Global ETD Search

1	Infra-red laser applications in the reproductive sciences : improving safety for assisted reproductive technology and developing novel research tools Davidson, Lien M. January 2017 (has links) Assisted reproductive technology (ART) has been rapidly expanding since the birth of Louise Brown, the first test tube baby, in 1978. Although an increasingly complex array of laboratory skills and procedures have been developed for infertility treatments, the success rate of ART remains low. In an attempt to make ART safer and more efficient, international medical practice is trending towards single embryo transfers and the use of innovative, sophisticated technologies to identify promising gametes and embryos with the highest potential to generate a pregnancy. Laser technology is increasingly being used to accomplish these aims. The application of lasers for ART has been successfully employed in clinical practice for some time now and is continually the subject of investigative research in order to generate new methods to improve operations. Moreover, lasers serve as a powerful tool at the forefront of investigative research in the reproductive sciences, assisting in broadening our understanding of reproductive and developmental biology. Nevertheless, there is a paucity of literature pertaining to the safe standardisation of such laser procedures with evidence at the molecular level. The primary aim of this thesis was to optimise applications of laser technology for clinical ART and research applications in the reproductive sciences. This thesis utilised the mouse embryo model to investigate potential deleterious effects of different laser treatment applications, both by the operator and hardware manufacturer. Safe and unsafe laser operator parameters were elucidated by assessing deleterious effects to the plasma membrane integrity, blastocyst survival rate, DNA fragmentation levels, and changes in gene expression of key developmental genes. The effect of altering the laser hardware to lower the power output was evaluated and it was determined that if a lower power laser is used to deliver a set amount of energy over a longer period of time, a smaller amount of damage is incurred. Work in this thesis also established a new method in which laser technology can be used as a research tool for the reproductive sciences, by creating a novel stimuli-responsive laser-activated nanoparticle delivery system with spatial control and increased efficiency in a mammalian cell model. The field of reproductive science continues to benefit greatly from laser application clinically to improve infertility treatments, and in research, to elucidate mechanisms underlying infertility, with a hope of increasing our understanding and eventually developing new treatment options.
2	Molecular dynamics simulation of penetrant transport in composite poly (4-methyl-2-pentyne) and nanoparticles of different types Yang, Quan 10 December 2013 (has links) Membranes made of composite polymer material are widely employed to separate gas mixtures in industrial processes. These membranes have better performance than membranes consisting of polymer alone. To understand the mechanism and therefore aid membrane design it is essential to explore the penetrant transport in the complex composites from the molecular level, but few researchers have done such research to our knowledge. Herein the penetrant transport in the composite Poly (4-methyl-2-pentyne) (PMP) and silica nanoparticle is being explored with molecular dynamics (MD) simulations. The structure of the PMP and amorphous silica nanoparticle composite was modeled and with the structure the variation of the cavity size distribution was established due to the existence of nanoparticles. The diffusivity of different penetrants, including H2, O2, Ar, CH4 and n-C4H10 was determined through least square fit of the data of mean square displacement at different times in the Fickian diffusive regime. The solubility coefficients and the permeability of different penetrants in PMP and the composite were calculated and the distribution of potential difference due to the penetrant insertion was analyzed in detail to find the reason of higher solubility in composite than pure PMP. Silica has different crystalline form. In faujasite silica, there are pores that are large enough to allow penetrants to pass