Estudio del armazón arquitectónico y del sistema vascular de los tumores neuroblásticos

Los pacientes con tumores neuroblásticos presentan una evolución clínica heterogénea, desde la regresión espontánea hasta una alta propensión para la diseminación metastática generalizada. Aunque la aplicación de una clasificación de riesgo pre-tratamiento bien definida tiene un papel central en la mejora de la supervivencia durante los últimos años, han de llevarse a cabo más avances para mejorar la superviencia de los pacientes en general y específicamente el subgrupo de pacientes de alto riesgo. El estudio morfológico del tejido tumoral está contribuyendo a dicha mejora. La categoría histológica o el porcentaje de estroma tumoral, así como el grado de diferenciación de las células neuroblásticas, determinadas por el patólogo con el microscopio óptico, son factores con un papel importante en el diagnóstico y el pronóstico de los pacientes. Actualmente, dada la relevancia de la matriz extracelular tumoral en la biotensegridad y la mecanotransducción, su arquitectura y la topología de sus elementos, así como su interacción están siendo cada vez más considerados. Su cuantificación y caracterización con técnicas de imagen microscópicas empiezan a ser utilizadas. Nuestra hipótesis es que el destino de una célula tumoral neuroblástica es complejo y entre otros factores, está determinado por las características de un grupo de elementos estructurales no celulares de la matriz extracelular. Además pensamos que aplicando los patrones derivados del análisis morfométrico de estos elementos y asociandolos al impacto de los factores pronósticos conocidos, se mejorará la supervivencia de los pacientes. Nuestro objetivo es el desarrollo de técnicas morfométricas para caracterizar distintos elementos del andamiaje de la matriz extracelular y de la vascularización con el fin de encontrar usos potenciales como nuevos marcadores con valor pronóstico para mejorar la estratificación de los pacientes, o como dianas terapéuticas para ser capaces de remodelar los elementos aberrantes del andamiaje tisular, incluyendo la microvascularización. Hemos construido 19 micromatrices de tejido incluyendo más de 500 neuroblastomas, que fueron teñidos con alzul alcián a pH 2,5, Gomori, tricrómico de Masson, orceína y anti-CD31 para glicosaminoglicanos, fibras de reticulina, fibras de colágeno tipo I, fibras elásticas y vasos sanguíneos, respectivamente. Las laminillas fueron digitalizadas con un escáner de preparaciones y distintos algoritmos de análisis de imagen fueron diseñados o personalizados para detectar y caracterizar la cantidad, el tamaño y la forma de los distintos elementos estudiados de la matriz extracelular. Estos parámetros se relacionaron con los distintos subgrupos de neuroblastoma, teniendo en cuenta varias características clínicas, histopatológicas y genéticas. Los resultados obtenidos mostraron que las fibras de reticulina eran los componentes mayoritarios del andamiaje fibroso y que la abundancia y arquitectura de la microvascularización era relevante para el pronóstico de los niños con neuroblastoma. Una matriz extracelular rígida y poco porosa con vasos sanguíneos con luces irregulares se detectó principalmente en tumores pertenecientes a pacientes con pronóstico desfavorable. Un subgrupo de la cohorte de alto riesgo con muy mala supervivencia pudo ser definido por variables morfométricas de las fibras de reticulina y de los vasos sanguíneos. Concretamente, las muestras con un mayores áreas ocupadas tanto por fibras de reticulina formando grandes redes entrecruzadas, ramificadas y de organización compleja, como por vasos sanguíneos, junto con capilares y vasos tipo sinusoide de forma irregular y vénulas y arteriolas dilatas, estaban asociadas a un pronóstico muy desfavorable. En esta cohorte, las células con amplificación del gen MYCN conllevaron cambios topológicos detectables en relación a las fibras de reticulina y los vasos sanguíneos. Podemos concluir que es possible y conveniente cuantificar la sustancia fundamental, caracterizar el andamiaje fibroso y