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1. Design and Application of Functional Hydrophilic Polymers in Engineering and Biomedical Drug Delivery

Author

Lo, Chiao-Yueh, Dunn, Bruce S1, Zink, Jeffrey I, Lo, Chiao-Yueh, Lo, Chiao-Yueh, Dunn, Bruce S1, Zink, Jeffrey I, and Lo, Chiao-Yueh

Abstract

Synthetic hydrophilic polymers are a type of polymers with polar or charged functional groups, and such functional groups render them with favorable interactions with water, leading to solubility or swellability. These polymers have been used in a wide variety of applications because they can be fabricated into novel materials with customized properties through carefully designed synthetic strategy and proper modification.In the first chapter, a series of polyacrylamide (PAM) based polymers were applied to cohesionless, sandy soil for dust suppression. PAM is a hydrogel, a hydrophilic crosslinked polymer that does not dissolve in water and is a super water absorbent. We copolymerized PAM with hydrophobic units to control the polymer swelling ratio, and thus managed to mitigate the undesirable polymer swelling, soil matrix expansion, and the mechanical strength loss upon wet-dry processes. We further demonstrated that the treatment depth is controllable, which is crucial to minimize environmental impact, by fine-tuning the precursor composition for in-situ curing.In the second and third chapters, we combined the functions of piezoresistive strain sensing and photothermal actuation into a single material, resembling living organisms’ neuromuscular behaviors. This design solved the limitation of conventional physically-integrated sensory actuator systems with interface constraints and predefined functions. The material composed of an interpenetrating double-network of a nanostructured thermo-responsive hydrogel poly(N-isopropylacrylamide) and a light-absorbing, electrically conductive polymer. When connected to a control circuit, these muscle-like materials achieved closed-loop feedback controlled, reversible step motion.In the fourth chapter, polydopamine (PDA) nanoparticles mixed with large pore MSNs were used to deliver drugs. This research seeks to develop nanotherapeutics to deliver an ultra-short course tuberculosis treatment regimen via inhalation, for both drug

Published
2022

2. Nanomachines and Other Caps on Mesoporous Silica Nanoparticles for Drug Delivery.

Author

Chen, Wei, Chen, Wei, Glackin, Carlotta A, Horwitz, Marcus A, Zink, Jeffrey I, Chen, Wei, Chen, Wei, Glackin, Carlotta A, Horwitz, Marcus A, and Zink, Jeffrey I

Abstract

Mesoporous silica nanoparticles (MSNs) are delivery vehicles that can carry cargo molecules and release them on command. The particles used in the applications reported in this Account are around 100 nm in diameter (about the size of a virus) and contain 2.5 nm tubular pores with a total volume of about 1 cm3/g. For the biomedical applications discussed here, the cargo is trapped in the pores until the particles are stimulated to release it. The challenges are to get the particles to the site of a disease and then to deliver the cargo on command. We describe methods to do both, and we illustrate the applicability of the particles to cure cancer and intracellular infectious disease. Our first steps were to design multifunctional nanoparticles with properties that allow them to carry and deliver hydrophobic drugs. Many important pharmaceuticals are hydrophobic and cannot reach the diseased sites by themselves. We describe how we modified MSNs to make them dispersible, imagable, and targetable and discuss in vitro studies. We then present examples of surface modifications that allow them to deliver large molecules such as siRNA. In vivo studies of siRNA delivery to treat triple-negative breast and ovarian cancers are presented. The next steps are to attach nanomachines and other types of caps that trap drug molecules but release them when stimulated. We describe nanomachines that respond autonomously (without human intervention) to stimuli specific to disease sites. A versatile type of machine is a nanovalve that is closed at neutral (blood) pH but opens upon acidification that occurs in endolysosomes of cancer cells. Another type of machine, a snap-top cap, is stimulated by reducing agents such as glutathione in the cytosol of cells. Both of these platforms were studied in vitro to deliver antibiotics to infected macrophages and in vivo to cure and kill the intracellular bacteria M. tuberculosis and F. tularensis. The latter is a tier 1 select agent of bioterrorism. F

Published
2019

3. Nanoparticle Formulation of Moxifloxacin and Intramuscular Route of Delivery Improve Antibiotic Pharmacokinetics and Treatment of Pneumonic Tularemia in a Mouse Model.

Author

Clemens, Daniel L, Clemens, Daniel L, Lee, Bai-Yu, Plamthottam, Sheba, Tullius, Michael V, Wang, Ruining, Yu, Chia-Jung, Li, Zilu, Dillon, Barbara Jane, Zink, Jeffrey I, Horwitz, Marcus A, Clemens, Daniel L, Clemens, Daniel L, Lee, Bai-Yu, Plamthottam, Sheba, Tullius, Michael V, Wang, Ruining, Yu, Chia-Jung, Li, Zilu, Dillon, Barbara Jane, Zink, Jeffrey I, and Horwitz, Marcus A

Abstract

Francisella tularensis causes a serious and often fatal infection, tularemia. We compared the efficacy of moxifloxacin formulated as free drug vs disulfide snap-top mesoporous silica nanoparticles (MSNs) in a mouse model of pneumonic tularemia. We found that MSN-formulated moxifloxacin was more effective than free drug and that the intramuscular and subcutaneous routes were markedly more effective than the intravenous route. Measurement of tissue silica levels and fluorescent flow cytometry assessment of colocalization of MSNs with infected cells revealed that the enhanced efficacy of MSNs and the intramuscular route of delivery was not due to better delivery of MSNs to infected tissues or cells. However, moxifloxacin blood levels demonstrated that the nanoparticle formulation and intramuscular route provided the longest half-life and longest time above the minimal inhibitory concentration. Thus, improved pharmacokinetics are responsible for the greater efficacy of nanoparticle formulation and intramuscular delivery compared with free drug and intravenous delivery.

Published
2019

4. Activity and electrochemical properties: iron complexes of the anticancer drug triapine and its analogs.

Author

Plamthottam, Sheba, Plamthottam, Sheba, Sun, Daniel, Van Valkenburgh, Juno, Valenzuela, Jeffrey, Ruehle, Bastian, Steele, Dalton, Poddar, Soumya, Marshalik, Maxim, Hernandez, Selena, Radu, Caius Gabriel, Zink, Jeffrey I, Plamthottam, Sheba, Plamthottam, Sheba, Sun, Daniel, Van Valkenburgh, Juno, Valenzuela, Jeffrey, Ruehle, Bastian, Steele, Dalton, Poddar, Soumya, Marshalik, Maxim, Hernandez, Selena, Radu, Caius Gabriel, and Zink, Jeffrey I

Abstract

Triapine (3-AP), is an iron-binding ligand and anticancer drug that is an inhibitor of human ribonucleotide reductase (RNR). Inhibition of RNR by 3-AP results in the depletion of dNTP precursors of DNA, thereby selectively starving fast-replicating cancer cells of nucleotides for survival. The redox-active form of 3-AP directly responsible for inhibition of RNR is the Fe(II)(3-AP)2 complex. In this work, we synthesize 12 analogs of 3-AP, test their inhibition of RNR in vitro, and study the electronic properties of their iron complexes. The reduction and oxidation events of 3-AP iron complexes that are crucial for the inhibition of RNR are modeled with solution studies. We monitor the pH necessary to induce reduction in iron complexes of 3-AP analogs in a reducing environment, as well as the kinetics of oxidation in an oxidizing environment. The oxidation state of the complex is monitored using UV-Vis spectroscopy. Isoquinoline analogs of 3-AP favor the maintenance of the biologically active reduced complex and possess oxidation kinetics that allow redox cycling, consistent with their effective inhibition of RNR seen in our in vitro experiments. In contrast, methylation on the thiosemicarbazone secondary amine moiety of 3-AP produces analogs that form iron complexes with much higher redox potentials, that do not redox cycle, and are inactive against RNR in vitro. The catalytic subunit of human Ribonucleotide Reductase (RNR), contains a tyrosyl radical in the enzyme active site. Fe(II) complexes of 3-AP and its analogs can quench the radical and, subsequently, inactivate RNR. The potency of RNR inhibitors is highly dependent on the redox properties of the iron complexes, which can be tuned by ligand modifications. Complexes are found to be active within a narrow redox window imposed by the cellular environment.

