Liangping Zhou

Multifunctional nanoprobes for upconversion fluorescence, MR and CT trimodal imaging

Early diagnosis probes that combine fluorescence, X-ray computed tomography (CT) and magnetic resonance (MR) imagings are anticipated to give three dimensional (3D) details of tissues and cells of high resolution and sensitivity. However, how to combine these three modalities together within a sub-50 nm sized structure is technically challenging. Here we report a trimodal imaging probe of PEGylated NaY/GdF(4): Yb, Er, Tm @SiO(2)-Au@PEG(5000) nanopaticles of uniform size of less than 50 nm. The as-designed nanoprobes showed (1) strong emissions ranging from the visible (Vis) to near infrared (NIR) for fluorescent imaging, (2) T(1)-weighted MRI by shorting T(1) relaxation time and (3) enhanced HU value as a CT contrast agent. The structure was optimized based on a comprehensive investigation on the influence of the distance between the NaY/GdF(4): Yb, Er, Tm core and Au nanoparticles (NPs) at the surface. The potential of trimodal imaging for cancerous cells and lesions was further demonstrated both in vitro and in vivo.

Dual-targeting upconversion nanoprobes across the blood-brain barrier for magnetic resonance/fluorescence imaging of intracranial glioblastoma

Surgical resection, one of the main clinical treatments of intracranial glioblastoma, bears the potential risk of incomplete excision due to the inherent infiltrative character of the glioblastoma. To maximize the accuracy of surgical resection, the magnetic resonance (MR) and fluorescence imaging are widely used for the tumor preoperative diagnosis and intraoperative positioning. However, present commercial MR contrast agents and fluorescent dyes can only function for single mode of imaging and are subject to poor blood-brain barrier (BBB) permeability and nontargeting-specificity, resulting in the apparent risks of inefficient diagnosis and resection of glioblastoma. Considering the unique MR/upconversion luminescence (UCL) bimodal imaging feature of upconversion nanoparticles (UCNPs), herein, we have developed a dual-targeting nanoprobe (ANG/PEG-UCNPs) to cross the BBB, target the glioblastoma, and then function as a simultaneous MR/NIR-to-NIR UCL bimodal imaging agent, which showed a much enhanced imaging performance in comparison with the clinically used single MRI contrast (Gd-DTPA) and fluorescent dye (5-ALA). Moreover, their biocompatibility, especially to brains, was systematically assessed by the histological/hematological examination, indicating a negligible in vivo toxicity. As a proof-of-concept, the ANG/PEG-UCNPs hold the great potential in MR diagnosis and fluorescence positioning of glioblastoma for the efficient tumor surgery.

Rattle-Structured Multifunctional Nanotheranostics for Synergetic Chemo-/Radiotherapy and Simultaneous Magnetic/Luminescent Dual-Mode Imaging

Most hypoxic tumors are insensitive to radiation, which is a major obstacle in the development of conventional radiotherapy for tumor treatment. Some drugs, such as cisplatin (CDDP), have been extensively used both as an anticancer drug and clinically as a radiosensitizer to enhance radiotherapy. Herein, we develop rattle-structured multifunctional up-conversion core/porous silica shell nanotheranostics (UCSNs) for delivering CDDP to tumors for synergetic chemo-/radiotherapy by CDDP radiosensitization and magnetic/luminescent dual-mode imaging. UCSNs had a dynamic light scattering diameter of 79.1 nm and excellent water dispersity and stability. In vitro studies showed that CDDP loaded in UCSNs (UCSNs-CDDP) was more effective than free CDDP as a radiosensitizer. After injection, UCSNs-CDDP also demonstrated unambiguously enhanced radiotherapy efficacy in vivo. Our report aims at presenting a novel strategy in biomedical nanotechnology that allows simultaneous dual-mode imaging and localized therapy via synergetic chemo-/radiotherapy, which may achieve optimized therapeutic efficacy in cancer treatment.

