Institut National de la Recherche Scientifique, Centre Énergie, Matériaux et Télécommunications, Université du Québec , 1650 Boulevard Lionel-Boulet , Varennes , Quebec J3X 1S2 , Canada.
NanoRobotics Laboratory, Department of Computer and Software Engineering, Institute of Biomedical Engineering , Polytechnique Montréal , Montreal , Quebec H3T 1J4 , Canada.
ACS Nano. 2019 Jan 22;13(1):408-420. doi: 10.1021/acsnano.8b06563. Epub 2019 Jan 7.
Developing multifunctional therapeutic and diagnostic (theranostic) nanoplatforms is critical for addressing challenging issues associated with cancers. Here, self-assembled supernanoparticles consisting of superparamagnetic FeO nanoparticles and photoluminescent PbS/CdS quantum dots whose emission lies within the second biological window (II-BW) are developed. The proposed self-assembled FeO and PbS/CdS (II-BW) supernanoparticles [SASNs (II-BW)] exhibit outstanding photoluminescence detectable through a tissue as thick as 14 mm, by overcoming severe light extinction and concomitant autofluorescence in II-BW, and significantly enhanced T relaxivity (282 mM s, ca. 4 times higher than free FeO nanoparticles) due to largely enhanced magnetic field inhomogeneity. On the other hand, SASNs (II-BW) possess the dual capacity to act as both magnetothermal and photothermal agents, overcoming the main drawbacks of each type of heating separately. When SASNs (II-BW) are exposed to the dual-mode (magnetothermal and photothermal) heating, the thermal energy transfer efficiency is amplified 7-fold compared with magnetic heating alone. These results, in hand with the excellent photo- and colloidal stability, and negligible cytotoxicity, demonstrate the potential use of SASNs (II-BW) for deep-tissue bimodal (magnetic resonance and photoluminescence) in vivo imaging, while simultaneously providing the possibility of SASNs (II-BW)-mediated amplified dual-mode heating treatment for cancer therapy.
开发多功能治疗和诊断(治疗)纳米平台对于解决与癌症相关的挑战性问题至关重要。在这里,开发了由超顺磁性 FeO 纳米粒子和光致发光 PbS/CdS 量子点组成的自组装超纳米粒子,其发射位于第二生物窗口(II-BW)内。所提出的自组装 FeO 和 PbS/CdS(II-BW)超纳米粒子[SASNs(II-BW)]表现出出色的光致发光性能,可通过厚度达 14mm 的组织进行检测,克服了在 II-BW 中严重的光衰减和伴随的自发荧光,并由于磁场不均匀性大大增强,显著提高了 T 弛豫率(282mM s,约比游离 FeO 纳米粒子高 4 倍)。另一方面,SASNs(II-BW)具有作为磁热和光热剂的双重能力,克服了每种类型加热的主要缺点。当 SASNs(II-BW)暴露于双模(磁热和光热)加热时,与单独的磁加热相比,热能传递效率放大了 7 倍。这些结果,再加上优异的光和胶体稳定性以及可忽略的细胞毒性,表明 SASNs(II-BW)有潜力用于深部组织双模(磁共振和光致发光)体内成像,同时还为 SASNs(II-BW)介导的放大双模加热治疗癌症提供了可能性。
