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The Effect of Particle Size and Shape on the In Vivo Journey of NanoparticlesToy, Randall 12 June 2014 (has links)
No description available.
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Pathogenesis and Treatment of Canine Prostate CancerElshafae, Said Mohammed Abbas 22 May 2017 (has links)
No description available.
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Modulation of Human Dendritic Cell Activity by Adsorbed Fibrin(ogen)Thacker, Robert I. January 2008 (has links)
No description available.
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Optimizing Channel Formation in PEG Maleimide HydrogelsKannadasan, Bakthavachalam 14 November 2023 (has links) (PDF)
Blood vessels including the arteries, veins, and capillaries are a critical and indispensable component of various organisms. Some studies estimate that if all the blood vessels present in our body are arranged in line, they would amount to a total length of approximately 60,000 miles. This distance is enough to circle the world two and a half times! In addition to being all pervasive, blood vessels perform certain key functions such as delivery of oxygen and nutrients to various tissues in the body. They also assist in the spread of diseases such as cancer. Therefore, it is important to study vessels from the point of view of tissue engineering applications.
In this study, I have adapted the design of an open-source 3D printed device to create channels in Poly (ethylene glycol) Maleimide (PEG-Mal) hydrogels using the subtractive technique. The PEG-Mal hydrogels can be formed in various formulations to mimic the biophysical and biochemical properties of various tissues such as bone marrow, brain, and lung. These channels created within hydrogels can be easily perfused with physiologically relevant flow rates found in blood vessels and capillaries. Additionally, I have also optimized the hydrogel formulations to improve channel reproducibility. It was found that the number of arms of PEG-Mal contributed the most to channel reproducibility with higher success rates of channel formation in 8-arm gels when compared to 4-arm gels. Therefore, this project delineates the formation of simple in vitro channels in hydrogels which combines properties of the tissue specific extracellular matrix with hemodynamics. It is expected that such a system will find potential use in various tissue engineering and disease modeling studies.
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Role Of Tumor Microenvironment in Breast Cancer MetastasisAparna B. Shinde (5930267) 10 June 2019 (has links)
<p>Metastasis of primary
mammary tumors to vital secondary organs is the primary cause of breast cancer-associated
death, with no effective treatment. Metastasis is a highly selective process
that requires cancer cells to overcome multiple barriers to escape the primary
tumor, survive in circulation, and eventually colonize distant secondary
organs. One of the important aspects of metastatic cancers is the ability to
undergo epithelial-mesenchymal transition (EMT) and the reverse process
mesenchymal-epithelial transition (MET) process. Constant interconversion of
tumor cells between these phenotypes creates epithelial-mesenchymal heterogeneity
(EMH) and interaction between these tumor cell types and the stromal cell
compartment is clearly important to metastasis. In healthy tissues, stromal
cells maintain the composition and structure of the tissue through the production
of extracellular matrix (ECM) proteins and paracrine signaling with epithelial
cells. However, little is known about how EMH
promotes changes in the ECM to promote breast cancer progression and
metastasis. Cancer cells also secret exosomes, nano-size extracellular
vesicles, to establish intercellular communication with distant organs in order
to induce metastasis. These exosomes contain a plethora of different proteins
including extracellular matrix proteins and matrix crosslinking enzymes.