Published
2019

5. Facile Strategy Enabling Both High Loading and High Release Amounts of the Water-Insoluble Drug Clofazimine Using Mesoporous Silica Nanoparticles.

Author

Chen, Wei, Chen, Wei, Cheng, Chi-An, Lee, Bai-Yu, Clemens, Daniel L, Huang, Wen-Yen, Horwitz, Marcus A, Zink, Jeffrey I, Chen, Wei, Chen, Wei, Cheng, Chi-An, Lee, Bai-Yu, Clemens, Daniel L, Huang, Wen-Yen, Horwitz, Marcus A, and Zink, Jeffrey I

Abstract

The use of nanocarriers to deliver poorly soluble drugs to the sites of diseases is an attractive and general method, and mesoporous silica nanoparticles (MSNs) are increasingly being used as carriers. However, both loading a large amount of drugs into the pores and still being able to release the drug is a challenge. In this paper, we demonstrate a general strategy based on a companion molecule that chaperones the drug into the pores and also aids it in escaping. A common related strategy is to use a miscible co-solvent dimethyl sulfoxide (DMSO), but although loading may be efficient in DMSO, this co-solvent frequently diffuses into an aqueous environment, leaving the drug behind. We demonstrate the method by using acetophenone (AP), an FDA-approved food additive as the chaperone for clofazimine (CFZ), a water-insoluble antibiotic used to treat leprosy and multidrug-resistant tuberculosis. AP enables a high amount of CFZ cargo into the MSNs and also carries CFZ cargo out from the MSNs effectively when they are in an aqueous biorelevant environment. The amount of loading and the CFZ release efficiency from MSNs were optimized; 4.5 times more CFZ was loaded in MSNs with AP than that with DMSO and 2300 times more CFZ was released than that without the assistance of the AP. In vitro treatment of macrophages infected by Mycobacterium tuberculosis with the optimized CFZ-loaded MSNs killed the bacteria in the cells in a dose-dependent manner. These studies demonstrate a highly efficient method for loading nanoparticles with water-insoluble drug molecules and the efficacy of the nanoparticles in delivering drugs into eukaryotic cells in aqueous media.

Published
2018

6. Synthesis of Reactive Metal Complexes Supported by 1,1’-disubstituted Ferrocene Ligands

Author

Brosmer, Jonathan Lee, Diaconescu, Paula L1, Zink, Jeffrey I, Brosmer, Jonathan Lee, Brosmer, Jonathan Lee, Diaconescu, Paula L1, Zink, Jeffrey I, and Brosmer, Jonathan Lee

Abstract

Reliable transformation of low-cost rare-earth metal oxides to organometallic rare-earth metal complexes is a prerequisite for the advancement of non-aqueous rare-earth metal chemistry. We have recently developed an in situ method to prepare rare-earth alkyl and halide precursors supported by a diamidoferrocene NNfc, 1,1’-fc(NSiMe2Bu)2, as an ancillary ligand. We extended the scope of this method to other lanthanide ions including those that are redox active, such as cerium, praseodymium, samarium, terbium, thulium, and ytterbium. Specifically, samarium trisbenzyl could be generated in situ and then converted to the corresponding samarium benzyl or iodide complexes in good yield. However, it was found that ytterbium trisbenzyl could not be formed cleanly and the consequent conversion to ytterbium iodide complex was low yielding. By adapting an alternative route, the desired ytterbium chloride precursor could be obtained in good yield and purity. The synthesis and characterization of two yttrium alkyl complexes supported by a bisphosphinimine ferrocene ligand, NPfc (1,1′-di(2,4-di-tert-butyl-6-diphenylphosphiniminophenoxy)ferrocene), were accomplished. Although (NPfc)Y(CH2Ph) and (NPfc)Y(CH2SiMe3) could be structurally characterized, these compounds are thermally sensitive and decompose at ambient temperature within hours. Their characterization was accomplished by NMR spectroscopy, electrochemical measurements, and elemental analysis. Reactivity studies were also carried out; however, the lack of prolonged thermal stability at ambient temperature of these molecules led to decomposition before a clean transformation to reaction products could be observed.The synthesis and characterization of Ln-C4Ph4-K, [(NNTBS)Ln(η2-C4Ph4)][K(THF)x] (Ln = Sc, Y, Lu), rare-earth metal complexes supported by a ferrocene diamide ligand, NNTBS (NNTBS = fc(NSitBuMe2)2, fc = 1,1′-ferrocenediyl), were accomplished. The preparation of the half-sandwich compounds, Ln-naph-K, [(NNTBS)Ln(μ-C10

Published
2017

7. A Pathogen-Specific Cargo Delivery Platform Based on Mesoporous Silica Nanoparticles.

Author

Ruehle, Bastian, Ruehle, Bastian, Clemens, Daniel L, Lee, Bai-Yu, Horwitz, Marcus A, Zink, Jeffrey I, Ruehle, Bastian, Ruehle, Bastian, Clemens, Daniel L, Lee, Bai-Yu, Horwitz, Marcus A, and Zink, Jeffrey I

Abstract

We present a synthetic approach to a highly pathogen-selective detection and delivery platform based on the interaction of an antibody nanovalve with a tetrasaccharide from the O-antigen of the lipopolysaccharide (LPS) of Francisella tularensis bacteria, a Tier 1 Select Agent of bioterrorism. Different design considerations are explored, and proof-of-concept for highly pathogen-specific cargo release from mesoporous silica nanoparticles is demonstrated by comparisons of the release of a signal transducer and model drug by LPS from F. tularensis vs Pseudomonas aeruginosa and by F. tularensis live bacteria vs the closely related bacterium Francisella novocida. In addition to the specific response to a biowarfare agent, treatment of infectious diseases in general could benefit tremendously from a delivery platform that releases its antibiotic payload only at the site of infection and only in the presence of the target pathogen, thereby minimizing off-target toxicities.

