Tensile Strength, Cellular Content and Degradation properties in three generations of concentrated growth factors.

IF 2.6 2区医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE

BMC Oral Health Pub Date : 2025-05-01 DOI:10.1186/s12903-025-05825-6

Akram A Alshirah, Mohamed H Elnaem, Ziad Al-Ani, Malik Hudieb, Jeremy Hamilton, Deborah Lowry, Paul A McCarron

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引用次数: 0

Abstract

Background: Concentrated growth factors (CGF) is a biomaterial with regenerative potential, enriched with platelets, leukocytes, growth factors, and fibrin, but it degrades within 2-3 weeks. Albumin extends CGF stability, while silver nanoparticles (SNP) improve its mechanical and antibacterial properties. This in vitro and ex vivo study investigates the impact of albumin (Alb-CGF) and albumin with SNP (Alb-CGF-SNP) on CGF's mechanical properties, degradation rate, and cellular bioactivity.

Methods: Blood samples were collected from 15 healthy volunteers who met specific inclusion criteria, with the sample size determined using G*Power software for power calculation. Three groups were prepared: control CGF, experimental Alb-CGF, and Alb-CGF-SNP. Membranes were produced using a Medifuge MF200 centrifuge and activated plasma albumin gel (APAG) device following standard settings. In experimental groups, the superficial 2.5 ml of plasma layer was heated at 75 °C for 10 min before combining with the buffy coat layer of CGF. Mechanical properties were tested using a texture analyzer, degradation rates were measured by weight loss percentage, and cellular bioactivity was evaluated with a Sysmex hematology analyzer. Data analysis was conducted using GraphPad Prism 8.0. Group differences were assessed via one-way ANOVA and Welch ANOVA, with Tukey's HSD test for post hoc paired group comparisons.

Results: The control (CGF) showed the highest mechanical properties, with Ultimate Tensile Strength (UTS) (95.6 kPa), Modulus of Toughness (55.55 kJ/m³), and Young's Modulus (75.73 kPa; (P < 0.01). No significant differences were observed in the strain at break across groups (P > 0.90). Alb-CGF-SNP displayed superior degradation resistance, with 45.2% weight loss at day 60 versus 84.2% in CGF (P < 0.01). CGF had the highest WBC and platelet levels, with amounts of 2.25 and 3.11-fold, respectively (P < 0.01).

Conclusion: The modification of CGF with albumin and silver nanoparticles enhanced degradation resistance, although it did not reach the tensile strength and cellular content of unmodified CGF. Clinically, Alb-CGF and Alb-CGF-SNP serve as effective barrier membranes due to their prolonged stability, while CGF remains advantageous where high mechanical strength is required. Despite lower elasticity limiting suturing, their plasticity supports use as fillers or for tissue phenotype modification in regenerative applications.

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三代浓缩生长因子的抗拉强度、细胞含量和降解性能。

背景：浓缩生长因子（CGF）是一种具有再生潜力的生物材料，富含血小板、白细胞、生长因子和纤维蛋白，但在2-3周内降解。白蛋白延长CGF的稳定性，而银纳米颗粒（SNP）提高其机械和抗菌性能。在体外和离体实验中，研究了白蛋白（Alb-CGF）和带SNP的白蛋白（Alb-CGF-SNP）对CGF力学性能、降解率和细胞生物活性的影响。方法：采集符合特定纳入标准的15名健康志愿者的血液样本，使用G*Power软件计算样本量。制备三组：对照组CGF、实验组Alb-CGF和Alb-CGF- snp。使用Medifuge MF200离心机和活化血浆白蛋白凝胶（APAG）装置按照标准设置生产膜。实验组表面2.5 ml等离子体层在75℃下加热10 min后与CGF的灰白色涂层结合。使用质地分析仪测试机械性能，通过失重百分比测量降解率，使用Sysmex血液学分析仪评估细胞生物活性。使用GraphPad Prism 8.0进行数据分析。通过单因素方差分析和韦尔奇方差分析评估组间差异，并使用Tukey’s HSD检验进行事后配对组比较。结果：对照组（CGF）的力学性能最高，极限抗拉强度（UTS）为95.6 kPa，韧性模量（55.55 kJ/m3），杨氏模量（75.73 kPa）；(P 0.90)。Alb-CGF-SNP表现出更强的抗降解能力，在第60天体重减轻45.2%，而CGF则为84.2% (P)。结论：白蛋白和纳米银修饰CGF增强了抗降解能力，尽管其抗拉强度和细胞含量没有达到未修饰CGF的水平。在临床上，Alb-CGF和Alb-CGF- snp由于其长期的稳定性而成为有效的屏障膜，而CGF在需要高机械强度的情况下仍然具有优势。尽管较低的弹性限制了缝合，但它们的可塑性支持用作填充物或用于再生应用中的组织表型修饰。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BMC Oral Health DENTISTRY, ORAL SURGERY & MEDICINE-

CiteScore

3.90

自引率

6.90%

发文量

481

审稿时长

6-12 weeks

期刊介绍： BMC Oral Health is an open access, peer-reviewed journal that considers articles on all aspects of the prevention, diagnosis and management of disorders of the mouth, teeth and gums, as well as related molecular genetics, pathophysiology, and epidemiology.