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悪性グリオーマに対する遺伝子治療水野, 正明, 吉田, 純, Mizuno Masaaki, Masaaki, Yoshida, Jun 10 1900 (has links)
(<特集>悪性脳腫瘍の病態と治療)
(<SPECIAL ISSUE>Pathology and Treatment of Malignant Brain Tumors)
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脳腫瘍の遺伝子治療水野, 正明, 吉田, 純, Mizuno, Masaaki, Yoshida, Jun 05 1900 (has links)
No description available.
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Enhancing Dendritic Cell Migration to Drive Antitumor ResponsesBatich, Kristen Anne January 2017 (has links)
<p>The histologic subtypes of malignant glial neoplasms range from anaplastic astrocytoma to the most deadly World Health Organization (WHO) Grade IV glioblastoma (GBM), the most common primary brain tumor in adults. Over the past 40 years, only modest advancements in the treatment of GBM tumors have been reached. Current therapies are predominantly for palliative endpoints rather than curative, although some treatment modalities have been shown to extend survival in particular cases. Patients undergoing current standard of care therapy, including surgical resection, radiation therapy, and chemotherapy, have a median survival of 12-15 months, with less than 25% of patients surviving up to two years and fewer than 10% surviving up to five years. A variety of factors contribute to standard treatment failure, including highly invasive tumor grade at the time of diagnosis, the intrinsic resistance of glioma cells to radiation therapy, the frequent impracticality of maximal tumor resection of eloquent cortical structures, and the fragile intolerance of healthy brain for cytotoxic therapies. Treatment with immunotherapy is a potential answer to the aforementioned problems, as the immune system can be harnessed and educated to license rather potent antitumor responses in a highly specific and safe fashion. One of the most promising vehicles for immunotherapy is the use of dendritic cells, which are professional antigen-presenting cells that are highly effective in the processing of foreign antigens and the education of soon-to-be activated T cells against established tumors. The work outlined in this dissertation encompasses the potential of dendritic cell therapy, the current limitations of reaching full efficacy with this platform, and the recent efforts employed to overcome such barriers. This work spans the characterization and preclinical testing of utilizing protein antigens such as tetanus-diphtheria toxoid to pre-condition the injection site prior to dendritic cell vaccination against established tumors expressing tumor-specific antigens. </p><p>Chapter 1 comprises an overview of the current standard therapies for malignant brain tumors. Chapters 2 and 3 provide a review of immunotherapy for malignant gliomas in the setting of preclinical animal models and discuss issues relevant to the efficacy of dendritic cell vaccines for targeting of GBM. Chapters 4 provides the rationale, methodology, and results of research to improve the lymph node homing and immunogenicity of tumor antigen-specific dendritic cell vaccines in mouse models and in patients with newly diagnosed GBM. Chapter 5 delineates the interactions discovered through efforts in Chapter 4 that comprise protein antigen-specific CD4+ T cell responses to induced chemokines and how these interactions result in increased dendritic cell migration and antitumor responses. Lastly, Chapter 6 discusses the future utility of migration of DC vaccines as a surrogate for antitumor responses and clinical outcomes. </p><p>This dissertation comprises original research as well as figures and illustrations from previously published material used to exemplify distinct concepts in immunotherapy for cancer. These published examples were reproduced with permission in accordance with journal and publisher policies described in the Appendix. </p><p>In summary, this work 1) identifies inefficient lymph node homing of peripherally administered dendritic cells as one of the glaring barriers to effective dendritic cell immunotherapy, 2) provides answers to overcome this limitation with the use of readily available pre-conditioning recall antigens, 3) has opened up a new line of investigation for interaction between recall responses and host chemokines to activate immune responses against a separate antigen, and 4) provides future prospects of utilizing chemokines as adjuvants for additional immunotherapies targeting aggressive tumors. Together, these studies hold great promise to improve the responses in patients with GBM.</p> / Dissertation
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Treatment outcomes on malignant gliomas using oncolytic virusesTehranipour, Pegah January 2020 (has links)
Purpose: The objective of this thesis is to evaluate clinical studies that have used oncolytic viruses as treatment and to compare their treatment-outcomes on patients with malignant glioma. Method: This thesis is a systematic literature review where PubMed has been used as the database for data collection. Two searches were done using the search phrases oncolytic virus AND Glioma and oncolytic virus AND brain tumor. Several of the articles showed up multiple times in different searches. After having applied the inclusion criteria, ten of the seventeen articles were removed. Remaining were seven articles used for the thesis. Results: The study conducted by Forsythe et al., using reovirus showed the median overall survival (OS) to be 21 weeks and the median time to progression (TTP) was 4.3 weeks. The study conducted by Kicielinski et al., using REOLYSIN showed the median OS to be 140 days. Median TTP was 61 days. The study conducted by Geletneky et al., 2017 was the first dose-escalating clinical trial for the use of H-1 parvovirus. The median TTP was 111 days and the median OS was 464 days. The study conducted by Lang et al., DNX-2401 was used and in group A the median OS time was 9.5 months. In group B the median OS in the group was 13 months. In another example of an oncolytic adenovirus is ONYX-015, the median TTP after treatment for all patients was 46 days. The median OS for patients diagnosed with glioblastoma multiforme was 4.9 months and for patients with anaplastic astrocytoma and anaplastic oligodendroglioma was 11.3 months across. In a study conducted by Freeman et al. using newcastle disease virus, the OS ranged from 3-66 weeks from the start of treatment and TTP ranged from 2-53 weeks. The study conducted by Markert et al., the median OS from treatment with G207 was 7.5 months. The median TTP was around 2.5 months. Conclusion: Oncolytic viruses are promising agents for treatment against malignant gliomas. No definite outcomes of the treatment could be concluded, however, the median survival was extended in certain cases. The patients tolerated the oncolytic viruses well with no adverse effects correlated with the treatments. There are currently more virus vectors being tested as new developments are needed in this field.
