Global ETD Search

31	Liquid biopsies of solid tumors: non-small-cell lung and pancreatic cancer Kalubowilage, Madumali January 1900 (has links) Doctor of Philosophy / Department of Chemistry / Stefan H. Bossmann / Cancer is a group of diseases that are characterized by uncontrolled growth and spread of cells. In order to treat cancer successfully, it is important to diagnose cancers in their early stages, because survival often depends on the stage of cancer detection. For that purpose, highly sensitive and selective methods must be developed, taking advantage of suitable biomarkers. The expression levels of proteases differ from one cancer type to the other, because different cancers arise from different cell types. According to the literature, there are significant differences between the protease expression levels of cancer patients and healthy people, because solid tumors rely on proteases for survival, angiogenesis and metastasis. Development of fluorescence-based nanobiosensors for the early detection of pancreatic cancer and non-small-cell lung cancer is discussed in this thesis. The nanobiosensors are capable of detecting protease/arginase activities in serum samples over a broad range. The functionality of the nanobiosensor is based on Förster resonance energy transfer and surface energy transfer mechanisms. The nanobiosensors for protease detection feature dopamine-coated Fe/Fe₃O₄ nanoparticles, consensus (cleavage) peptide sequences, meso-tetra(4-carboxyphenyl)porphine (TCPP), and cyanine 5.5. The consensus peptide sequences were synthesized by solid-supported peptide synthesis. In this thesis, improved consensus sequences were used, which permit faster synthesis and higher signal intensities. TCPP, which is the fluorophore of the nanoplatform, was connected to the N-terminal end of the oligopeptides while it was still on the resin. After the addition of TCPP, the TCPP-oligopeptide was cleaved off the resin and linked to the primary amine groups of Fe/Fe₃O₄-bound via a stable amide bond. In the presence of a particular protease, the consensus sequences attached to the nanoparticle can be cleaved and release TCPP to the aqueous medium. Upon releasing the dye, the emission intensity increases significantly and can be detected by fluorescence spectroscopy or, similarly, by using a fluorescence plate reader. In sensing of arginase, posttranslational modification of the peptide sequence will occur, transforming arginine to ornithine. This changes the conformational dynamics of the oligopeptide tether, leading to the increase of the TCPP signal. This is a highly selective technology, which has a very low limit of detection (LOD) of 1 x 10⁻¹⁶ molL⁻¹ for proteases and arginase. The potential of this nanobiosensor technology to detect early pancreatic and lung cancer was demonstrated by using serum samples, which were collected from patients who have been diagnosed with pancreatic cancer and non-small cell lung cancer at the South Eastern Nebraska Cancer Center (lung cancer) and the University of Kansas Cancer Center (pancreatic cancer). As controls, serum samples collected from healthy volunteers were analyzed. In pancreatic cancer detection, the protease/arginase signature for the detection of pancreatic adenocarcinomas in serum was identified. It comprises arginase, MMPs -1, - 3, and -9, cathepsins -B and -E, urokinase plasminogen activator, and neutrophil elastase. For lung cancer detection, the specificity and sensitivity of the nanobiosensors permit the accurate measurements of the activities of nine signature proteases in serum samples. Cathepsin -L and MMPs-1, -3, and -7 permit detecting non-small-cell lung-cancer at stage 1. liquid biopsy pancreatic cancer non small cell lung cancer fluorescence detection nanobiosensor cancer detection
32	Antenna characterisation and optimal sampling constraints for breast microwave imaging systems with a novel wave speed propagation algorithm Rodriguez Herrera, Diego 04 1900 (has links) Breast microwave imaging (BMI) is a novel modality that complements current breast screening tools. Microwave radar imaging creates a radar cross-section (reflection) map of the breast. The difference in permittivity between healthy and malignant tissue is between 10-50%. This contrast is significantly higher than that obtained with x-rays and supports the use of microwave imaging for breast cancer diagnosis. Prior to widespread clinical use, some areas require further study. Firstly, the performance of three different antennas was carried out, to assess their suitability for a BMI system. Secondly, the sampling constraint of a circular scan geometry was studied and tested using experimental phantoms and these antennas. For accurate breast BMI reconstruction, the transmission speed of the radio waves inside the breast must be determined. The tissue composition of each patient is different, making this task challenging. This work presents an algorithm for wave speed estimation in different mediums. / February 2017 BMI Microwave Imaging Microwave Breast Cancer Detection Breast Cancer Antenna Radar system Microwave holography
33	Medical imaging using the acousto-electromagnetic technique Khan, Zein A. January 2011 (has links) No description available.
