Showing papers by "Luodan Yu published in 2017"

Two-Dimensional Ultrathin MXene Ceramic Nanosheets for Photothermal Conversion

Abstract: Ceramic biomaterials have been investigated for several decades, but their potential biomedical applications in cancer therapy have been paid much less attentions, mainly due to their lack of related material functionality for combating the cancer. In this work, we report, for the first time, that MAX ceramic biomaterials exhibit the unique functionality for the photothermal ablation of cancer upon being exfoliated into ultrathin nanosheets within atomic thickness (MXene). As a paradigm, biocompatible Ti3C2 nanosheets (MXenes) were successfully synthesized based on a two-step exfoliation strategy of MAX phase Ti3AlC2 by the combined HF etching and TPAOH intercalation. Especially, the high photothermal-conversion efficiency and in vitro/in vivo photothermal ablation of tumor of Ti3C2 nanosheets (MXenes) were revealed and demonstrated, not only in the intravenous administration of soybean phospholipid modified Ti3C2 nanosheets but also in the localized intratumoral implantation of a phase-changeable PLGA/Ti...

Metalloporphyrin-Encapsulated Biodegradable Nanosystems for Highly Efficient Magnetic Resonance Imaging-Guided Sonodynamic Cancer Therapy

Abstract: Traditional photodynamic therapy (PDT) suffers from the critical issues of low tissue-penetrating depth of light and potential phototoxicity, which are expected to be solved by developing new dynamic therapy-based therapeutic modalities such as sonodynamic therapy (SDT). In this work, we report on the design/fabrication of a high-performance multifunctional nanoparticulate sonosensitizer for efficient in vivo magnetic resonance imaging (MRI)-guided SDT against cancer. The developed approach takes the structural and compositional features of mesoporous organosilica-based nanosystems for the fabrication of sonosensitizers with intriguing theranostic performance. The well-defined mesoporosity facilitates the high loading of organic sonosensitizers (protoporphyrin, PpIX) and further chelating of paramagnetic transitional metal Mn ions based on metalloporphyrin chemistry (MnPpIX). The mesoporous structure of large surface area also maximizes the accessibility of water molecules to the encapsulated paramagnetic...

Site-specific sonocatalytic tumor suppression by chemically engineered single-crystalline mesoporous titanium dioxide sonosensitizers

Abstract: The biomedical applications of TiO2-based nanosystems develop very slowly among diverse inorganic bio-nanosystems (e.g., Fe3O4, SiO2, MnO, Au, etc.) due to the lack of adequate synthetic strategies to fabricate TiO2 nanoparticles with desirable nanostructures and their specific light responses in the ultraviolet range with potential phototoxicity and low tissue-penetrating capability. In this work, we report on the rational design and fabrication of colloidal single-crystalline and mesoporous anatase TiO2 nanoparticles (MTNs) with high dispersity, well-defined mesoporosity, uniform morphology and nanosized single-crystalline structure, employing a facile yet versatile bottom-up chemical strategy, i.e., pre-hydrolysis of titanium precursors combined with subsequent solvothermal treatment (PH-ST) simply using water as the additive. Highly biocompatible PEGylated MTNs have exerted their unique function as efficient sonosensitizers for sonodynamic therapy (SDT) of cancer, as systematically demonstrated both in vitro and in vivo. The production of reactive oxygen species (ROS) by MTN-sonosensitized SDT has been demonstrated to be the mechanism for efficient tumor SDT. The in vivo biocompatibility assay revealed that either a single dose at 150 mg kg−1 or repeated doses at as high as a total of 400 mg kg−1 exhibited no obvious in vivo toxicity. The ultrasound irradiation of MTNs in SDT is expected to break the depth shadow of light responsiveness of TiO2-based nanosystems in the ultraviolet range, and the presence of well-defined mesoporous nanostructures of MTNs shows great potential for the delivery of therapeutic agents for combined cancer therapy.

Generic synthesis and versatile applications of molecularly organic–inorganic hybrid mesoporous organosilica nanoparticles with asymmetric Janus topologies and structures

Abstract: Precise control over the morphology, nanostructure, composition, and particle size of molecularly organic–inorganic hybrid mesoporous organosilica nanoparticles (MONs) still remains a major challenge, which severely restricts their broad applications. In this work, an efficient bridged organic group-determined growth strategy has been proposed for the facile synthesis of highly dispersed and uniform MONs with multifarious Janus morphologies, nanostructures, organic–inorganic hybrid compositions, and particle sizes, which can be easily controlled simply by varying the bridged organic groups and the concentration of bis-silylated organosilica precursors used in the synthesis. In addition, the formation mechanism of Janus MONs determined by the bridged organic group has been discussed. Based on the specific structures, compositions, and asymmetric morphologies, all the synthesized Janus MONs with hollow structures (JHMONs) demonstrate excellent performances in nanomedicine as desirable drug carriers with high drug-loading efficiencies/capacities, pH-responsive drug releasing, and enhanced therapeutic efficiencies, as attractive contrast-enhanced contrast agents for ultrasound imaging, and as excellent bilirubin adsorbents with noticeably high adsorption capacities and high blood compatibilities. The developed versatile synthetic strategy and the obtained JHMONs are extremely important in the development and applications of MONs, particularly in the areas of nanoscience and nanotechnology.