聚己内酯—聚乙二醇—血小板浓缩生长因子复合支架的制备及其对人牙周膜干细胞生物学特性的影响

doi:10.7518/hxkq.2025.2025044

华西口腔医学杂志 ›› 2025, Vol. 43 ›› Issue (6): 819-828.doi: 10.7518/hxkq.2025.2025044

聚己内酯—聚乙二醇—血小板浓缩生长因子复合支架的制备及其对人牙周膜干细胞生物学特性的影响

高丽¹^,²(), 赵明月¹^,², 杨顺¹, 王茹楠¹, 程佳佳¹^,², 陈广生¹^,²

^1.遵义医科大学口腔医学院，遵义 563099
^2.遵义医科大学附属口腔医院牙周科，遵义 563099

收稿日期:2025-02-06 修回日期:2025-06-02 出版日期:2025-12-01 发布日期:2025-11-27
通讯作者: 高丽 E-mail:467278759@qq.com
作者简介:高丽，副教授，硕士，E-mail：467278759@qq.com
基金资助:
贵州省卫健委科学技术基金(gzwkj2023-202);国家自然科学基金(82060204);贵州省科技计划项目［基金黔科合基础—ZK（2021）一般437］

Preparation of polycaprolactone-polyethylene glycol-concentrated growth factor composite scaffolds and the effects on the biological properties of human periodontal ligament stem cells

Gao Li¹^,²(), Zhao Mingyue¹^,², Yang Shun¹, Wang Runan¹, Cheng Jiajia¹^,², Chen Guangsheng¹^,²

^1.School of Stomatology, Zunyi Medical University, Zunyi 563099, China
^2.Dept. of Periodontology, Affiliated Stomatological Hospital of Zunyi Medical University, Zunyi 563099, China

Received:2025-02-06 Revised:2025-06-02 Online:2025-12-01 Published:2025-11-27
Contact: Gao Li E-mail:467278759@qq.com
Supported by:
National Natural Science Foundation of China(82060204);Science and Technology Fund Project of Guizhou Provincial Health and Health Commission(gzkj2023-202);Science and Technology Department of Guizhou Pro-vince(ZK[2021]437)

摘要/Abstract

摘要：

目的探究负载了血小板浓缩生长因子（CGF）的聚己内酯（PCL）—聚乙二醇（PEG）支架对人牙周膜干细胞（hPDLSCs）黏附、增殖及成骨分化能力的影响。方法通过浸入及冻干法制备PCL-PEG-CGF复合支架，观察复合支架的显微结构并检测其机械性能及生物相容性。酶消化法培养hPDLSCs，并通过流式细胞术鉴定hPDLSCs。选取第三代hPDLSCs，分别通过CCK-8实验、4’,6-二脒基-2-苯基吲哚（DAPI）染色、碱性磷酸酶（ALP）染色、茜素红染色及Western blot实验检测PCL-PEG-CGF复合支架对hPDLSCs黏附、增殖及成骨分化能力的影响及成骨相关蛋白［Runt相关转录因子2（Runx2）、ALP、骨形态发生蛋白2（BMP2）］的表达情况。结果 PCL-PEG-CGF复合支架在扫描电镜下呈孔隙大小不等的蜂窝状结构，其亲水性6 s时θ角接近0°，弹性模量为（4.590 0±0.149 3）MPa，其亲水性、断裂拉伸强度及断裂延伸率均与PCL-PEG支架相似；hPDLSCs在PCL-PEG-CGF复合支架上的黏附能力明显优于PCL-PEG支架（P<0.01），与对照组相比，第3、5、7天时各实验组的hPDLSCs增殖速率显著增加（P<0.01），且PCL-PEG-CGF复合支架与其余组间差异有统计学意义（P<0.01）；PCL-PEG-CGF复合支架组ALP活性明显升高（P<0.05），矿化结节数量明显增加及成骨相关蛋白（Runx2、BMP2、ALP）的表达均明显增强（P<0.05）。结论 PCL-PEG-CGF复合支架具有较好的机械性能及生物相容性，可促进hPDLSCs黏附及增殖，并通过增强成骨相关蛋白的表达促进hPDLSCs的成骨分化能力。

关键词: 血小板浓缩生长因子, 聚己内酯—聚乙二醇—血小板浓缩生长因子复合支架, 聚己内酯—聚乙二醇支架, 人牙周膜干细胞, 细胞增殖, 成骨分化

Abstract:

