Assuntos
Orçamentos/legislação & jurisprudência , Governo Federal , Apoio à Pesquisa como Assunto/legislação & jurisprudência , Ciência/economia , Ciência/legislação & jurisprudência , Brasil , Seleção de Pessoal , Pesquisadores/normas , Pesquisadores/provisão & distribuição , Apoio à Pesquisa como Assunto/economia , Ciência/organização & administração , Síncrotrons/economiaRESUMO
The high peak brilliance and femtosecond pulse duration of X-ray free-electron lasers (XFELs) provide new scientific opportunities for experiments in physics, chemistry and biology. In structural biology, one of the major applications is serial femtosecond crystallography. The intense XFEL pulse results in the destruction of any exposed microcrystal, making serial data collection mandatory. This requires a high-throughput serial approach to sample delivery. To this end, a number of such sample-delivery techniques have been developed, some of which have been ported to synchrotron sources, where they allow convenient low-dose data collection at room temperature. Here, the current sample-delivery techniques used at XFEL and synchrotron sources are reviewed, with an emphasis on liquid injection and high-viscosity extrusion, including their application for time-resolved experiments. The challenges associated with sample delivery at megahertz repetition-rate XFELs are also outlined.
Assuntos
Cristalografia por Raios X/instrumentação , Elétrons , Análise de Injeção de Fluxo/instrumentação , Lasers , Síncrotrons/instrumentação , Animais , Cristalografia por Raios X/economia , Humanos , Proteínas/química , Síncrotrons/economia , Fatores de Tempo , ViscosidadeRESUMO
Minibeam radiation therapy (MBRT) is an innovative synchrotron radiotherapy technique able to shift the normal tissue complication probability curves to significantly higher doses. However, its exploration was hindered due to the limited and expensive beamtime at synchrotrons. The aim of this work was to develop a cost-effective equipment to perform systematic radiobiological studies in view of MBRT. Tumor control for various tumor entities will be addressable as well as studies to unravel the distinct biological mechanisms involved in normal and tumor tissues responses when applying MBRT. With that aim, a series of modifications of a small animal irradiator were performed to make it suitable for MBRT experiments. In addition, the brains of two groups of rats were irradiated. Half of the animals received a standard irradiation, the other half, MBRT. The animals were followed-up for 6.5 months. Substantial brain damage was observed in the group receiving standard RT, in contrast to the MBRT group, where no significant lesions were observed. This work proves the feasibility of the transfer of MBRT outside synchrotron sources towards a small animal irradiator.
Assuntos
Neoplasias Encefálicas/patologia , Encéfalo/patologia , Análise Custo-Benefício , Imagens de Fantasmas , Síncrotrons/economia , Síncrotrons/instrumentação , Animais , Encéfalo/efeitos da radiação , Neoplasias Encefálicas/radioterapia , Dosagem Radioterapêutica , Planejamento da Radioterapia Assistida por Computador , RatosAssuntos
Orçamentos/legislação & jurisprudência , Governo Federal , Pesquisadores/economia , Apoio à Pesquisa como Assunto/economia , Apoio à Pesquisa como Assunto/legislação & jurisprudência , Pesquisa/economia , Academias e Institutos/economia , Brasil , Organização do Financiamento/legislação & jurisprudência , Organização do Financiamento/organização & administração , Laboratórios/economia , Pesquisa/legislação & jurisprudência , Síncrotrons/economiaAssuntos
Cooperação Internacional , Síncrotrons , Raios Infravermelhos , Jordânia , Oriente Médio , Múmias , Síncrotrons/economia , Raios XRESUMO
This paper provides a model for planning a new proton therapy center based on clinical data, referral pattern, beam utilization and technical considerations. The patient-specific data for the depth of targets from skin in each beam angle were reviewed at our center providing megavoltage photon external beam and proton beam therapy respectively. Further, data on insurance providers, disease sites, treatment depths, snout size and the beam angle utilization from the patients treated at our proton facility were collected and analyzed for their utilization and their impact on the facility cost. The most common disease sites treated at our center are head and neck, brain, sarcoma and pediatric malignancies. From this analysis, it is shown that the tumor depth from skin surface has a bimodal distribution (peak at 12 and 26 cm) that has significant impact on the maximum proton energy, requiring the energy in the range of 130-230 MeV. The choice of beam angles also showed a distinct pattern: mainly at 90° and 270°; this indicates that the number of gantries may be minimized. Snout usage data showed that 70% of the patients are treated with 10 cm snouts. The cost of proton beam therapy depends largely on the type of machine, maximum beam energy and the choice of gantry versus fixed beam line. Our study indicates that for a 4-room center, only two gantry rooms could be needed at the present pattern of the patient cohorts, thus significantly reducing the initial capital cost. In the USA, 95% and 100% of patients can be treated with 200 and 230 MeV proton beam respectively. Use of multi-leaf collimators and pencil beam scanning may further reduce the operational cost of the facility.