el sistema vascular de los tumors neuroblásticos gracias al análisis morfométrico de imágenes microscópicas. Algunas de las características morfométricas relaciondas con los distintos elementos de la matriz extracelular estudiados podrían ser usadas como ayuda diagnóstica del grupo de pacientes con riesgo ultra alto, tras estudiar una mayor cohorte. Los resultados obtenidos sugieren la necesidad de realizar trabajos multidisciplinarios para integrar de estos estudios a nivel internacional y que la información morfométrica de los elementos de la matriz extracelular, incluyendo el sistema vascular, pueda ser utilizada para una terapia basada en la mecanotransducción.Neuroblastic tumor patients present an heterogeneous clinical evolution, from spontaneous regression to a high propensity for widespread metastatic dissemination. Although the application of a well-defined pre-treatment risk classification plays a central role in the improvement of survival during the last years, more efforts must be done to improve patient’s survival in general and specifically in the subgroup of high risk patients. The morphological study of the tumoral tissue is contributing to such improvement. The histological category or the percentage of tumoral stroma, as well as the degree of differentiation of neuroblastic cells, evaluated by the pathologist with light microscopy, are factors that play a role in the diagnosis and prognosis of the patients. Given the role of tumoral extracellular matrix in biotensegrity and mechanotransduction, its architecture and the topology of its elements, as well as their interaction are being increasingly considered. Its quantification and characterization with microscopic image techniques start to be used. We hypothesize that the destiny of a neuroblastic tumor cell is complex and, is in part directed by characteristics of a set of non-cellular extracellular matrix structural elements. Additionally, we think that the application of the patterns derived from the morphometric analysis of such elements and their association with the impact of the known prognostic factors, patient’s survival will be improved. We aim to develop morphometric techniques to characterize different extracellular matrix scaffolding and vascular elements to find out potential uses as new prognostic markers for a better pre-treatment stratification of the patients or as therapeutic targets to be able to remodel the aberrant elements of the tissue scaffolding, including microvascularization. We constructed 19 tissue microarrays including more than 500 neuroblastomas which were stained with alcian blue pH 2.5, Gomori, Masson’s trichrome, orcein and anti-CD31 for glycosaminoglycans, reticulin fibers, collagen type I fibers, elastic fibers and blood vessels, respectively. The slides were digitized with a whole-slide scanner and different image-analysis algorithms were designed or customized to specifically detect and characterize the amount, the size and the shape of the different extracellular matrix elements studied. These parameters were related to different neuroblastoma subgroups, taking into account several clinical, histopathological and genetic features. The results obtained showed that reticulin fibers were the main components of the fibrous scaffolding and that microvasculature amount and architecture were relevant in the prognosis of neuroblastoma patients. A stiff and poorly porous extracellular matrix with irregularly-shaped vascular lumens was mainly detected in tumors belonging to patients with unfavorable prognosis. A subgroup of the high risk cohort with very poor survival could be defined by morphometric variables of reticulin fibers and blood vessels. Specificallly, those samples with high stained areas occupied by reticulin fibers forming large, crosslinking, branching and disorganized networks and by blood vessels, as well as with irregularly-shaped capillaries and sinusoid-like vessels and dilated venules, presented a very unfavorable survival. In this cohort, cells with MYCN gene amplification led to detectable topological changes regarding