34	Development of novel strategies for detection and treatment of cancer Samarakoon, Thilani Nishanthika January 1900 (has links) Doctor of Philosophy / Department of Chemistry / Stefan H. Bossmann / Cancer is one of the leading causes of death in the world. Billions of dollars are spent to treat cancer every year. This clearly shows the need for developing improved treatment techniques that are affordable to every person. Early diagnosis and imaging of tumors is equally important for the battle against this disease. This dissertation will discuss new approaches for discovering and developing novel detection and treatment techniques for cancer using organic ligands, and Fe/Fe3O4 core/shell magnetic nanoparticles. A series of o-phenylenediamine derivatives with nitro-, methyl- and chloro- substituents were synthesized and studied their ability to act as anticancer agents by using steady-state, UV/Vis-, and fluorescence spectroscopy. In the absence of zinc(II), intercalation with DNA is the most probable mode of interaction. Upon addition of zinc(II), DNA-surface binding of the supramolecular aggregates was observed. The interaction of the supramolecular (-ligand-Zn2+-)n aggregates with MDA 231 breast cancer cells led to significant cell death in the presence of UVA at λ=313 nm displaying their potential as anticancer agents. Bimagnetic Fe/Fe3O4 core/shell nanoparticles (MNPs) were designed for cancer targeting after intratumoral or intravenous administration. Their inorganic center was protected by dopamine-oligoethylene glycol ligands. TCPP (4-tetracarboxyphenyl porphyrin), a fluorescent dye, was attached to the dopamine-oligoethylene glycol ligands. These modified nanoparticles have the ability to selectively accumulate within the cancerous cells. They are suitable candidates for local hyperthermia treatment. We have observed a temperature increase of 11 ºC in live mice when subcutaneously injecting the MNPs at the cancer site and applying an alternating magnetic field The system is also suitable for Magnetic Resonance Imaging (MRI), which is a diagnostic tool to obtain images of the tumors. Our superparamagnetic iron oxide nanoparticles have the ability to function as T1 weighted imaging agents or positive contrasting agents. We were able to image tumors in mice using MRI. Various proteases are over-expressed by numerous cancer cell lines and, therefore, of diagnostic value. Our diagnostic nanoplatforms, designed for the measurement of protease activities in various body fluids (blood, saliva, and urine), comprise Fe/Fe3O4 core/shell nanoparticles featuring consensus sequences, which are specific for the target protease. Linked to the consensus sequence is a fluorescent organic dye (e.g. TCPP). Cleavage of the sequence by the target protease can be detected as a significant increase in fluorescence occurring from TCPP. We were able to correlate our diagnostic results with cancer prognosis. Urokinase plasmin activator (UPA) Matrix metalloproteinases (MMPs) Fluorescence assays Cancer detection Cancer treatment Hyperthermia Chemistry (0485)
35	Luminol luminescence-based theranostics for pre-clinical breast adenocarcinoma Alshetaiwi, Hamad S. January 1900 (has links) Master of Science / Department of Anatomy & Physiology / Deryl L. Troyer / Breast cancer ranks second as a cause of cancer death in women in the USA. Detection of early tumors and tumor-targeted treatments could decrease the problems associated with breast cancer management. Photodynamic therapy (PDT) is a cancer treatment that uses a photosensitizer and a specific wavelength of light and is currently in clinical trials for breast cancer. When tumor cells which have absorbed photosensitizer are exposed to the correct wavelength of light, reactive oxygen species are generated, resulting in tumor cell death. Poor tissue penetration of light is a major limitation in PDT, restricting its use to treatment of localized tumors. Light generation at the tumor area might increase the effectiveness of PDT. Polymorphonuclear neutrophils (PMNs) are known to often infiltrate breast adenocarcinoma, and their activatation in tumor stroma produces luminescence in the presence of luminol. Here, we hypothesized that luminol can be used as a theranostic agent for luminescence-based early tumor detection (diagnosis) and in situ PDT (treatment). BALB/c mice were transplanted with 4T1 mammary adenocarcinoma cells to establish a breast adenocarcinoma model. The early tumor detection objective was tested by daily intraperitoneal injection of luminol and in vivo luminescence imaging. To test the PDT treatment objective,the photosensitizer 5-aminolevulinic acid (ALA) and luminol were administered to mice through intraperitoneal and