Objective This study investigated the effects of a polycaprolactone (PCL)-polyethylene glycol (PEG) scaffold incorporated with concentrated growth factor (CGF) on the adhesion, proliferation, and osteogenic differentiation of human periodontal ligament stem cells (hPDLSCs). Methods The PCL-PEG-CGF composite scaffold was fabricated using an immersion and freeze-drying technique. Its microstructure, mechanical properties, and biocompatibility were systematically characterized. The hPDLSCs were isolated through enzymatic digestion, and the hPDLSCs were identified through flow cytometry. Third-passage hPDLSCs were seeded onto the composite scaffolds, and their adhesion, proliferation and osteogenic differentiation were assessed using CCK-8 assays, 4’,6-diamidino-2-phenylindole (DAPI) staining, alkaline phosphatase (ALP) staining, alizarin red staining, and Western blot analysis of osteogenesis-related proteins [Runt-related transcription factor 2 (Runx2), ALP, and morphogenetic protein 2 (BMP2)]. Results Scanning electron microscopy revealed that the PCL-PEG-CGF composite scaffold exhibited a honeycomb-like structure with heterogeneous pore sizes. The composite scaffold exhibited excellent hydrophilicity, as evidenced by a contact angle (θ) approaching 0° within 6 s. Its elastic modulus was measured at (4.590 0±0.149 3) MPa, with comparable hydrophilicity, fracture tensile strength, and fracture elongation to PCL-PEG scaffold. The hPDLSCs exhibited significantly improved adhesion to the PCL-PEG-CGF composite scaffold compared with the PCL-PEG scaffold (P<0.01). Additionally, cell proliferation was markedly improved in all the experimental groups on days 3, 5, and 7 (P<0.01), and statistically significant differences were found between the PCL-PEG-CGF group and other groups (P<0.01). The PCL-PEG-CGF group showed significantly elevated ALP activity (P<0.05), increased mineralization nodule formation, and upregulated expression of osteogenic-related proteins (Runx2, BMP2 and ALP; P<0.05). Conclusion The PCL-PEG-CGF composite scaffold exhibited excellent mechanical properties and biocompatibility, enhancing the adhesion and proliferation of hPDLSCs and promoting their osteogenic differentiation by upregulating osteogenic-related proteins.

Key words: concentrated growth factor, polycaprolactone-polyethylene glycol-concentrated growth factor composi-te scaffold, polycaprolactone-polyethylene glycol scaffold, human periodontal ligament stem cells, cell proliferation, osteogenic differentiation

中图分类号:

R781.4

高丽, 赵明月, 杨顺, 王茹楠, 程佳佳, 陈广生. 聚己内酯—聚乙二醇—血小板浓缩生长因子复合支架的制备及其对人牙周膜干细胞生物学特性的影响[J]. 华西口腔医学杂志, 2025, 43(6): 819-828.

Gao Li, Zhao Mingyue, Yang Shun, Wang Runan, Cheng Jiajia, Chen Guangsheng. Preparation of polycaprolactone-polyethylene glycol-concentrated growth factor composite scaffolds and the effects on the biological properties of human periodontal ligament stem cells[J]. West China Journal of Stomatology, 2025, 43(6): 819-828.