through, while in cristobalite silica, the Si and O atoms are densely packed and there are no pores that penetrants can pass through. The transport properties of penetrants in the composite of PMP and nanoparticles of these two types of silica are therefore different. The molecular dynamics method was employed in the research to explore the transport of different penetrants in the composites of PMP and nanoparticles of two forms of silica, namely the cristobalite form and the faujasite form. The structures of the PMP and nanoparticle of cristobalite silica composite (PMPC) and the PMP and nanoparticle of faujasite silica composite (PMPF) were established and relaxed. With the relaxed structure, the cavity size change due to the insertion of both types of nanoparticle was analyzed. The diffusivity of different penetrants was determined through least square fit of the data of mean square displacement at different time in Fickian diffusive regime. The solubility coefficients and the permeability of different penetrants in PMPC and PMPF were calculated and compared. The parameters of "Ti" in the Lennard-Jones potential equation were estimated; MD simulation of penetrants transport in composite poly (4-methyl-2-pentyne) and TiO2 nanoparticles were done; the simulation results were compared with composite poly (4-methyl-2-pentyne) and silica nanoparticles. / Ph. D. Molecular dynamics simulation PMP and silica nanoparticle composite cristobalite silica faujasite silica
3	Binary Planet–Satellite Nanostructure Using RAFT Polymer Peng, Wentao 05 June 2020 (has links) No description available. 540 Nanopatterning RAFT polymer Gold nanoparticle Silica nanoparticle Magnetite nanoparticle Silver nanoparticle Chemie (PPN62138352X)
4	Influence of PEG Conformation on Efficacy of Silica Nanoparticle Immunotherapy for Metastatic Tumors Becicka, Wyatt Morgan January 2020 (has links) No description available. Biomedical Engineering Cancer immunotherapy mesoporous silica nanoparticle systemic drug delivery STING agonist PEG
5	Estudo da cinética da tirosinase imobilizada em nanopartícula de sílica com obtenção de revestimento de eumelanina / Study of the kinetics of tyrosinase immobilized in nanoparticle silica wiht obtention of eumelanin coating Miranda, Andre José Cardoso de 22 December 2015 (has links) Melanina é um polímero constituído por uma grande heterogeneidade de monômeros tendo como característica comum a presença de grupos indóis. Por outro lado, a eumelanina produzida pela oxidação enzimática da tirosina é um polímero mais simples constituído principalmente de monômeros 5,6-dihidroxindol (DHI) e de indol-5,6-quinona (IQ). Tirosinase é a enzima chave na produção de melanina, sendo que a sua atividade cinética é medida em função da formação do intermediário dopacroma. Nanopartículas (NPs) de sílica são partículas nanométricas compostas de oxido de silício e são obtidas pelo processo sol-gel desenvolvido por Stöber de hidrólise e condensação de tetraetilortosilicato (TEOS), usando etanol como solvente em meio alcalino. As NPs foram funcionalizadas com 3-Aminopropiltrietoxissilano (ATPES) e depois com glutaraldeído. Este último permitiu a imobilização da tirosinase na superfície da sílica. Caracterizamos as NPs antes e após a reação da enzima, a atividade catalítica da enzima ligada à NP e o mecanismos de formação de melanina na superfície da sílica. As NPs foram caracterizadas por espectrofotometria de absorção e de reflectância, termogravimetria e microscopia eletrônica. A síntese da NP de sílica retornou partículas esféricas com 55nm de diâmetro e a funcionalização da partícula mostrou modificar eficientemente a sua superfície. A imobilização da tirosinase por ligação covalente foi de 99,5% contra 0,5% da adsorção física. A atividade da tirosinase foi caracterizada pela formação de dopacroma. O Km da enzima imobilizada não sofreu alteração em comparação com a tirosinase livre, mas a eficiência catalítica - que considera a eficiência recuperada - foi de apenas 1/3 para a enzima ligada covalentemente, significando que 2/3 das enzimas ligadas não estão ativas. Obtivemos NPs revestidas com melanina a partir de oxidação de tirosina solubilizada em duas preparações: NP com tirosinase ligada covalentemente na superfície e NP funcionalizada com glutaraldeido dispersa em solução de DHI e IQ. O revestimento de melanina foi na forma de um filme