Yang Xiaoling, Li Chenchen, Li Bo, Zhang Yuanyuan, Li Jinping, Liu Na, Nie Xin, Zhang Dawei, Zhou Ming, Liao Xiaoling
School of New Energy and Material, Southwest Petroleum University, Chengdu 610500, China.
Chongqing Engineering Laboratory of Nano/Micro Biomedical Detection Technology, Chongqing University of Science and Technology, Chongqing 401331, China.
Regen Biomater. 2025 Apr 26;12:rbaf031. doi: 10.1093/rb/rbaf031. eCollection 2025.
Hydrogel-based wound dressings, which facilitate rapid wound closure and healing, are essential for effective wound management. However, the development of an ideal hydrogel that possesses excellent mechanical properties, effective self-healing capabilities, tissue adherence and antimicrobial characteristics for wound dressing presents a significant challenge in clinical settings. Inspired by lotus-fiber and mussel, we synthesized a novel multifunctional hydrogel composed of bacterial cellulose-reinforced dopamine-grafted oxidized hyaluronic acid/polyacrylamide (OHA-DA/PAM/BC). This was achieved through a one-pot reaction that employed free radical polymerization of acrylamide, dynamic Schiff bonding and intermolecular hydrogen bonding. Compared with the pure PAM hydrogels, which exhibited an elongation at break of 4022% and a maximum tensile strength of 26.42 kPa, the OHA-DA/PAM hydrogel demonstrated significantly enhanced stretchability at 9949% and an increased tensile strength of 34.73 kPa when 0.3% OHA-DA was incorporated during hydrogel formulation. Notably, the addition of 0.8% BC significantly enhanced the tensile strength to 57.04 kPa and super-stretchability to 10679%. The OHA-DA/PAM/BC hydrogel also exhibited remarkable self-healing capabilities, achieving a mechanical recovery of 84.74% within 12 h. Additionally, its adhesive and injectable properties are advantageous for dynamic wound repair. Furthermore, the OHA-DA/PAM/BC hydrogel exhibited minimal hemolytic activity and potent intrinsic antibacterial properties against both and . In a mouse model of wound healing, this hydrogel reduced the healing duration to 14 days while enhancing the regeneration of both skin structure and function. Histological analyses further revealed that the hydrogel significantly promoted the development of well-organized granulation tissue, angiogenic tissue and collagen accumulation in the wound region. This study successfully developed an OHA-DA/PAM/BC multifunctional hydrogel characterized by exceptional stretchability, self-healing, adhesiveness, injectability and antibacterial activity, demonstrating a significant impact on wound healing . These findings indicated that the OHA-DA/PAM/BC hydrogel holds substantial potential as wound dressings for future clinical applications.
基于水凝胶的伤口敷料有助于伤口快速闭合和愈合,是有效伤口管理的关键。然而,开发一种具有优异机械性能、有效的自愈能力、组织粘附性和抗菌特性的理想伤口敷料水凝胶在临床环境中面临重大挑战。受莲花纤维和贻贝的启发,我们合成了一种新型多功能水凝胶,它由细菌纤维素增强的多巴胺接枝氧化透明质酸/聚丙烯酰胺(OHA-DA/PAM/BC)组成。这是通过一锅法反应实现的,该反应采用了丙烯酰胺的自由基聚合、动态席夫键合和分子间氢键。与纯PAM水凝胶相比,其断裂伸长率为4022%,最大拉伸强度为26.42 kPa,当在水凝胶配方中加入0.3%的OHA-DA时,OHA-DA/PAM水凝胶的拉伸率显著提高到9949%,拉伸强度增加到34.73 kPa。值得注意的是,添加0.8%的BC可将拉伸强度显著提高到57.04 kPa,超拉伸率提高到10679%。OHA-DA/PAM/BC水凝胶还表现出显著的自愈能力,在12小时内机械恢复率达到84.74%。此外,其粘附性和可注射性有利于动态伤口修复。此外,OHA-DA/PAM/BC水凝胶表现出最小的溶血活性,并对[具体细菌]具有强大的内在抗菌性能。在伤口愈合的小鼠模型中,这种水凝胶将愈合时间缩短至14天,同时增强了皮肤结构和功能的再生。组织学分析进一步表明,水凝胶显著促进了伤口区域组织良好的肉芽组织、血管生成组织和胶原蛋白积累的发展。本研究成功开发了一种具有卓越拉伸性、自愈性、粘附性、可注射性和抗菌活性的OHA-DA/PAM/BC多功能水凝胶,证明了其对伤口愈合有显著影响。这些发现表明,OHA-DA/PAM/BC水凝胶作为未来临床应用的伤口敷料具有巨大潜力。
