Click Cross-Linking Improves Retention and Targeting of Refillable Alginate Depots

Christopher T. Moody, Sandeep Palvai, Y. Brudno
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引用次数: 18

Abstract

Injectable alginate hydrogels have demonstrated utility in tissue engineering and drug delivery applications due in part to their mild gelation conditions, low host responses and chemical versatility. Recently, the potential of these gels has expanded with the introduction of refillable hydrogel depots - alginate gels chemically decorated with click chemistry groups to efficiently capture prodrug refills from the blood. Unfortunately, high degrees of click group substitution on alginate lead to poor viscoelastic properties and loss of ionic cross-linking. In this work, we introduce tetrabicyclononyne (tBCN) agents that covalently cross-link azide-modified alginate hydrogels for tissue engineering and drug delivery application in vivo. Adjusting cross-linker concentration allowed tuning the hydrogel mechanical properties for tissue-specific mechanical strength. The bioorthogonal and specific click reaction creates stable hydrogels with improved in vivo properties, including improved retention at injected sites. Azide-alginate hydrogels cross-linked with tBCN elicited minimal inflammation and maintained structural integrity over several months and efficiently captured therapeutics drug surrogates from the circulation. Taken together, azide-alginate hydrogels cross-linked with tBCN convey the benefits of alginate hydrogels for use in tissue engineering and drug delivery applications of refillable drug delivery depots. Statement of Significance Ionically cross-linked, injectable alginate biomaterials hold promise in many different clinical settings. However, adding new chemical functionality to alginate can disrupt their ionic cross-linking, limiting their utility. We have developed a "click" cross-linking strategy to improve the mechanical properties and tissue function of modified alginate biomaterials and enable them to capture small molecule drugs from the blood. We show that click cross-linked materials remain in place better than ionically cross-linked materials and efficiently capture payloads from the blood. Development of click cross-linking for refillable depots represents a crucial step toward clinical application of this promising drug delivery platform.
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点击交叉链接可以提高可填充藻酸盐仓库的保留率和目标
可注射海藻酸盐水凝胶在组织工程和药物输送应用中已经证明了它的实用性,部分原因是它具有温和的凝胶条件,低宿主反应和化学多功能性。最近,这些凝胶的潜力随着可再填充水凝胶仓库的引入而扩大——海藻酸盐凝胶用化学修饰,以有效地从血液中捕获前药再填充。不幸的是,海藻酸盐上高程度的点击基团取代会导致较差的粘弹性和离子交联的损失。在这项工作中,我们介绍了共价交联叠氮修饰海藻酸盐水凝胶的四环克隆酮(tBCN)制剂,用于组织工程和体内给药应用。调整交联剂浓度可以调整水凝胶的机械性能,以达到组织特异性的机械强度。生物正交和特异性点击反应产生稳定的水凝胶,改善了体内性能,包括改善了注射部位的保留率。叠氮酰海藻酸盐水凝胶与tBCN交联,引起最小的炎症,并在几个月内保持结构完整性,并有效地从循环中捕获治疗药物替代品。综上所述,叠氮化物-海藻酸盐水凝胶与tBCN交联,传达了海藻酸盐水凝胶在组织工程和可再填充药物输送库的药物输送应用中的好处。离子交联的可注射海藻酸盐生物材料在许多不同的临床环境中都有应用前景。然而,向海藻酸盐中添加新的化学功能会破坏它们的离子交联,限制它们的效用。我们已经开发了一种“点击”交联策略,以改善改性海藻酸盐生物材料的机械性能和组织功能,并使它们能够从血液中捕获小分子药物。我们表明,点击交联材料比离子交联材料更能保持原位,并有效地从血液中捕获有效载荷。可重复填充储药库的点击交联的开发是这一前景广阔的给药平台临床应用的关键一步。
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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