A. James Clark School of Engineering

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The collections in this community comprise faculty research works, as well as graduate theses and dissertations.

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Subject: search.filters.subject.Nanoparticle

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Now showing 1 - 7 of 7
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    Overcoming the Extracellular Matrix Barrier to Nanoparticle Transport
    (2024) Cahn, Devorah; Duncan, Gregg A; Bioengineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The extracellular matrix (ECM) is a major component of the tumor microenvironment which poses a significant barrier to nanoparticle (NP) transport, preventing delivery of therapeutic cargo. Studies have shown that PEGylation offers an effective strategy for improving NP transport in ECM. However, these studies have generally used ECM models that are not wholly representative of the native matrix. Furthermore, while ECM characteristics and composition varies across organs, it is unclear to what extent these tissue-specific characteristics affect NP transport through the ECM and how NP surface chemistry impacts ECM penetration in distinct tissues. The overall objective of this dissertation is to identify key factors of NP transport through the tumor microenvironment, facilitating the development of strategies to improve NP distribution throughout the tumor microenvironment. We hypothesized that PEG branching will enhance stability and mobility of NPs in ECM and that ECM source impacts NP transport. We further hypothesized that PEG architecture significantly affects NP mobility in ECM as well as biodistribution and tumor accumulation in vivo. Our first aim was to determine the effects of PEG branching on NP stability and transport through in vitro basement membrane model. We found that branched PEG significantly increased both the stability and mobility of NPs in Matrigel, a basement membrane model. We then assessed the impact of tissue source on NP transport through an in vitro ECM model. We decellularized porcine lung, liver, and small intestine submucosa to form tissue specific hydrogels and found NP mobility was significantly impacted by tissue source where low molecular weight linear PEG generally provided the greatest benefit to NP mobility within the different matrices. Finally, we evaluated how PEG branching affects biodistribution, immune cell infiltration, and NP uptake in tumors in vivo. We found that NPs coated with branched PEG increased NP accumulation within tumors and PEGylation significantly impacted immune cell infiltration within these tumors. This work provides additional insight into the transport mechanisms of NPs throughout the tumor microenvironment as well as additional considerations for the design of efficient NP delivery systems.
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    ENGINEERING NANOPARTICLES FOR IMPROVED LYMPHATIC DELIVERY AND ELUCIDATING MECHANISMS REGULATING NANOPARTICLE TRANSPORT INTO LYMPHATICS
    (2023) McCright, Jacob Connor; Maisel, Katharina; Bioengineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Immune modulatory therapies usually need to be effectively delivered to lymph nodes to enhance therapeutic effectiveness. Lymphatic vessels exist throughout the body and can transport 10 – 250 nm therapeutic nanoparticles to lymph nodes, however, nanoparticle formulations required to maximize this transport, and the mechanisms governing this transport are poorly understood. Here, we probed the effect of surface charge, surface poly(ethylene glycol) (PEG) density, shape, and size on nanoparticle transport across LECs (LECs) and lymph node delivery. Using an established in-vitro lymphatic transport model, we found PEGylation improved the transport of 100 and 40 nm nanoparticles across LECs 50-fold compared to non-PEGylated nanoparticles and that transport is maximized when the PEG is in a dense brush conformation corresponding to a high grafting density (Rf/D = 4.9). PEGylating 40 nm nanoparticles improved transport efficiency across LECs 68-fold compared to unmodified nanoparticles, demonstrating that the addition of PEG improves transport in a size-independent manner. We injected these nanoparticle formulations intradermally into C57Bl/6J mice and found that PEGylated 100 nm and 40 nm nanoparticles accumulate in lymph nodes within 4 hours, while unmodified nanoparticles accumulated minimally. Densely PEGylated nanoparticles also traveled furthest from the injection site. In this thesis, we also determined that nanoparticles are transported via both paracellular and transcellular mechanisms, and that both PEG conformation and nanoparticle size and shape modulates the cellular transport mechanisms. We also expanded our in-vitro lymphatic transport model to model important physiological conditions including transmural flow and found that the presence of this flow increased transport across lymphatic barriers in a shape and mechanism-dependent manner. To further investigate the mechanisms regulating nanoparticle transport, we generated a computational kinetic transport model that was able to quantify the contributions of both paracellular and transcellular transport mechanisms, as well as predict transport efficiency as a function of nanoparticle characteristics including size and surface chemistry. Using transport inhibitors, we can expand our system of equations to describe precise uptake and transport mechanisms, and the relation between nanoparticle formulation and mechanism. This computational model is one of the first to describe transport across lymphatic vessels, and offers some of the first definitions for coefficients used to quantitatively describe nanoparticles transport across LECs (i.e., permeability). Our computational, in-vitro, and in-vivo results indicate that nanoparticle surface charge, PEG conformation, and size are key criteria for nanoparticle design for effective lymphatic delivery with a dense, neutrally charged coating of PEG maximizing transport across LEC barriers and transport to lymph nodes. Optimizing nanoparticle formulation and surface characteristics, including PEG density, has the potential to enhance immunotherapeutic and vaccine outcomes.