fino com espessura ~1,9nm, conferindo perfil de absorção luminosa equivalente ao da própria melanina. Mostramos que o mecanismo de polimerização passa pela oxidação da tirosina pela tirosinase, que gera intermediários oxidados (principalmente DHI e IQ) que vão para solução (mesmo quando a tirosinase está ligada covalentemente na sílica). Estes intermediários ligam-se ao glutaraldeido e a superfície da sílica passa a funcionar como ambiente de polimerização da melanina. / Melanin is a polymer consisting of a large heterogeneity of monomers having as a common feature the presence of indole groups. Contrarily, eumelanin produced by enzymatic oxidation of tyrosine is a simpler polymer consisting mainly of 5,6-dihidroxindol (DHI) and indole-5,6-quinone (IQ) monomers. Tyrosinase is the key enzyme in melanin production, and its kinetic activity is measured by the formation of the intermediate dopacroma. Nanoparticles (NPs) are made of silica nanoparticles of silicon oxide and are obtained by sol-gel method developed by Stöber of hydrolysis and condensation of tetraethylorthosilicate (TEOS), using ethanol as solvent in an alkaline medium. NPs were functionalized with 3-Aminopropyltriethoxysilane (ATPES) and then with glutaraldehyde. The latter allows the immobilization of tyrosinase on the silica surface. We characterized NPs before and after the reaction of the enzyme, the catalytic activity of the enzyme bound to the NP and melanin-forming mechanisms on the silica surface. NPs were characterized by absorption spectrophotometry and reflectance, electron microscopy and thermogravimetric analysis. The synthesis of silica NP returned spherical particles of 55nm diameter and particle functionalization showed efficiently modify its surface. The immobilization of tyrosinase by covalent bond was 99.5% versus 0.5% by physical adsorption. The activity of tyrosinase was characterized by the formation of dopacroma. The Km of the immobilized enzyme did not change compared to the free tyrosinase, but the catalytic efficiency - considering the recovered efficiently - was only 1/3 for the enzyme covalently bound, meaning that 2/3 of the enzymes are not connected active. We obtained melanin coated NPs from tyrosine oxidation in two preparations: NP with covalently bound tyrosinase in the NP surface and NP functionalized with glutaraldehyde dispersed in DHI and IQ solution. The melanin coating was in the form of a thin film with the thickness of ~ 1,9 nm, giving light absorption profile equivalent to that of melanin itself. We showed that the polymerization mechanism involves the oxidation of tyrosine by tyrosinase, which generates oxidized intermediates (especially DHI and lQ) that go into solution (even when tyrosinase is covalently bound to the silica). These intermediates bind the glutaraldehyde and the surface of the silica begins to function as an environment for melanin polymerization. Atividade enzimática Coating nanomaterial Enzyme activity Enzyme immobilization Imobilização de enzimas Melanin Melanina Nanopartícula de sílica Revestimento de nanomaterial Silica nanoparticle Tirosinase Tyrosinase
6	Synthesis, Functionalization and Characterization of Ultrasmall Hybrid Silica Nanoparticles for Theranostic Applications / Synthèse, Fonctionnalisation et Caractérisation des Nanoparticules Hybrides à base de Silices pour des Applications Théranostiques Tran, Vu Long 22 February 2018 (has links) Les nanoparticules (NPs) hybrides peuvent combiner les propriétés physiques uniques des éléments inorganiques pour des applications en imagerie et en thérapeutique avec la biocompatibilité des structures organiques. Cependant, leur utilisation en médecine est encore limitée par des risques potentiels de toxicité à long terme. Dans ce contexte, des NPs hybrides ultrafines pouvant être éliminées rapidement par la voie rénale apparaissent comme de bonnes candidates pour la nanomédicine. La NP à base de silice contenant des chélates du gadolinium appelée AGuIX (Activation et Guidage de l’Irradiation par rayon-X) a été développée avec un diamètre hydrodynamique de moins de 5 nm qui lui permet d’être éliminée rapidement via l’urine après injection intraveineuse. Cette NP s’est révélée être une sonde efficace en imagerie multimodale et un amplificateur local en radiothérapie pour le diagnostic et le traitement du cancer. Elle est en train d’être évaluée dans