Zhong Cao

Enzymatic PEGylated Poly(lactone-co-β-amino ester) Nanoparticles as Biodegradable, Biocompatible and Stable Vectors for Gene Delivery

We have developed new, efficient gene delivery systems based on PEGylated poly(lactone-co-β-amino ester) block copolymers that are biodegradable, stable and low in toxicity. The PEG-poly[PDL-co-3-(4-(methylene)piperidin-1-yl)propanoate] (PEG-PPM) diblock and PPM-PEG-PPM triblock copolymers with various compositions were synthesized in one step via lipase-catalyzed copolymerization of ω-pentadecalactone (PDL) and ethyl 3-(4-(hydroxymethyl)piperidin-1-yl)propanoate (EHMPP) with an appropriate PEG (MeO-PEG-OH or HO-PEG-OH). The amphiphilic block copolymers are capable of condensing DNA in aqueous medium via a self-assembly process to form polyplex micelle nanoparticles with desirable particle sizes (70-140 nm). These micelles possess low CMC values and are stable in the medium containing serum protein molecules (FBS). Among the PEG-PPM and PPM-PEG-PPM micelles, the PEG-PPM-15% PDL micelle particles exhibited high DNA-binding ability, the fastest cellular uptake rate and highest gene transfection efficacy. Flow cytometry analysis shows that LucDNA/PEG-PPM-15% PDL polyplex micelles can effectively escape from endosomal degradation after cellular uptake likely due to the presence of the tertiary amine groups in the copolymer chains that act as proton sponges. In vitro cytotoxicity and hemolysis assay experiments indicate that all copolymer samples are nonhemolytic and have minimal toxicity toward COS-7 cells within the polymer concentration range (≤200 μg/mL) used for the gene transfection. These results demonstrate that the PEGylated poly(lactone-co-β-amino ester) block copolymers are promising new vectors for gene delivery applications.

Stable cerasomes for simultaneous drug delivery and magnetic resonance imaging

Magnetic liposomes have been frequently used as nanocarriers for targeted drug delivery and magnetic resonance imaging in recent years. Despite great potentials, their morphological/structural instability in the physiological environment still remains an intractable challenge for clinical applications. In this study, stable hybrid liposomal cerasomes (ie, liposomes partially coated with silica) which can co-encapsulate Fe3O4 nanoparticles and the anticancer drug paclitaxel were developed using thin film hydration method. Compared with the drug loaded liposomes, the paclitaxel-loaded magnetic cerasomes (PLMCs) exhibited much higher storage stability and better sustained release behavior. Cellular uptake study showed that the utilization of an external magnetic field significantly facilitated the internalization of PLMCs into cancer cells, resulting in potentiated drug efficacy of killing tumor cells. The T2 relaxivity (r2) of our PLMCs was much higher than that of free Fe3O4 nanoparticles, suggesting increased sensitivity in T2-weighted imaging. Given its excellent biocompatibility also shown in the study, such dual functional PLMC is potentially a promising nanosystem for effective cancer diagnosis and therapy.

Stimuli-Responsive Polymeric Nanocarriers for Efficient Gene Delivery

Gene therapy provides an alternative and effective method for treatment of genetic diseases and cancers that are refractory to conventional therapeutics. The success of gene therapy is largely dependent on the development of safe and effective gene delivery vectors for transporting genetic material from the blood stream to the cytoplasm or nucleus. Current gene vectors can be divided into viral and non-viral vectors. Although non-viral gene delivery carriers can offer some advantages, such as safety and facile fabrication, they do not possess the same high gene transfection efficiency as viral vectors due to a lack of functionality to overcome extra- and intracellular gene delivery obstacles. On the basis of these disadvantages, researchers are developing “smart” non-viral gene-delivery carriers in order to overcome the physiological barriers and realize efficient gene transfection. These “smart” stimuli-responsive carriers can undergo physical or chemical reactions in response to internal tumor-specific environments, such as pH conditions, redox potentials, enzymatic activations and thermal gradients, as well as external stimulations, such as ultrasound, light, magnetic fields, and electrical fields. Furthermore, “smart” carriers can also be triggered by dual or multiple combinations of different stimuli. In this review, we highlight the recent stimuli-sensitive polymeric nanocarriers for gene delivery, and we discuss the potential of combining multiple stimuli-responsive strategies for future gene therapy applications.

Highly Uniform Perfluoropropane-Loaded Cerasomal Microbubbles As a Novel Ultrasound Contrast Agent

Microbubbles are widely used as ultrasound contrast agents owing to their excellent echoing characteristics under ultrasound radiation. However, their short sonographic duration and wide size distribution still hinder their application. Herein, we present a hard-template approach to produce perfluoropropane-loaded cerasomal microbubbles (PLCMs) with uniform size and long sonographic duration. The preparation of PLCMs includes deposition of Si-lipids onto functionalized CaCO3 microspheres, removal of their CaCO3 cores and mild infusion of perfluoropropane. In vitro and in vivo experiments showed that PLCMs had excellent echoing characteristics under different ultrasound conditions. More importantly, PLCMs could be imaged for much longer than SonoVue (commercially used microbubbles) under the same ultrasound parameters and concentrations. Our results demonstrated that PLCMs have great potential for use as a novel contrast agent in ultrasound imaging.