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    CONFINED PHOTOTHERMAL HEATING OF NANOPARTICLE DISPLAYED BIOMATERIALS
    (2021) Hastman, David A; Medintz, Igor L; Aranda-Espinoza, Helim; Bioengineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Controlling the temperature of biological systems has long been utilized as a tool for regulating their subsequent biological activity. Recently, photothermal heating of gold nanoparticles (AuNPs) has emerged as an efficient and remote method to heat proximal biological materials. Moreover, this technique has tremendous potential for controlling biological systems at the subcellular level, as specific components within the system can be heated while the larger system remains unaffected. The small size, biocompatiblilty, and optical properties of AuNPs make them attractive nanoscale heat sources for controlling biological systems. While the utility of photothermal heating has significantly advanced through the optimization of AuNP size, shape, and composition, the choice of incident light source utilized has largely been unexplored. One of the more interesting excitation sources is a femtosecond (fs) pulsed laser, as the subsequent temperature increase lasts for only a few nanoseconds and is confined to the nanoscale. However, it is not yet clear how biological materials respond to these short-lived and ultra-confined nanoscale spaciotemporal temperature increases. In this dissertation, we utilize fs laser pulse excitation to locally heat biological materials displayed on the surface of AuNPs in order to understand the corresponding heating profiles and, in turn, interpret how this can be used to modulate biological activity. Due to its unique temperature sensitive hybridization properties, we exploit double-stranded deoxyribonucleic acid (dsDNA) as our prototypical biological material and demonstrate precise control over the rate of dsDNA denaturation by controlling the laser pulse radiant exposure, dsDNA melting temperature, bulk solution temperature, and the distance between the dsDNA and AuNP surface. The rate of dsDNA denaturation was well fit by a modified DNA dissociation equation from which a “sensed” temperature value could be obtained. Evaluating this sensed temperature in the context of the theoretical temperature profile revealed that the ultra-high temperatures near the AuNP surface play a significant role in denaturation. Additionally, we evaluate this technique as a potential means to enhance enzyme activity and report that enhancement is governed by the laser repetition rate, pulse width, and the enzyme’s inherent turnover number. Overall, we demonstrate that the confined and nanosecond duration temperature increase achievable around AuNPs with fs laser pulse excitation can be used to precisely control biological function and establish important design considerations for coupling this technique to more complex biological systems.
