College of Chemistry and Materials Science, Sichuan Normal University, Chengdu 610068, China.
Department of Obstetrics and Gynecology, West China Second University Hospital, Sichuan University, Chengdu 610041, China.
Acta Biomater. 2024 Aug;184:144-155. doi: 10.1016/j.actbio.2024.06.043. Epub 2024 Jul 2.
The integration of barrier materials with pharmacological therapy is a promising strategy to treat intrauterine adhesions (IUAs). However, most of these materials are surgically implanted in a fixed shape and incongruence with the natural mechanical properties of the uterus, causing poor adaptability and significant discomfort to the patients. Herein, an injectable, biodegradable, and mechanically adaptive hydrogel loaded with platelet-rich plasma (PRP) is created by L‑serine and allyl functionalized chitosan (ACS) to achieve efficient, comfortable, and minimally invasive treatment of IUAs. L‑serine induces fast gelation and mechanical reinforcement of the hydrogel, while ACS introduces, imparting a good injectability and complaint yet strong feature to the hydrogel. This design enables the hydrogel to adapt to the complex geometry and match the mechanical properties of the uterine. Moreover, the hydrogel exhibits proper degradability, sustained growth factors (GFs) of PRP release ability, and good biocompatibility. Consequently, the hydrogel shows promising therapeutic efficacy by reducing collagen fiber deposition and facilitating endometrium cell proliferation, thereby restoring the fertility function of the uterus in an IUAs model of rats. Accordingly, the combination of L‑serine and ACS-induced hydrogel with such advantages holds great potential for treating IUAs. STATEMENT OF SIGNIFICANCE: This research introduces a breakthrough in the treatment of intrauterine adhesions (IUAs) with an injectable, biodegradable and mechanically adaptive hydrogel using L‑serine and allyl functionalized chitosan (ACS). Unlike traditional surgical treatments, this hydrogel uniquely conforms to the uterus's geometry and mechanical properties, offering a minimally invasive, comfortable, and more effective solution. The hydrogel is designed to release growth factors from platelet-rich plasma (PRP) sustainably, promoting tissue regeneration by enhancing collagen fiber deposition and endometrium cell proliferation. Demonstrated efficacy in a rat model of IUAs indicates its great potential to significantly improve fertility restoration treatments. This advancement represents a significant leap in reproductive medicine, promising to transform IUAs treatment with its innovative approach to achieving efficient, comfortable, and minimally invasive therapy.
将屏障材料与药物治疗相结合是治疗宫腔粘连(IUAs)的一种很有前途的策略。然而,这些材料大多数以固定形状进行手术植入,与子宫的自然机械性能不一致,导致适应性差,给患者带来极大的不适。在这里,通过 L-丝氨酸和烯丙基功能化壳聚糖(ACS)创建了一种可注射的、可生物降解的和机械适应性的水凝胶,该水凝胶负载富血小板血浆(PRP),以实现 IUAs 的有效、舒适和微创治疗。L-丝氨酸诱导水凝胶快速胶凝和机械增强,而 ACS 则引入了良好的可注射性和可抱怨性但具有较强的特性。这种设计使水凝胶能够适应复杂的几何形状并与子宫的机械性能相匹配。此外,水凝胶具有适当的降解性、PRP 的生长因子(GFs)的持续释放能力和良好的生物相容性。因此,水凝胶通过减少胶原纤维沉积和促进子宫内膜细胞增殖,显示出有希望的治疗效果,从而恢复大鼠 IUAs 模型中子宫的生育功能。因此,L-丝氨酸和 ACS 诱导的水凝胶具有这些优势,为治疗 IUAs 提供了巨大的潜力。
本研究使用 L-丝氨酸和烯丙基功能化壳聚糖(ACS)介绍了一种治疗宫腔粘连(IUAs)的突破性方法,即使用可注射、可生物降解和机械适应性水凝胶。与传统的手术治疗不同,这种水凝胶独特地适应子宫的几何形状和机械性能,提供了一种微创、舒适和更有效的解决方案。水凝胶的设计目的是可持续地从富含血小板的血浆(PRP)中释放生长因子,通过增强胶原纤维沉积和子宫内膜细胞增殖来促进组织再生。在 IUAs 大鼠模型中的功效表明,它具有显著改善生育力恢复治疗的巨大潜力。这一进展代表了生殖医学的重大飞跃,有望通过其创新方法实现高效、舒适和微创治疗,改变 IUAs 治疗方法。