Targeted Ultrasound-Triggered Phase Transition Nanodroplets for Her2-Overexpressing Breast Cancer Diagnosis and Gene Transfection

For successful gene therapy, it is imperative to accumulate therapeutic gene in tumor tissues followed by efficiently delivering gene into targeted cells. Ultrasound irradiation, as a noninvasive and cost-effective external stimulus, has been proved to be one of the most potential external-stimulating gene delivery strategies recently in further improving gene transfection. In this study, we developed tumor-targeting ultrasound-triggered phase-transition nanodroplets AHNP-PFP-TNDs comprising a perfluorinated poly(amino acid) C11F17-PAsp (DET) as a core for simultaneously loading perfluoropentane (PFP) and nucleic acids, and a polyanionic polymer PGA-g-PEG-AHNP as the shell for not only modifying the surface of nanodroplets but also introducing an anti-Her2/neu peptide (AHNP) aiming to targeted treatment of Her2-overexpressing breast cancer. The results showed the average diameter of AHNP-PFP-TNDs was below 400 nm, nearly spherical in shape. The modification of PGA-g-PEG-AHNP not only increased the serum stability of the nanodroplets but also improved the affinity between nanodroplets and Her2-overexpressing breast cells. Both intratumor and intravenous injection of AHNP-PFP-TNDs into nude mice bearing HGC-27 xenografts showed that the gene transfection efficiency and the ultrasound contrast effect were significantly enhanced after exposed to the ultrasound irradiation with optimized ultrasound parameters. Therefore, this targeting nanodroplets system could be served as a potential theranostic vector for tumor targeting ultrasound diagnosis and gene therapy.

pH and redox dual-responsive multifunctional gene delivery with enhanced capability of transporting DNA into the nucleus

Stimuli-responsive gene delivery vectors based on physiologically triggered structure changing have been recently recognized as a new therapeutic agent for their excellent performance in vivo. Herein, we present an intelligent gene delivery system based on the octa-arginine peptides (R8)-conjugated polyamino acid derivatives noted as PPCRC (PVIm-(PAsp-Cystamine-R8)-Cholesteryl), which processed pH responsive, surface charge-switching, intracellular redox-responsive and enhanced nucleus import of gene together. Due to the imidazole group in the PPCRC backbone, the DNA/PPCRC polyplexes not only exhibited the enhanced buffering capacity in the endosome after endocytosis, but also displayed the reversible surface charge from negative to positive with decreasing the pH value form pH 7.4 to pH 6.5-6.8, which would promote the cell membrane binding and cellular uptake. The disulfide bond for R8 peptides conjugation in the polymer side chain could be rapidly cleaved under reductive conditions, facilitating DNA release in the cytoplasm. Subsequently, the DNA would be still associated with the R8 peptides, which would promote the intracellular nucleus import of DNA. The luciferase gene expression level of COS-7 cells transfected by DNA/PPCRC polyplexes was almost 2000 folds higher than cells transfected by DNA/PPCC polyplexes (without R8 peptides modification) in growth-arrested cell model. Nearly 10 folds enhanced gene transfection efficiency was found on human bone mesenchymal stem cells (hBMSCs) using the same strategy, which revealed that this intelligent vector can be also utilized in transfection of non-dividing cells. Intravenous injection of the DNA/PPCRC polyplexes also achieved the effective transfection in subcutaneous tumor model. Taken together, PPCRC vector has great potential for both dividing and non-dividing cells transfection and in vivo gene delivery application.

Chitosan coated gold nanorod chelating gadolinium for MRI-visible photothermal therapy of cancer

The quick development of photothermal therapy (PTT) affords great opportunities for cancer therapy owing to its minimally invasive nature and controllable treatment method. A facile imaging guidance for the treatment will facilitate its clinical application potential. A type of multifunctional hybrid nanoparticles (h-NPs) has been developed by loading gold nanorods (GNRs) into gadolinium (Gd)–DTPA-conjugated chitosan (Gd–DTPA–CS). Then, the vesicular surface was coated with a PGA-g-mPEG layer via electrostatic adsorption, resulting in GNR/Gd–DTPA–CS@PEG NPs with uniform size distribution, high colloidal stability and bio-safety. In vivo magnetic resonance (MR) imaging of tumor bearing mice revealed tumor accumulation of h-NPs administered by intravenous (IV) injection. Under the guidance of MR imaging, the photothermal therapy achieved an effective tumor ablation. Thus, this study showed the potential of h-NPs as a potent photothermal agent for MRI-guided cancer treatment.

Cerasome-based Gold-Nanoshell Encapsulating L-Menthol for Ultrasound Contrast Imaging and Photothermal Therapy of Cancer

Various nanoformulations of perfluorocarbon have been developed thus far, to achieve ultrasound imaging of tumors and tumor-targeted therapy. However, their application has been greatly limited by their short sonographic duration and large size distribution. A novel theranostic agent was constructed based on gold nanoshell cerasome-encapsulated L-menthol (GNC-LM). Owing to the sustained and controllable generation of L-menthol bubbles under near-infrared laser irradiation, GNC-LM showed good performance in contrast enhancement of ultrasound imaging in vivo. GNC-LM could be imaged for 30 min, which is much longer than the imaging time of SonoVue (commercially used microbubbles). Moreover, photothermal therapy (PTT) based on the light-to-heat conversion of the nanosystem effectively ablated the tumor. Our study demonstrated the promising potential of the obtained GNC-LM to serve as a therapeutic nanoprobe for ultrasound contrast imaging and PTT of tumors.