Mind the mechanical strength: tailoring a 3D matrix to encapsulate isolated human preantral follicles.

IF 8.3 Q1 OBSTETRICS & GYNECOLOGY Human reproduction open Pub Date : 2023-01-01 DOI:10.1093/hropen/hoad004
Arezoo Dadashzadeh, Saeid Moghassemi, Alexis Peaucelle, Carolina M Lucci, Christiani A Amorim
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引用次数: 1

Abstract

Study question: Would a hydrogel with similar mechanical properties to the human ovarian cortex support preantral follicle development?

Summary answer: Yes, our tailored PEGylated fibrin hydrogel was shown to significantly improve follicle growth in vitro.

What is known already: One of the main challenges in developing an engineered ovary is to provide a 3D matrix that supports the follicle architecture and the interaction between granulosa cells and the oocyte as they are essential for folliculogenesis. Thanks to its biocompatibility and bioactivity, fibrin has been employed to fabricate a 3D matrix to encapsulate ovarian follicles. However, follicles lose their physical support within a few days owing to rapid fibrin degradation. Therefore, different strategies, including physical and chemical modifications, have been developed to enhance the stability of fibrin.

Study design size duration: By developing a matrix made of a synthetic (polyethylene glycol: PEG) and natural polymer (fibrin), we aimed to overcome fibrin degradation by the chemical reaction of PEGylation and tailor a PEGylated fibrin hydrogel formulation with mechanical strength similar to the ovarian cortex in women of reproductive age. To this end, response surface methodology was employed to obtain a tailored formulation of PEGylated fibrin. This hydrogel was then tested to encapsulate and support isolated human preantral follicles in vitro.

Participants/materials setting methods: A PEGylated fibrin formulation was tailored using mathematical modeling software to mimic the mechanical properties of human ovarian tissue at reproductive age. Human preantral follicles were isolated from 11 patients of reproductive age and encapsulated in the tailored hydrogels, which were cultured in vitro for 4 or 7 days. Follicle survival and diameter were assessed on Days 1 and 7. Furthermore, the follicles were subjected to confocal microscopy to evaluate their growth (Ki67 staining) on Day 7 and analyze cell-cell communication (connexin 43 and transzonal projection staining) on Day 4.

Main results and the role of chance: In this study, mathematical modeling was applied to achieve the biomechanically tailored PEGylated fibrin formulation by targeting the specific goal of 3178 ± 245 Pascal, Young's modulus of ovarian cortical tissue in reproductive-age women. Our results demonstrated that the PEGylated fibrin hydrogel consisting of 39.06 mg/ml of PEGylated fibrinogen and 50.36 IU/ml of thrombin was the optimum condition with the desirability of 97.5%. This tailored hydrogel yielded a high follicle survival rate (83%) after 7 days of in vitro culture and supported its development up to the secondary stage. Follicle growth was confirmed by the presence of Ki67-positive granulosa cells on Day 7. Additionally, connexin 43 and Phalloidin staining indicated the retention of connections between granulosa cells and the oocyte.

Large scale data: N/A.

Limitations reasons for caution: In this study, our tailored hydrogel was only tested in vitro, which is not the same as the physiological environment. It is crucial to conduct a study assessing the follicles following their encapsulation in the tailored hydrogel and transplantation, which will be the next step of our investigation.

Wider implications of the findings: The findings from this study introduced a suitable biomaterial similar to the ovarian cortex in reproductive-age women in terms of biomechanical properties for encapsulating human preantral follicles. This biomaterial allowed the radial growth of follicles and preserved their viability. Furthermore, PEGylation improved the stability of fibrin and the physical support of follicles.

Study funding/competing interests: This study was supported by grants from the Fondation Louvain (PhD scholarship awarded to S.M., as part of a legacy from Mr Frans Heyes, and PhD scholarship awarded to A.D. as part of a legacy from Mrs Ilse Schirmer). The authors declare no competing interests.

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注意机械强度:定制一个3D矩阵来封装孤立的人类腔前卵泡。
研究问题:与人类卵巢皮质具有相似机械特性的水凝胶是否能支持腔前卵泡发育?概要回答:是的,我们量身定制的聚乙二醇化纤维蛋白水凝胶在体外被证明能显著改善卵泡生长。已知情况:开发工程化卵巢的主要挑战之一是提供3D基质来支持卵泡结构以及颗粒细胞和卵母细胞之间的相互作用,因为它们对卵泡形成至关重要。由于其生物相容性和生物活性,纤维蛋白已被用于制造3D基质来包裹卵巢卵泡。然而,由于纤维蛋白的快速降解,卵泡在几天内就失去了它们的物理支持。因此,不同的策略,包括物理和化学修饰,已经开发,以提高纤维蛋白的稳定性。研究设计规模持续时间:通过开发由合成(聚乙二醇:PEG)和天然聚合物(纤维蛋白)制成的基质,我们旨在通过聚乙二醇化的化学反应克服纤维蛋白降解,并定制聚乙二醇化纤维蛋白水凝胶配方,其机械强度与育龄妇女卵巢皮质相似。为此,采用响应面法获得了聚乙二醇化纤维蛋白的定制配方。然后测试该水凝胶在体外封装和支持分离的人腔前卵泡。参与者/材料设置方法:使用数学建模软件定制聚乙二醇化纤维蛋白配方,以模拟育龄人类卵巢组织的力学特性。从11例育龄患者中分离出人腔前卵泡,包封在定制的水凝胶中,体外培养4天或7天。在第1天和第7天评估卵泡存活率和直径。第7天用共聚焦显微镜观察毛囊的生长情况(Ki67染色),第4天用连接蛋白43和跨区投影染色分析细胞间通讯。主要结果和随机因素的作用:本研究采用数学模型,以育龄女性卵巢皮质组织的杨氏模量(3178±245)为目标,实现生物力学量身定制的聚乙二醇化纤维蛋白配方。结果表明,聚乙二醇化纤维蛋白原39.06 mg/ml和凝血酶50.36 IU/ml的聚乙二醇化纤维蛋白水凝胶为最佳制备条件,适宜率为97.5%。这种定制水凝胶在体外培养7天后获得了很高的卵泡存活率(83%),并支持其发展到二期。第7天出现ki67阳性颗粒细胞,证实卵泡生长。此外,连接蛋白43和Phalloidin染色显示颗粒细胞与卵母细胞之间的连接保留。大规模数据:无。局限性:在本研究中,我们定制的水凝胶仅在体外测试,与生理环境不一样。在定制的水凝胶中对卵泡进行包封和移植后进行研究是至关重要的,这将是我们研究的下一步。研究结果的更广泛意义:本研究的结果介绍了一种适合的生物材料,类似于育龄妇女卵巢皮质,在生物力学特性方面可以包裹人类腔前卵泡。这种生物材料允许卵泡径向生长并保持其活力。此外,聚乙二醇化改善了纤维蛋白的稳定性和卵泡的物理支持。研究经费/竞争利益:本研究由Louvain基金会资助(博士奖学金授予s.m.,作为Frans Heyes先生遗产的一部分,博士奖学金授予A.D.,作为Ilse Schirmer夫人遗产的一部分)。作者声明没有利益冲突。
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