intravenous routes, respectively. This treatment regimen was repeated six times and ALA alone/luminol alone/saline treated tumor-bearing mice were used as controls. Results demonstrated that luminol allowed detection of activated PMNs only two days after 4T1 cell transplantation, even though tumors were not yet palpable. Relative differences in the increase of tumor volume and final tumor weights were analyzed to test the in situ PDT. Analysis of the data showed luminol treatments resulted in breast adenocarcinoma tumor growth attenuation. In conclusion this study provides evidence that luminol can be a theranostic agent for breast adenocarcinoma. Cancer therapy Cancer detection Breast cancer Photodynamic therapy Bioluminescence Luminol Medicine (0564)
36	Oncoproteomic applications for detection of breast cancer : proteomic profiling of breast cancer models and biopsies Shaheed, Sadr-ul January 2017 (has links) The heterogeneity of breast cancer (disease stage and phenotype) makes it challenging to differentiate between each subtype; luminal A, luminal B, HER2, basal-like and claudin-low, on the basis of a single gene or protein. Therefore, a collection of markers is required that can serve as a signature for diagnosing different types of breast cancer. New developments in proteomics have provided the opportunity to look at phenotype-specific breast cancer cell lines and stage-specific liquid biopsies (nipple aspirate fluid [NAF], plasma samples) to identify disease and phenotype specific signature. An 8-plex iTRAQ quantification strategy was employed to compare proteomic profiles of a range of breast cancer and ‘normal-like’ cell lines with primary breast epithelial cells. From this, 2467 proteins were identified on Orbitrap Fusion and Ultraflex II, of which 1430 were common. Matched pairs of NAF samples from four patients with different stages of breast cancer, were analysed by SCX-LC-MS and a total of 1990 unique gene products were identified. More than double the number of proteins previously published data, were detected in NAF, including 300 not detected in plasma. The NAF from the diseased patients have 138 potential phenotype biomarkers that were significantly changed compared to the healthy volunteer (7 for luminal A, 9 for luminal B, 11 for HER2, 14 for basal-like and 52 for claudin-low type). The average coefficient of variation for triplicate analyses by multiple reaction monitoring mass spectrometry (MRM-MS), was 9% in cell lines, 17 % in tissue biopsies, 22% in serum samples and 24% in NAF samples. Overall, the results provide a strong paradigm to develop a clinical assay based on proteomic changes in NAF samples for the early detection of breast cancer supplementary to established mammography programmes. 570
37	Development of a Fourier Domain Low Coherence Interferometry Optical System for Applications in Early Cancer Detection Graf, Robert Nicholas January 2009 (has links) <p>Cancer is a disease that affects millions of people each year. While methods for the prevention and treatment of the disease continue to advance, the early detection of precancerous development remains a key factor in reducing mortality and morbidity among patients. The current gold standard for cancer detection is the systematic biopsy. While this method has been used for decades, it is not without limitations. Fortunately, optical detection of cancer techniques are particularly well suited to overcome these limitations. This dissertation chronicles the development of one such technique called Fourier domain low coherence interferometry (fLCI). </p><p>The presented work first describes a detailed analysis of temporal and spatial coherence. The study shows that temporal coherence information in time frequency distributions contains valuable structural information about experimental samples. Additionally, the study of spatial coherence demonstrates the necessity of spatial resolution in white light interferometry systems. The coherence analysis also leads to the development of a new data processing technique that generates depth resolved spectroscopic information with simultaneously high depth and spectral resolution. </p><p>The development of two new fLCI optical systems is also presented. These systems are used to complete a series of controlled experiments validating the theoretical basis and functionality of the fLCI system and processing methods. First, the imaging capabilities of the fLCI system are validated through scattering standard experiments and animal tissue imaging. Next, the new processing method is validated by a series of absorption phantom experiments. Additionally, the nuclear sizing capabilities of the fLCI technique are validated by a study measuring the nuclear morphology of in vitro cell monolayers.</p><p>The validation experiments set the stage for two animal studies: an initial, pilot study and a complete animal trial. The results of these animal studies show that fLCI can distinguish between normal and dyplastic epithelial tissue with high sensitivity and specificity. The results of the work presented in this dissertation show that fLCI has great potential to develop into an effective method for early cancer detection.</p> / Dissertation Engineering, Biomedical early cancer detection light scattering low coherence interferometry optical coherence tomography spectroscopy