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    ACTUATION OF MULTIFUNCTIONAL HARD NANOPARTICLES FOR ACTIVELY CONTROLLED DRUG RELEASE
    (2019) Sangtani, Ajmeeta; Delehanty, James B; Stroka, Kimberly M; Bioengineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Systemic drug delivery relies on repeated dosing of large concentrations of poorly targeted drug leading to off-target toxicity. Recently, nanoparticle (NP)-mediated drug delivery (NMDD) has been developed as an approach to overcome the limitations of traditional drug delivery. The unique size-dependent properties of NPs and their ability to augment the activity of attached/loaded cargos makes them attractive drug delivery vectors. NPs are classified into two categories (soft or hard depending on their material composition) and our understanding of how to load and control soft NP materials currently surpasses that of hard NPs. In this dissertation we seek to further our fundamental knowledge of hard NP-based drug delivery systems. In Aim 1 we utilize a quantum dot (QD)-cell uptake peptide complex as a central scaffold to append various responsive peptide-drug constructs in order to modulate the toxicity of one of the most widely used chemotherapeutics, doxorubicin. By doing a comparative study of four chemical linkages, we determine the role played by attachment chemistry in controlling drug release. In Aim 2, we utilize the knowledge gained from Aim 1 to develop a system capable of overcoming multidrug resistance in cancer cells, which is known to severely limit the efficacy of chemotherapeutics. Our hard NP conjugate system is unique as it is one of the few systems reported in the literature to bypass multidrug resistance pumps without the need for exogenous drugs. Finally, in Aim 3 we append a peptide for membrane targeting and a photosensitizing drug capable of generating reactive oxygen species to the QD. This multifunctional system displays augmented therapeutic efficacy of the appended photosensitizer by delivering it to the membrane of cells and controlling its actuation using energy transfer. The work described here details basic concepts for the design of “smart” hard NP materials for internally and externally-triggered, active release of surface-appended drug cargos. Additionally, we hope to elucidate the important design considerations that must be taken into account when designing hard NP systems for controlled drug delivery.
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    Design of Self-Assembling Nanostructures to Promote Immune Tolerance
    (2018) Hess, Krystina; Jewell, Christopher M; Bioengineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In autoimmune diseases, which affect more than 23 million Americans, the immune system mistakenly attacks healthy tissue. This occurs when the process that normally controls self-reactive inflammatory cells (i.e. tolerance) fails. In multiple sclerosis (MS), the myelin sheath, which insulates nerves, is recognized as a foreign antigen. Demyelination by immune cells results in serious symptoms of neurodegeneration. Current treatments for MS are not curative, but rather manage symptoms by broadly suppressing the immune system, leaving patients unable to fight infection. New therapies that are more specific and effective could greatly improve the quality of life for patients. Biomaterials offer specific advantages for generating antigen-specific tolerance, such as cargo protection, targeted delivery, and controlled release of signals. Additionally, recent reports demonstrate that materials themselves can be intrinsically immunogenic. Two promising biomaterials-based strategies for combating autoimmunity involve: 1) delivery of self-antigen with a regulatory molecule or 2) delivery of self-antigen alone. Aim 1 of this dissertation focuses on the first strategy, creating a novel delivery system for myelin peptide and GpG, an immunomodulatory oligonucleotide. This approach involves electrostatic self-assembly of the two immune signals, eliminating the need for a carrier that could exacerbate inflammation, while still offering attractive features of biomaterials, such as co-delivery. The goal is for immune cells to encounter both signals simultaneously, biasing the response towards tolerance. This work represents the first studies using self-assembled materials to target toll-like receptor signaling, recently shown to be implicated in many autoimmune diseases. Aim 2 of this dissertation is based on the second strategy above, which relies on evidence that changing the trafficking and processing of a self-antigen can impact the development of inflammation or tolerance. Quantum dots, NPs that are intrinsically fluorescent and rapidly drain to lymph nodes, can be decorated with a large and controllable number of myelin peptides. These key features of QDs were exploited to reveal that parameters of self-antigen display (i.e. dose, density) impact biodistribution and immune cell uptake, and are directly correlated to the level of tolerance induced. Together, the described nanotechnologies offer opportunities to probe important questions towards the design of antigen-specific therapies.
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    Controlled Delivery of a Glutamate Receptor Modulator to Promote Regulatory T cells and Restrain Autoimmunity
    (2015) Gammon, Joshua Marvin; Jewell, Christopher M; Bioengineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Autoimmunity occurs when the immune system incorrectly recognizes and attacks self-molecules. Current therapies involve broad immunosuppressants that are not curative and leave patients immunocompromised. Dendritic cells (DCs) are a target for new therapies because DCs influence the differentiation of immune effector cells. N-Phenyl-7-(hydroxyimino)cyclopropa[b]chromen-1a-carboxamide (PHCCC), a glutamate receptor enhancer, modulates DC cytokine profiles to polarize T cells toward regulatory phenotypes (TREG ) that are protective in multiple sclerosis (MS). However, PHCCC treatment is limited by poor solubility, a short half-life, and toxicity. We hypothesized that controlled delivery of PHCCC from nanoparticles would alter DC function with reduced treatment frequency. PHCCC nanoparticles attenuated DC activation and promoted TREGs while reducing toxicity 30-fold. In mouse models of MS, these particles delayed disease and reduced severity compared to an equivalent dosing schedule of soluble drug. This outcome demonstrates controlled delivery of metabolic modulators can promote tolerance, suggesting a new route to improve autoimmune therapy.