Fibronectin, an important ECM protein, plays an active role in tumor
progression and is often crosslinked by tissue transglutaminase 2 (TGM2) to
promote fibrosis in cancer. Both FN and TGM2 exist in exosomes and are
expressed by heterogenous breast tumors. Although FN and TGM2 have been
reported to play essential roles in cancer, their involvement in metastasis
remains unclear. This work utilizes a variety of approaches to investigate the
role of tumor heterogeneity and ECM proteins in promoting breast cancer
metastasis. In this dissertation, we establish that mesenchymal cells
expressing intracellular FN are held in a stable non-metastatic mesenchymal
phenotype and produce cellular fibrils containing functionalized FN capable of
supporting the growth of metastatic competent epithelial cells. We introduce a
novel 3D culture system consisting of a tessellated scaffold which is capable
of recapitulating cellular and matrix phenotypes <i>in vivo. </i>Further, we
also demonstrate breast tumor cells secrete exosomes containing TGM2
crosslinked FN fibrils to promote premetastatic niche formation and induction
of metastasis.<i> </i>Using genetic approaches, we establish TGM2 is essential
and sufficient to drive metastasis. Finally, we demonstrate pharmacological
inhibition of TGM2 offers a potential therapeutic strategy to treat metastatic
breast cancer. Altogether, our research provides insights into the mechanism
through which TGM2 promotes metastatic breast cancer. This work will help in
developing new drugs to target TGM2 aimed at reducing breast cancer metastasis.<br></p>
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Hyaluronic Acid Based Biodegradable Polyelectrolyte Nanocapsules and Modified Protein Nanoparticles for Targeted Delivery of Anticancer AgentsSreeranjini, P January 2015 (has links) (PDF)
Targeted delivery aids in minimizing most of the drug-originated systemic toxic effects as well as improving the pharmacokinetic properties of anticancer therapeutics. Tumor targeting using hyaluronic acid (HA) as the targeting ligand has attracted a great deal of interest among a host of strategies developed to target the overexpressed tumor specific receptors. HA is an endogenous molecule that possesses a lot of biological functions in the human body. The role of HA synthases, HA degrading enzymes and the interaction of HA with its primary receptor CD44 in tumor metastasis and angiogenesis is really complex and controversial to date. However, overexpression of CD44receptors on tumor surface has been well studied, which have been utilized to direct tumor targeted drugs. Most of the HA based targeting systems were HA drug conjugates and surface modified colloidal carriers which required covalent modification. The lack of accurate structural characterization of these systems resulted in modification of HA binding sites that could affect the efficient cellular uptake.
LbL technique is a simple and facile method to incorporate several materials into polyelectrolyte assemblies for drug delivery applications. HA being a negatively charged polysaccharide can be easily incorporated into such systems without any covalent modification. Although HA based polyelectrolyte multilayer films and microcapsules have been reported in combination with polycations like PAH, PLL and chitosan, their application as targeted drug delivery systems have not yet been explored. Herein, two LbL architectures with HA as the terminal layer have been investigated as targeted drug carriers, which can recognize overexpressed CD44 receptors in metastatic breast cancer cells.
In the first part of the thesis, a novel polyelectrolyte nanocapsule system composed of biopolymers HA and protamine sulphate (PR) as the wall components was prepared and characterized. These pH and enzyme responsive nanocapsules were then utilized for efficient loading and release of anticancer drug doxorubicin (dox). Higher drug release was observed in simulated intracellular conditions like acidic pH and presence of hyaluronidase enzyme as compared to physiological pH. In the second part of the thesis, dox incorporated bovine serum albumin (BSA) nanoparticles modified with HA-Poly(l-Lysine) multilayers were developed and characterized. The drug release pattern of the dox loaded BSA nanoparticles was found to depend on the presence of a protease enzyme trypsin than pH variations. Both of these drug delivery systems were then evaluated for their cell targeting efficiency and cytotoxicity in CD44+ positive metastatic breast cancer cell line MDA MB 231. The final layer HA facilitated targeted delivery of these drug carriers via CD44 receptor mediated endocytosis. The enhanced cellular uptake followed by sustained delivery of dox by virtue of slow intracellular enzymatic degradation of the drug carriers resulted in their improved cytotoxicity as compared to free dox. Further in vitro biodistribution and tumor suppression efficiency of both the systems were studied in breast cancer xenograft models using BALB/c nude mice. Enhance accumulation of dox in the tumor tissue and significant tumor reduction were observed when treated with encapsulated dox using the HA based nanocarriers as opposed to free dox.
