Liquid metal–polymer nano-microconjugations as an injectable and photo-activatable drug carrier†

IF 3.2 3区 工程技术 Q2 CHEMISTRY, PHYSICAL Molecular Systems Design & Engineering Pub Date : 2024-05-02 DOI:10.1039/D4ME00028E
Tomoka Hirose, Robin Rajan, Eijiro Miyako and Kazuaki Matsumura
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Abstract

Materials with distinct stimulus-responsive properties hold potential as carriers in next-generation drug delivery systems. In this study, we propose the design and characterisation of a carrier that can stably administer drugs, regardless of external conditions, through a two-step reaction achieved by creating a composite of materials possessing photothermal and temperature-responsive (dual-stimuli) characteristics. This composite, a novel integration of photothermal liquid metals (LMs) responsive to near-infrared laser irradiation and a temperature-responsive carboxylated polylysine-based polyampholyte, marks a significant advancement in drug delivery technology. The temperature-responsive liquid–liquid phase separation behaviour of the polymer, crucial for drug release, is precisely controlled by adjusting the ratio and concentration of the polymer anions and cations. Moreover, the heat required for phase separation and compatibility with the polymer solution is modulated through nanoparticle formation of the photothermal LMs, along with variations in the irradiation time and intensity of near-infrared laser light. Our findings, corroborated through laser microscopy and cell toxicity tests, demonstrate that this composite can generate heat upon photo-stimulation and use this heat to induce phase separation. Additionally, unlike conventional temperature-responsive carriers, this composite concentrates drugs, likely due to enhanced electrostatic interactions between the polyampholyte and the drug. This research not only overcomes the challenges faced by traditional stimulus-responsive carriers, which are influenced by the surrounding physiological environment, but also demonstrates the potential of a two-step reaction approach to concentrate and deliver drugs effectively.

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液态金属-聚合物纳米微共轭物作为可注射和可光激活的药物载体
具有独特刺激响应特性的材料有望成为下一代给药系统的载体。在本研究中,我们提出了一种载体的设计和表征方法,这种载体可以不受外部条件的影响,通过两步反应实现稳定给药,具体方法是创建一种具有光热和温度响应(双刺激)特性的复合材料。这种复合材料是对近红外激光照射有反应的光热液态金属(LMs)和对温度有反应的羧基聚赖氨酸基聚酰胺的新型集成,标志着给药技术的重大进步。通过调整聚合物阴阳离子的比例和浓度,可精确控制聚合物的温度响应型液相-液相分离行为,这对药物释放至关重要。此外,相分离所需的热量以及与聚合物溶液的相容性可通过光热 LM 的纳米颗粒化以及近红外激光照射时间和强度的变化来调节。我们的研究结果通过激光显微镜和细胞毒性测试得到证实,证明这种复合材料在光刺激下能产生热量,并利用这种热量诱导相分离。此外,与传统的温度响应载体不同,这种复合材料可以浓缩药物,这可能是由于聚阴离子与药物之间的静电相互作用增强所致。这项研究不仅克服了受周围生理环境影响的传统刺激响应载体所面临的挑战,还证明了两步反应法浓缩和有效递送药物的潜力。
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来源期刊
Molecular Systems Design & Engineering
Molecular Systems Design & Engineering Engineering-Biomedical Engineering
CiteScore
6.40
自引率
2.80%
发文量
144
期刊介绍: Molecular Systems Design & Engineering provides a hub for cutting-edge research into how understanding of molecular properties, behaviour and interactions can be used to design and assemble better materials, systems, and processes to achieve specific functions. These may have applications of technological significance and help address global challenges.
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Back cover Back cover Dual responsive fluorescence switching of organohydrogel towards base/acid† Back cover Graph-based networks for accurate prediction of ground and excited state molecular properties from minimal features†
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