Published
2017

8. Nanoparticle delivery of siRNA against TWIST to reduce drug resistance and tumor growth in ovarian cancer models.

Author

Roberts, Cai M, Roberts, Cai M, Shahin, Sophia Allaf, Wen, Wei, Finlay, James B, Dong, Juyao, Wang, Ruining, Dellinger, Thanh H, Zink, Jeffrey I, Tamanoi, Fuyuhiko, Glackin, Carlotta A, Roberts, Cai M, Roberts, Cai M, Shahin, Sophia Allaf, Wen, Wei, Finlay, James B, Dong, Juyao, Wang, Ruining, Dellinger, Thanh H, Zink, Jeffrey I, Tamanoi, Fuyuhiko, and Glackin, Carlotta A

Abstract

Epithelial ovarian cancer (EOC) is the most deadly gynecologic malignancy on account of its late stage at diagnosis and frequency of drug resistant recurrences. Novel therapies to overcome these barriers are urgently needed. TWIST is a developmental transcription factor reactivated in cancers and linked to angiogenesis, metastasis, cancer stem cell phenotype, and drug resistance, making it a promising therapeutic target. In this work, we demonstrate the efficacy of TWIST siRNA (siTWIST) and two nanoparticle delivery platforms to reverse chemoresistance in EOC models. Polyamidoamine dendrimers and mesoporous silica nanoparticles (MSNs) carried siTWIST into target cells and led to sustained TWIST knockdown in vitro. Mice treated with cisplatin plus MSN-siTWIST exhibited lower tumor burden than mice treated with cisplatin alone, with most of the effect coming from reduction in disseminated tumors. This platform has potential application for overcoming the clinical challenges of metastasis and chemoresistance in EOC and other TWIST overexpressing cancers.

Published
2017

9. Synthesis of Reactive Metal Complexes Supported by 1,1'-disubstituted Ferrocene Ligands

Author

Brosmer, Jonathan Lee, Diaconescu, Paula L1, Zink, Jeffrey I, Brosmer, Jonathan Lee, Brosmer, Jonathan Lee, Diaconescu, Paula L1, Zink, Jeffrey I, and Brosmer, Jonathan Lee

Abstract

Reliable transformation of low-cost rare-earth metal oxides to organometallic rare-earth metal complexes is a prerequisite for the advancement of non-aqueous rare-earth metal chemistry. We have recently developed an in situ method to prepare rare-earth alkyl and halide precursors supported by a diamidoferrocene NNfc, 1,1'-fc(NSiMe2Bu)2, as an ancillary ligand. We extended the scope of this method to other lanthanide ions including those that are redox active, such as cerium, praseodymium, samarium, terbium, thulium, and ytterbium. Specifically, samarium trisbenzyl could be generated in situ and then converted to the corresponding samarium benzyl or iodide complexes in good yield. However, it was found that ytterbium trisbenzyl could not be formed cleanly and the consequent conversion to ytterbium iodide complex was low yielding. By adapting an alternative route, the desired ytterbium chloride precursor could be obtained in good yield and purity. The synthesis and characterization of two yttrium alkyl complexes supported by a bisphosphinimine ferrocene ligand, NPfc (1,1 -di(2,4-di-tert-butyl-6-diphenylphosphiniminophenoxy)ferrocene), were accomplished. Although (NPfc)Y(CH2Ph) and (NPfc)Y(CH2SiMe3) could be structurally characterized, these compounds are thermally sensitive and decompose at ambient temperature within hours. Their characterization was accomplished by NMR spectroscopy, electrochemical measurements, and elemental analysis. Reactivity studies were also carried out; however, the lack of prolonged thermal stability at ambient temperature of these molecules led to decomposition before a clean transformation to reaction products could be observed. The synthesis and characterization of Ln-C4Ph4-K, [(NNTBS)Ln(2-C4Ph4)][K(THF)x] (Ln = Sc, Y, Lu), rare-earth metal complexes supported by a ferrocene diamide ligand, NNTBS (NNTBS = fc(NSitBuMe2)2, fc = 1,1 -ferrocenediyl), were accomplished. The preparation of the half-sandwich compounds, Ln-naph-K, [(NNTBS)Ln( -C10H8)][K(THF)2] (Ln = Sc, Y, Lu, La), was necessary in order to obtain high yields of rare-earth metallacyclopentadienes. Unlike Y and Lu, La did not show the same reactivity toward PhCCPh. The characterization of the new metal complexes was accomplished by NMR spectroscopy, elemental analysis, and single-crystal X-ray diffraction.

Published
2017

10. Redox-Triggered Release of Moxifloxacin from Mesoporous Silica Nanoparticles Functionalized with Disulfide Snap-Tops Enhances Efficacy Against Pneumonic Tularemia in Mice.

Author

Lee, Bai-Yu, Lee, Bai-Yu, Li, Zilu, Clemens, Daniel L, Dillon, Barbara Jane, Hwang, Angela A, Zink, Jeffrey I, Horwitz, Marcus A, Lee, Bai-Yu, Lee, Bai-Yu, Li, Zilu, Clemens, Daniel L, Dillon, Barbara Jane, Hwang, Angela A, Zink, Jeffrey I, and Horwitz, Marcus A

Abstract

Effective and rapid treatment of tularemia is needed to reduce morbidity and mortality of this potentially fatal infectious disease. The etiologic agent, Francisella tularensis, is a facultative intracellular bacterial pathogen which infects and multiplies to high numbers in macrophages. Nanotherapeutics are particularly promising for treatment of infectious diseases caused by intracellular pathogens, whose primary host cells are macrophages, because nanoparticles preferentially target and are avidly internalized by macrophages. A mesoporous silica nanoparticle (MSN) has been developed functionalized with disulfide snap-tops that has high drug loading and selectively releases drug intracellularly in response to the redox potential. These nanoparticles, when loaded with Hoechst fluorescent dye, release their cargo exclusively intracellularly and stain the nuclei of macrophages. The MSNs loaded with moxifloxacin kill F. tularensis in macrophages in a dose-dependent fashion. In a mouse model of lethal pneumonic tularemia, MSNs loaded with moxifloxacin prevent weight loss, illness, and death, markedly reduce the burden of F. tularensis in the lung, liver, and spleen, and are significantly more efficacious than an equivalent amount of free drug. An important proof-of-principle for the potential therapeutic use of a novel nanoparticle drug delivery platform for the treatment of infectious diseases is provided.

Published
2016

11. Intracellular Delivery: Redox-Triggered Release of Moxifloxacin from Mesoporous Silica Nanoparticles Functionalized with Disulfide Snap-Tops Enhances Efficacy Against Pneumonic Tularemia in Mice (Small 27/2016).

Author

Lee, Bai-Yu, Lee, Bai-Yu, Li, Zilu, Clemens, Daniel L, Dillon, Barbara Jane, Hwang, Angela A, Zink, Jeffrey I, Horwitz, Marcus A, Lee, Bai-Yu, Lee, Bai-Yu, Li, Zilu, Clemens, Daniel L, Dillon, Barbara Jane, Hwang, Angela A, Zink, Jeffrey I, and Horwitz, Marcus A

Abstract

The drug trapping and intracellular release mechanism of redox-responsive disulfide snap-top mesoporous silica nanoparticles (MSN-SS-MXF) is depicted by J. I. Zink, M. A. Horwitz and co-workers on page 3690. Mesoporous silica nanoparticles with antibiotic (cyan) trapped within their pores by disulfide snap-tops are avidly ingested by macrophages. The intracellular redox potential reduces the disulfide (yellow) in the stalk (green/blue), releases the caps (orange) and frees drug to kill Francisella tularensis (green). Artwork by Bastian Ruehle.