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Understanding the role of the matricellular protein SMOC-2 in renal cell carcinomaFeng, Daniel 08 1900 (has links)
Les proteins matricellulaires (MPs) sont des macromolécules non structurales de la matrice extracellulaire (ECM) qui sont induites de façon transitoire lors du développement, de la réparation et du remodelage tissulaire et lors de l’inflammation. L’expression des MPs peut être déclenchée par des dommages tissulaires aigus, et leur expression à long terme peut contribuer à certaines maladies chroniques. Les MPs agissent principalement pour médier les événements du remodelage tissulaire en facilitant les interactions et les signaux à partir de l’ECM vers l’environnement cellulaire avoisinant.
En utilisant des données de RNA-seq provenant de deux modèles distincts de dommages rénaux, soit l’Acide Folique (FA) ou l’Obstruction Urétérale Unilatérale (UUO), nous avons analysé les profils d’expressions de plusieurs familles bien connues de MPs lors des blessures aigues et chroniques. Nous révélons de nouvelles MPs impliquées dans les dommages rénaux et présentons de nouveaux réseaux entre les membres de chaque famille de MPs, en utilisant des outils bioinformatiques. L’expression de l’ARNm de certaines MPs a été confirmée par immuno-buvardage de type Western (WB).
Afin d’approfondir notre connaissance des mécanismes de réparation tissulaire et de remodelage de la matrice, nous avons choisi SMOC-2 comme MP modèle dans l’étude des carcinomes cellulaires rénaux (RCC), cancers qui présentent de fortes tendances métastatiques. Nous avons démontré que la surexpression de SMOC-2 ainsi que le traitement avec la protéine recombinante de lignées cellulaires RCC (786-O, et ACHN) induisent un profil métastatique de transition épithélio-mésenchymateuse (EMT) par WB et des tests fonctionnels. Nous avons également démontré que l’inhibition de SMOC-2 par siRNA donne les résultats opposés.
L’ensemble de nos travaux utilise la compréhension des patrons d’expressions temporels des MPs pour améliorer notre compréhension des mécanismes et conditions qui supportent une activation persistante dans des états pathologiques chroniques. Globalement, notre étude sur SMOC-2 offre une perspective ainsi qu’un modèle intéressant pour l’étude et la caractérisation de nouvelles MPs dans des maladies impliquant le remodelage et la réparation de la matrice. / Matricellular proteins (MPs) are non-structural ECM macromolecules induced transiently during development, tissue repair and remodeling, and inflammation. Expression of MPs can be triggered by acute tissue injury and their sustained expression can contribute to chronic disease. MPs primarily act to mediate tissue remodeling events by facilitating interactions and signals from the ECM to the surrounding cellular niche.
Using published RNA-seq data from two distinct models of kidney injury, Folic Acid (FA) and Unilateral Ureteral Obstruction (UUO), we analyzed the expression profile of various members of well-known MP families during the acute and fibrotic injury phases. We reveal novel MPs implicated in renal injury and present informative networks between members of each MP family using bioinformatic tools. mRNA expression of select candidate MPs were confirmed by Western blot.
To extend our understanding of translatable mechanisms in repair and matrix remodeling, we chose SMOC-2 as our MP model to study in Renal Cell Carcinoma (RCC) which has strong metastatic tendencies. SMOC-2 overexpression and recombinant protein treatment of RCC cell lines (786-O, ACHN) were shown to induce a metastatic EMT profile by Western blot analysis, supported by functional assays (proliferation, migration). Silencing SMOC-2 by siRNA showed the contrary results.
Taken together, our work utilizes the understanding of temporal expression patterns of MPs to gain insight into mechanisms and conditions that support persistent activation in chronic injury states. Overall, our work with SMOC-2 provides a valuable perspective and template to approach studying and characterizing novel MPs in diseases involving pathological matrix remodeling and repair.
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