un essai clinique de phase I par radiothérapie des métastases cérébrales (NANO-RAD, NCT02820454). Néanmoins, la synthèse d’AGuIX est un procédé multi-étapes qui est difficilement modulable.Ce manuscrit rapporte, pour la première fois, le développement d’un protocole « one-pot » direct pour des nanoparticules de silice ultrafines (USNP) contenant des chélateurs complexés ou non à partir des précurseurs silanes chélatants moléculaires. Dans ce nouveau protocole, la taille des particules et les types des métaux chélatés peuvent être contrôlés facilement. Certaines des propriétés chimiques des USNP ont été clarifiées davantage pendant ce travail exploratoire. Les particules élaborées ont été caractérisées par différentes techniques analytiques complémentaires. Ces nouvelles nanoparticules USNPs présentent des caractéristiques similaires aux AGuIX en terms de propriétes biologiques et de biodistribution.Dans un second temps, un nouveau protocole de fonctionnalisation d’USNP par des précurseurs silanes chélatants a été développé. Ces chélatants libres fonctionnalisés sur la particule peuvent être alors utilisés afin de complexer des radiométaux pour l’imagerie bimodale. Enfin, d’autres stratégies de fonctionnalisation sont aussi décrites. La nouvelle sonde (17VTh031) combinant un petit chélateur cyclique (NODA) et un fluorophore proche-infrarouge tumeur ciblant (IR783) ainsi que le pyridinium quaternaire ont été greffés sur l’AGuIX pour créer une nouvelle sonde en imagerie multimodale et cibler des tumeurs chondrosarcomes respectivement / Hybrid nanoparticles (NPs) can combine unique physical properties for imaging and therapeutic applications of inorganic elements in bio-friendly organic structures. However, their uses in medicine are limited by the potential risks of long-term toxicities. In this context, ultrasmall renal clearable NPs appear as novel solutions. Silica based NP displaying gadolinium chelates named AGuIX (Activation and Guidance for Irradiation by X-ray) has been developed to have hydrodynamic diameter less than 5 nm which allows rapid elimination through urine after intravenous injection. This NP has been demonstrated as an efficient multimodal imaging probe and a local enhancer for radiotherapy for cancer diagnostics and treatment. It is now being evaluated in a phase I clinical trial by radiotherapy of cerebral metastases (NANO-RAD NCT02820454). Nevertheless, the synthesis of AGuIX implies a multisteps process that can be further improved.This manuscript shows, for the first time, the development of a straightforward one-pot protocol for ultrasmall silica nanoparticles (USNP) containing complexed or non-complexed chelators from molecular chelating silane precursors. In this new protocol, the size of particle and types of metals can be easily tuned. The chemical properties of USNP have been further clarified during this exploratory work. The produced particles have been characterized by different complimentary analytical techniques. These new nanoparticles USNPs show similar characteristics to AGuIX in terms of biological properties and biodistribution.Secondly, a new protocol of functionalization for USNP by chelating silane precursors has been developed. These functionalized free chelators on the particle can be used then to complex radiometals for bimodal imaging applications. Finally, other functionalization strategies have also been described. New probe (17VTh031) combining small cyclic chelator (NODA) and tumor targeting near-infrared fluorophore (IR783) as well as quaternary pyridinium have been grafted on AGuIX for creating new multimodal imaging probe and targeting chondrosarcoma tumors respectively Nanoparticule de silice ultrafine Cancer Sonde en imagerie multimodale Radiosensibilisateur Ultrasmall silica nanoparticle Cancer Multimodal imaging probe Radiosensitizer 540