Published
2016

12. Aerosol droplet delivery of mesoporous silica nanoparticles: A strategy for respiratory-based therapeutics.

Author

Li, Xueting, Li, Xueting, Xue, Min, Raabe, Otto G, Aaron, Holly L, Eisen, Ellen A, Evans, James E, Hayes, Fred A, Inaga, Sumire, Tagmount, Abderrahmane, Takeuchi, Minoru, Vulpe, Chris, Zink, Jeffrey I, Risbud, Subhash H, Pinkerton, Kent E, Li, Xueting, Li, Xueting, Xue, Min, Raabe, Otto G, Aaron, Holly L, Eisen, Ellen A, Evans, James E, Hayes, Fred A, Inaga, Sumire, Tagmount, Abderrahmane, Takeuchi, Minoru, Vulpe, Chris, Zink, Jeffrey I, Risbud, Subhash H, and Pinkerton, Kent E

Abstract

UnlabelledA highly versatile nanoplatform that couples mesoporous silica nanoparticles (MSNs) with an aerosol technology to achieve direct nanoscale delivery to the respiratory tract is described. This novel method can deposit MSN nanoparticles throughout the entire respiratory tract, including nasal, tracheobronchial and pulmonary regions using a water-based aerosol. This delivery method was successfully tested in mice by inhalation. The MSN nanoparticles used have the potential for carrying and delivering therapeutic agents to highly specific target sites of the respiratory tract. The approach provides a critical foundation for developing therapeutic treatment protocols for a wide range of diseases where aerosol delivery to the respiratory system would be desirable.From the clinical editorDelivery of drugs via the respiratory tract is an attractive route of administration. In this article, the authors described the design of mesoporous silica nanoparticles which could act as carriers for drugs. The underlying efficacy was successfully tested in a mouse model. This drug-carrier inhalation nanotechnology should potentially be useful in human clinical setting in the future.

Published
2015

14. Enhancing the imaging and biosafety of upconversion nanoparticles through phosphonate coating.

Author

Li, Ruibin, Li, Ruibin, Ji, Zhaoxia, Dong, Juyao, Chang, Chong Hyun, Wang, Xiang, Sun, Bingbing, Wang, Meiying, Liao, Yu-Pei, Zink, Jeffrey I, Nel, Andre E, Xia, Tian, Li, Ruibin, Li, Ruibin, Ji, Zhaoxia, Dong, Juyao, Chang, Chong Hyun, Wang, Xiang, Sun, Bingbing, Wang, Meiying, Liao, Yu-Pei, Zink, Jeffrey I, Nel, Andre E, and Xia, Tian

Abstract

Upconversion nanoparticles (UCNPs), which are generated by doping with rare earth (RE) metals, are increasingly used for bioimaging because of the advantages they hold over conventional fluorophores. However, because pristine RE nanoparticles (NPs) are unstable in acidic physiological fluids (e.g., lysosomes), leading to intracellular phosphate complexation with the possibility of lysosomal injury, it is important to ensure that UCNPs are safely designed. In this study, we used commercially available NaYF4:Er/Yb UCNPs to study their stability in lysosomes and simulated lysosomal fluid. We demonstrate that phosphate complexation leads to REPO4 deposition on the particle surfaces and morphological transformation. This leads to a decline in upconversion fluorescence efficiency as well as inducing pro-inflammatory effects at the cellular level and in the intact lung. In order to preserve the imaging properties of the UCNPs as well as improve their safety, we experimented with a series of phosphonate chemical moieties to passivate particle surfaces through the strong coordination of the organophosphates with RE atoms. Particle screening and physicochemical characterization revealed that ethylenediamine tetra(methylenephosphonic acid) (EDTMP) surface coating provides the most stable UCNPs, which maintain their imaging intensity and do not induce pro-inflammatory effects in vitro and in vivo. In summary, phosphonate coating presents a safer design method that preserves and improves the bioimaging properties of UCNPs, thereby enhancing their biological use.

Published
2015

15. pH-Responsive Isoniazid-Loaded Nanoparticles Markedly Improve Tuberculosis Treatment in Mice.

Author

Hwang, Angela A, Hwang, Angela A, Lee, Bai-Yu, Clemens, Daniel L, Dillon, Barbara Jane, Zink, Jeffrey I, Horwitz, Marcus A, Hwang, Angela A, Hwang, Angela A, Lee, Bai-Yu, Clemens, Daniel L, Dillon, Barbara Jane, Zink, Jeffrey I, and Horwitz, Marcus A

Abstract

Tuberculosis is a major global health problem for which improved therapeutics are needed to shorten the course of treatment and combat emergence of drug resistance. Mycobacterium tuberculosis, the etiologic agent of tuberculosis, is an intracellular pathogen of mononuclear phagocytes. As such, it is an ideal pathogen for nanotherapeutics because macrophages avidly ingest nanoparticles even without specific targeting molecules. Hence, a nanoparticle drug delivery system has the potential to target and deliver high concentrations of drug directly into M. tuberculosis-infected cells-greatly enhancing efficacy while avoiding off-target toxicities. Stimulus-responsive mesoporous silica nanoparticles of two different sizes, 100 and 50 nm, are developed as carriers for the major anti-tuberculosis drug isoniazid in a prodrug configuration. The drug is captured by the aldehyde-functionalized nanoparticle via hydrazone bond formation and coated with poly(ethylene imine)-poly(ethylene glycol) (PEI-PEG). The drug is released from the nanoparticles in response to acidic pH at levels that naturally occur within acidified endolysosomes. It is demonstrated that isoniazid-loaded PEI-PEG-coated nanoparticles are avidly ingested by M. tuberculosis-infected human macrophages and kill the intracellular bacteria in a dose-dependent manner. It is further demonstrated in a mouse model of pulmonary tuberculosis that the nanoparticles are well tolerated and much more efficacious than an equivalent amount of free drug.

Published
2015

16. Tuberculosis: pH-Responsive Isoniazid-Loaded Nanoparticles Markedly Improve Tuberculosis Treatment in Mice (Small 38/2015).

Author

Hwang, Angela A, Hwang, Angela A, Lee, Bai-Yu, Clemens, Daniel L, Dillon, Barbara Jane, Zink, Jeffrey I, Horwitz, Marcus A, Hwang, Angela A, Hwang, Angela A, Lee, Bai-Yu, Clemens, Daniel L, Dillon, Barbara Jane, Zink, Jeffrey I, and Horwitz, Marcus A

Abstract

On page 5066, J. I. Zink, M. A. Horwitz, and co-workers use confocal microscopy to demonstrate the avid uptake of RITC-labeled mesoporous silica nanoparticles loaded with the anti-tuberculosis drug isoniazid (shown here in red) by human macrophages (nuclei stained blue with DAPI) infected with GFP-expressing Mycobacterium tuberculosis (shown here in green).

Published
2015

17. Mesoporous Silica Nanoparticles with pH-Sensitive Nanovalves for Delivery of Moxifloxacin Provide Improved Treatment of Lethal Pneumonic Tularemia.