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    An Integrated Gas Sensing System Based on Surface-Functionalized Gallium Nitride Nanowires with Embedded Micro-Heaters
    (2015) Liu, Guannan; Peckerar, Martin C; Motayed, Abhishek; Electrical Engineering; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In the last few decades, significant improvements have been made in gas sensor technologies. Metal-oxide sensors have been used for low-cost detection of combustible and toxic gases. However, hurdles relating to sensitivity, stability and selectivity still remain. Recently, nanotechnology has helped tremendously through the introduction of nano-engineered materials like nanowires and nanoclusters. Nanowire sensors have much better sensitivity as compared with thin-film devices due to the larger detecting surface-to-volume ratio. But clearly, improvements are still needed. For real-world applications, selectivity between different classes of compounds, such as combustible and toxic gases, is highly desirable. An ideal chemical sensor should distinguish between the individual analytes from a single class of compounds. For example, in detection of benzene or toluene, a good sensor will not be disturbed by other aromatic compounds present in the environment. This is a huge challenge for semiconductor based metal-oxide sensors, such as TiO2, SnO2, Fe2O3 and ZnO, which have inherent non-selective surface adsorption sites. Recently, a new class of nanowire-nanocluster (NWNC) based gas sensors has gained interest. This type of sensor represents a new method of functionalizing the surface for selective adsorption and detection. The adjustable sensitivity can be achieved by tuning the density, size or composition of the nanoparticles that decorate the nanowires. These advantages make the NWNC sensors a good alternative to conventional thin-film sensors. So far, research into NWNC sensors has demonstrated the potential in sensing many important classes of compounds. However, most of these NWNC devices require elevated working temperatures. They also have long response/recovery times and must function in an inert atmosphere. All these limitation will be the obstacles in real-world usage for domestic, environmental or industrial applications. And finally, the sensors thus developed must be manufacturable. That is, they must be batch fabricated with high yield. To remedy these problems, my thesis was divided into the following tasks, 1. Develop dry etching techniques to fabricate horizontally aligned GaN nanowires (NW), combining these techniques with wet etching treatment for surface damages removal. I call this a “top-down approach” using a subtractive process that fabricates NWs from thin-films and adding sensitive nanocrystals after the initial NW definition. This is to be compared to the additive “bottom-up” nanowire growth by MBE/HVPE/Sol-gel, in which NWs are grown, harvested from the growth surface and subsequently re-attached to a new surface. The top-down approach enhances the yield and homogeneity of the NW and it is mass-production oriented. 2. Study the metal-oxide nanoclusters (NCs) deposition method by physical vapor deposition (PVD) and rapid thermal annealing (RTA) for TiO2, SnO2, WO3, Fe2O3, etc. Develop the metal nanoparticle deposition method by PVD for Au, Ag, Pt, Pd, etc. 3. Study the crystalline phases and gas adsorption sites formed by the method and establish a database connecting metal-oxide bonding sites with different target chemicals. 4. Utilize Si doped n-type and unintentionally doped GaN nanowires functionalized with different metal-oxide and metal-oxide/metal composite nanoclusters to create a series of highly selective and sensitive gas sensing nanostructure devices. 5. Develop a low-cost micro-heater (MH) for local high temperature generation with low power consumption. This allows the rapid chemical desorption cycles as we anticipate frequently re-use or reset of the sensor. It also enables the use of these NWs in high temperature sensor applications. 6. Integrate the NW, NCs and MH into one working sensor, and integrate multiple types of gas sensors on a single chip. The chip can simultaneously sense many types of gases without interference. In this study, the potential of multicomponent NWNC based sensors for developing the next-generation of ultra-sensitive and highly selective chemical sensors was explored. We have achieved uA and nA levels of baseline detector current and we have shown that low UV illumination enhances sensitivity for some cases. These sensors have low power consumption making them suitable for portable devices.