Browsing by Author "Zhao, Zongmin"

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    Exploring the activity of a polyazine bridged Ru(ii)-Pt(ii) supramolecule in F98 rat malignant glioma cells
    Zhu, Jie; Rodriguez-Corrales, José Á.; Prussin, Reece; Zhao, Zongmin; Dominijanni, Anthony; Hopkins, Samantha L.; Winkel, Brenda S. J.; Robertson, John L.; Brewer, Karen J. (Royal Society of Chemistry, 2016-11-07)
    The mixed-metal supramolecular complex, [(Ph2phen)2Ru(dpp)PtCl2]2+, displays significant DNA modification, cell growth inhibition, and toxicity towards F98 malignant glioma cells following visible light irradiation. The design of this complex affords superior cellular uptake and antiproliferative activity compared to the classic chemotherapeutic agent, cisplatin.
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    Factors that Affect the Immunogenicity of Lipid-PLGA Nanoparticle-Based Nanovaccines against Nicotine Addiction
    Zhao, Zongmin (Virginia Tech, 2017-09-06)
    Tobacco smoking has consistently been the leading cause of preventable diseases and premature deaths. Currently, pharmacological interventions have only shown limited smoking cessation efficacy and sometimes are associated with severe side effects. As an alternative, nicotine vaccines have emerged as a promising strategy to combating nicotine addiction. However, conventional conjugate nicotine vaccines have shown limited ability to induce a sufficiently strong immune response due to their intrinsic shortfalls. In this study, a lipid-poly(lactic-co-glycolic acid) (PLGA) nanoparticle-based next-generation nicotine vaccine has been developed to overcome the drawbacks of conjugate nicotine vaccines. Also, the influence of multiple factors, including nanoparticle size, hapten density, hapten localization, carrier protein, and molecular adjuvants, on its immunogenicity has been investigated. Results indicated that all these studied factors significantly affected the immunological efficacy of the nicotine nanovaccine. First, 100 nm nanovaccine was found to elicit a significantly higher anti-nicotine antibody titer than the 500 nm nanovaccine. Secondly, the high-density nanovaccine exhibited a better immunological efficacy than the low- and medium-density counterparts. Thirdly, the nanovaccine with hapten localized on both carrier protein and nanoparticle surface induced a significantly higher anti-nicotine antibody titer and had a considerably better ability to block nicotine from entering the brain of mice than the nanovaccines with hapten localized only on carrier protein or nanoparticle surface. Fourthly, the nanovaccines carrying cross reactive materials 197 (CRM197) or tetanus toxoid (TT) showed a better immunological efficacy than the nanovaccines using keyhole limpet hemocyanin (KLH) or KLH subunit as carrier proteins. Finally, the co-delivery of monophosphoryl lipid A (MPLA) and Resiquimod (R848) achieved a considerably higher antibody titer and brain nicotine reduction than only using MPLA or R848 alone as adjuvants. Collectively, the findings from this study may lead to a better understanding of the impact of multiple factors on the immunological efficacy of the hybrid nanoparticle-based nicotine nanovaccine. The findings may also provide significant guidance for the development of other drug abuse and nanoparticle-based vaccines. In addition, the optimized lipid-PLGA hybrid nanoparticle-based nicotine nanovaccine obtained by modulating the studied factors can be a promising candidate as the next-generation nicotine vaccine for treating nicotine addiction.
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    The impact of sphingosine kinase inhibitor-loaded nanoparticles on bioelectrical and biomechanical properties of cancer cells
    Babahosseini, Hesam; Srinivasaraghavan, Vaishnavi; Zhao, Zongmin; Gillam, Francis; Childress, Elizabeth; Strobl, Jeannine S.; Santos, Webster L.; Zhang, Chenming; Agah, Masoud (The Royal Society of Chemistry, 2015-11-19)
    Cancer progression and physiological changes within the cells are accompanied by alterations in the biophysical properties. Therefore, the cell biophysical properties can serve as promising markers for cancer detection and physiological activities. To aid in the investigation of the biophysical markers of cells, a microfluidic chip has been developed which consists of a constriction channel and embedded microelectrodes. Single-cell impedance magnitudes at four frequencies and entry and travel times are measured simultaneously during their transit through the constriction channel. This microchip provides a high-throughput, label-free, automated assay to identify biophysical signatures of malignant cells and monitor the therapeutic efficacy of drugs. Here, we monitored the dynamic cellular biophysical properties in response to sphingosine kinase inhibitors (SphKIs), and compared the effectiveness of drug delivery using poly lactic-co-glycolic acid (PLGA) nanoparticles (NPs) loaded with SphKIs versus conventional delivery. Cells treated with SphKIs showed significantly higher impedance magnitudes at all four frequencies. The bioelectrical parameters extracted using a model also revealed that the highly aggressive breast cells treated with SphKIs shifted electrically towards that of a less malignant phenotype; SphKI-treated cells exhibited an increase in cell-channel interface resistance and a significant decrease in specific membrane capacitance. Furthermore, SphKI-treated cells became slightly more deformable as measured by a decrease in their channel entry and travel times. We observed no significant difference in the bioelectrical changes produced by SphKI delivered conventionally or with NPs. However, NPs-packaged delivery of SphKI decreased the cell deformability. In summary, this study showed that while the bioelectrical properties of the cells were dominantly affected by SphKIs, the biomechanical properties were mainly changed by the NPs.
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    Rationalization of a nanoparticle-based nicotine nanovaccine as an effective next-generation nicotine vaccine: A focus on hapten localization
    Zhao, Zongmin; Hu, Yun; Harmon, Theresa; Pentel, Paul; Ehrich, Marion F.; Zhang, Chenming (2017-09-01)
    A lipid-polymeric hybrid nanoparticle-based next-generation nicotine nanovaccine was rationalized in this study to combat nicotine addiction. A series of nanovaccines, which had nicotine-haptens localized on carrier protein (LPKN), nanoparticle surface (LPNK), or both (LPNKN), were designed to study the impact of hapten localization on their immunological efficacy. All three nanovaccines were efficiently taken up and processed by dendritic cells. LPNKN induced a significantly higher immunogenicity against nicotine and a significantly lower anti-carrier protein antibody level compared to LPKN and LPNK. Meanwhile, it was found that the anti-nicotine antibodies elicited by LPKN and LPNKN bind nicotine stronger than those elicited by LPKN, and LPNK and LPNKN resulted in a more balanced Th1-Th2 immunity than LPKN. Moreover, LPNKN exhibited the best ability to block nicotine from entering the brain of mice. Collectively, the results demonstrated that the immunological efficacy of the hybrid nanoparticle-based nicotine vaccine could be enhanced by modulating hapten localization, providing a promising strategy to combatting nicotine addiction.