38	Medical Electro-thermal Imaging Carlak, Hamza Feza 01 February 2012 (has links) (PDF) Breast cancer is the most crucial cancer type among all other cancer types. There are many imaging techniques used to screen breast carcinoma. These are mammography, ultrasound, computed tomography, magnetic resonance imaging, infrared imaging, positron emission tomography and electrical impedance tomography. However, there is no gold standard in breast carcinoma diagnosis. The object of this study is to create a hybrid system that uses thermal and electrical imaging methods together for breast cancer diagnosis. Body tissues have different electrical conductivity values depending on their state of health and types. Consequently, one can get information about the anatomy of the human body and tissue&rsquo / s health by imaging tissue conductivity distribution. Due to metabolic heat generation values and thermal characteristics that differ from tissue to tissue, thermal imaging has started to play an important role in medical diagnosis. To increase the temperature contrast in thermal images, the characteristics of the two imaging modalities can be combined. This is achieved by implementing thermal imaging applying electrical currents from the body surface within safety limits (i.e., thermal imaging in active mode). Electrical conductivity of tissues changes with frequency, so it is possible to obtain more than one thermal image for the same body. Combining these images, more detailed information about the tumor tissue can be acquired. This may increase the accuracy in diagnosis while tumor can be detected at deeper locations. Feasibility of the proposed technique is investigated with analytical and numerical simulations and experimental studies. 2-D and 3-D numerical models of the female breast are developed and feasibility work is implemented in the frequency range of 10 kHz and 800 MHz. Temporal and spatial temperature distributions are obtained at desired depths. Thermal body-phantoms are developed to simulate the healthy breast and tumor tissues in experimental studies. Thermograms of these phantoms are obtained using two different infrared cameras (microbolometer uncooled and cooled Quantum Well Infrared Photodetectors). Single and dual tumor tissues are determined using the ratio of uniform (healthy) and inhomogeneous (tumor) images. Single tumor (1 cm away from boundary) causes 55 &deg / mC temperature increase and dual tumor (2 cm away from boundary) leads to 50 &deg / mC temperature contrast. With multi-frequency current application (in the range of 10 kHz-800 MHz), the temperature contrast generated by 3.4 mm3 tumor at 9 mm depth can be detected with the state-of-the-art thermal imagers. TK Electronics 7800-8360
39	Immunomagnetic microfluidic screening system for circulating tumor cells detection and analysis Huang, Yu-Yen, active 21st century 24 February 2015 (has links) Circulating tumor cells (CTCs) are known to escape from the primary tumor site and may settle down at the distant organ to grow a second tumor. CTCs are one of causes initiating carcinoma metastasis. Detection of CTCs has been considered to be valuable for cancer management, including diagnosis, prognosis, and clinical treatment management. However, efficient isolation, enumeration, characterization, and genetic analysis of CTCs in whole-blood samples from cancer patients are very challenging due to their extremely low concentration and rare nature (per CTC in blood cells is 1:106–109). With the increasing worldwide death rate associated with cancer, there is a desperate demand for a high-sensitivity, high-throughput, and low-cost detection and separation system. My doctoral research focused on the design and fabrications of the screening system for the detection of CTCs with further analysis of captured CTCs, such as immunofluoresce staining and fluorescence in-situ hybridization (FISH). The distinct significance of this research is that the development of the computer-controlled rotational holder with a series of six inverted microfluidic chips reduced the cost by significantly reducing