Your search keyword '"Guo, Yubo"' showing total 7 results

1. Angiopep-Conjugated Nanoparticles for Targeted Long-Term Gene Therapy of Parkinson’s Disease

Author

Huang, Rongqin, Ma, Haojun, Guo, Yubo, Liu, Shuhuan, Kuang, Yuyang, Shao, Kun, Li, Jianfeng, Liu, Yang, Han, Liang, Huang, Shixian, An, Sai, Ye, Liya, Lou, Jinning, and Jiang, Chen

Published

2013

2. Choline transporter-targeting and co-delivery system for glioma therapy.

Author

Li, Jianfeng, Guo, Yubo, Kuang, Yuyang, An, Sai, Ma, Haojun, and Jiang, Chen

Subjects

*CHOLINE, *GLIOMA treatment, *DRUG delivery systems, *CANCER treatment, *GENE therapy, *CANCER chemotherapy, *TUMOR necrosis factors, *BLOOD-brain barrier

Abstract

Abstract: Combination of gene therapy and chemotherapy is a promising approach for glioma therapy. In this study, a co-delivery system of plasmid encoding human tumor necrosis factor-related apoptosis-inducing ligand (pORF-hTRAIL, Trail) and doxorubicin (DOX) has been simply constructed in two steps. Firstly, DOX was intercalated into Trail to form a stable complex. Secondly, DOX-Trail complex was condensed by Dendrigraft poly-l-lysine (DGL) to form a nanoscaled co-delivery system. Choline transporters are both expressed on blood–brain barrier (BBB) and glioma, Herein, a choline derivate with high choline transporter affinity was chosen as BBB and glioma dual targeting ligand. Choline-derivate modified co-delivery system showed higher cellular uptake efficiency and cytotoxicity than unmodified co-delivery system in U87 MG cells. In comparison with single medication or unmodified delivery system, Choline-derivate modified co-delivery system induced more apoptosis both in vitro and in vivo. The therapeutic efficacy on U87 MG bearing xenografts further confirmed the predominance of this dual targeting and co-delivery system. [Copyright &y& Elsevier]

Published

2013

3. Targeting Caspase-3 as Dual Therapeutic Benefits by RNAi Facilitating Brain-Targeted Nanoparticles in a Rat Model of Parkinson’s Disease

Author

Liu, Yang, Guo, Yubo, An, Sai, Kuang, Yuyang, He, Xi, Ma, Haojun, Li, Jianfeng, Lv, Jing, Zhang, Ning, and Jiang, Chen

Subjects

*CASPASE inhibitors, *RNA interference, *NANOMEDICINE, *PARKINSON'S disease, *APOPTOSIS, *INFLAMMATION, *LABORATORY rats

Abstract

The activation of caspase-3 is an important hallmark in Parkinson’s disease. It could induce neuron death by apoptosis and microglia activation by inflammation. As a result, inhibition the activation of caspase-3 would exert synergistic dual effect in brain in order to prevent the progress of Parkinson’s disease. Silencing caspase-3 genes by RNA interference could inhibit the activation of caspase-3. We developed a brain-targeted gene delivery system based on non-viral gene vector, dendrigraft poly-L-lysines. A rabies virus glycoprotein peptide with 29 amino-acid linked to dendrigraft poly-L-lysines could render gene vectors the ability to get across the blood brain barrier by specific receptor mediated transcytosis. The resultant brain-targeted vector was complexed with caspase-3 short hairpin RNA coding plasmid DNA, yielding nanoparticles. In vivo imaging analysis indicated the targeted nanoparticles could accumulate in brain more efficiently than non-targeted ones. A multiple dosing regimen by weekly intravenous administration of the nanoparticles could reduce activated casapse-3 levels, significantly improve locomotor activity and rescue dopaminergic neuronal loss and in Parkinson’s disease rats’ brain. These results indicated the rabies virus glycoprotein peptide modified brain-targeted nanoparticles were promising gene delivery system for RNA interference to achieve anti-apoptotic and anti-inflammation synergistic therapeutic effects by down-regulation the expression and activation of caspase-3. [ABSTRACT FROM AUTHOR]

Published

2013

4. Gene and doxorubicin co-delivery system for targeting therapy of glioma

Author

Liu, Shuhuan, Guo, Yubo, Huang, Rongqin, Li, Jianfeng, Huang, Shixian, Kuang, Yuyang, Han, Liang, and Jiang, Chen

Subjects

*GLIOMA treatment, *DOXORUBICIN, *DRUG delivery systems, *TARGETED drug delivery, *GENE therapy, *CANCER chemotherapy, *DRUG design

Abstract

Abstract: The combination of gene therapy and chemotherapy is a promising treatment strategy for brain gliomas. In this paper, we designed a co-delivery system (DGDPT/pORF-hTRAIL) loading chemotherapeutic drug doxorubicin and gene agent pORF-hTRAIL, and with functions of pH-trigger and cancer targeting. Peptide HAIYPRH (T7), a transferrin receptor-specific peptide, was chosen as the ligand to target the co-delivery system to the tumor cells expressing transferrin receptors. T7-modified co-delivery system showed higher efficiency in cellular uptake and gene expression than unmodified co-delivery system in U87 MG cells, and accumulated in tumor more efficiently in vivo. DOX was covalently conjugated to carrier though pH-trigged hydrazone bond. In vitro incubation of the conjugates in buffers led to a fast DOX release at pH 5.0 (intracellular environment) while at pH 7.4 (blood) the conjugates are relatively stable. The combination treatment resulted in a synergistic growth inhibition (combination index, CI < 1) in U87 MG cells. The synergism effect of DGDPT/pORF-hTRAIL was verified in vitro and in vivo. In vivo anti-glioma efficacy study confirmed that DGDPT/pORF-hTRAIL displayed anti-glioma activity but was less toxic. [Copyright &y& Elsevier]