Author

Li, Zilu, Li, Zilu, Clemens, Daniel L, Lee, Bai-Yu, Dillon, Barbara Jane, Horwitz, Marcus A, Zink, Jeffrey I, Li, Zilu, Li, Zilu, Clemens, Daniel L, Lee, Bai-Yu, Dillon, Barbara Jane, Horwitz, Marcus A, and Zink, Jeffrey I

Abstract

We have optimized mesoporous silica nanoparticles (MSNs) functionalized with pH-sensitive nanovalves for the delivery of the broad spectrum fluoroquinolone moxifloxacin (MXF) and demonstrated its efficacy in treating Francisella tularensis infections both in vitro and in vivo. We compared two different nanovalve systems, positive and negative charge modifications of the mesopores, and different loading conditions-varying pH, cargo concentration, and duration of loading-and identified conditions that maximize both the uptake and release capacity of MXF by MSNs. We have demonstrated in macrophage cell culture that the MSN-MXF delivery platform is highly effective in killing F. tularensis in infected macrophages, and in a mouse model of lethal pneumonic tularemia, we have shown that the drug-loaded MSNs are much more effective in killing F. tularensis than an equivalent amount of free MXF.

Published
2015

18. Aerosol droplet delivery of mesoporous silica nanoparticles: A strategy for respiratory-based therapeutics.

Author

Li, Xueting, Li, Xueting, Xue, Min, Raabe, Otto G, Aaron, Holly L, Eisen, Ellen A, Evans, James E, Hayes, Fred A, Inaga, Sumire, Tagmount, Abderrahmane, Takeuchi, Minoru, Vulpe, Chris, Zink, Jeffrey I, Risbud, Subhash H, Pinkerton, Kent E, Li, Xueting, Li, Xueting, Xue, Min, Raabe, Otto G, Aaron, Holly L, Eisen, Ellen A, Evans, James E, Hayes, Fred A, Inaga, Sumire, Tagmount, Abderrahmane, Takeuchi, Minoru, Vulpe, Chris, Zink, Jeffrey I, Risbud, Subhash H, and Pinkerton, Kent E

Abstract

A highly versatile nanoplatform that couples mesoporous silica nanoparticles (MSNs) with an aerosol technology to achieve direct nanoscale delivery to the respiratory tract is described. This novel method can deposit MSN nanoparticles throughout the entire respiratory tract, including nasal, tracheobronchial and pulmonary regions using a water-based aerosol. This delivery method was successfully tested in mice by inhalation. The MSN nanoparticles used have the potential for carrying and delivering therapeutic agents to highly specific target sites of the respiratory tract. The approach provides a critical foundation for developing therapeutic treatment protocols for a wide range of diseases where aerosol delivery to the respiratory system would be desirable.From the clinical editorDelivery of drugs via the respiratory tract is an attractive route of administration. In this article, the authors described the design of mesoporous silica nanoparticles which could act as carriers for drugs. The underlying efficacy was successfully tested in a mouse model. This drug-carrier inhalation nanotechnology should potentially be useful in human clinical setting in the future.

Published
2015

19. Enhancing the imaging and biosafety of upconversion nanoparticles through phosphonate coating.

Author

Li, Ruibin, Li, Ruibin, Ji, Zhaoxia, Dong, Juyao, Chang, Chong Hyun, Wang, Xiang, Sun, Bingbing, Wang, Meiying, Liao, Yu-Pei, Zink, Jeffrey I, Nel, Andre E, Xia, Tian, Li, Ruibin, Li, Ruibin, Ji, Zhaoxia, Dong, Juyao, Chang, Chong Hyun, Wang, Xiang, Sun, Bingbing, Wang, Meiying, Liao, Yu-Pei, Zink, Jeffrey I, Nel, Andre E, and Xia, Tian

Abstract

Upconversion nanoparticles (UCNPs), which are generated by doping with rare earth (RE) metals, are increasingly used for bioimaging because of the advantages they hold over conventional fluorophores. However, because pristine RE nanoparticles (NPs) are unstable in acidic physiological fluids (e.g., lysosomes), leading to intracellular phosphate complexation with the possibility of lysosomal injury, it is important to ensure that UCNPs are safely designed. In this study, we used commercially available NaYF4:Er/Yb UCNPs to study their stability in lysosomes and simulated lysosomal fluid. We demonstrate that phosphate complexation leads to REPO4 deposition on the particle surfaces and morphological transformation. This leads to a decline in upconversion fluorescence efficiency as well as inducing pro-inflammatory effects at the cellular level and in the intact lung. In order to preserve the imaging properties of the UCNPs as well as improve their safety, we experimented with a series of phosphonate chemical moieties to passivate particle surfaces through the strong coordination of the organophosphates with RE atoms. Particle screening and physicochemical characterization revealed that ethylenediamine tetra(methylenephosphonic acid) (EDTMP) surface coating provides the most stable UCNPs, which maintain their imaging intensity and do not induce pro-inflammatory effects in vitro and in vivo. In summary, phosphonate coating presents a safer design method that preserves and improves the bioimaging properties of UCNPs, thereby enhancing their biological use.

Published
2015

21. Mesoporous silica nanoparticle delivery of chemically modified siRNA against TWIST1 leads to reduced tumor burden.

Author

Finlay, James, Finlay, James, Roberts, Cai M, Dong, Juyao, Zink, Jeffrey I, Tamanoi, Fuyuhiko, Glackin, Carlotta A, Finlay, James, Finlay, James, Roberts, Cai M, Dong, Juyao, Zink, Jeffrey I, Tamanoi, Fuyuhiko, and Glackin, Carlotta A

Abstract

Growth and progression of solid tumors depend on the integration of multiple pro-growth and survival signals, including the induction of angiogenesis. TWIST1 is a transcription factor whose reactivation in tumors leads to epithelial to mesenchymal transition (EMT), including increased cancer cell stemness, survival, and invasiveness. Additionally, TWIST1 drives angiogenesis via activation of IL-8 and CCL2, independent of VEGF signaling. In this work, results suggest that chemically modified siRNA against TWIST1 reverses EMT both in vitro and in vivo. siRNA delivery with a polyethyleneimine-coated mesoporous silica nanoparticle (MSN) led to reduction of TWIST1 target genes and migratory potential in vitro. In mice bearing xenograft tumors, weekly intravenous injections of the siRNA-nanoparticle complexes resulted in decreased tumor burden together with a loss of CCL2 suggesting a possible anti-angiogenic response. Therapeutic use of TWIST1 siRNA delivered via MSNs has the potential to inhibit tumor growth and progression in many solid tumor types.From the clinical editorTumor progression and metastasis eventually lead to patient mortality in the clinical setting. In other studies, it has been found that TWIST1, a transcription factor, if reactivated in tumors, would lead to downstream events including angiogenesis and result in poor prognosis in cancer patients. In this article, the authors were able to show that when siRNA against TWIST1 was delivered via mesoporous silica nanoparticle, there was tumor reduction in an in-vivo model. The results have opened up a new avenue for further research in this field.

Published
2015

22. Photo-redox activated drug delivery systems operating under two photon excitation in the near-IR.

Author

Guardado-Alvarez, Tania M, Guardado-Alvarez, Tania M, Devi, Lekshmi Sudha, Vabre, Jean-Marie, Pecorelli, Travis A, Schwartz, Benjamin J, Durand, Jean-Olivier, Mongin, Olivier, Blanchard-Desce, Mireille, Zink, Jeffrey I, Guardado-Alvarez, Tania M, Guardado-Alvarez, Tania M, Devi, Lekshmi Sudha, Vabre, Jean-Marie, Pecorelli, Travis A, Schwartz, Benjamin J, Durand, Jean-Olivier, Mongin, Olivier, Blanchard-Desce, Mireille, and Zink, Jeffrey I

Abstract

We report the design and synthesis of a nano-container consisting of mesoporous silica nanoparticles with the pore openings covered by "snap-top" caps that are opened by near-IR light. A photo transducer molecule that is a reducing agent in an excited electronic state is covalently attached to the system. Near IR two-photon excitation causes inter-molecular electron transfer that reduces a disulfide bond holding the cap in place, thus allowing the cargo molecules to escape. We describe the operation of the "snap-top" release mechanism by both one- and two-photon activation. This system presents a proof of concept of a near-IR photoredox-induced nanoparticle delivery system that may lead to a new type of photodynamic drug release therapy.