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The Oncogenic Role and the Prognostic Value Of Notch3 Gene In Human Malignant GliomaAlqudah, Mohammad Ali Yousef 01 July 2013 (has links)
Malignant glioma have poor prognosis resulting mainly from high level of cell proliferation and invasion and resistance to conventional therapy. Identification of novel targets that are critical elements in gliomagenesis may help improve therapeutic outcome. Using genome-wide explorations of a comprehensive glioma specimen population, we identified whole gain of chromosome 19 as one of the major chromosomal aberrations in high grade glioma that correlates to patients' outcomes. Our analysis revealed for the first time NOTCH3 as one of the most significant gene amplifications mapped to chromosome 19. This amplification is associated with worse outcome compared to tumors with non-amplified locus. NOTCH signaling pathway is essential for cell proliferation, stem cell maintenance and differentiation and its deregulation has been reported in several human cancers. NOTCHs are key positive regulators of cell-cell interactions, angiogenesis, cell adhesion and stem cell niche development which have been shown to play critical roles in gliomagenesis and glioma drug resistance. Our objective is to determine NOTCH3 molecular roles in glioma pathogenesis and aggressiveness. Here we show for the first time that NOTCH3 plays a role in glioma cell proliferation, cell migration, invasion and apoptosis. We also found a NOTCH3 glioma addiction phenomenon. Therefore, our study uncovers, for the first time, the prognostic value and the oncogenic function of NOTCH3 in gliomagenesis and supports NOTCH3 as a promising target of therapy in high grade glioma. Our studies allow the identification of a subset of population that may benefit from GSI-based therapies. This may lead to the design of novel strategies to improve therapeutic outcome of patients with glioma by establishing medical and scientific basis for personalized medicine.
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Diffusion-weighted Imaging (DWI) und Diffusion-tensor Imaging (DTI) zur Analyse möglicher Ausbreitungswege/-formen von malignen Gliomen / Diffusion weighted imaging (DWI) and diffusion tensor imaging (DTI) in the analysis of possible pathways and patterns of infiltration of malignant gliomaGoldmann, Torben 04 June 2013 (has links)
No description available.
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A descriptive analysis of end-of-life discussions for high-grade glioma patients / 悪性神経膠腫患者のEnd of Life Discussionに関する記述的研究Chikada, Ai 24 May 2021 (has links)
京都大学 / 新制・課程博士 / 博士(人間健康科学) / 甲第23385号 / 人健博第92号 / 新制||人健||6(附属図書館) / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 田村 恵子, 教授 稲富 宏之, 教授 溝脇 尚志 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM
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Irreversible Electroporation for the Treatment of Aggressive High-Grade GliomaGarcia, Paulo A. 21 December 2010 (has links)
Malignant gliomas (MG), most notably glioblastoma multiforme (GBM), are among the most aggressive of all malignancies. High-grade variants of this type of brain cancer are generally considered incurable with singular or multimodal therapies. Many patients with GBM die within one year of diagnosis, and the 5-year survival rate in people is approximately 10%. Despite extensive research in diagnostic and therapeutic technologies, very few developments have emerged that significantly improve survival over the last seven decades.
Irreversible electroporation (IRE) is a new non-thermal focal tissue ablation technique that uses low-energy electric pulses to destabilize cell membranes, thus achieving tissue death. The procedure is minimally invasive and is performed through small electrodes inserted into the tissue with treatment duration of about one minute. The pulses create an electric field that induces an increase in the resting transmembrane potential (TMP) of the cells in the tissue. The induced increase in the TMP is dependent on the electric pulse parameters. Depending on the magnitude of the induced TMP the electric pulses can have no effect, transiently increase membrane permeability or cause spontaneous death.