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参考文献 24

[1]	Pigeot S, Klein T, Gullotta F, et al. Manufacturing of human tissues as off-the-shelf grafts programmed to induce regeneration[J]. Adv Mater, 2021, 33(43): e2103737.
[2]	Maia FR, Bastos AR, Oliveira JM, et al. Recent approa-ches towards bone tissue engineering[J]. Bone, 2022, 154: 116256.
[3]	Atala A. Bioengineered tissues for urogenital repair in children[J]. Pediatr Res, 2008, 63(5): 569-575.
[4]	Elghblawi E. Platelet-rich plasma, the ultimate secret for youthful skin elixir and hair growth triggering[J]. J Cosmet Dermatol, 2018, 17(3): 423-430.
[5]	Sarkar R, Gupta M. Platelet-rich plasma in melasma-A systematic review[J]. Dermatol Surg, 2022, 48(1): 131-134.
[6]	Sheikh Z, Hamdan N, Ikeda Y, et al. Natural graft tissues and synthetic biomaterials for periodontal and alveolar bone reconstructive applications: a review[J]. Biomater Res, 2017, 21(1): 9.
[7]	王妮, 程佳佳, 高丽. 静电纺丝复合支架在骨组织工程中的应用[J]. 遵义医科大学学报, 2024, 47(2): 194-200.
	Wang N, Cheng JJ, Gao L. Application of electrospinning composite scaffold in bone tissue engineering[J]. J Zunyi Med Univ, 2024, 47(2): 194-200.
[8]	Pan L, Yang J, Xu L. Preparation and characterization of simvastatin-loaded PCL/PEG nanofiber membranes for drug sustained release[J]. Molecules, 2022, 27(21): 7158.
[9]	Koupaei N, Karkhaneh A, Daliri Joupari M. Preparation and characterization of (PCL-crosslinked-PEG)/hydroxyapatite as bone tissue engineering scaffolds[J]. J Biomed Mater Res A, 2015, 103(12): 3919-3926.
[10]	Dai T, Ma J, Ni S, et al. Attapulgite-doped electrospun PCL scaffolds for enhanced bone regeneration in rat cranium defects[J]. Biomater Adv, 2022, 133: 112656.
[11]	Mijiritsky E, Assaf HD, Peleg O, et al. Use of PRP, PRF and CGF in periodontal regeneration and facial rejuvenation-A narrative review[J]. Biology (Basel), 2021, 10(4): 317.
[12]	Honda H, Tamai N, Naka N, et al. Bone tissue enginee-ring with bone marrow-derived stromal cells integrated with concentrated growth factor in Rattus norvegicus calvaria defect model[J]. J Artif Organs, 2013, 16(3): 305-315.
[13]	Kashef-Saberi MS, Hayati Roodbari N, Parivar K, et al. Enhanced osteogenic differentiation of mesenchymal stem cells on electrospun polyethersulfone/poly (vinyl) alcohol/platelet rich plasma nanofibrous scaffolds[J]. ASAIO J, 2018, 64(5): e115-e122.
[14]	Pini M. Mechanical properties of the periodontal ligament: a systematic review[J]. J Biomech, 2019, 87: 1-11.
[15]	Ritsvall O, Albinsson S. Emerging role of YAP/TAZ in vascular mechanotransduction and disease[J]. Microcirculation, 2024, 31(4): e12838.
[16]	Inchingolo AD, Inchingolo AM, Malcangi G, et al. Effects of resveratrol, curcumin and quercetin supplementation on bone metabolism-A systematic review[J]. Nutrients. 2022, 14(17): 3519.
[17]	Liu Y, Cooper PR, Barralet JE, et al. Influence of calcium phosphate crystal assemblies on the proliferation and osteogenic gene expression of rat bone marrow stromal cells[J]. Biomaterials, 2007, 28(7): 1393-1403.
[18]	McMurray RJ, Gadegaard N, Tsimbouri PM, et al. Nanoscale surfaces for the long-term maintenance of mesenchymal stem cell phenotype and multipotency[J]. Nat Mater, 2011, 10(8): 637-644.
[19]	Bharti R, Anisha, Tikku AP, et al. Effect of platelet-rich fibrin and concentrated growth factor on the regenerative potential of human-induced pluripotent stem cells: a comparative analysis[J]. J Conserv Dent Endod, 2024, 27(9): 975-982.
[20]	Dipalma G, Inchingolo AM, Colonna V, et al. Autologous and heterologous minor and major bone regeneration with platelet-derived growth factors[J]. J Funct Biomater, 2025, 16(1): 16.
[21]	Arya PN, Saranya I, Selvamurugan N. RUNX2 regulation in osteoblast differentiation: a possible therapeutic function of the lncRNA and miRNA-mediated network[J]. Differentiation, 2024, 140: 100803.
[22]	Wu M, Wu S, Chen W, Li YP. The roles and regulatory mechanisms of TGF-β and BMP signaling in bone and cartilage development, homeostasis and disease[J]. Cell Res, 2024, 34(2): 101-123.
[23]	Beederman M, Lamplot JD, Nan G, et al. BMP signaling in mesenchymal stem cell differentiation and bone formation[J]. J Biomed Sci Eng, 2013, 6(8A): 32-52.
[24]	Bartold M, Gronthos S, Haynes D, et al. Mesenchymal stem cells and biologic factors leading to bone formation[J]. J Clin Periodontol, 2019, 46 (): 12-32.

项目	PCL-PEG支架	PCL-PEG-CGF复合支架	P值
断裂拉伸强度	4.573 3±0.105 0	4.440 0±0.115 3	0.213
断裂延伸率	123.333 3±0.577 4	124.000 0±1.000 0	0.374
杨氏弹性模量	5.270 0±0.111 4	4.590 0±0.149 3	0.003*

聚己内酯—聚乙二醇—血小板浓缩生长因子复合支架的制备及其对人牙周膜干细胞生物学特性的影响

Preparation of polycaprolactone-polyethylene glycol-concentrated growth factor composite scaffolds and the effects on the biological properties of human periodontal ligament stem cells

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