Boffito Monica, Torchio Alessandro, Tonda-Turo Chiara, Laurano Rossella, Gisbert-Garzarán Miguel, Berkmann Julia C, Cassino Claudio, Manzano Miguel, Duda Georg N, Vallet-Regí María, Schmidt-Bleek Katharina, Ciardelli Gianluca
Department of Mechanical and Aerospace Engineering, Politecnico di Torino, Turin, Italy.
Department of Surgical Sciences, Università degli Studi di Torino, Turin, Italy.
Front Bioeng Biotechnol. 2020 May 19;8:384. doi: 10.3389/fbioe.2020.00384. eCollection 2020.
Injectable therapeutic formulations locally releasing their cargo with tunable kinetics in response to external biochemical/physical cues are gaining interest in the scientific community, with the aim to overcome the cons of traditional administration routes. In this work, we proposed an alternative solution to this challenging goal by combining thermo-sensitive hydrogels based on custom-made amphiphilic poly(ether urethane)s (PEUs) and mesoporous silica nanoparticles coated with a self-immolative polymer sensitive to acid pH (MSN-CS-SIP). By exploiting PEU chemical versatility, Boc-protected amino groups were introduced as PEU building block (PEU-Boc), which were then subjected to a deprotection reaction to expose pendant primary amines along the polymer backbone (PEU-NH, 3E18 -NH/g) with the aim to accelerate system response to external acid pH environment. Then, thermo-sensitive hydrogels were designed (15% w/v) showing fast gelation in physiological conditions (approximately 5 min), while no significant changes in gelation temperature and kinetics were induced by the Boc-deprotection. Conversely, free amines in PEU-NH effectively enhanced and accelerated acid pH transfer (pH 5) through hydrogel thickness (PEU-Boc and PEU-NH gels covered approximately 42 and 52% of the pH delta between their initial pH and the pH of the surrounding buffer within 30 min incubation, respectively). MSN-CS-SIP carrying a fluorescent cargo as model drug (MSN-CS-SIP-Ru) were then encapsulated within the hydrogels with no significant effects on their thermo-sensitivity. Injectability and gelation at 37°C were demonstrated through sub-cutaneous injection in rodents. Moreover, MSN-CS-SIP-Ru-loaded gels turned out to be detectable through the skin by IVIS imaging. Cargo acid pH-triggered delivery from PEU-Boc and PEU-NH gels was finally demonstrated through drug release tests in neutral and acid pH environments (in acid pH environment approximately 2-fold higher cargo release). Additionally, acid-triggered payload release from PEU-NH gels was significantly higher compared to PEU-Boc systems at 3 and 4 days incubation. The herein designed hybrid injectable formulations could thus represent a significant step forward in the development of multi-stimuli sensitive drug carriers. Indeed, being able to adapt their behavior in response to biochemical cues from the surrounding physio-pathological environment, these formulations can effectively trigger the release of their payload according to therapeutic needs.
可注射治疗制剂能够响应外部生化/物理线索以可调动力学局部释放其负载物,这在科学界正引起越来越多的关注,旨在克服传统给药途径的缺点。在这项工作中,我们通过将基于定制两亲性聚(醚氨酯)(PEU)的热敏水凝胶与涂有对酸性pH敏感的自牺牲聚合物的介孔二氧化硅纳米颗粒(MSN-CS-SIP)相结合,为这一具有挑战性的目标提出了一种替代解决方案。通过利用PEU的化学多功能性,引入受Boc保护的氨基作为PEU结构单元(PEU-Boc),然后对其进行脱保护反应,以暴露聚合物主链上的侧链伯胺(PEU-NH,3E18 -NH/g),目的是加速系统对外部酸性pH环境的响应。然后设计了热敏水凝胶(15% w/v),其在生理条件下显示出快速凝胶化(约5分钟),而Boc脱保护未引起凝胶化温度和动力学的显著变化。相反,PEU-NH中的游离胺通过水凝胶厚度有效地增强并加速了酸性pH转移(pH 5)(在30分钟孵育内,PEU-Boc和PEU-NH凝胶分别覆盖了其初始pH与周围缓冲液pH之间约42%和52%的pH差值)。然后将携带荧光负载物作为模型药物的MSN-CS-SIP(MSN-CS-SIP-Ru)封装在水凝胶中,对其热敏性没有显著影响。通过在啮齿动物皮下注射证明了在37°C下的可注射性和凝胶化。此外,通过IVIS成像证明了负载MSN-CS-SIP-Ru的凝胶可透过皮肤检测到。最终通过在中性和酸性pH环境中的药物释放测试证明了负载物从PEU-Boc和PEU-NH凝胶中由酸性pH触发的释放(在酸性pH环境中负载物释放约高2倍)。此外,在孵育3天和4天时,与PEU-Boc系统相比,PEU-NH凝胶的酸性触发负载物释放显著更高。因此,本文设计的混合可注射制剂可能代表了多刺激敏感药物载体开发中的重要一步。实际上,这些制剂能够根据周围生理病理环境中的生化线索调整其行为,从而可以根据治疗需求有效地触发其负载物的释放。