Published
2014

23. Probing the Microenvironment in the Confined Pores of Mesoporous Silica Nanoparticles.

Author

Xue, Min, Xue, Min, Zink, Jeffrey I, Xue, Min, Xue, Min, and Zink, Jeffrey I

Abstract

The microenvironment inside of the pores of mesoporous silica nanoparticles is probed using spectroscopic techniques. The probe molecules are sealed inside of the pores by a nanovalve system that is capable of controlling the access to the pore and ensuring the exclusive probing of the pore environment without any interference from the probe molecules on the outer surface of the particles or from the surrounding solution. Rigidochromism studies are used to evaluate the rigidity of the solvent matrix inside of the pore, and dynamic fluorescence anisotropy experiments are employed to determine the rotational diffusion freedom of the probe molecule. The data show that those probe molecules are neither completely free to move nor tightly attached to the pore wall, and their mobility is changed by altering the charge of the pore wall.

Published
2014

24. Probing the Microenvironment in the Confined Pores of Mesoporous Silica Nanoparticles.

Author

Xue, Min, Xue, Min, Zink, Jeffrey I, Xue, Min, Xue, Min, and Zink, Jeffrey I

Abstract

The microenvironment inside of the pores of mesoporous silica nanoparticles is probed using spectroscopic techniques. The probe molecules are sealed inside of the pores by a nanovalve system that is capable of controlling the access to the pore and ensuring the exclusive probing of the pore environment without any interference from the probe molecules on the outer surface of the particles or from the surrounding solution. Rigidochromism studies are used to evaluate the rigidity of the solvent matrix inside of the pore, and dynamic fluorescence anisotropy experiments are employed to determine the rotational diffusion freedom of the probe molecule. The data show that those probe molecules are neither completely free to move nor tightly attached to the pore wall, and their mobility is changed by altering the charge of the pore wall.

Published
2014

25. Photo-redox activated drug delivery systems operating under two photon excitation in the near-IR.

Author

Guardado-Alvarez, Tania M, Guardado-Alvarez, Tania M, Devi, Lekshmi Sudha, Vabre, Jean-Marie, Pecorelli, Travis A, Schwartz, Benjamin J, Durand, Jean-Olivier, Mongin, Olivier, Blanchard-Desce, Mireille, Zink, Jeffrey I, Guardado-Alvarez, Tania M, Guardado-Alvarez, Tania M, Devi, Lekshmi Sudha, Vabre, Jean-Marie, Pecorelli, Travis A, Schwartz, Benjamin J, Durand, Jean-Olivier, Mongin, Olivier, Blanchard-Desce, Mireille, and Zink, Jeffrey I

Abstract

We report the design and synthesis of a nano-container consisting of mesoporous silica nanoparticles with the pore openings covered by "snap-top" caps that are opened by near-IR light. A photo transducer molecule that is a reducing agent in an excited electronic state is covalently attached to the system. Near IR two-photon excitation causes inter-molecular electron transfer that reduces a disulfide bond holding the cap in place, thus allowing the cargo molecules to escape. We describe the operation of the "snap-top" release mechanism by both one- and two-photon activation. This system presents a proof of concept of a near-IR photoredox-induced nanoparticle delivery system that may lead to a new type of photodynamic drug release therapy.

Published
2014

26. Use of coated silver nanoparticles to understand the relationship of particle dissolution and bioavailability to cell and lung toxicological potential.

Author

Wang, Xiang, Wang, Xiang, Ji, Zhaoxia, Chang, Chong Hyun, Zhang, Haiyuan, Wang, Meiying, Liao, Yu-Pei, Lin, Sijie, Meng, Huan, Li, Ruibin, Sun, Bingbing, Winkle, Laura Van, Pinkerton, Kent E, Zink, Jeffrey I, Xia, Tian, Nel, André E, Wang, Xiang, Wang, Xiang, Ji, Zhaoxia, Chang, Chong Hyun, Zhang, Haiyuan, Wang, Meiying, Liao, Yu-Pei, Lin, Sijie, Meng, Huan, Li, Ruibin, Sun, Bingbing, Winkle, Laura Van, Pinkerton, Kent E, Zink, Jeffrey I, Xia, Tian, and Nel, André E

Abstract

Since more than 30% of consumer products that include engineered nanomaterials contain nano-Ag, the safety of this material is of considerable public concern. In this study, Ag nanoparticles (NPs) are used to demonstrate that 20 nm polyvinylpyrrolidone (PVP or P) and citrate (C)-coated Ag NPs induce more cellular toxicity and oxidative stress than larger (110 nm) particles due to a higher rate of dissolution and Ag bioavailability. Moreover, there is also a higher propensity for citrate 20 nm (C20) nanoparticles to generate acute neutrophilic inflammation in the lung and to produce chemokines compared to C110. P110 has less cytotoxic effects than C110, likely due to the ability of PVP to complex released Ag(+) . In contrast to the more intense acute pulmonary effects of C20, C110 induces mild pulmonary fibrosis at day 21, likely as a result of slow but persistent Ag(+) release leading to a sub-chronic injury response. Interestingly, the released metallic Ag is incorporated into the collagen fibers depositing around airways and the lung interstitium. Taken together, these results demonstrate that size and surface coating affect the cellular toxicity of Ag NPs as well as their acute versus sub-chronic lung injury potential.

Published
2014

27. Functioning of nanovalves on polymer coated mesoporous silica Nanoparticles.

Author

Dong, Juyao, Dong, Juyao, Xue, Min, Zink, Jeffrey I, Dong, Juyao, Dong, Juyao, Xue, Min, and Zink, Jeffrey I

Abstract

Nanomachines activated by a pH change can be combined with polymer coatings on mesoporous silica nanoparticles to produce a new generation of nanoparticles for drug delivery that exhibits properties of both components. The nanovalves can trap cargos inside the mesoporous silica nanoparticles without premature release and only respond to specific stimuli, resulting in a high local concentration of drugs at the site of release. The polymer surface coatings can increase the cellular uptake, avoid the reticuloendothelial uptake, provide protected space for storing siRNA, and enhance the biodistribution of nanoparticles. Two nanovalve-polymer systems are designed and their successful assembly is confirmed by solid state NMR and thermogravimetric analysis. The fluorescence spectroscopy results demonstrate that the controlled release functions of the nanomachines in both of the systems are not hindered by the polymer surface coatings. These new multifunctional nanoparticles combining stimulated molecule release together with the functionality provided by the polymers produce enhanced biological properties and multi-task drug delivery applications.