7	Estudo da cinética da tirosinase imobilizada em nanopartícula de sílica com obtenção de revestimento de eumelanina / Study of the kinetics of tyrosinase immobilized in nanoparticle silica wiht obtention of eumelanin coating Andre José Cardoso de Miranda 22 December 2015 (has links) Melanina é um polímero constituído por uma grande heterogeneidade de monômeros tendo como característica comum a presença de grupos indóis. Por outro lado, a eumelanina produzida pela oxidação enzimática da tirosina é um polímero mais simples constituído principalmente de monômeros 5,6-dihidroxindol (DHI) e de indol-5,6-quinona (IQ). Tirosinase é a enzima chave na produção de melanina, sendo que a sua atividade cinética é medida em função da formação do intermediário dopacroma. Nanopartículas (NPs) de sílica são partículas nanométricas compostas de oxido de silício e são obtidas pelo processo sol-gel desenvolvido por Stöber de hidrólise e condensação de tetraetilortosilicato (TEOS), usando etanol como solvente em meio alcalino. As NPs foram funcionalizadas com 3-Aminopropiltrietoxissilano (ATPES) e depois com glutaraldeído. Este último permitiu a imobilização da tirosinase na superfície da sílica. Caracterizamos as NPs antes e após a reação da enzima, a atividade catalítica da enzima ligada à NP e o mecanismos de formação de melanina na superfície da sílica. As NPs foram caracterizadas por espectrofotometria de absorção e de reflectância, termogravimetria e microscopia eletrônica. A síntese da NP de sílica retornou partículas esféricas com 55nm de diâmetro e a funcionalização da partícula mostrou modificar eficientemente a sua superfície. A imobilização da tirosinase por ligação covalente foi de 99,5% contra 0,5% da adsorção física. A atividade da tirosinase foi caracterizada pela formação de dopacroma. O Km da enzima imobilizada não sofreu alteração em comparação com a tirosinase livre, mas a eficiência catalítica - que considera a eficiência recuperada - foi de apenas 1/3 para a enzima ligada covalentemente, significando que 2/3 das enzimas ligadas não estão ativas. Obtivemos NPs revestidas com melanina a partir de oxidação de tirosina solubilizada em duas preparações: NP com tirosinase ligada covalentemente na superfície e NP funcionalizada com glutaraldeido dispersa em solução de DHI e IQ. O revestimento de melanina foi na forma de um filme fino com espessura ~1,9nm, conferindo perfil de absorção luminosa equivalente ao da própria melanina. Mostramos que o mecanismo de polimerização passa pela oxidação da tirosina pela tirosinase, que gera intermediários oxidados (principalmente DHI e IQ) que vão para solução (mesmo quando a tirosinase está ligada covalentemente na sílica). Estes intermediários ligam-se ao glutaraldeido e a superfície da sílica passa a funcionar como ambiente de polimerização da melanina. / Melanin is a polymer consisting of a large heterogeneity of monomers having as a common feature the presence of indole groups. Contrarily, eumelanin produced by enzymatic oxidation of tyrosine is a simpler polymer consisting mainly of 5,6-dihidroxindol (DHI) and indole-5,6-quinone (IQ) monomers. Tyrosinase is the key enzyme in melanin production, and its kinetic activity is measured by the formation of the intermediate dopacroma. Nanoparticles (NPs) are made of silica nanoparticles of silicon oxide and are obtained by sol-gel method developed by Stöber of hydrolysis and condensation of tetraethylorthosilicate (TEOS), using ethanol as solvent in an alkaline medium. NPs were functionalized with 3-Aminopropyltriethoxysilane (ATPES) and then with glutaraldehyde. The latter allows the immobilization of tyrosinase on the silica surface. We characterized NPs before and after the reaction of the enzyme, the catalytic activity of the enzyme bound to the NP and melanin-forming mechanisms on the silica surface. NPs were characterized by absorption spectrophotometry and reflectance, electron microscopy and thermogravimetric analysis. The synthesis of silica NP returned spherical particles of 55nm diameter and particle functionalization showed efficiently modify its surface. The immobilization of tyrosinase by covalent bond was 99.5% versus 0.5% by physical adsorption. The activity of tyrosinase was characterized by the formation of dopacroma. The Km of the immobilized enzyme did not change compared to the free tyrosinase, but the catalytic efficiency - considering the recovered efficiently - was only 1/3 for the enzyme covalently bound, meaning that 2/3 of the enzymes are not connected active. We obtained melanin coated NPs from tyrosine oxidation in two preparations: NP with covalently bound tyrosinase in the NP surface and NP functionalized with glutaraldehyde dispersed in DHI and IQ solution. The melanin coating was in the form of a thin film with the thickness of ~ 1,9 nm, giving light absorption profile equivalent to that of melanin itself. We showed that the polymerization mechanism involves the oxidation of tyrosine by tyrosinase, which generates oxidized intermediates (especially DHI and lQ) that go into solution (even when tyrosinase is covalently bound to the silica). These intermediates bind the glutaraldehyde and the surface of the silica begins to function as an environment for melanin polymerization. Atividade enzimática Imobilização de enzimas Melanina Nanopartícula de sílica Revestimento de nanomaterial Tirosinase Coating nanomaterial Enzyme activity Enzyme immobilization Melanin Silica nanoparticle Tyrosinase