In this dissertation we hypothesize that irreversible electroporation is capable of ablating normal (gray and white matter) and pathological (MG and/or GBM) brain tissue in a highly focused non-thermal manner that is modulated through pulse parameters and electrode configuration. Through a comprehensive experimental and numerical investigation, we tested and attained results strongly supporting our hypothesis. Specifically, we developed numerical models that were capable of simulating an entire IRE treatment protocol and would take into account pulse parameters (e.g. duration, frequency, repetition rate and strength) in addition to the dynamic changes in tissue electrical conductivity due to electroporation and joule heating, as well as biologically relevant processes such as blood perfusion and metabolic heat. We also provided a method to isolate the IRE effects from undesired thermal damage in models that were validated with real-time temperature measurements during the delivery of the pulses. Finally we outlined a procedure to use 3D volumetric reconstructions of IRE lesions using patient specific MRI scans in conjunction with the models described for establishing field thresholds or performing treatment planning prior to the surgical procedure; thus supplying the readers with the tools and understanding necessary to design appropriate treatment protocols for their specific application.
Experimentally we presented the first systematic in vivo study of IRE in normal canine brain and the multimodal treatment of a canine MG patient. We confirmed that the procedure can be applied safely in the brain and was well tolerated clinically. The lesions created with IRE were sub-millimeter in resolution and we achieved 75% tumor volume reduction within 3 days post-IRE in the patient. In addition to the sharp delineation between necrotic and normal brain, the treatments spared the major blood vessels, making it appropriate for treatment of tumors adjacent to, or enveloping critical vascular structures. We believe that irreversible electroporation will play a key role in the treatment of intracranial disorders including malignant brain cancer in which the intent is to focally kill undesired tissue while minimizing damage to surrounding healthy tissue. / Ph. D.
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Advancements in the Treatment of Malignant Gliomas and Other Intracranial Disorders With Electroporation-Based TherapiesLorenzo, Melvin Florencio 19 April 2021 (has links)
The most common and aggressive malignant brain tumor, glioblastoma (GBM), demonstrates on average a 5-year survival rate of only 6.8%. Difficulties arising in the treatment of GBM include the inability of large molecular agents to permeate through the blood-brain barrier (BBB); migration of highly invasive GBM cells beyond the solid tumor margin; and gross, macroscopic intratumor heterogeneity. These characteristics complicate treatment of GBM with standard of care, resulting in abysmal prognosis. Electroporation-based therapies have emerged as attractive alternates to standard of care, demonstrating favorable outcomes in a variety of tumors. Notably, irreversible electroporation (IRE) has been used for BBB disruption and nonthermal ablation of intracranial tumor tissues. Despite promising results, IRE can cause unintended muscle contractions and is susceptible to electrical heterogeneities. Second generation High-frequency IRE (H-FIRE) utilizes bursts of bipolar pulsed electric fields on the order of the cell charging time constant (~1 μs) to ablate tissue while reducing nerve excitation, muscle contraction, and is far less prone to differences in electrical heterogeneities.
Throughout my dissertation, I discuss investigations of H-FIRE for the treatment of malignant gliomas and other intracranial disorders. To advance the versatility, usability, and understanding of H-FIRE for intracranial applications, my PhD thesis focuses on: (1) characterizing H-FIRE-mediated BBB disruption effects in an in vivo healthy rodent model; (2) the creation of a novel, real-time impedance spectroscopy technique (Fourier Analysis SpecTroscopy, FAST) using waveforms compatible with existing H-FIRE pulse generators; (3) development of FAST as an in situ technique to monitor ablation growth and to determine patient-specific ablation endpoints; (4) conducting a preliminary efficacy study of H-FIRE ablation in an orthotopic F98 rodent glioma model; and (5) establishing the feasibility of MRI-guided H-FIRE for the ablation malignant gliomas in a spontaneous canine glioma model. The culmination of this thesis advances our understanding of H-FIRE in intracranial tissues, as well as develops a novel, intraoperative impedance spectroscopy technique towards determining patient-specific ablation endpoints for intracranial H-FIRE procedures. / Doctor of Philosophy / The most aggressive malignant brain tumor, glioblastoma (GBM), demonstrates on average a 5-year survival rate of only 6.8%. Difficulties arising in the treatment of GBM include the inability of chemotherapy agents to diffuse into brain tumor tissue as these molecular are unable to pass the so-called blood-brain barrier (BBB). This tumor tissue also presents with cells with the propensity to invade healthy tissue, to the point where diagnostic scans are unable to capture this migration. These characteristics complicate treatment of GBM with standard of care, resulting in abysmal prognosis. Electroporation-based therapies have emerged as attractive alternates to standard of care, demonstrating favorable outcomes in a variety of tumors. For instance, irreversible electroporation (IRE) has been used to successfully treat tumors in the prostate, liver, kidney, and pancreas. Second generation High-frequency IRE (H-FIRE) may possess even greater antitumor qualities and this is the focus of my dissertation.