Published
2013

28. An enzymatic chemical amplifier based on mechanized nanoparticles.

Author

Xue, Min, Xue, Min, Zink, Jeffrey I, Xue, Min, Xue, Min, and Zink, Jeffrey I

Abstract

A chemical amplifier was constructed based on enzyme-encapsulated mesoporous silica nanoparticles. By employing a supramolecular nanogate assembly that is capable of controlling the access to the encapsulated enzyme, selectivity toward substrate sizes is enabled. When an analyte molecule actuates the mechanical nanogate and exposes the enzymes, a catalytic production of fluorescent molecules is initiated. This study demonstrates a new concept of self-amplification of a chemical sensing process and can potentially increase the detection sensitivity.

Published
2013

29. Cerium dioxide nanoparticles do not modulate the lipopolysaccharide-induced inflammatory response in human monocytes

Author

Hussain,Salik, Al-Nsour,Faris, Rice,Annette B, Marshburn,Jamie, Ji,Zhaoxia, Zink,Jeffrey I, Yingling,Brenda, Walker,Nigel J, Garantziotis,Stavros, Hussain,Salik, Al-Nsour,Faris, Rice,Annette B, Marshburn,Jamie, Ji,Zhaoxia, Zink,Jeffrey I, Yingling,Brenda, Walker,Nigel J, and Garantziotis,Stavros

Abstract

Salik Hussain1,*, Faris Al-Nsour1,*, Annette B Rice1, Jamie Marshburn1, Zhaoxia Ji2, Jeffery I Zink2, Brenda Yingling1, Nigel J Walker3, Stavros Garantziotis11Clinical Research Unit, National Institute of Environmental Health Sciences/National Institute of Health, Research Triangle Park, NC, 2UC Center for Environmental Implications of Nanotechnology University of California, Los Angeles, CA, 3Division of National Toxicology Program, National Institute of Environmental Health Sciences/National Institute of Health, Research Triangle Park, NC, USA*Both are principal authorsBackground: Cerium dioxide (CeO2) nanoparticles have potential therapeutic applications and are widely used for industrial purposes. However, the effects of these nanoparticles on primary human cells are largely unknown. The ability of nanoparticles to exacerbate pre-existing inflammatory disorders is not well documented for engineered nanoparticles, and is certainly lacking for CeO2 nanoparticles. We investigated the inflammation-modulating effects of CeO2 nanoparticles at noncytotoxic concentrations in human peripheral blood monocytes.Methods: CD14+ cells were isolated from peripheral blood samples of human volunteers. Cells were exposed to either 0.5 or 1 µg/mL of CeO2 nanoparticles over a period of 24 or 48 hours with or without lipopolysaccharide (10 ng/mL) prestimulation. Modulation of the inflammatory response was studied by measuring secreted tumor necrosis factor-alpha, interleukin-1beta, macrophage chemotactic protein-1, interferon-gamma, and interferon gamma-induced protein 10.Results: CeO2 nanoparticle suspensions were thoroughly characterized using dynamic light scattering analysis (194 nm hydrodynamic diameter), zeta potential analysis (-14 mV), and transmission electron microscopy (irregular-shaped particles). Transmission electron microscopy of CD14+ cells exposed to CeO2 nanoparticles revealed that these nanoparticles were efficiently internalized by monocytes and were fou

Published
2012

30. Targeted intracellular delivery of antituberculosis drugs to Mycobacterium tuberculosis-infected macrophages via functionalized mesoporous silica nanoparticles.

Author

Clemens, Daniel L, Clemens, Daniel L, Lee, Bai-Yu, Xue, Min, Thomas, Courtney R, Meng, Huan, Ferris, Daniel, Nel, Andre E, Zink, Jeffrey I, Horwitz, Marcus A, Clemens, Daniel L, Clemens, Daniel L, Lee, Bai-Yu, Xue, Min, Thomas, Courtney R, Meng, Huan, Ferris, Daniel, Nel, Andre E, Zink, Jeffrey I, and Horwitz, Marcus A

Abstract

Delivery of antituberculosis drugs by nanoparticles offers potential advantages over free drug, including the potential to target specifically the tissues and cells that are infected by Mycobacterium tuberculosis, thereby simultaneously increasing therapeutic efficacy and decreasing systemic toxicity, and the capacity for prolonged release of drug, thereby allowing less-frequent dosing. We have employed mesoporous silica nanoparticle (MSNP) drug delivery systems either equipped with a polyethyleneimine (PEI) coating to release rifampin or equipped with cyclodextrin-based pH-operated valves that open only at acidic pH to release isoniazid (INH) into M. tuberculosis-infected macrophages. The MSNP are internalized efficiently by human macrophages, traffic to acidified endosomes, and release high concentrations of antituberculosis drugs intracellularly. PEI-coated MSNP show much greater loading of rifampin than uncoated MSNP and much greater efficacy against M. tuberculosis-infected macrophages. MSNP were devoid of cytotoxicity at the particle doses employed for drug delivery. Similarly, we have demonstrated that the isoniazid delivered by MSNP equipped with pH-operated nanovalves kill M. tuberculosis within macrophages significantly more effectively than an equivalent amount of free drug. These data demonstrate that MSNP provide a versatile platform that can be functionalized to optimize the loading and intracellular release of specific drugs for the treatment of tuberculosis.

Published
2012

31. Cerium dioxide nanoparticles do not modulate the lipopolysaccharide-induced inflammatory response in human monocytes

Author

Hussain,Salik, Al-Nsour,Faris, Rice,Annette B, Marshburn,Jamie, Ji,Zhaoxia, Zink,Jeffrey I, Yingling,Brenda, Walker,Nigel J, Garantziotis,Stavros, Hussain,Salik, Al-Nsour,Faris, Rice,Annette B, Marshburn,Jamie, Ji,Zhaoxia, Zink,Jeffrey I, Yingling,Brenda, Walker,Nigel J, and Garantziotis,Stavros

Abstract

Salik Hussain1,*, Faris Al-Nsour1,*, Annette B Rice1, Jamie Marshburn1, Zhaoxia Ji2, Jeffery I Zink2, Brenda Yingling1, Nigel J Walker3, Stavros Garantziotis11Clinical Research Unit, National Institute of Environmental Health Sciences/National Institute of Health, Research Triangle Park, NC, 2UC Center for Environmental Implications of Nanotechnology University of California, Los Angeles, CA, 3Division of National Toxicology Program, National Institute of Environmental Health Sciences/National Institute of Health, Research Triangle Park, NC, USA*Both are principal authorsBackground: Cerium dioxide (CeO2) nanoparticles have potential therapeutic applications and are widely used for industrial purposes. However, the effects of these nanoparticles on primary human cells are largely unknown. The ability of nanoparticles to exacerbate pre-existing inflammatory disorders is not well documented for engineered nanoparticles, and is certainly lacking for CeO2 nanoparticles. We investigated the inflammation-modulating effects of CeO2 nanoparticles at noncytotoxic concentrations in human peripheral blood monocytes.Methods: CD14+ cells were isolated from peripheral blood samples of human volunteers. Cells were exposed to either 0.5 or 1 µg/mL of CeO2 nanoparticles over a period of 24 or 48 hours with or without lipopolysaccharide (10 ng/mL) prestimulation. Modulation of the inflammatory response was studied by measuring secreted tumor necrosis factor-alpha, interleukin-1beta, macrophage chemotactic protein-1, interferon-gamma, and interferon gamma-induced protein 10.Results: CeO2 nanoparticle suspensions were thoroughly characterized using dynamic light scattering analysis (194 nm hydrodynamic diameter), zeta potential analysis (-14 mV), and transmission electron microscopy (irregular-shaped particles). Transmission electron microscopy of CD14+ cells exposed to CeO2 nanoparticles revealed that these nanoparticles were efficiently internalized by monocytes and were fou