8	Matériaux hybrides organique-inorganique à base de résine et de particules d'oxydes : application dans les panneau photovoltaïques / Resin and oxide particles-based hybrid organic-inorganic materials and their application in photovoltaic panels Girard, Anaëlle 06 June 2014 (has links) Dans le contexte énergétique actuel, la conception de panneaux photovoltaïques efficaces représente une des solutions pour pallier à la pénurie prochaine des énergies fossiles. Cependant, les phénomènes de dégradation de l’encapsulant, un des matériaux passifs du panneau, sont une des origines de la baisse de rendement des modules. L’objectif de ce travail de thèse a été de concevoir, caractériser et évaluer les différentes propriétés de nouveaux encapsulants hybrides organique-inorganique contenant des ressources renouvelables. Ainsi, trois matériaux ont été élaborés à partir d’alcool polyvinylique (PVA), de résines terpéniques et de charges minérales (silice ou argile (Bentonite)). Un premier matériau comprenant PVA, résine et silicates, dans lequel composantes organique et inorganique sont liées par des liaisons covalentes fortes (hybride de classe II), a conduit à des stabilités thermiques et photochimiques, et des propriétés optiques et barrières à la vapeur d’eau et à l’oxygène, similaires à celles des encapsulants actuels.L’introduction de nanoparticules de silice dans un mélange PVA/résine via des liaisons faibles a ensuite fourni un matériau hybride de classe I aux propriétés barrières à la vapeur d’eau satisfaisantes mais avec des transparences optiques insuffisantes pour une utilisation comme encapsulant, du fait de l’agrégation des nanoparticules. Enfin, malgré une transparence optique devant être encore optimisée, un matériau hybride de classe I constitué de PVA, de résine et de Bentonite a conduit à de bonnes propriétés thermiques, photochimiques, barrières à la vapeur d’eau et surtout d’excellentes propriétés barrières à l’oxygène, ce qui ouvre de nouvelles perspectives (emballage alimentaire…). / In the current energetic context, the design of efficient solar photovoltaic panels represents one of the solutions to overcome the coming fossil fuels shortage. However, degradation phenomena of the encapsulant, one of the passive materials of the panel, have been evidenced as one of the reasons of the performance decrease. The aim of this PhD research work was to design, characterize and assess the different properties of more environment-friendly new hybrid organic-inorganic encapsulants. In this way, three materials have been developed using polyvinyl alcohol (PVA), terpenic resins and mineral fillers (silica or clay(Bentonite)). A first material including PVA, resin and silicates, in which both organic and inorganic networksare linked through strong covalent bonds (class II hybrid material), led to thermal and photochemical stabilities, and water vapor and oxygen barriers properties similar to those of commercial encapsulants.Dispersion of silica nanoparticles into PVA/terpenic resin mixture through weak bond then provided a class Ihybrid material showing rather good water vapor barrier properties but optical transmittance too low to beused as an encapsulant, due to the aggregation of the nanoparticles. Finally, despite an optical transparency that should be optimized, a class I hybrid material made of PVA, resin and Bentonite showed promisingbehavior with good thermal, photochemical and water barrier properties and remarkable oxygen barrier properties, which opens up new prospects in the field of food packaging. Hybride organique-inorganique Alcool polyvinylique Résine terpénique Nanoparticule de silice Argile Membrane Photovoltaic panels encapsulation Organic-inorganic hybrid Polyvinyl alcohol Terpenic resin Silica nanoparticle Clay Membrane