reticulin fibers and bood vessels. We can conclude that it is possible and convenient to quantify the fundamental substance and characterize the architecture of the fibrous scaffolding and the vascular system of neuroblastic tumors by means of the morphometric analysis of microscopic images. Some of the morphometric features related to the different extracellular matrix elements studied could be used as a diagnostic support for the ultra-high risk group of patients, after studying a larger cohort. The obtained results suggest the need of developing multidisciplinary efforts for an international integration of these studies, and that the morphometric information of the elements of the extracellular matrix, including the vascular system, could be used for a therapy based on mechanotransduction

A multi-technique hierarchical X-ray phase-based approach for the characterization and quantification of the effects of novel radiotherapies

Cancer is the first or second leading cause of premature deaths worldwide with an overall rapidly growing burden. Standard cancer therapies include surgery, chemotherapy and radiotherapy (RT) and often a combination of the three is applied to improve the probability of tumour control. Standard therapy protocols have been established for many types of cancers and new approaches are under study especially for treating radio-resistant tumours associated to an overall poor prognosis, as for brain and lung cancers. Follow up techniques able to monitor and investigate the effects of therapies are important for surveying the efficacy of conventionally applied treatments and are key for accessing the curing capabilities and the onset of acute and late adverse effects of new therapies. In this framework, this doctoral Thesis proposes the X-ray Phase Contrast Im-aging - Computed Tomography (XPCI-CT) technique as an imaging-based tool to study and quantify the effects of novel RTs, namely Microbeam and Minibeam Radiation therapy (MRT and MB), and to compare them to the standard Broad Beam (BB) induced effects on brain and lungs. MRT and MB are novel radiotherapies that deliver an array of spatially fractionated X-ray beamlets issued from a synchrotron radiation source, with widths of tens or hundreds of micrometres, respectively. MRT and MB exploit the so-called dose-volume effect: hundreds of Grays are well tolerated by healthy tissues and show a preferential effect on tumour cells and vasculature when delivered in a micrometric sized micro-plane, while induce lethal effects if applied over larger uniform irradiation fields. Such highly collimated X-ray beams need a high-resolution and a full-organ approach that can visualize, with high sensitivity, the effects of the treatment along and outside the beamlets path. XPCI-CT is here suggested and proven as a powerful imaging technique able to determine and quantify the effects of the radiation on normal and tumour-bearing tissues. Moreover, it is shown as an effective technique to complement, with 3D information, the histology findings in the follow-up of the RT treatments. Using a multi-scale and multi-technique X-ray-based approach, I have visualized and analysed the effects of RT delivery on healthy and glioblastoma multiforme (GBM)-bearing rat brains as well as on healthy rat lungs. Ex-vivo XPCI-CT datasets acquired with isotropic voxel sizes in the range 3.253 – 0.653 μm3 could distinguish, with high sensitivity, the idiopathic effects of MRT, MB and BB therapies. Histology, immunohistochemistry, Small- and Wide-Angle X-ray Scattering and X-ray Fluorescence experiments were also carried out to accurately interpret and complement the XPCI-CT findings as well as to obtain a detailed structural and chemical characterization of the detected pathological features. Overall, this multi-technique approach could detect: i) a different radio-sensitivity for the MRT-treated brain areas; ii) Ca and Fe deposits, hydroxyapatite crystals formation; iii) extended and isolated fibrotic contents. Full-organ XPCI-CT datasets allowed for the quantification of tumour and mi-crocalcifications’ volumes in treated brains and the amount of scarring tissue in irradiated lungs. Herein, the role of XPCI-CT as a 3D virtual histology technique for the follow-up of ex-vivo RT effects has been assessed as a complementary method for an accurate volumetric investigation of normal and pathological states in brains and lungs, in a small animal model. Moreover, the technique is proposed as a guidance and auxiliary tool for conventional histology, which is the gold standard for pathological evaluations, owing to its 3D capabilities and the possibility of virtually navigating within samples. This puts a landmark for XPCI-CT inclusion in the pre-clinical studies pipeline and for advancing towards in-vivo XPCI-CT imaging of treated organs.Weltweit gilt Krebs als häufigste bzw. zweithäufigste Ursache eines zu früh erfolgenden Todes, wobei die Zahlen rasch ansteigen. Standardmäßige Krebstherapien umfassen chirurgische Eingriffe, Chemotherapie und Strahlentherapie (radiotherapy, RT); oft kommt eine Kombination daraus zur Anwendung, um die Wahrscheinlichkeit der Tumorkontrolle zu erhöhen. Es wurden Standardtherapieprotokolle für zahlreiche Krebsarten eingerichtet und es wird vor allem in der Behandlung von strahlenresistenten Tumoren mit allgemein schlechter Prognose wie bei Hirn- und Lungentumoren an neuen Ansätzen geforscht. Nachverfolgungstechniken, welche die Auswirkungen von Therapien überwachen und ermitteln, sind zur Überwachung der Wirksamkeit herkömmlich angewandter Behandlungen wichtig und auch maßgeblich am Zugang zu den Fähigkeiten zur Heilung sowie zum Auftreten akuter und verzögerter Nebenwirkungen neuer Therapien beteiligt. In diesem Rahmenwerk unterbreitet diese Doktorarbeit die Technik der Röntgen-Phasenkontrast-Bildgebung über Computertomographie (X-ray Phase Contrast Imaging - Computed Tomography, XPCI‑CT) als bildverarbeitungs-basiertes Tool zur Untersuchung und Quantifizierung der Auswirkungen neuartiger Strahlentherapien, nämlich der Mikrobeam- und Minibeam-Strahlentherapie (MRT und MB), sowie zum Vergleich derselben mit den herkömmlichen durch Breitstrahlen (Broad Beam, BB) erzielten Auswirkungen auf Gehirn und Lunge. MRT und MB sind neuartige Strahlentherapien, die ein Array räumlich aufgeteilter Röntgenstrahlenbeamlets aus einer synchrotronen Strahlenquelle mit einer Breite von Zehnteln bzw. Hundersteln Mikrometern abgeben. MRT und MB nutzen den sogenannten Dosis-Volumen-Effekt: Hunderte Gray werden von gesundem Gewebe gut vertragen und wirken bei der Abgabe in einer Mikroebene im Mikrometerbereich vorrangig auf Tumorzellen und Blutgefäße, während sie bei einer Anwendung über größere gleichförmige Strahlungsfelder letale Auswirkungen aufweisen. Solche hoch kollimierten Röntgenstrahlen erfordern eine hohe Auflösung und einen Zugang zum gesamten Organ, bei dem die Auswirkungen der Behandlung entlang und außerhalb der Beamletpfade mit hoher Empfindlichkeit visualisiert werden können. Hier empfiehlt und bewährt sich die XPCI‑CT als leistungsstarke Bildverarbeitungstechnik, welche die Auswirkungen der Strahlung auf normale und tumortragende Gewebe feststellen und quantifizieren kann. Außerdem hat sich gezeigt, dass sie durch 3‑D-Informationen eine effektive Technik zur Ergänzung der histologischen Erkenntnisse in der Nachverfolgung der Strahlenbehandlung ist. Anhand eines mehrstufigen und multitechnischen röntgenbasierten Ansatzes habe ich die Auswirkungen der Strahlentherapie auf gesunde und von Glioblastomen (GBM) befallene Rattenhirne sowie auf gesunde Rattenlungen visualisiert und analysiert. Mit isotropen Voxelgrößen im Bereich von 3,53 bis 0,653 μm3 erfasste Ex-vivo-XPCI-CT-Datensätze konnten die idiopathischen Auswirkungen der MRT-, MB- und BB‑Behandlung mit hoher Empfindlichkeit unterscheiden. Es wurden auch Experimente zu Histologie, Immunhistochemie, Röntgenklein- und ‑weitwinkelstreuung und Röntgenfluoreszenz durchgeführt, um die XPCI‑CT-Erkenntnisse präzise zu interpretieren und zu ergänzen sowie eine detaillierte strukturelle und chemische Charakterisierung der nachgewiesenen pathologischen Merkmale zu