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Harnessing the Heat Shock Response to Raise Refined Therapeutic OutcomesHall, Alexis K. 02 May 2008 (has links)
Activated Heat Shock Transcription Factor 1 (HSF1) has received attention in recent literature as a therapeutic effector in diseases of protein misfolding, as an immune modulating adjuvant in tumor regression, and as a trigger for gene therapy transcription. In its normal function, activated HSF1 enhances heat shock protein (Hsp) expression when additional molecular chaperoning is required (i.e., in situations of proteotoxic stress, including thermal stress) in a process known as the heat shock (HS) response. Thus, HSF1 acts as an environmental sensor, and a harness based on the biology of this capability enables transcription of genes for engineered purposes. The hypothesis of this thesis is that a harness of the heat shock response, when paired with a therapeutic mechanism, will refine novel therapies. Extensions to the concept of deliberately activating HSF1's normal functions for therapeutic purposes are examined through in vitro trials and in vivo preliminary studies that feature the use of HSF1 as a regulator of therapy. Successful in vitro work translated to pioneering preclinical studies, launched at the University of Florida's Center for Environmental and Human Toxicology. Collaboration supported the development of an innovative project to treat solid tumors using a recombinant virus system. The system was designed to facilitate intratumoral delivery of a previously characterized molecular switch, which was newly engineered to control cytotoxic gene transcription that produced dramatic consequences in cells of human origin. Central to the targeting of the in vivo therapy, is a transient, initial trigger: a thermal dose, delivered to solid tumors, which localizes HSF1 activation (a constitutively active mouse HSF1 construct was also produced to aid clarification of physiological consequences associated with deliberately upregulating HSF1 activity in vivo). Gene transcription was expected to ensue to both cause and sustain tumor regression through other regulatory elements of the molecular switch. Results demonstrated practical potential to achieve a therapeutic outcome of solid tumor regression and define contemporary challenges that continuing research directions (e.g.: production of additional viral vectors, an improved animal model, and a refined heat system) now confront in order to target and safely regulate even more potent, novel therapeutic agents.
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Microbeam Irradiation as a Simultaneously Integrated Boost in a Conventional Whole-Brain Radiotherapy ProtocolJaekel, Felix, Bräuer-Krisch, Elke, Bartzsch, Stefan, Laissue, Jean, Blattmann, Hans, Scholz, Marten, Soloviova, Julia, Hildebrandt, Guido, Schültke, Elisabeth 02 February 2024 (has links)
Microbeam radiotherapy (MRT), an experimental high-dose rate concept with spatial
fractionation at the micrometre range, has shown a high therapeutic potential as well as good
preservation of normal tissue function in pre-clinical studies. We investigated the suitability of MRT
as a simultaneously integrated boost (SIB) in conventional whole-brain irradiation (WBRT). A 174 Gy
MRT SIB was administered with an array of quasi-parallel, 50 m wide microbeams spaced at a
centre-to-centre distance of 400 m either on the first or last day of a 5 4 Gy radiotherapy schedule
in healthy adult C57 BL/6J mice and in F98 glioma cell cultures. The animals were observed for signs
of intracranial pressure and focal neurologic signs. Colony counts were conducted in F98 glioma cell
cultures. No signs of acute adverse effects were observed in any of the irradiated animals within
3 days after the last irradiation fraction. The tumoricidal effect on F98 cell in vitro was higher when
the MRT boost was delivered on the first day of the irradiation course, as opposed to the last day.
Therefore, the MRT SIB should be integrated into a clinical radiotherapy schedule as early as possible.
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