A NaYbF4: Tm3+ nanoprobe for CT and NIR-to-NIR fluorescent bimodal imaging

Early diagnosis that combines the high-resolutional CT and sensitive NIR-fluorescence bioimaging could provide more accurate information for cancerous tissues, which, however, remain a big challenge. Here we report a simple bimodal imaging platform based on PEGylated NaYbF(4): Tm(3+) nanoparticles (NPs) of less than 20 nm in diameter for both CT and NIR-fluorescence bioimaging. The as-designed nanoprobes showed excellent in vitro and in vivo performances in the dual-bioimaging, very low cytotoxicity and no detectable tissue damage in one month. Remarkably, the Yb(3+) in the lattice of NaYbF(4): Tm(3+) NPs functions not only as a promising CT contrast medium due to its high X-ray absorption coefficiency, but also an excellent sensitizer contributing to the strong NIR-fluorescent emissions for its large NIR absorption cross-section. In addition, these NPs could be easily excreted mainly via feces without detectable remnant in the animal bodies.

Simultaneous nuclear imaging and intranuclear drug delivery by nuclear-targeted multifunctional upconversion nanoprobes

Nuclear-targeted therapy by delivering anticancer drug directly into cancer cell nuclei can elicit synergistic therapeutic effects and kill these cancer cells with much enhanced efficiencies. Besides nuclear targeting, another difficulty in nuclear-targeted therapy is how to achieve real-time monitoring of the therapy process simultaneously. In this article we report on the development of multifunctional upconversion nanoparticles (UCNPs) which were able to target cancer cell nuclei, and thus deliver the anticancer drug directly to the nuclear region and simultaneously image cell nucleus by magnetic resonance (MR)/upconversion fluorescent for real-time guidance of their therapeutic action simultaneously. The Er/Yb-doped NaYF(4) core and NaGdF(4) shell endow the core/shell structured UCNPs with enhanced upconversion fluorescent imaging and more sensitive T(1)-MR imaging performances, and the surface conjugation of TAT peptide served as a key role in the nuclear targeting and nuclear transport process. This multifunctional UCNPs-based nano-theranostic was used to improve the efficacy of DOX in Hela humor tumor models, by direct DOX delivery to the nucleus under the synchronous monitoring of the nano-theranostics. Further development of this technology may provide more exciting opportunities in treating cancer disease by nuclear-targeted therapy.

A uniform sub-50 nm-sized magnetic/upconversion fluorescent bimodal imaging agent capable of generating singlet oxygen by using a 980 nm laser.

Upconverting nanoparticles (UCNPs) with fascinating properties hold great potential as nanotransducers for solving the problems that traditional photodynamic therapy (PDT) has been facing. In this report, by using well-selected bifunctional gadolinium (Gd)-ion-doped UCNPs and water-soluble methylene blue (MB) combined with the water-in-oil reverse microemulsion technique, we have succeeded in developing a new kind of UCNP/MB-based PDT drug, NaYF(4):Er/Yb/Gd@SiO(2)(MB), with a particle diameter less than 50 nm. Great efforts have been made to investigate the drug-formation mechanism and provide detailed physical and photochemical characterizations and the potential structure optimization of the as-designed PDT drug. We envision that such a PDT drug will become a potential theranostic nanomedicine for future near-infrared laser-triggered photodynamic therapy and simultaneous magnetic/optical bimodal imaging.

Controlled Synthesis of Uniform and Monodisperse Upconversion Core/Mesoporous Silica Shell Nanocomposites for Bimodal Imaging

Here we report the design and controlled synthesis of monodisperse and precisely size-controllable UCNP@mSiO(2) nanocomposites smaller than 50 nm by directly coating a mesoporous silica shell (mSiO(2)) on upconversion nanocrystals NaYF(4):Tm/Yb/Gd (UCNPs), which can be used as near-infrared fluorescence and magnetic resonance imaging (MRI) agents and a platform for drug delivery as well. Some key steps such as transferring hydrophobic UCNPs to the water phase by using cetyltrimethylammonium bromide (CTAB), removal of the excess amount of CTAB, and temperature-controlled ultrasonication treatment should be adopted and carefully monitored to obtain uniform upconversion core/mesoporous silica shell nanocomposites. The excellent performance of the core-shell-structured nanocomposite in near-infrared fluorescence and magnetic resonance imaging was also demonstrated.