Published

2012

5. T7 peptide-functionalized nanoparticles utilizing RNA interference for glioma dual targeting.

Author

Kuang, Yuyang, An, Sai, Guo, Yubo, Huang, Shixian, Shao, Kun, Liu, Yang, Li, Jianfeng, Ma, Haojun, and Jiang, Chen

Subjects

*PEPTIDES, *NANOMEDICINE, *RNA interference, *GLIOMA treatment, *TARGETED drug delivery, *CANCER treatment, *GENE therapy, *DRUG delivery systems, *THERAPEUTICS

Abstract

Abstract: Among all the malignant brain tumors, glioma is the deadliest and most common form with poor prognosis. Gene therapy is regarded as a promising way to halt the progress of the disease or even cure the tumor and RNA interference (RNAi) stands out. However, the existence of the blood–brain barrier (BBB) and blood tumor barrier (BTB) limits the delivery of these therapeutic genes. In this work, the delivery system targeting to the transferrin (Tf) receptor highly expressed on both BBB and glioma was successfully synthesized and would not compete with endogenous Tf. U87 cells stably express luciferase were employed here to simulate tumor and the RNAi experiments in vitro and in vivo validated that the gene silencing activity was 2.17-fold higher with the targeting ligand modification. The dual-targeting gene delivery system exhibits a series of advantages, such as high efficiency, low toxicity, stability and high transaction efficiency, which may provide new opportunities in RNAi therapeutics and nanomedicine of brain tumors. [Copyright &y& Elsevier]

Published

2013

6. Brain-targeted co-delivery of therapeutic gene and peptide by multifunctional nanoparticles in Alzheimer's disease mice.

Author

Liu, Yang, An, Sai, Li, Jianfeng, Kuang, Yuyang, He, Xi, Guo, Yubo, Ma, Haojun, Zhang, Yu, Ji, Bin, and Jiang, Chen

Subjects

*ALZHEIMER'S disease treatment, *NANOPARTICLES, *GENE delivery techniques, *NANOCARRIERS, *BRAIN physiology, *LABORATORY mice

Abstract

Multifunctional nanocarriers are increasingly promising for disease treatment aimed to regulate multiple pathological dysfunctions and overcome barriers in drug delivery. Here we develop a multifunctional nanocarrier for Alzheimer's disease (AD) treatment by achieving therapeutic gene and peptide co-delivery to brain based on PEGylated dendrigraft poly- l -lysines (DGLs) via systemic administration. The dendritic amine-rich structure of DGLs provides plenty reaction sites and positive charge for drug loading. Successful co-delivery of drugs overcoming the blood–brain barrier by brain-targeted ligand modification was demonstrated both in vitro and in vivo . The pharmacodynamics study of the system following multiple-dosing treatment was verified in transgenic AD mice. Down-regulation of the key enzyme in amyloid-β formation was achieved by delivering non-coding RNA plasmid. Simultaneous delivery of the therapeutic peptide into brain leads to reduction of neurofibrillary tangles. Meanwhile, memory loss rescue in AD mice was also observed. Taken together, the multifunctional nanocarrier provides an excellent drug co-delivery platform for brain diseases. [ABSTRACT FROM AUTHOR]

Published

2016

7. Tumor targeting and microenvironment-responsive nanoparticles for gene delivery.

Author

Huang, Shixian, Shao, Kun, Kuang, Yuyang, Liu, Yang, Li, Jianfeng, An, Sai, Guo, Yubo, Ma, Haojun, He, Xi, and Jiang, Chen

Subjects

*TUMOR treatment, *TARGETED drug delivery, *NANOMEDICINE, *CANCER treatment, *GENE therapy, *DRUG delivery systems, *MATRIX metalloproteinases, *GENETIC regulation

Abstract

Abstract: A tumor targeting nanoparticle system has been successfully developed to response to the lowered tumor extracellular pH (pHe) and upregulated matrix metalloproteinase 2 (MMP2) in the tumor microenvironment. The nanoparticles are modified with activatable cell-penetrating peptide (designated as dtACPP) that's dual-triggered by the lowered pHe and MMP2. In dtACPP, the internalization function of cell-penetrating peptide (CPP) is quenched by a pH-sensitive masking peptide, linking by a MMP2 substrate. The masking peptide is negatively charged to quench the cationic CPP well after systemic administration. Hence, dtACPP-modified nanoparticles possesses passive tumor targetability via the enhanced permeability and retention (EPR) effect. Once reaching the tumor microenvironment, the pre-existing attraction would be eliminated due to the lowered pHe, accompanying the linker cleaved by MMP2, dtACPP would be activated to expose CPP to drive the nanoparticles' internalization into the intratumoral cells. The studies of plasmid DNA loading, toxicity assessment, cellular uptake, tumor targeting delivery, and gene transfection demonstrate that dtACPP-modified nanoparticle system is a potential candidate for tumor targeting gene delivery. [Copyright &y& Elsevier]

Published

2013