erhalten. Im Allgemeinen wurde durch diesen multitechnischen Ansatz Folgendes ermittelt: i) eine un-terschiedliche Strahlenempfindlichkeit der mit MRT behandelten Gehirnbereiche; ii) Ca- und Fe-Ablagerungen und die Bildung von Hydroxylapatitkristallen; iii) ein ausgedehnter und isolierter Fibrosegehalt. XPCI‑CT-Datensätze des gesamten Organs ermöglichten die Quantifizierung der Volume von Tumoren und Mikroverkalkungen in den behandelten Gehirnen und der Menge des Narbengewebes in bestrahlten Lungen. Dabei wurde die Rolle der XPCI‑CT als virtuelle 3‑D-Histologietechnik für die Nachverfolgung von Ex-vivo-RT‑Auswirkungen als ergänzende Methode für eine präzise volumetrische Untersuchung des normalen und pathologischen Zustands von Gehirnen und Lungen im Kleintiermodell untersucht. Darüber hinaus wird die Technik aufgrund ihrer 3‑D-Fähigkeiten und der Möglichkeit zur virtuellen Navigation in den Proben als Leitfaden und Hilfstool für die herkömmliche Histologie vorgeschlagen, die der Goldstandard für die pathologische Evaluierung ist. Dies markiert einen Meilenstein für die Übernahme der XPCI‑CT in die Pipeline präklinischer Studien und für den Übergang zur In-vivo-XPCI‑CT von behandelten Organen

American Thyroid Association Guide to Investigating Thyroid Hormone Economy and Action in Rodent and Cell Models

Background: An in-depth understanding of the fundamental principles that regulate thyroid hormone homeostasis is critical for the development of new diagnostic and treatment ap-proaches for patients with thyroid disease. Summary: Important clinical practices in use today for the treatment of patients with hypothy-roidism, hyperthyroidism, or thyroid cancer, are the result of laboratory discoveries made by scientists investigating the most basic aspects of thyroid structure and molecular biology. In this document, a panel of experts commissioned by the American Thyroid Association makes a se-ries of recommendations related to the study of thyroid hormone economy and action. These recommendations are intended to promote standardization of study design, which should in turn increase the comparability and reproducibility of experimental findings. Conclusions: It is expected that adherence to these recommendations by investigators in the field will facilitate progress towards a better understanding of the thyroid gland and thyroid hormone dependent processes

Psr1p interacts with SUN/sad1p and EB1/mal3p to establish the bipolar spindle

Regular Abstracts - Sunday Poster Presentations: no. 382During mitosis, interpolar microtubules from two spindle pole bodies (SPBs) interdigitate to create an antiparallel microtubule array for accommodating numerous regulatory proteins. Among these proteins, the kinesin-5 cut7p/Eg5 is the key player responsible for sliding apart antiparallel microtubules and thus helps in establishing the bipolar spindle. At the onset of mitosis, two SPBs are adjacent to one another with most microtubules running nearly parallel toward the nuclear envelope, creating an unfavorable microtubule configuration for the kinesin-5 kinesins. Therefore, how the cell organizes the antiparallel microtubule array in the first place at mitotic onset remains enigmatic. Here, we show that a novel protein psrp1p localizes to the SPB and plays a key role in organizing the antiparallel microtubule array. The absence of psr1+ leads to a transient monopolar spindle and massive chromosome loss. Further functional characterization demonstrates that psr1p is recruited to the SPB through interaction with the conserved SUN protein sad1p and that psr1p physically interacts with the conserved microtubule plus tip protein mal3p/EB1. These results suggest a model that psr1p serves as a linking protein between sad1p/SUN and mal3p/EB1 to allow microtubule plus ends to be coupled to the SPBs for organization of an antiparallel microtubule array. Thus, we conclude that psr1p is involved in organizing the antiparallel microtubule array in the first place at mitosis onset by interaction with SUN/sad1p and EB1/mal3p, thereby establishing the bipolar spindle.postprin