Published
2012

32. Photochemical Enzyme Co-Factor Regeneration: Towards Continuous Glutamate Monitoring with a Sol-Gel Optical Biosensor

Author

CALIFORNIA UNIV LOS ANGELES DEPT OF MATERIALS SCIENCE AND ENGINEERING, Rickus, Jenna L., Tobin, Allan J., Zink, Jeffrey I., Dunn, Bruce, CALIFORNIA UNIV LOS ANGELES DEPT OF MATERIALS SCIENCE AND ENGINEERING, Rickus, Jenna L., Tobin, Allan J., Zink, Jeffrey I., and Dunn, Bruce

Abstract

Sol-gel encapsulation has recently surfaced as a successful approach to biomolecule immobilization. Proteins, including enzymes, are trapped in the pores of the sol-gel derived glass while retaining their spectroscopic properties and biological activity. Our current work extends the unique capabilities of biomolecule-doped sol-gel materials to the detection of glutamate, the major excitatory neurotransmitter in the central nervous system. We are developing an in vivo fiber optic biosensor for glutamate along with methods to achieve continuous monitoring. In our research to date we have encapsulated GDH in a silica sol-gel film on the tip of an optical fiber. GDH catalyzes the oxidative deamination of glutamate to alpha ketoglutarate and the simultaneous reduction of NAD+ to NADH. To quantify the glutamate concentration, we observe the rate of change of NADH fluorescence as a function of time. An important consideration for continuous in vivo monitoring is the incorporation of a self- sustaining NAD+ source. We have adopted a photochemical means of regenerating NAD+ from NADH, by irradiating thionine (3,7-diaminophenothiazin-5-ium) which we incorporate into the sol-gel sensor material. When excited with visible light (lamba sub abs)^ 596 nm), thionine undergoes a reaction with NADH resulting in a non-fluorescent form of thionine and NAD+. We have characterized the kinetics of this reaction in the sol-gel matrix, and have shown that the reaction results in regenerated co-factor that is usable by GDH for the oxidation of glutamate., This article is from the Mat. Res. Soc. Symp. Proc. Vol. 723, (pages), 2002. Prepared in cooperation with the Univ. of California at Irvine; Portland State Univ., Oregon; Texas A and M Univ., College Station, Texas; Univ. of California at San Diego, La Jolla, California, p155-160. This article is from ADA412559 Materials Research Society Symposium Proceedings. Volume 723. Molecularly Imprinted Materials - Sensors and Other Devices. Symposia Held in San Francisco, California on April 2-5, 2002

Published
2002

33. Chemical and Electrochemical Reactions in Porous Sol-Gel Materials.

Author

CALIFORNIA UNIV LOS ANGELES DEPT OF MATERIALS SCIENCE AND ENGINEERING, Dave, Bakul C., Dunn, Bruce, Zink, Jeffrey I., CALIFORNIA UNIV LOS ANGELES DEPT OF MATERIALS SCIENCE AND ENGINEERING, Dave, Bakul C., Dunn, Bruce, and Zink, Jeffrey I.

Abstract

Sol-gel synthesis approaches have enabled researchers to design composite-type materials where dopant molecules which carry out various types of chemical reactions are trapped in the nanopores of the host material. Dopant molecules have been shown to undergo chemical, photochemical and electrochemical reactions in the pores of sol-gel matrices with specific examples including complexation reactions, redox reactions, catalysis, protonation-deprotonation, isomerization and ion/electron transfer. The interconnected pore network of the xerogel or aged gel structure ensures that the molecules are responsive to the outside environment, yet the molecules are also trapped within the inorganic matrix which confines molecular motion and prevents their being leached from the matrix. jg p.1

Published
1995

34. Triboluminescence Spectroscopy of Aromatic Compounds

Author

CALIFORNIA UNIV SANTA BARBARA DEPT OF CHEMISTRY, Hardy,Gordon E., Baldwin,James C., Zink,Jeffrey I., Kaska,William C., Liu,Po-Hsin, CALIFORNIA UNIV SANTA BARBARA DEPT OF CHEMISTRY, Hardy,Gordon E., Baldwin,James C., Zink,Jeffrey I., Kaska,William C., and Liu,Po-Hsin

Published
1976

35. Triboluminescence

Author

CALIFORNIA UNIV LOS ANGELES, Kaska, William C, Zink, Jeffrey I, CALIFORNIA UNIV LOS ANGELES, Kaska, William C, and Zink, Jeffrey I

Abstract

Triboluminescence is the emission of light caused by the application of mechanical energy to solids. Although the phenomenon has been known since the 17th century, neither the excited state origins of the luminescence nor the mechanism by which it is excited were understood until recently. Our efforts have focussed on the fundamental requirements for triboluminescence. We have uncovered and studied the fracture requirement, the pressure requirement, and the structure requirement for triboluminescence activity. We have also derived a quantitative theory for the dynamics of triboluminescence based on the dynamics of the creation and interaction of mobile fractures in a crystal. In addition to explaining the time dependence of the luminescence, the theory treats the effects of size ad impact velocity on the luminescence intensity. The instrument--which was designed to measure these effects--also enabled us to quantitively compare the relative intensities of various crystals. We have continued to study triboluminescence spectroscopy. High pressure spectroscopy has played an important role in investigating the pressure requirements for triboluminescence. Finally, the synthesis and chemistry of triboluminescent materials, which have continued to be a cornerstone in the above investigations, led to the discovery of the polymorphic hexaphenylcarbodiphosphorane crystals and to other interesting materials which are described., Personally Identifiable Information (PII) was redacted.

Published
1980

36. Pulsed Infrared Laser Induced Visible Luminescence.

Author

UNIVERSITY OF SOUTHERN CALIFORNIA LOS ANGELES DEPT OF CHEMISTRY, Hardy,G E, Chandra,A P, Zink,Jeffrey I, Adamson,Arthur W, Fukuda,R, UNIVERSITY OF SOUTHERN CALIFORNIA LOS ANGELES DEPT OF CHEMISTRY, Hardy,G E, Chandra,A P, Zink,Jeffrey I, Adamson,Arthur W, and Fukuda,R

Abstract

Crystals of saccharin doped with p-toluenesulfonamide, courmarin, NaCl, and KCl are found to emit in the visible, following a 20 nsec pulse of high intensity 1060 nm radiation. The pulses were 0.5 to 4 J/sq.cm. in energy, corresponding to up to 200 MW peak power. The emissions in the first two cases are from molecular excited states, but with differences in detail from those induced by photoexcitation or found in triboluminescence. NaCl and KCl show neither photoemission or relevant triboluminescence, and the laser induced emission is essentially that found thermally or by mechanically stressing x- or gamma-ray irradiated crystals. It is attributed to electron-hole recombination. The mechanism of the laser induced emission may thus involve some combination of mechanical shock wave and of plasma ionization. The trivial explanations of photoexcitation by higher harmonics of the 1060 nm fundamental or through successive multiple photon processes can be ruled out. (Author)

Published
1979

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