9	Advanced Mesoporous Silica Nanoparticles for the Treatment of Brain Tumors Bielecki, Peter 27 August 2020 (has links) No description available. Biomedical Engineering Immunology mesoporous silica nanoparticle nanoparticle glioblastoma multiforme brain tumor triggered drug release drug delivery STING agonist immunotherapy glioma stem cell brain tumor initiating cell
10	NANOHARVESTING AND DELIVERY OF BIOACTIVE MATERIALS USING ENGINEERED SILICA NANOPARTICLES Khan, Md Arif 01 January 2019 (has links) Mesoporous silica nanoparticles (MSNPs) possess large surface areas and ample pore space that can be readily modified with specific functional groups for targeted binding of bioactive materials to be transported through cellular barriers. Engineered silica nanoparticles (ESNP) have been used extensively to deliver bio-active materials to target intracellular sites, including as non-viral vectors for nucleic acid (DNA/RNA) delivery such as for siRNA induced interference. The reverse process guided by the same principles is called “nanoharvesting”, where valuable biomolecules are carried out and separated from living and functioning organisms using nano-carriers. This dissertation focuses on ESNP design principles for both applications. To investigate the bioactive materials loading, the adsorption of antioxidant flavonoids was investigated on titania (TiO2) functionalized MSNPs (mean particle diameter ~170 nm). The amount of flavonoid adsorbed onto particle surface was a strong function of active group (TiO2) grafting and a 100-fold increase in the adsorption capacity was observed relative to nonporous particles with similar TiO2 coverage. Active flavonoid was released from the particle surface using citric acid-mediated ligand displacement. Afterwards, nanoharvesting of flavonoids from plant hairy roots is demonstrated using ESNP in which TiO2 and amine functional groups are used as specific binding sites and positive surface charge source, respectively. Isolation of therapeutics was confirmed by increased pharmacological activity of the particles. After nanoharvesting, roots are found to be viable and capable of therapeutic re-synthesis. In order to identify the underlying nanoparticle uptake mechanism, TiO2 content of the plant roots was quantified with exposure to nanoparticles. Temperature (4 or 23 °C) dependent particle recovery, in which time dependent release of ESNP from plant cells showed a similar trend, indicated an energy independent process (passive transport). To achieve the selective separation and nanoharvesting of higher value therapeutics, amine functionalized MSNPs were conjugated with specific functional oligopeptides using a hetero-bifunctional linker. Fluorescence spectroscopy was used to confirm and determine binding efficiency using fluorescently attached peptides. Binding of targeted compounds was confirmed by solution depletion using liquid chromatography–mass spectrometry. The conjugation strategy is generalizable and applicable to harvest the pharmaceuticals produced in plants by selecting a specific oligopeptide that mimic the appropriate binding sites. For related gene delivery applications, the thermodynamic interaction of amine functionalized MSNPs with double-stranded (ds) RNA was investigated by isothermal titration calorimetry (ITC). The heat of interaction was significantly different for particles with larger pore size (3.2 and 7.6 nm) compared to that of small pore particles (1.6 nm) and nonporous particles. Interaction of dsRNA also depended on molecular length, as longer RNA (282 base pair) was unable to load into 1.6 nm particles, consistent with previous confocal microscopy observations. Calculated thermodynamic parameters (enthalpy, entropy and free energy of interaction) are essential to design pore size dependent dsRNA loading, protection and delivery using MSNP carriers. While seemingly diverse, the highly tunable nature of ESNP and their interactions with cells are broadly applicable, and enable facile nano-harvesting and delivery based on a continuous uptake-expulsion mechanism. Engineered silica nanoparticle Nanoharvesting Nucleic acid delivery Cellular interactions Functional oligopeptide Conjugation Biochemical and Biomolecular Engineering Biology and Biomimetic Materials Chemical Engineering Materials Science and Engineering Nanoscience and Nanotechnology

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