3D-printed hydrogel patch for controlled topical release: Gelatin/tannic acid formulation meets additive manufacturing

IF 4.3 2区医学 Q1 PHARMACOLOGY & PHARMACY

European Journal of Pharmaceutics and Biopharmaceutics Pub Date : 2025-06-25 DOI:10.1016/j.ejpb.2025.114802

Angélica Graça , Valeria Tonioli , Ana M. Martins , Helena M. Ribeiro , Joana Marto

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引用次数: 0

Abstract

Prolonged use of protective masks can cause skin issues like rosacea and “maskne,” particularly among healthcare workers. Poorly fitting commercial dressings often worsen these problems. A novel solution involves 3D-printing personalized hydrogel patches with active ingredients, with customizable designs, concentrations, and controlled release rates.

This study explores customizable 3D-printed gelatin/ tannic acid hydrogel patches containing metronidazole for rosacea or salicylic acid for maskne treatment. Rheological properties, including gelation temperature, viscosity at gelation temperature, gelation time, and viscosity during printing, were analysed. Optimal printing conditions were determined using a Quality by Design approach with Design of Experiments framework. Three patch designs—occlusive, grid, and triangular infill—were 3D-printed. Mechanical properties were assessed via tensile strength tests, and in vitro studies evaluated the release profiles and permeation of the active ingredients.

The gelatin/tannic acid and gelatin/tannic acid-metronidazole hydrogels had similar gelation temperatures, while the salicylic acid hydrogel gelled at a lower temperature. All formulations had comparable viscosities at gelation, and gelation times (∼20 s). Optimal print conditions were 42 °C, 25 Psi, and 30 mm/s gelatin/tannic acid and metronidazole hydrogels, and 36 °C and 30 Psi for the salicylic acid formulation. Infill patterns affected mechanical properties and drug release, with grid patterns showing stronger structures and higher drug release rates compared to triangular patterns. In vitro permeation tests revealed salicylic acid penetrated the epidermal barrier and accumulated within the skin, despite low overall retention of both active ingredients.

These findings highlight the potential of personalized 3D-printed patches for treating mask-related skin conditions.

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用于局部控制释放的3d打印水凝胶贴片：明胶/单宁酸配方符合增材制造

长期使用防护口罩会导致酒渣鼻和“口罩”等皮肤问题，尤其是在医护人员中。不合适的商业敷料往往使这些问题恶化。一种新颖的解决方案涉及3d打印具有活性成分的个性化水凝胶贴片，具有可定制的设计，浓度和控制的释放速率。本研究探索可定制的3d打印明胶/单宁酸水凝胶贴片，其中含有用于酒渣鼻的甲硝唑或用于面膜治疗的水杨酸。分析了胶凝温度、胶凝温度下的粘度、胶凝时间和印刷时的粘度等流变特性。采用设计质量法和实验设计框架确定最佳印刷条件。三种贴片设计-闭塞，网格和三角形填充-被3d打印。通过拉伸强度测试评估了机械性能，并在体外研究中评估了活性成分的释放曲线和渗透。明胶/单宁酸水凝胶和明胶/单宁酸-甲硝唑水凝胶的凝胶温度相似，水杨酸水凝胶的凝胶温度较低。所有配方在胶凝时具有相当的粘度和胶凝时间（~ 20 s）。最佳打印条件为42°C， 25 Psi和30 mm/s明胶/单宁酸和甲硝唑水凝胶，36°C和30 Psi为水杨酸配方。填充模式影响机械性能和药物释放，与三角形模式相比，网格模式显示出更强的结构和更高的药物释放率。体外渗透试验显示水杨酸穿透表皮屏障并在皮肤内积聚，尽管两种活性成分的总体保留率较低。这些发现突出了个性化3d打印贴片在治疗口罩相关皮肤病方面的潜力。

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来源期刊

European Journal of Pharmaceutics and Biopharmaceutics 医学-药学

CiteScore

8.80

自引率

4.10%

发文量

211

审稿时长

36 days

期刊介绍： The European Journal of Pharmaceutics and Biopharmaceutics provides a medium for the publication of novel, innovative and hypothesis-driven research from the areas of Pharmaceutics and Biopharmaceutics. Topics covered include for example: Design and development of drug delivery systems for pharmaceuticals and biopharmaceuticals (small molecules, proteins, nucleic acids) Aspects of manufacturing process design Biomedical aspects of drug product design Strategies and formulations for controlled drug transport across biological barriers Physicochemical aspects of drug product development Novel excipients for drug product design Drug delivery and controlled release systems for systemic and local applications Nanomaterials for therapeutic and diagnostic purposes Advanced therapy medicinal products Medical devices supporting a distinct pharmacological effect.