Department of Materials, University of Manchester, Oxford Road, Manchester M13 9PL, U.K.
Manchester Institute of Biotechnology, Oxford Road, Manchester M13 9PL, U.K.
Biomacromolecules. 2022 Jun 13;23(6):2624-2634. doi: 10.1021/acs.biomac.2c00356. Epub 2022 May 11.
Hydrogels are versatile materials that have emerged in the last few decades as promising candidates for a range of applications in the biomedical field, from tissue engineering and regenerative medicine to controlled drug delivery. In the drug delivery field, in particular, they have been the subject of significant interest for the spatially and temporally controlled delivery of anticancer drugs and therapeutics. Self-assembling peptide-based hydrogels, in particular, have recently come to the fore as potential candidate vehicles for the delivery of a range of drugs. In order to explore how drug-peptide interactions influence doxorubicin (Dox) release, five β-sheet-forming self-assembling peptides with different physicochemical properties were used for the purpose of this study, namely: FEFKFEFK (F8), FKFEFKFK (FK), FEFEFKFE (FE), FEFKFEFKK (F8K), and KFEFKFEFKK (KF8K) (F: phenylalanine; E: glutamic acid; K: lysine). First, Dox-loaded hydrogels were characterized to ensure that the incorporation of the drug did not significantly affect the hydrogel properties. Subsequently, Dox diffusion out of the hydrogels was investigated using UV absorbance. The amount of drug retained in F8/FE composite hydrogels was found to be directly proportional to the amount of charge carried by the peptide fibers. When cation-π interactions were used, the position and number of end-lysine were found to play a key role in the retention of Dox. In this case, the amount of Dox retained in F8/KF8K composite hydrogels was linked to the amount of end-lysine introduced, and an end-lysine/Dox interaction stoichiometry of 3/1 was obtained. For pure FE and KF8K hydrogels, the maximum amount of Dox retained was also found to be related to the overall concentration of the hydrogels and, therefore, to the overall fiber surface area available for interaction with the drug. For 14 mM hydrogel, ∼170-200 μM Dox could be retained after 24 h. This set of peptides also showed a broad range of susceptibilities to enzymatic degradation opening the prospect of being able to control also the rate of degradation of these hydrogels. Finally, the Dox released from the hydrogel was shown to be active and affect 3T3 mouse fibroblasts viability in vitro. Our study clearly shows the potential of this peptide design as a platform for the formulation of injectable or sprayable hydrogels for controlled drug delivery.
水凝胶是一种多功能材料,在过去几十年中作为生物医学领域一系列应用的有前途的候选材料而出现,从组织工程和再生医学到控制药物输送。在药物输送领域,特别是对于抗癌药物和治疗剂的时空控制输送,它们一直是研究的热点。特别是基于自组装肽的水凝胶,最近作为各种药物输送的潜在候选载体而受到关注。为了探索药物-肽相互作用如何影响阿霉素(Dox)的释放,本研究使用了具有不同物理化学性质的五种β-折叠形成自组装肽,即:FEFKFEFK(F8)、FKFEFKFK(FK)、FEFEFKFE(FE)、FEFKFEFKK(F8K)和 KFEFKFEFKK(KF8K)(F:苯丙氨酸;E:谷氨酸;K:赖氨酸)。首先,对载药水凝胶进行了表征,以确保药物的掺入不会显著影响水凝胶的性质。随后,使用紫外吸收法研究了 Dox 从水凝胶中的扩散。发现 F8/FE 复合水凝胶中保留的药物量与肽纤维所带电荷的量成正比。当使用阳离子-π 相互作用时,末端赖氨酸的位置和数量被发现对 Dox 的保留起着关键作用。在这种情况下,F8/KF8K 复合水凝胶中保留的 Dox 量与引入的末端赖氨酸量有关,并且获得了 Dox/末端赖氨酸的相互作用化学计量比为 3/1。对于纯 FE 和 KF8K 水凝胶,也发现保留的最大药物量与水凝胶的总浓度有关,因此与用于与药物相互作用的总纤维表面积有关。对于 14 mM 水凝胶,在 24 小时后可保留约 170-200 μM 的 Dox。这组肽也表现出对酶降解的广泛敏感性,为控制这些水凝胶的降解速率开辟了前景。最后,从水凝胶中释放的 Dox 被证明是活性的,并在体外影响 3T3 小鼠成纤维细胞的活力。我们的研究清楚地表明了这种肽设计作为用于控制药物输送的可注射或喷雾水凝胶制剂的平台的潜力。
