was prepared by enzymatic digestion and a combined chemical-ultrasonic method. A photocrosslinkable polyvinyl alcohol-glycidyl methacrylate polymer was synthesized. 8% polymer solution and 3% decellularized cartilage matrix solution were mixed at volume ratios of 8:1, 4:1, and 2:1 to prepare electrospinning precursor solutions. Nanofiber scaffolds were fabricated using electrospinning technology, designated as PVA-GMA-dECM(8:1), PVA-GMA-dECM(4:1), and PVA-GMA-dECM(2:1), respectively. A polyvinyl alcohol-glycidyl methacrylate nanofiber scaffold (PVA-GMA) was also prepared. The microstructure of each scaffold was characterized. Chondrocytes were co-cultured non-contact with the four types of ultraviolet-irradiated crosslinked scaffolds using Transwell chambers, and cell proliferation was detected by the CCK-8 assay. Based on morphological observations and CCK-8 results, a suitable scaffold was selected for subsequent experiments. (2) The surface water contact angle and maximum tensile stress of PVA-GMA, PVA-GMA-dECM(8:1), and PVA-GMA-dECM(4:1) were measured. Based on these results, a suitable scaffold was selected for further experiments. Chondrocytes were co-cultured non-contact with ultraviolet-irradiated crosslinked PVA-GMA and PVA-GMA-dECM(4:1) using Transwell chambers. EdU staining and live/dead staining were used to assess cell proliferation and viability, and scratch assay and invasion assay were used to evaluate cell migration ability. (3) Using a Transwell chamber, chondrocytes were co-cultured non-contact with ultraviolet-irradiated cross-linked PVA-GMA and PVA-GMA-dECM (4:1). After chondrogenic induction culture, the chondrogenic differentiation efficiency was evaluated by Alcian blue staining, RT-qPCR (detecting type II collagen and Sox9 mRNA expression), immunofluorescence staining (detecting type II collagen and aggrecan expression), and western blot assay (detecting type II collagen and Sox9 protein expression).
RESULTS AND CONCLUSION: (1) Scanning electron microscopy showed that a high proportion of decellularized cartilage matrix (2:1) affected the fiber morphology, while a 4:1 ratio yielded well-structured nanofibers. CCK-8 assay showed that PVA-GMA-dECM promoted ATDC5 chondrocyte proliferation compared with PVA-GMA. Based on the results of these two experiments, PVA-GMA-dECM (2:1) was excluded from subsequent experiments. The water contact angle of PVA-GMA-dECM (4:1) was lower than that of PVA-GMA and PVA-GMA-dECM (8:1), and the maximum tensile strength was greater than that of PVA-GMA and PVA-GMA-dECM (8:1). Therefore, PVA-GMA-dECM (8:1) was excluded from subsequent experiments. Live/dead staining and EdU staining showed that both PVA-GMA and PVA-GMA-dECM (4:1) maintained cell viability, and PVA-GMA-dECM (4:1) had a better cell proliferation effect than PVA-GMA. PVA-GMA-dECM (4:1) had a stronger cell migration ability than PVA-GMA. PVA-GMA-dECM (4:1) had a stronger chondrogenic differentiation efficiency than PVA-GMA. (2) The results show that PVA-GMA-dECM (4:1) exhibits excellent bioactivity and can effectively promote chondrocyte proliferation, migration, and chondrogenic differentiation, making it a promising scaffold material for cartilage tissue engineering.

Key words: electrospinning, decellularized cartilage matrix, photocrosslinking modification, cartilage repair, tissue engineering, cartilage regeneration

CLC Number:

Zhu Jisheng, Teng Jianxiang, Zou Zihao, Pan Jiazhao, Zhou Tianqi, Shu Xiaolin, He Cheng, Yuan Daizhu, Tian Xiaobin . Application of photocrosslinkable nanofiber scaffold loaded with decellularized cartilage matrix in cartilage tissue engineering[J]. Chinese Journal of Tissue Engineering Research, 2026, 30(32): 8402-8412.

Figures/Tables 5

2.2 支架表征结果 2.2.1 支架形貌扫描电镜显示，聚乙烯醇-甲基丙烯酸缩水甘油酯具有良好的可纺性，脱细胞软骨基质溶液的加入使得纳米纤维直径逐渐降低，PVA-GMA纳米纤维直径为(87.25±31.18) nm，PVA-GMA-dECM(2∶1)纳米纤维直为(58.69±20.32) nm，但当脱细胞软骨基质溶液体积过高时[PVA-GMA-dECM(2∶1)]，可见部分未分散的脱细胞软骨基质影响了聚乙烯醇-甲基丙烯酸缩水甘油酯的可纺性能(图2A)。 2.2.2 细胞增殖培养1 d后，各组细胞吸光度值比较差异无显著性意义(P > 0.05)；培养3，5 d，各实验组细胞吸光度值高于对照组(P < 0.000 1)，PVA-GMA-dECM(8∶1)组、PVA-GMA-dECM(4∶1)组、PVA-GMA-dECM(2∶1)组细胞吸光度值高于PVA-GMA组(P < 0.000 1)，见图2B。结合支架形貌观察结果，由于PVA-GMA-dECM(2∶1)的可纺性能受到影响，因此排除该组进行以下检测。 2.2.3 亲水性能脱细胞软骨基质溶液的加入使得纳米纤维的亲水性能明显改善，PVA-GMA的水接触角为(125.97±0.66)°，PVA-GMA(8∶1)的水接触角为(47.23±0.71)°，PVA-GMA-dECM(4∶1)的接触角为(37.33±0.51)°，相较于PVA-GMA和PVA-GMA-dECM(8∶1)，PVA-GMA(4∶1)的水接触角显著降低(P < 0.000 1)，见图2C，表明PVA-GMA(4∶1)的亲水性能更好。 2.2.4 力学测试 PVA-GMA、PVA-GMA-dECM(8∶1)、PVA-GMA-dECM(4∶1)的力-位移曲线，见图2D。PVA-GMA、PVA-GMA-dECM(8∶1)、PVA-GMA-dECM(4∶1)的最大拉力分别为(3.438 0±1.206 5)，(6.370 0±1.027 0)，(9.472 7±0.756 4) N，组间两两比较差异均有显著性意义，见图2E。结合亲水性能检测结果，认为PVA-GMA-dECM(4∶1)为合适的支架，所以后续实验排除PVA-GMA-dECM(8∶1)。 2.2.5 支架的组成成分傅里叶变换红外光谱图显示，3 300 cm-1附近的强信号为聚乙烯醇-甲基丙烯酸缩水甘油酯中游离-OH的伸缩振动信号，2 900 cm-1附近的信号为聚乙烯醇-甲基丙烯酸缩水甘油酯和脱细胞软骨基质结构中饱和C-H的伸缩振动信号，1 600 cm-1附近的信号为聚乙烯醇-甲基丙烯酸缩水甘油酯中C=C的伸缩振动信号，1 400 cm-1附近的信号为聚乙烯醇-甲基丙烯酸缩水甘油酯和脱细胞软骨基质中烯烃=C-H的弯曲振动信号，1 300 cm-1附近的信号为C-H的面内弯曲振动信号，1 100 cm-1附近的强信号为聚乙烯醇-甲基丙烯酸缩水甘油酯和脱细胞软骨基质中C-O-C的伸缩振动信号，800 cm-1附近的信号为游离-OH的面外弯曲振动信号，表明脱细胞软骨基质成功地负载于支架上(图2F)。 "

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