the consumption of magnetic carriers (25% of the consumed amount used in the commercial CellSearch® system), increasing the capture efficiency by manipulating the blood sedimentation in the microchannel, enhancing the system stability by integrating the micromagnets on the plain glass slide substrate, and achieving high throughput because of the high flow rate (2.5 mL/hr) and large screening volume (screening up to six chips in parallel with each containing 2.5 mL of blood). Immunofluorescence staining and the FISH method have been performed to prove the capability of the system. In addition, the system has been successfully applied for patient samples screening. The incorporation of micromagnets has demonstrated that micromagnets provide localized magnetic forces to scatter the target cancer cells and free nanoparticles throughout the whole channel substrate to increase the channel space usage by 13%. Four cancer cell lines, including COLO 205 (colorectal cancer), SK-BR-3 (breast cancer), MCF-7 (breast cancer), and PC3 (prostate cancer), were spiked in blood samples from healthy donors to verify high capture efficiency of the developed system. On average, over a 97% capture rate was demonstrated for all cell lines. Moreover, the developed screening system has been successfully screened over 40 patient samples, including metastatic lung cancer, breast cancer, prostate cancer, and colorectal cancer. After capture of CTCs, immunofluorescence staining was used to identified the captured cancer cells and the FISH method was performed to characterize the isolated cancer cells by studying the gene expression of CTCs from breast cancer. The proposed automated immunomagnetic microchip-based screening system shows high capture efficiency (average 97% for three spiked cell lines), high throughput (15 mL of blood sample per screening), high sensitivity, high specificity, and low nanoparticle consumption (75% less than CellSearch® system). The screening system provides great promise as a clinical tool for early cancer diagnosis, diagnosis, personalized therapy, and treatment monitoring. / text Circulating tumor cell (CTC) Microfluidic device Micromagnet Cancer detection
40	An individual patient data meta-analysis on characteristics and outcome of patients with papillary glioneuronal tumor, rosette glioneuronal tumor with neuropil-like islands and rosette forming glioneuronal tumor of the fourth ventricle Schlamann, Annika, von Bueren, André, Hagel, Christian, Zwiener, Isabella, Seidel, Clemens, Kortmann, Rolf-Dieter, Müller, Klaus 11 July 2014 (has links) (PDF) Background and Purpose: In 2007, the WHO classification of brain tumors was extended by three new entities of glioneuronal tumors: papillary glioneuronal tumor (PGNT), rosette-forming glioneuronal tumor of the fourth ventricle (RGNT) and glioneuronal tumor with neuropil-like islands (GNTNI). Focusing on clinical characteristics and outcome, the authors performed a comprehensive individual patient data (IPD) meta-analysis of the cases reported in literature until December 2012. Methods: PubMed, Embase and Web of Science were searched for peer-reviewed articles reporting on PGNT, RGNT, and GNTNI using predefined keywords. Results: 95 publications reported on 182 patients (PGNT, 71; GNTNI, 26; RGNT, 85). Median age at diagnosis was 23 years (range 4–75) for PGNT, 27 years (range 6–79) for RGNT, and 40 years (range 2–65) for GNTNI. Ninety-seven percent of PGNT and 69% of GNTNI were located in the supratentorial region, 23% of GNTNI were in the spinal cord, and 80% of RGNT were localized in the posterior fossa. Complete resection was reported in 52 PGNT (73%), 36 RGNT (42%), and 7 GNTNI (27%) patients. Eight PGNT, 3 RGNT, and 12 GNTNI patients were treated with chemo- and/or radiotherapy as the primary postoperative treatment. Follow-up data were available for 132 cases. After a median follow-up time of 1.5 years (range 0.2–25) across all patients, 1.5-year progression-free survival rates were 52±12% for GNTNI, 86±5% for PGNT, and 100% for RGNT. The 1.5-year overall-survival were 95±5%, 98±2%, and 100%, respectively. Conclusions: The clinical understanding of the three new entities of glioneuronal tumors, PGNT, RGNT and GNTNI, is currently emerging. The present meta-analysis will hopefully contribute to a delineation of their diagnostic, therapeutic, and prognostic profiles. However, the available data do not provide a solid basis to define the optimum treatment approach. Hence, a central register should be established. Zentralnervensystem Krebsdiagnostik Krebsbehandlung Metaanalyse Central nervous system cancer detection and diagnosis cancer treatment meta-analysis ddc:610

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