Throughout my dissertation, I discuss investigations of H-FIRE with applications to treat malignant gliomas and other intracranial disorders. My PhD thesis focuses on: (1) characterizing H-FIRE effects for enhanced drug delivery to the brain; (2) the creation of a new, real-time electrical impedance spectroscopy technique (Fourier Analysis SpecTroscopy, FAST) using waveforms compatible with existing H-FIRE pulse generators; (3) development of FAST as a technique to determine H-FIRE treatment endpoints; (4) conducting a preliminary efficacy study of H-FIRE to ablate rodent glioma tumors; and (5) establishing the feasibility of MRI-guided H-FIRE for the ablation malignant gliomas in a spontaneous canine glioma model. The culmination of this thesis advances our understanding of H-FIRE in intracranial tissues, as well as develops a new impedance spectroscopy technique to be used in determining patient-specific ablation endpoints for intracranial H-FIRE procedures.
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Design and Validation of Medical Devices for Photothermally Augmented TreatmentsAndriani, Rudy Thomas 15 September 2014 (has links)
*1-Dimensional Advective-Diffusion Model in Porous Media
Infusion of therapeutic agents into tissue is makes use of two mass transport modes: advective transport, and molecular diffusion.
Bulk infusion into a 0.6% wt agarose phantom was modeled as an infinite, homogenous, and isotropic porous medium saturated with the same solvent used in the infused dye tracer. The source is assumed to be spherical and isotropic with constant flow rate and concentration. The Peclet numberdecreases with power function Pe = 15762t0.337 due to the decrease in mean dye-front pore velocity as V goes to Vfinal.
Diffusive mass transport does not become significant during any relevent time period.
*Arborizing Fiberoptic Microneedle Catheter
We have developed an arborizing catheter that allows multiple slender fused-silica CED cannulae to be deployed within a target volume of the brain via a single needle tract, and tested it in a widely accepted tissue phantom.
The arborizing catheter was constructed by bonding and encapsulating seven slender PEEK tubes in a radially symmetric bundle with a progressive helical angle along the length, then grinding a conicle tip where the helical angle is greatest.
The catheter was tested by casting 0.6% wt agarose around the device with all needles deployed to a tip-to-tip distance of 4 mm. Phantom temperature was maintained at 26 ± 2°C. 5% wt Indigo Carmine dye was infused at a rate of 0.3 uL/min/needle for 4 hours.
N=4 infusions showed a Vd/Vi of 139.774, with a standard deviation of 45.01. This is an order of magnitude greater than single-needle infusions under similar conditions [45]. The arborizer showed the additional benefit of arresting reflux propagating up the lengths of individual needles, which has historically been a weakness of single-needle CED catheter designs.
*In Vivo Co-Delivery of Single Walled Carbon Nano-horns and Laser Light to Treat Human Transitional Cell Carcinoma of the Urinary Bladder in a Rodent Model
Using a rodent model we explored a treatment method for Transitional Cell Carcinoma (TCC) in the urinary bladder in which Single Walled Carbon Nanohorn (SWNH) solution and 1064 nm laser light are delivered into tumorous tissue via a co-delivery Fiberoptic Microneedle Device (FMD).
Preliminary treatment parameters were determined by injecting SWNH solutions with concentrations of 0 mg/mL, 0.17 mg/mL, or 0.255 mg/mL into ex vivo porcine skin and irradiating each for three minutes at laser powers of 500 mW, or 1000 mW. The combination with the greatest temperature increase without burning the tissue, 0.17 mg/mL at 1000 mW, was selected for the in vivo treatment.
TCC tumors were induced in a rodent model by injecting a solution of 106 AY27 urothelial carcinoma cells into the lateral aspect of the left hind leg of young, female F344 rats. When tumors reached 5-10 mm3, rats were anesthitized and treated. SWNH solution was injected directly into the tumor and irradiated until the target temperature of 60degC was achieved. The rats were then recovered from anestesia and monitored for 7-14 days, at which point they were humanely sacrificed, and the tumors prepared for histological examination.
Histological assessment of areas of FMD treatment correlated well with gross morphological appearance. Foci of tumor necrosis showed sharp (1-2 mm) delineation from areas of viable tumor (not treated) and normal tissue.
We believe we have demonstrated the feasibility of using the FMD for treatment of urothelial carcinoma using an animal model of this disease, and are encouraged to continue development of this treatment and testing in larger animal models. / Master of Science
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