Radiopaque fluorescence-transparent TaOx decorated upconversion nanophosphors for in vivo CT/MR/UCL trimodal imaging

To address the intractable issues such as the low performance or biocompatibility frequently encountered in previous CT, magnetic resonance (MR) and fluorescence trimodal imaging nanoprobes, a nanocomposite has been constructed by decorating gadolinium ions doped upconversion nanoparticle (Gd-doped UCNP) with radiopaque but fluorescence-transparent tantalum oxide (TaO(x), x ≈ 1). The as-synthesized water-soluble nanoparticle showed a litchi-like shape with an average size of ~30 nm and demonstrated extraordinarily high longitudinal and transverse relaxivity values (r(1) = 11.45 mM(-1)s(-1) and r(2) = 147.3 mM(-1)s(-1)) compared with the reported Gd-doped UCNPs to date. Obvious CT contrast enhancement was obtained by the combined effect between the radiopaque TaO(x) shell and the Gd-doped UCNP inner core. Strong upconversion luminescence (UCL) signal could unobstructedly penetrate out in virtue of high transparency of the TaO(x) shell. No mutual interference among different modalities of the upconversion nanolitchi (UCNL) was found, which ensured that the individual merits of every imaging modality could be brought into full play, demonstrated by in vitro and in vivo imagings. Furthermore, UCNLs showed only a slight effect on macrophages and RBCs in vitro and tissue in vivo.

Ultrasmall NaGdF4 Nanodots for Efficient MR Angiography and Atherosclerotic Plaque Imaging

Dr. H. Xing, Prof. W. Bu, Dr. L. Wang, Dr. Q. Xiao, Dr. D. Ni, Prof. J. Shi State Key Laboratory of High Performance Ceramics and Superfi ne Microstructure Shanghai Institute of Ceramics Chinese Academy of Sciences Shanghai 200050 , P.R. China E-mail: wbbu@mail.sic.ac.cn; jlshi@mail.sic.ac.cn Dr. S. Zhang, Prof. L. Zhou, Prof. W. Peng, Prof. K. Zhao Department of radiology Shanghai Cancer Hospital Fudan University Shanghai 200032 , P.R. China Prof. X. Zheng, Prof. Y. Hua Department of radiation oncology Shanghai Huadong Hospital Fudan University Shanghai 200040 , P.R. China Dr. J. Zhang Shanghai (Red Cross) Blood Center Shanghai Institute of Blood Transfusion Shanghai 200051 , P.R. China

A Gd-doped Mg-Al-LDH/Au nanocomposite for CT/MR bimodal imagings and simultaneous drug delivery

The early diagnosis and simultaneous drug delivery monitored by non-invasive visualization are highly challenging but clinical-relevant for the diagnostics and therapy monitoring of serious diseases such as cancers. Herein, a Gd-doped layered double hydroxide (LDH)/Au nanocomposite has been developed as both a drug carrier and a diagnostic agent. The obtained nanocomposite shows high non-anionic anti-cancer drug DOX loading capacity and an interesting pH-responsive release profile of loaded DOX. The nanocomposite was found to be able to efficiently transport DOX into the cancer cell, release the DOX in the acidic cytoplasm and then cause death of cancer cells. Meanwhile, the nanocomposite demonstrates better in vitro CT and T(1)-weighted MR imaging capabilities than the commercial MRI and CT contrast agents and favorable in vivo CT and T(1)-weighted MR imaging performance. After being modified with heparin, the nanocomposite also demonstrates effective CT and MR imagings of tumors by intravenous administration in tumor-bearing mice. Furthermore, the nanocomposite shows negligible cytotoxicity and no detectable tissue damage on mice after injection of high dosage of nanocomposite. In conclusion, the synthetic nanocomposite is expected to be a potential theranostic agent for bimodal imagings of cancers and anti-cancer drug delivery as well.